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aws-xray-sdk-core
Advanced tools
The aws-xray-sdk-core package is a library for AWS X-Ray, which helps developers analyze and debug production, distributed applications, such as those built using a microservices architecture. With AWS X-Ray, you can trace requests as they travel through your application, gain insights into performance bottlenecks, and identify errors.
Tracing HTTP Requests
This feature allows you to trace HTTP requests made by your application. The `captureHTTPs` method wraps the HTTP module to automatically capture and record data about outgoing HTTP requests.
const AWSXRay = require('aws-xray-sdk-core');
const http = AWSXRay.captureHTTPs(require('http'));
http.get('http://www.example.com', (res) => {
res.on('data', (chunk) => {
console.log(`BODY: ${chunk}`);
});
res.on('end', () => {
console.log('No more data in response.');
});
});
Tracing AWS SDK Calls
This feature allows you to trace AWS SDK calls. The `captureAWS` method wraps the AWS SDK to automatically capture and record data about AWS service calls made by your application.
const AWSXRay = require('aws-xray-sdk-core');
const AWS = AWSXRay.captureAWS(require('aws-sdk'));
const s3 = new AWS.S3();
s3.listBuckets((err, data) => {
if (err) console.log(err, err.stack);
else console.log(data);
});
Custom Subsegments
This feature allows you to create custom subsegments to add more detailed tracing information. The `captureFunc` method creates a subsegment where you can add annotations and metadata to provide more context about the operation being traced.
const AWSXRay = require('aws-xray-sdk-core');
AWSXRay.captureFunc('annotations', function(subsegment) {
subsegment.addAnnotation('userId', '12345');
subsegment.addMetadata('key', 'value');
// Your code here
subsegment.close();
});
AWS SDK v2.7.15 or greater if using captureAWS
or captureAWSClient
The AWS X-Ray SDK (the SDK) allows developers to instrument their web applications to automatically record information for incoming and outgoing requests and responses. It can also record local data such as function calls, time, variables (via metadata and annotations), and Amazon EC2, ECS, and Elastic Beanstalk metadata (via plugins). Currently, Express and Restify applications are supported for automatic capturing via middleware. AWS Lambda functions can also be instrumented.
The SDK exposes the Segment and Subsegment objects so you can create your own capturing mechanisms, but a few are supplied. See Capturing Function Calls below.
The AWS X-Ray SDK has two modes: manual
and automatic
.
By default, the SDK is in automatic mode. You can flip the mode of the SDK using the following:
AWSXRay.enableAutomaticMode();
AWSXRay.enableManualMode();
/* see https://github.com/aws/aws-xray-sdk-node/pull/595
for details on using this environment variable
to prevent memory leaks when using manual mode
*/
process.env.AWS_XRAY_MANUAL_MODE = 'true';
Automatic mode is designed for use with Express, Restify, and Lambda applications, but can be used outside of such applications. For more information about developing your own middleware or using automatic mode without middleware, see the developing custom solutions using automatic mode section below.
Automatic mode uses the cls-hooked
package and automatically tracks
the current segment or subsegment when using the built-in capture functions or any
of the aws-xray-sdk modules. Using the built-in capture functions or other aws-xray-sdk modules automatically creates
new subsegments to capture additional data and update the current segment or subsegment on that context.
You can retrieve the current segment or subsegment at any time using the following:
var segment = AWSXRay.getSegment();
Manual mode requires that you pass around the segment reference. See the manual mode examples section for different usages.
Environment variables always override values set in code.
AWS_XRAY_DEBUG_MODE Enables logging of debug messages to console output. Logging to a file is no longer built in. See 'configure logging' below.
AWS_XRAY_MANUAL_MODE For overriding the default automatic mode. See 'Automatic mode'.
AWS_XRAY_TRACING_NAME For overriding the default segment name to use
with the middleware. See 'dynamic and fixed naming modes'.
AWS_XRAY_DAEMON_ADDRESS For setting the daemon address and port.
AWS_XRAY_CONTEXT_MISSING For setting the SDK behavior when trace context is missing. Valid values are 'RUNTIME_ERROR', 'IGNORE_ERROR' or 'LOG_ERROR'. The SDK's default behavior is 'LOG_ERROR'.
AWS_XRAY_LOG_LEVEL Sets a log level for the SDK built in logger. This value is ignored if AWS_XRAY_DEBUG_MODE is set.
AWS_XRAY_COLLECT_SQL_QUERIES Enables SQL query capture (currently only Postgres and MySQL supported)
By default, the SDK expects the daemon to be at 127.0.0.1 (localhost) on port 2000. You can override the address for both UDP and TCP. You can change this via the environment variables listed above, or through code. The same format applies to both.
AWSXRay.setDaemonAddress('hostname:8000');
AWSXRay.setDaemonAddress('186.34.0.23:8082');
AWSXRay.setDaemonAddress('tcp:186.34.0.23:8082, udp:127.0.0.1:3000');
AWSXRay.setDaemonAddress('udp:186.34.0.23:8082, tcp:127.0.0.1:3000');
By default the SDK will log error messages to the console using the standard methods on the console object. The log
level of the built in logger can be set bu using either the AWS_XRAY_DEBUG_MODE
or AWS_XRAY_LOG_LEVEL
environment
variables.
If AWS_XRAY_DEBUG_MODE
is set to a truthy value, e.g. true, then the log level will be set to debug. If
AWS_XRAY_DEBUG_MODE
is not set then AWS_XRAY_LOG_LEVEL
will be used to determine the log level. This variable can
be set to either debug, info, warn, error or silent. Be warned if the log level is set to silent then NO log
messages will be produced. The default log level is error and this will be used if neither environment variable
is set or if an invalid level is specified.
If you wish to provide a different format or destination for the logs then you can provide the SDK with your own implementation of the logger interface as shown below. Any object that implements this interface can be used. This means that many logging libraries, e.g. Winston, could be used and passed to the SDK directly.
// Create your own logger or instantiate one using a library.
var logger = {
error: (message, meta) => { /* logging code */ },
warn: (message, meta) => { /* logging code */ },
info: (message, meta) => { /* logging code */ },
debug: (message, meta) => { /* logging code */ }
}
AWSXRay.setLogger(logger);
If you use your own logger you are responsible for determining the log level as the AWS_XRAY_DEBUG_MODE
and
AWS_XRAY_LOG_LEVEL
only apply to the default logger.
Note that by default the provided logger prefixes each log line with a timestamp and the log level of the message. However this is not the case when using this SDK within an AWS Lambda function. In that scenario the timestamp and level are added by the Lambda runtime instead.
By default, when the X-Ray SDK is operating in automatic mode and attempts to find a segment in the cls-hooked
context but
cannot find one, it throws a runtime error. This behavior can be undesirable when unit testing or doing experimentation.
It can be changed to instead log an error either by using the AWS_XRAY_CONTEXT_MISSING
environment variable documented above, or programatically by calling
AWSXRay.setContextMissingStrategy("LOG_ERROR");
You can also pass in your own function to set custom behavior for handling context missing errors.
AWSXRay.setContextMissingStrategy(myFunction);
When using our supported AWS X-Ray-enabled frameworks, you can configure the rates at which the SDK samples requests to capture. By default the SDK fetches sampling rules from X-Ray service. You can disable it by calling
AWSXRay.middleware.disableCentralizedSampling();
so that the SDK use local rules exclusively. You can also set local sampling rules in case the X-Ray SDK can't reach the back-end service and the service sampling rules expire (TTL is 1 hour). The following shows how to configure local rules.
A local sampling rule defines the rate at which requests are sampled for a particular endpoint, HTTP method, and URL of the incoming request.
In this way, you can change the behavior of sampling using http_method
, host
, url_path
attributes to specify the route, and then
use fixed_target
and rate to determine sampling rates.
Fixed target refers to the maximum number of requests to sample per second. When this threshold is reached, the sampling decision uses the specified percentage (rate) to sample on.
The SDK comes with a default sampling file at /lib/resources/sampling_rules.js
.
You can choose to override this by providing a custom sampling file.
AWSXRay.middleware.setSamplingRules(<path to file>);
AWSXRay.middleware.setSamplingRules(<JSON object>);
A sampling file must have a "default" defined. The default matches all routes as a fallback, if none of the rules match.
{
"rules": [],
"default": {
"fixed_target": 10,
"rate": 0.05
},
"version": 2
}
Order of priority is determined by the spot in the rules array, top being highest priority. The default is always checked last.
Host, URL path, and HTTP method patterns are case insensitive, and use a string with wild cards as the pattern format.
A *
represents any number of characters, while ?
represents a single character. A description is optional.
{
"rules": [
{
"description": "Sign-in request",
"http_method": "GET",
"host": "*.foo.com",
"url_path": "/signin/*",
"fixed_target": 10,
"rate": 0.05
}
],
"default": {
"fixed_target": 10,
"rate": 0.05
},
"version": 2
}
The AWS X-Ray SDK automatically captures data from AWS SDK calls, including service,
operation, start time, end time, and any errors returned.
However, some service operations are allow-listed to capture extra parameters on the request and response.
These are pulled in via a default allow-listing file in the SDK in the aws-xray-sdk-core
package under lib/resources/aws_whitelist.json
.
Each service is allow-listed by the AWS SDK's service identifier
and operation
properties.
request_parameters are properties to capture in the request
request_descriptors are objects to capture, or to process and capture in the request (get_keys, get_count)
response_parameters are properties to capture in the response data
response_descriptors are objects to capture, or to process and capture in the response data (get_keys, get_count)
This is an example document that allow-lists X-Ray to capture the Bucket
and key
request parameters on an s3.getObject call.
{
"services": {
"s3": {
"operations": {
"getObject": {
"request_parameters": [
"Bucket",
"Key"
]
}
}
}
}
}
You can set a custom AWS allow-list using the following:
AWSXRay.setAWSWhitelist(<path to file>); //Replaces the default allow-list with the given custom one
AWSXRay.setAWSWhitelist(<JSON object>);
AWSXRay.appendAWSWhitelist(<path to file>); //Appends to the current allow-list
AWSXRay.appendAWSWhitelist(<JSON object>);
The SDK requires that a default segment name is set when using middleware. If it
isn't set, an error is thrown. You can override this value via the AWS_XRAY_TRACING_NAME
environment variable.
app.use(AWSXRay.express.openSegment('defaultName'));
The SDK defaults to a fixed naming mode. This means that each time a new segment is created for an incoming request, the name of that segment is set to the default name.
In dynamic mode, the segment name can vary between the host header of the request or the default name.
AWSXRay.middleware.enableDynamicNaming(<pattern>);
If no pattern is provided, the host header is used as the segment name. If no host header is present, the default is used.
This is equivalent to using the pattern *
.
If a pattern is provided, in the form of a string with wild cards (ex: *.*.us-east-?.elasticbeanstalk.com
),
the host header of the request is checked against it.
A *
represents any number of characters, while ?
represents a single character.
If the host header is present and matches this pattern, it's used as the segment name.
Otherwise, the default name is used.
By default, the SDK is configured to have a threshold of 100 subsegments per segment. This is because the UDP packet maximum size is ~65 kb, and larger segments might trigger the 'Segment too large to send' error.
To remedy this, the SDK automatically sends the completed subsegments to the daemon when the threshold is breached. Additionally, subsegments that complete when over the threshold automatically send themselves. If a subsegment is sent out of band, it is pruned from the segment object. The full segment is reconstructed on the service side. You can change the threshold as needed.
AWSXRay.setStreamingThreshold(10);
Subsegments can be marked as in_progress
when sent to the daemon. The SDK is telling
the service to anticipate the asynchronous subsegment
to be received out of band when it has completed. When received, the in_progress subsegment
is discarded in favor of the completed subsegment.
AWSXRay.captureFunc<T>(
name: string,
fcn: (subsegment?: Subsegment) => T,
parent?: Segment | Subsegment
): T
AWSXRay.captureFunc
- Takes a function that takes a single subsegment argument. This creates a new nested subsegment and exposes it. The segment
closes automatically when the function finishes executing and returns the result if any. This does not correctly
time functions with asynchronous calls. Instead, use
captureAsyncFunc
.
captureAsyncFunc<T>(
name: string,
fcn: (subsegment?: Subsegment) => T,
parent?: Segment | Subsegment
): T
AWSXRay.captureAsyncFunc
- Takes an async function that takes a single subsegment argument and returns the promise by executing the function.
This creates a new nested subsegment and exposes it.
The segment must be closed using subsegment.close() the asynchronous function completes successfully.
captureCallbackFunc<S extends any[], T>(
name: string,
fcn: (...args: S) => T,
parent?: Segment | Subsegment
): (...args: S) => T
AWSXRay.captureCallbackFunc
- Takes a function to be used as a callback. Useful
for capturing callback information and directly associating it to the call
that generated it. This creates a new nested subsegment and exposes it by appending it onto the arguments used to call the callback. For this reason,
always call your captured callbacks with the full parameter list. The subsegment closes
automatically when the function finishes executing.
If your application isn't using a supported framework, you have to create the new segment and set this on the SDK. You need to create a new context using CLS and store your segment in it so that the SDK can retrieve it for automatic capturing. You can do so by using the CLS namespace object. We expose this via the following API:
AWSXRay.getNamespace();
The cls-hooked
library provides several methods of setting the context. Here is an example usage.
var segment = new AWSXRay.Segment(name, [optional root ID], [optional parent ID]);
var ns = AWSXRay.getNamespace();
ns.run(function () {
AWSXRay.setSegment(segment);
// Requests using AWS SDK, HTTP calls, SQL queries...
segment.close();
});
If you are using a different web framework and want to set up automatic capturing,
the X-Ray SDK provides helper functions under AWSXRay.middleware
.
See the aws-xray-sdk-express module for more information.
For additional information about and examples for using the CLS namespace to create a new context, see: https://github.com/jeff-lewis/cls-hooked.
If you have chained native Promise and you have subsegments generated within those promises, you should consider to run the following code to patch the behavior of CLS on binding X-Ray context to Promise.
AWSXRay.capturePromise();
This will solve the issue where the subsegments within a Promise chain are attached to wrong segments or nested instead of being siblings. For more details on the discussion please see this PR. See the "Capture all outgoing Axios requests" section for full sample code.
To understand X-Ray's integration with Lambda functions, please read the Lambda Developer Guide. Lambda functions are unique environments because a segment is automatically provided in function code once Active Tracing
is enabled for a function. That segment is immutable, however all subsegment operations described below are permitted.
By default in Lambda, the streaming threshold is set to 0 (immediate subsegment streaming), centralized sampling is disabled, automatic mode is enabled, and the daemon address is set by the Lambda runtime.
For an example function, see tracing node.js functions.
This can be used with either automatic or manual mode.
Use the 'npm start' script to enable.
var AWSXRay = require('aws-xray-sdk');
AWSXRay.config([AWSXRay.plugins.EC2Plugin]);
var key = 'hello';
var value = 'there'; // must be string, boolean or finite number
subsegment.addAnnotation(key, value);
var key = 'hello';
var value = 'there';
subsegment.addMetadata(key, value); // default namespace 'default'
subsegment.addMetadata(key, value, 'greeting'); // custom namespace 'greeting'
Note that this operation will not work in Lambda functions, because the segment object is immutable. setUser()
can only be applied to segments, not subsegments.
var user = 'john123';
AWSXRay.getSegment().setUser(user);
var newSubseg = subsegment.addNewSubsegment(name);
// Do something
newSubseg.close();
// Or
var newSubseg = new Subsegment(name);
subsegment.addSubsegment(newSubseg);
// Do something
newSubseg.close();
To modify the sampling decision at the subsegment level, subsegments that inherit the decision of their direct parent (segment or subsegment) can be created using the addNewSubsegment
and addSubsegment
APIs, and unsampled subsegments can be created using the addNewSubsegmentWithoutSampling
and addSubsegmentWithoutSampling
APIs.
The code snippet below demonstrates creating a sampled or unsampled subsegment based on the sampling decision of each SQS message processed by Lambda.
exports.handler = async function(event, context) {
event.Records.forEach(message => {
const { attributes } = message;
let facade = xrayContext.getSegment();
if(SqsMessageHelper.isSampled(message)){
let sampledSubsegment = facade.addNewSubsegment('sqs-subsegment-sampled');
xrayContext.setSegment(sampledSubsegment);
console.log("processing SQS message - sampled");
sampledSubsegment.close();
} else {
let unsampledSubsegment = facade.addNewSubsegmentWithoutSampling('sqs-subsegment-unsampled');
xrayContext.setSegment(unsampledSubsegment);
console.log("processing SQS message - unsampled");
unsampledSubsegment.close();
}
xrayContext.setSegment(facade);
});
return 'Success';
}
The code snippet below demonstrates wrapping a downstream AWS SDK request with an unsampled subsegment.
const { Segment } = require('aws-xray-sdk');
const xray = require('aws-xray-sdk');
// Instrument AWS SDK Clients
const AWS = xray.captureAWS(require('aws-sdk'));
exports.handler = async (event, context) => {
const facade = xray.getSegment();
// Create a not-sampled subsegment, which will coerce the downstream request to be unsampled
const unsampled = facade.addNewSubsegmentWithoutSampling('sqs-subsegment-unsampled');
// Set unsampled subsegment in context
xray.setSegment(unsampled);
try {
const sqs = new AWS.SQS();
const data = await sqs.listQueues().promise();
console.log(data);
} catch (error) {
console.log("retrieveFromSqs error:", error);
throw error;
}
unsampled.close();
return 'Success';
}
This creates 5 nested subsegments on the root segment and captures timing data individually for each subsegment. This example assumes an automatic mode environment.
captureFunc('1', function(subsegment1) {
//Exposing the subsegment in the function is optional, and is listed here as an example
//You can also use:
var subsegment1 = AWSXRay.getSegment();
captureFunc('2', function(subsegment2) {
captureFunc('3', function(subsegment3) {
captureFunc('4', function(subsegment4) {
captureFunc('5', function() {
//exposing the subsegment is optional
res.render('index');
});
});
});
});
});
var host = 'samplego-env.us-east-1.elasticbeanstalk.com';
AWSXRay.captureAsyncFunc('send', function(subsegment) {
//'subsegment' here is the newly created and exposed subsegment for the async
//request, and must be closed manually (this ensures timing data is correct)
sendRequest(host, function() {
console.log("Request sent!");
subsegment.close();
});
});
function sendRequest(host, cb) {
var options = {
host: host,
path: '/',
};
var callback = function(response) {
var str = '';
response.on('data', function (chunk) {
str += chunk;
});
response.on('end', function () {
cb();
});
}
http.request(options, callback).end();
};
This is only available for AWS SDK v2 due to the modular architecture of AWS SDK v3. For more details on the difference between AWS SDK v2 and v3, see this blog post.
var AWS = captureAWS(require('aws-sdk'));
// Create new AWS clients as usual.
AWS SDK v3
import { S3, PutObjectCommand } from '@aws-sdk/client-s3';
const s3 = AWSXRay.captureAWSv3Client(new S3({}));
await s3.send(new PutObjectCommand({
Bucket: bucketName,
Key: keyName,
Body: 'Hello!',
}));
Note: Some TypeScript users may experience a type incompatibility error when patching v3 clients. As a workaround, you can cast the client
to type any
when patching:
import { S3, PutObjectCommand } from '@aws-sdk/client-s3';
const s3 = new S3({});
const s3Patched = AWSXRay.captureAWSv3Client(s3 as any);
AWS SDK v2
var s3 = AWSXRay.captureAWSClient(new AWS.S3());
//Use client as usual
//Be sure any outgoing calls that are dependent on another async
//function are wrapped with captureAsyncFunc, or duplicate segments might leak
AWSXRay.captureHTTPsGlobal(require('http'));
AWSXRay.captureHTTPsGlobal(require('https'));
// Requests with this http client, and any other http/https client including
// those used by third party modules, will now be traced
var http = require('http');
const callback = (subsegment, req, res, err) => {
subsegment.addMetadata('accept', req.getHeader('accept'));
if (err && err.code) {
subsegment.addAnnotation('errorCode', err.code);
}
if (res) {
subsegment.addMetadata('content-type', res.getHeader('content-type'));
}
};
AWSXRay.captureHTTPsGlobal(require('http'), null, callback);
AWSXRay.captureHTTPsGlobal(require('https'), null, callback);
// Requests with this http client, and any other http/https client including
// those used by third party modules, will now be traced
// Additional metadata / annotations can be added in the callback based on
// the request, response and any error
var http = require('http');
//returns a copy of the http module that is patched, can patch https as well
var tracedHttp = AWSXRay.captureHTTPs(require('http'));
var options = {
...
}
tracedHttp.request(options, callback).end();
//Create new requests as usual
//Be sure any outgoing calls that are dependent on another async
//function are wrapped with captureAsyncFunc, or duplicate segments might leak
This sample code works with any promise-based HTTP client.
const AWSXRay = require('aws-xray-sdk');
AWSXRay.captureHTTPsGlobal(require('http'));
AWSXRay.capturePromise();
const AxiosWithXray = require('axios');
Note that in all these examples, a segment must be manually created and closed because they do not use middleware. If you are using middleware, or are on Lambda, the calls to create, close, and flush segments are not necessary.
Here, the root segment is created manually and 5 nested subsegments are attached to it. Note that the parent (sub)segment must be passed to each captured function as the last argument.
var AWSXRay = require('aws-xray-sdk');
AWSXRay.enableManualMode();
var segment = new AWSXRay.Segment('myApplication');
captureFunc('1', function(subsegment1) {
captureFunc('2', function(subsegment2) {
captureFunc('3', function(subsegment3) {
captureFunc('4', function(subsegment4) {
captureFunc('5', function() {
//subsegment need not be exposed here since we're not doing anything with it
console.log('hello world');
}, subsegment4);
}, subsegment3);
}, subsegment2);
}, subsegment1);
}, segment);
segment.close();
segment.flush();
var AWSXRay = require('aws-xray-sdk');
AWSXRay.enableManualMode();
var segment = new AWSXRay.Segment('myApplication');
var host = 'samplego-env.us-east-1.elasticbeanstalk.com';
AWSXRay.captureAsyncFunc('send', function(subsegment) {
sendRequest(host, function() {
console.log("Got response!");
subsegment.close();
}, subsegment);
}, segment);
function sendRequest(host, cb, subsegment) {
var options = {
host: host,
path: '/',
XRaySegment: subsegment //required 'XRaySegment' param
};
var callback = function(response) {
var str = '';
//The whole response has been received, so we just print it out here
//Another chunk of data has been received, so append it to `str`
response.on('data', function (chunk) {
str += chunk;
});
response.on('end', function () {
cb();
});
}
http.request(options, callback).end();
};
AWS SDK v3
You must re-capture the client every time the subsegment is attached to a new parent.
import { S3, PutObjectCommand } from '@aws-sdk/client-s3';
// subsegment is an optional parameter that is required for manual mode
// and can be omitted in automatic mode (e.g. inside a Lambda function).
const s3 = AWSXRay.captureAWSv3Client(new S3({}), subsegment);
await s3.send(new PutObjectCommand({
Bucket: bucketName,
Key: keyName,
Body: 'Hello!',
}));
Note: Some TypeScript users may experience a type incompatibility error when patching v3 clients. As a workaround, you can cast the client
to type any
when patching:
import { S3, PutObjectCommand } from '@aws-sdk/client-s3';
const s3 = new S3({});
const s3Patched = AWSXRay.captureAWSv3Client(s3 as any);
AWS SDK v2
var s3 = AWSXRay.captureAWSClient(new AWS.S3());
var params = {
Bucket: bucketName,
Key: keyName,
Body: 'Hello!',
XRaySegment: subsegment //required 'XRaySegment' param
};
s3.putObject(params, function(err, data) {
// ...
});
This is only available for AWS SDK v2 due to the modular architecture of AWS SDK v3. For more details on the difference between AWS SDK v2 and v3, see this blog post.
var AWS = captureAWS(require('aws-sdk'));
//Create new clients as usual
//Be sure any outgoing calls that are dependent on another async
//function are wrapped, or duplicate segments might leak
var tracedHttp = AWSXRay.captureHTTPs(require('http')); //returns a copy of the http module that is patched, can patch https as well.
...
//Include sub/segment reference in options as 'XRaySegment'
var options = {
...
XRaySegment: subsegment //required 'XRaySegment' param
}
tracedHttp.request(options, callback).end();
FAQs
AWS X-Ray SDK for Javascript
The npm package aws-xray-sdk-core receives a total of 429,307 weekly downloads. As such, aws-xray-sdk-core popularity was classified as popular.
We found that aws-xray-sdk-core demonstrated a healthy version release cadence and project activity because the last version was released less than a year ago. It has 24 open source maintainers collaborating on the project.
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