> ## Documentation Index > Fetch the complete documentation index at: https://docs.open-metadata.org/llms.txt > Use this file to discover all available pages before exploring further. # Run the Glue Pipeline Connector Externally > Use the YAML config for Glue pipeline ingestion to define metadata patterns, connection parameters, and lineage capture logic. export const ConnectorDetailsHeader = ({name, icon, stage, availableFeatures, unavailableFeatures = [], availableFeaturesCollate = []}) => { const showSubHeading = availableFeatures?.length > 0 || unavailableFeatures?.length > 0 || availableFeaturesCollate?.length > 0; const totalAvailableFeatures = [...availableFeatures || [], ...availableFeaturesCollate || []]; return

{icon &&

}

{name}

{stage}

{showSubHeading &&

Feature List

{totalAvailableFeatures.map(feature =>

✓ {feature}

)} {unavailableFeatures.map(feature =>

✕ {feature}

)}

}

; }; export const CodePanel = ({children, fileName = 'config.yaml', showLineNumbers = false}) => { const codePanelRef = useRef(null); const codeContentRef = useRef(null); const isProgrammaticScroll = useRef(false); const hoverTimeout = useRef(null); useEffect(() => { let tries = 0; const wrapLines = () => { const root = codeContentRef.current; if (!root) return; const pres = Array.from(root.querySelectorAll('pre')); if (!pres.length) { if (tries++ < 20) requestAnimationFrame(wrapLines); return; } let globalLine = 1; pres.forEach(pre => { const code = pre.querySelector('code') || pre; if (!code || code.dataset.wrapped === 'true') return; const raw = code.textContent || ''; let lines = raw.split('\n'); while (lines[0] === '') lines.shift(); while (lines[lines.length - 1] === '') lines.pop(); code.innerHTML = lines.map(line => { const ln = globalLine++; const num = showLineNumbers ? `${ln}` : ''; const safe = line.replace(//g, '>') || ' '; return `${num}${safe}`; }).join(''); code.dataset.wrapped = 'true'; }); }; wrapLines(); }, [children, showLineNumbers]); useEffect(() => { const panel = codePanelRef.current; const content = codeContentRef.current; if (!panel || !content) return; const waitForLines = () => { const codeLines = content.querySelectorAll('.code-line'); if (!codeLines.length) { requestAnimationFrame(waitForLines); return; } setupHighlighting(codeLines); }; const setupHighlighting = codeLines => { const layout = panel.closest('.split-layout'); const sections = layout.querySelectorAll('.content-section'); const parseLines = str => { if (!str) return []; const out = []; str.split(',').forEach(p => { if (p.includes('-')) { const [s, e] = p.split('-').map(Number); for (let i = s; i <= e; i++) out.push(i); } else { const n = Number(p); if (!isNaN(n)) out.push(n); } }); return out; }; const clearHighlight = () => { codeLines.forEach(l => l.classList.remove('highlighted')); }; const highlight = lines => { clearHighlight(); lines.forEach(n => { const el = content.querySelector(`.code-line[data-line="${n}"]`); if (el) el.classList.add('highlighted'); }); }; const scrollToLines = lines => { if (!lines.length) return; const first = lines[0]; const targetLine = lines.length > 1 ? first : lines[0]; const el = content.querySelector(`.code-line[data-line="${targetLine}"]`); if (!el) return; isProgrammaticScroll.current = true; const containerRect = content.getBoundingClientRect(); const elRect = el.getBoundingClientRect(); const offset = elRect.top - containerRect.top + content.scrollTop; const TOP_PADDING = 16; content.scrollTo({ top: Math.max(offset - TOP_PADDING, 0), behavior: 'smooth' }); setTimeout(() => { isProgrammaticScroll.current = false; }, 200); }; const activate = (section, scroll) => { if (section.classList.contains('active')) return; sections.forEach(s => s.classList.remove('active')); section.classList.add('active'); const lines = parseLines(section.dataset.lines); highlight(lines); if (scroll) scrollToLines(lines); }; const observer = new IntersectionObserver(entries => { if (isProgrammaticScroll.current) return; entries.forEach(e => { if (e.isIntersecting) activate(e.target, false); }); }, { threshold: 0.3, rootMargin: '-80px 0px -40% 0px' }); sections.forEach(section => { observer.observe(section); section.addEventListener('click', () => activate(section, true)); section.addEventListener('mouseenter', () => { clearTimeout(hoverTimeout.current); hoverTimeout.current = setTimeout(() => activate(section, true), 80); }); }); if (sections[0]) activate(sections[0], false); }; waitForLines(); }, []); const handleCopy = e => { const btn = e.currentTarget; const codeLines = codeContentRef.current?.querySelectorAll('.code-line'); if (!codeLines || codeLines.length === 0) return; const text = Array.from(codeLines).map(line => { const clone = line.cloneNode(true); const lineNumber = clone.querySelector('.line-number'); if (lineNumber) lineNumber.remove(); return clone.textContent; }).join('\n'); if (!text) return; navigator.clipboard.writeText(text).then(() => { btn.dataset.copied = 'true'; setTimeout(() => btn.dataset.copied = 'false', 1500); }); }; return

{fileName}

{children}

; }; export const ContentSection = ({id, title, lines, children}) =>

{title &&

{title}

} {children}

; export const ContentPanel = ({children}) =>

{children}

; export const CodePreview = ({children}) => { const [instanceId] = useState(() => `preview-${Math.random().toString(36).slice(2)}`); useEffect(() => { const nav = document.querySelector('nav') || document.querySelector('header') || document.querySelector('[class*="nav"]'); if (nav) { document.documentElement.style.setProperty('--navbar-height', `${nav.offsetHeight}px`); } }, []); return

{children}

; }; In this section, we provide guides and references to use the Glue connector. Configure and schedule Glue metadata and profiler workflows from the OpenMetadata UI: * [Requirements](#requirements) * [Metadata Ingestion](#metadata-ingestion) ## How to Run the Connector Externally To run the Ingestion via the UI you'll need to use the OpenMetadata Ingestion Container, which comes shipped with custom Airflow plugins to handle the workflow deployment. If, instead, you want to manage your workflows externally on your preferred orchestrator, you can check the following docs to run the Ingestion Framework **anywhere**. Get more information about running the Ingestion Framework Externally ## Requirements The Glue connector ingests metadata through AWS [Boto3](https://boto3.amazonaws.com/v1/documentation/api/latest/reference/services/glue.html) Client. We will ingest Workflows, its jobs and their run status. The user must have the following permissions for the ingestion to run successfully: * `glue:ListWorkflows` * `glue:GetWorkflow` * `glue:GetJobRuns` ### Python Requirements We have support for Python versions **3.9-3.11** To run the Glue ingestion, you will need to install: ```bash theme={null} pip3 install "openmetadata-ingestion[glue]" ``` ## Metadata Ingestion All connectors are defined as JSON Schemas. [Here](https://github.com/open-metadata/OpenMetadata/blob/main/openmetadata-spec/src/main/resources/json/schema/entity/services/connections/database/glueConnection.json) you can find the structure to create a connection to Glue. In order to create and run a Metadata Ingestion workflow, we will follow the steps to create a YAML configuration able to connect to the source, process the Entities if needed, and reach the OpenMetadata server. The workflow is modeled around the following [JSON Schema](https://github.com/open-metadata/OpenMetadata/blob/main/openmetadata-spec/src/main/resources/json/schema/metadataIngestion/workflow.json) ### 1. Define the YAML Config This is a sample config for Glue: #### Source Configuration - Service Connection AWS Access Key Credentials **awsAccessKeyId** and **awsSecretAccessKey** are used to authenticate and authorize programmatic requests to AWS services. An access key consists of: * **Access Key ID** (for example, `AKIAIOSFODNN7EXAMPLE`) * **Secret Access Key** (for example, `wJalrXUtnFEMI/K7MDENG/bPxRfiCYEXAMPLEKEY`) Both values must be provided together when using static credentials. For more information, see [Managing access keys](https://docs.aws.amazon.com/IAM/latest/UserGuide/id_credentials_access-keys.html). AWS Session Token **awsSessionToken** is required when using **temporary security credentials**, such as those obtained via AWS STS. The session token must be provided along with the access key ID and secret access key for the duration of the session. AWS Region **awsRegion** specifies the AWS Region where the target service is deployed (for example, `us-east-1`). This is the **only required parameter** when configuring an AWS connection. Other credentials can be resolved automatically using environment variables, AWS profiles, or IAM roles. Learn more in the [AWS Regions and Availability Zones documentation](https://docs.aws.amazon.com/AmazonRDS/latest/UserGuide/Concepts.RegionsAndAvailabilityZones.html). Custom Endpoint URL **endPointURL** is an optional custom endpoint used to connect to an AWS service. You may want to specify this when: * Using VPC endpoints * Connecting to local or AWS-compatible services * Overriding the default regional endpoint See [AWS service endpoints](https://docs.aws.amazon.com/general/latest/gr/rande.html) for details. AWS Profile Name **profileName** specifies the AWS CLI profile to use for authentication. Profiles store credentials and configuration in AWS config files. If not specified, the `default` profile is used. Learn more about [Named profiles for the AWS CLI](https://docs.aws.amazon.com/cli/latest/userguide/cli-configure-profiles.html). Assume Role ARN **assumeRoleArn** is the Amazon Resource Name (ARN) of the IAM role to assume. This is commonly used for: * Cross-account access * Delegated permissions * Enhanced security setups This field is **required** when using Assume Role authentication. See the [AssumeRole API reference](https://docs.aws.amazon.com/STS/latest/APIReference/API_AssumeRole.html). Assume Role Session Name **assumeRoleSessionName** identifies the assumed role session. This value helps uniquely identify a session when the same role is assumed multiple times or by different principals. If not provided, the default value `OpenMetadataSession` is used. Assume Role Source Identity **assumeRoleSourceIdentity** is an optional source identity passed when assuming a role. This value is recorded in AWS CloudTrail logs and can be used to trace actions performed using the assumed role. See [Source Identity in AssumeRole](https://docs.aws.amazon.com/STS/latest/APIReference/API_AssumeRole.html). #### Source Configuration - Source Config The `sourceConfig` is defined [here](https://github.com/open-metadata/OpenMetadata/blob/main/openmetadata-spec/src/main/resources/json/schema/metadataIngestion/pipelineServiceMetadataPipeline.json):

**dbServiceNames**: Database Service Name for the creation of lineage, if the source supports it.

**includeTags**: Set the 'Include Tags' toggle to control whether to include tags as part of metadata ingestion.

**includeUnDeployedPipelines**: Set the 'Include UnDeployed Pipelines' toggle to control whether to include un-deployed pipelines as part of metadata ingestion. By default it is set to `true`

**markDeletedPipelines**: Set the Mark Deleted Pipelines toggle to flag pipelines as soft-deleted if they are not present anymore in the source system.

**pipelineFilterPattern** and **chartFilterPattern**: Note that the `pipelineFilterPattern` and `chartFilterPattern` both support regex as include or exclude.

**includeOwners**: Set the 'Include Owners' toggle to control whether to include owners to the ingested entity if the owner email matches with a user stored in the OM server as part of metadata ingestion. If the ingested entity already exists and has an owner, the owner will not be overwritten.It supports boolean values either `true` or `false`.

**overrideLineage**: Set the 'Override Lineage' toggle to control whether to override the existing lineage. It supports boolean values either `true` or `false`.

**overrideMetadata**: Set the 'Override Metadata' toggle to control whether to override the existing metadata in the OpenMetadata server with the metadata fetched from the source. If the toggle is set to true, the metadata fetched from the source will override the existing metadata in the OpenMetadata server. If the toggle is set to false, the metadata fetched from the source will not override the existing metadata in the OpenMetadata server. This is applicable for fields like description, tags, owner and displayName. It supports boolean values either `true` or `false`.

To send the metadata to OpenMetadata, it needs to be specified as `type: metadata-rest`.

The main property here is the `openMetadataServerConfig`, where you can define the host and security provider of your OpenMetadata installation.

**Logger Level** You can specify the `loggerLevel` depending on your needs. If you are trying to troubleshoot an ingestion, running with `DEBUG` will give you far more traces for identifying issues.

**JWT Token** JWT tokens will allow your clients to authenticate against the OpenMetadata server. To enable JWT Tokens, you will get more details [here](/deployment/security/enable-jwt-tokens). You can refer to the JWT Troubleshooting section [link](/deployment/security/jwt-troubleshooting) for any issues in your JWT configuration.

**Store Service Connection** If set to `true` (default), we will store the sensitive information either encrypted via the Fernet Key in the database or externally, if you have configured any [Secrets Manager](/deployment/secrets-manager). If set to `false`, the service will be created, but the service connection information will only be used by the Ingestion Framework at runtime, and won't be sent to the OpenMetadata server.

**SSL Configuration** If you have added SSL to the [OpenMetadata server](/deployment/security/enable-ssl), then you will need to handle the certificates when running the ingestion too. You can either set `verifySSL` to `ignore`, or have it as `validate`, which will require you to set the `sslConfig.caCertificate` with a local path where your ingestion runs that points to the server certificate file. Find more information on how to troubleshoot SSL issues [here](/deployment/security/enable-ssl/ssl-troubleshooting).

**ingestionPipelineFQN** Fully qualified name of ingestion pipeline, used to identify the current ingestion pipeline.

```yaml theme={null} source: type: gluepipeline serviceName: local_glue serviceConnection: config: type: GluePipeline awsConfig: ``` ```yaml theme={null} sourceConfig: config: type: PipelineMetadata # lineageInformation: # dbServiceNames: [] # storageServiceNames: [] # markDeletedPipelines: True # includeTags: True # includeLineage: true # includeUnDeployedPipelines: true # pipelineFilterPattern: # includes: # - pipeline1 # - pipeline2 # excludes: # - pipeline3 # - pipeline4 # includeOwners: true # false # overrideLineage: false # true # overrideMetadata: false # true ``` ```yaml theme={null} sink: type: metadata-rest config: {} ``` ```yaml theme={null} workflowConfig: loggerLevel: INFO # DEBUG, INFO, WARNING or ERROR openMetadataServerConfig: hostPort: "http://localhost:8585/api" authProvider: openmetadata securityConfig: jwtToken: "{bot_jwt_token}" ## Store the service Connection information storeServiceConnection: true # false ## Secrets Manager Configuration # secretsManagerProvider: aws, azure or noop # secretsManagerLoader: airflow or env ## If SSL, fill the following # verifySSL: validate # or ignore # sslConfig: # caCertificate: /local/path/to/certificate # ingestionPipelineFQN: . ## e.g., "my_redshift.metadata" ``` ### 2. Run with the CLI First, we will need to save the YAML file. Afterward, and with all requirements installed, we can run: ```bash theme={null} metadata ingest -c ``` Note that from connector to connector, this recipe will always be the same. By updating the YAML configuration, you will be able to extract metadata from different sources.