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WiseTime SQL Connector

The WiseTime SQL Connector connects WiseTime to SQL databases and will upsert a new WiseTime tag whenever a new entity is discovered using the configured SQL.

The WiseTime SQL Connector can also sync activity types to WiseTime if configured.

In order to use the WiseTime SQL Connector, you will need a WiseTime Connect API key. The WiseTime SQL Connector runs as a Docker container and is easy to set up and operate.

Database Permissions Requirements

The database user that the connector uses (see below JDBC_USER variable) requires read access to the tables that the SQL attempts to read from.

Configuration

Configuration is done through environment variables. The following configuration options are required.

Environment Variable Description
API_KEY Your WiseTime Connect API Key
TAG_UPSERT_PATH The tag folder path to use for tags
TAG_SQL_FILE The path to a YAML configuration file containing the SQL queries to run to detect new tags and keywords to be upserted to WiseTime. The connector will watch the file for updates and is able to switch to the new queries as the file is updated, without restarting the connector. See below for file format.
JDBC_URL The JDBC URL for your database
JDBC_USER Username to use to connect to the database
JDBC_PASSWORD Password to use to connect to the database

TAG_SQL_FILE Requirements

The yaml configuration file expects one or more SQL queries to be provided, each labelled with a unique name. Here's a sample TAG_SQL_FILE:

name: cases
initialSyncMarker: 2001-01-01T00:00:00
skippedIds:
  - P01003789
  - P1025477
sql: >
  SELECT TOP 100
  [IRN] as [id],
  [IRN] AS [tag_name],
  [URL] AS [url],
  [EBILLREF] AS [external_id],
  [IRN] AS [additional_keyword],
  [TITLE] AS [tag_description],
  (SELECT
                 [CLIENT_NAME] as Client,
                 [PROJECT_NAME] as Project
               FROM [dbo].[PROJECTS] 
               WHERE [dbo].[PROJECTS].[IRN] = [dbo].[CASES].[IRN]
               FOR JSON PATH, WITHOUT_ARRAY_WRAPPER  
  ) AS [tag_metadata],   
  [DATE_UPDATED] AS [sync_marker]
  FROM [dbo].[CASES]
  WHERE [DATE_UPDATED] >= :previous_sync_marker
  AND [IRN] NOT IN (:skipped_ids)
  ORDER BY [DATE_UPDATED] ASC;

---
name: keywords
initialSyncMarker: 0
skippedIds: 0
sql: >
  SELECT TOP 100
  [PRJ_ID] AS [id],
  [IRN] AS [tag_name],
  CONCAT('FID', [PRJ_ID]) AS [additional_keyword],
  [URL] AS [url],
  [EBILLREF] AS [external_id],
  [DESCRIPTION] AS [tag_description],
  (SELECT 
     [CLIENT_NAME] as Client,
     [PROJECT_NAME] as Project
      FROM [dbo].[META_STORE] 
      WHERE [dbo].[META_STORE].[IRN] = [dbo].[PROJECTS].[IRN]
      FOR JSON PATH, WITHOUT_ARRAY_WRAPPER    
  ) AS [tag_metadata], 
  [PRJ_ID] AS [sync_marker]
  FROM [dbo].[PROJECTS]
  WHERE [PRJ_ID] >= :previous_sync_marker
  AND [PRJ_ID] NOT IN (:skipped_ids)
  ORDER BY [PRJ_ID] ASC;
continuousResync: no

In the above example, we have provided two queries, named cases and keywords. The connector will run the queries and upsert a tag in WiseTime for each record found. Starting from the top of the configuration file, each query is run repeatedly until there are no more records before moving on to the next query. This is behaviour is especially desirable when doing initial imports of a large number of tags. In this example we would prefer to import all cases first before moving on to the secondary task of detecting keywords.

Selecting an empty string for a field lets the connector know that we don't want to overwrite the field during upsert if a tag already exists. For example, when sending keywords to WiseTime via the second query, we don't want to change the current tag description.

The initialSyncMarker configuration is required and specifies the first value to be used for :previous_sync_marker.

The default sync behaviour of the of the connector is to detect all unsynced tags and sync them as fast as possible with WiseTime until there are no more tags detected by a query. In addition to this fast sync, a slow continuous sync can be configured for each query. The slow sync will sync one batch every 5 minutes. The continuousResync configuration enables or disables a slow resync that runs continuously and resets the sync marker when no more records are found. I.e. the connector resyncs from the start as it reaches the end.

Selected Fields

The TAG_SQL must select the relevant information as id, tag_name, additional_keyword, tag_description and sync_marker. The connector expects these names in the result set. The connector uses sync_marker to remember what tags it has already upserted. The following table explains how each selected field is used by the connector.

Field Explanation
id Used to perform deduplication during sync when the sync_marker is not unique
tag_name Used as the tag name when creating a tag for the record
url Not Required. If present will be used by Wisetime frontend as a link to the external system
external_id Not required. id of the activity in the external system
additional_keyword Used as the keyword to add to the tag during upsert. Previous keywords are not removed if the tag already exists.
tag_description Used as the tag description when creating the tag. This description will be searchable in the WiseTime Console UI. If empty, will not overwrite an existing description when upserting tag.
sync_marker Used as the sync position marker so that the connector remembers which records it has already synced. Should be comparable.
tag_metadata Not Required. Used as the tag metadata. The metadata represents a map of key-value pairs that will be recorded against the tag, eg. {"url":"http://test.instance/P12012123GBT1", "tag type 1":"Patent", "tag type 2":"Great Britain", "tag type 3":"Divisional"}.

Tag metadata

The metadata represents a map of key-value pairs that will be recorded against the tag. This is essentially a JSON object. In the examples above it is built using a select statement with FOR JSON PATH, WITHOUT_ARRAY_WRAPPER in the end. To understand how it works lets have a look at some more detailed examples.

Let's assume that we have two tables: PROJECT and CASES.

PROJECTS

IRN CLIENT_NAME PROJECT_NAME PROJECT_DESCRIPTION URL
P1000 CLIENT 1 PROJECT 1 Project description 1 http://www.google.com
P2000 CLIENT 2 PROJECT 2 Project description 2 http://www.google.com
P3000 CLIENT 3 PROJECT 3 Project description 3 http://www.google.com
P4000 CLIENT 4 PROJECT 4 Project description 4 http://www.google.com
P5000 CLIENT 5 PROJECT 5 Project description 5 http://www.google.com

CASES

IRN TITLE DESCRIPTION DATE_UPDATED
P1000 CASE 1 DESCRIPTION 1 01.01.2020
P2000 CASE 2 DESCRIPTION 2 02.01.2020
P3000 CASE 3 DESCRIPTION 3 03.01.2020
P4000 CASE 4 DESCRIPTION 4 04.01.2020
P5000 CASE 5 DESCRIPTION 5 05.01.2020
SELECT
     [CLIENT_NAME] as Client,
     [PROJECT_NAME] as Project,
     [PROJECT_DESCRIPTION] as Description
    FROM [PROJECTS] 
    FOR JSON PATH, WITHOUT_ARRAY_WRAPPER     

This select will return a set of json string objects

{ "Client": "CLIENT 1", "Project":"PROJECT 1", "Description":"Project description 1"},
{ "Client": "CLIENT 2","Project":"PROJECT 2",  "Description":"Project description 2"},
{ "Client": "CLIENT 3", "Project":"PROJECT 3", "Description":"Project description 3"},
{ "Client": "CLIENT 4", "Project":"PROJECT 4", "Description":"Project description 4"},
{ "Client": "CLIENT 5", "Project":"PROJECT 5", "Description":"Project description 5"},

These objects will be transformed into three metadata tags Client, Project, Description. But we have 5 records in database. It means that 4 records will be overridden by the record retrieved last. To avoid such a situation we should clearly indicate which record should be used.

For example

SELECT TOP 100
  [IRN] as [id],
  [IRN] AS [tag_name],
  [EBILLREF] AS [external_id],
  [IRN] AS [additional_keyword],
  [TITLE] AS [tag_description],
  (SELECT
      [CLIENT_NAME] as Client,
      [PROJECT_NAME] as Project
      FROM [dbo].[PROJECTS] 
      WHERE [dbo].[PROJECTS].[IRN] = [dbo].[CASES].[IRN]
      FOR JSON PATH, WITHOUT_ARRAY_WRAPPER  
  ) AS [tag_metadata],   
  [DATE_UPDATED] AS [sync_marker]
  FROM [dbo].[CASES]
  ORDER BY [DATE_UPDATED] ASC;

We will get the following set of values

id tag_name external_id additional_keyword tag_description tag_metadata date_updated
P1000 P1000 E1000 P1000 CASE 1 { "Client": "CLIENT 1", "Project":"PROJECT 1"} 01.01.2020
P2000 P2000 E2000 P1000 CASE 2 { "Client": "CLIENT 2", "Project":"PROJECT 2"} 02.01.2020
P3000 P3000 E3000 P1000 CASE 3 { "Client": "CLIENT 3", "Project":"PROJECT 3"} 03.01.2020
P4000 P4000 E4000 P1000 CASE 4 { "Client": "CLIENT 4", "Project":"PROJECT 4"} 04.01.2020
P5000 P5000 E5000 P1000 CASE 5 { "Client": "CLIENT 5", "Project":"PROJECT 5"} 05.01.2020

The similar approach can be used for Postgres database. The query below will return the exactly same result.

SELECT 
  IRN as id,
  IRN AS tag_name,
  IRN AS external_id,
  URL AS url,
  IRN AS additional_keyword,
  TITLE AS tag_description,
  (select row_to_json(t)
      from (
              SELECT
                CLIENT_NAME as Client,
                PROJECT_NAME as Project
             FROM dbo.PROJECTS 
             WHERE dbo.PROJECTS.IRN = dbo.CASES.IRN             
           ) t 
  ) AS tag_metadata,   
  DATE_UPDATED AS sync_marker
  FROM dbo.CASES
  ORDER BY DATE_UPDATED ASC LIMIT 100;

The metadata can also be retrieved from multiple tables. Let's assume that we have another table called TASKS that also contains some tag metadata.

IRN TEAM_NAME TASK_NAME TASK_DESCRIPTION DATE
P1000 TEAM 1 TASK 1 DESCRIPTION 1 01.01.2020
P2000 TEAM 2 TASK 2 DESCRIPTION 2 02.01.2020
P3000 TEAM 3 TASK 3 DESCRIPTION 3 03.01.2020
P4000 TEAM 4 TASK 4 DESCRIPTION 4 04.01.2020
P5000 TEAM 5 TASK 5 DESCRIPTION 5 05.01.2020

Here is an example how we can build tag metadata from multiple tables using INNER JOIN

SELECT TOP 100
  [IRN] as [id],
  [IRN] AS [tag_name],
  [EBILLREF] AS [external_id],
  [URL] AS [url],
  [IRN] AS [additional_keyword],
  [TITLE] AS [tag_description],
  (SELECT
     [p].[CLIENT_NAME] as Client,
     [p].[PROJECT_NAME] as Project,
     [t].[TEAM_NAME] as Team,
     [t].[TASK_NAME]  as Task
     FROM [dbo].[PROJECTS] p
     INNER JOIN [dbo].[TASKS] t 
     ON [dbo].[PROJECTS].[IRN]= [dbo].[TASKS].[IRN]
     WHERE [dbo].[PROJECTS].[IRN] = [dbo].[CASES].[IRN]
     FOR JSON PATH, WITHOUT_ARRAY_WRAPPER
  ) AS [tag_metadata],   
  [DATE_UPDATED] AS [sync_marker]
  FROM [dbo].[CASES]
  ORDER BY [DATE_UPDATED] ASC;

This query will produce following results

id tag_name external_id url additional_keyword tag_description tag_metadata date_updated
P1000 P1000 E1000 http://www.google.com P1000 CASE 1 { "Client": "CLIENT 1", "Project":"PROJECT 1","Team":"TEAM 1","Task":"TASK 1"} 01.01.2020
P2000 P2000 E2000 http://www.google.com P1000 CASE 2 { "Client": "CLIENT 2", "Project":"PROJECT 2","Team":"TEAM 2","Task":"TASK 2"} 02.01.2020
P3000 P3000 E3000 http://www.google.com P1000 CASE 3 { "Client": "CLIENT 3", "Project":"PROJECT 3","Team":"TEAM 3","Task":"TASK 3"} 03.01.2020
P4000 P4000 E4000 http://www.google.com P1000 CASE 4 { "Client": "CLIENT 4", "Project":"PROJECT 4","Team":"TEAM 4","Task":"TASK 4"} 04.01.2020
P5000 P5000 E5000 http://www.google.com P1000 CASE 5 { "Client": "CLIENT 5", "Project":"PROJECT 5","Team":"TEAM 5","Task":"TASK 5"} 05.01.2020

Placeholder Parameters

The SQL queries are parametised and the following placeholder parameters are required. They must be provided verbatim in each query.

Placeholder Parameter Explanation
:previous_sync_marker The connector will inject its current sync marker value at this position in the SQL query. This is how the connector skips over records that it has already synced.
:skipped_ids The connector will inject a list of IDs to skip plus previously synced IDs as a CSV using this placeholder parameter. This is how the connector performs deduplication in the event that the sync marker is non-unique, e.g. when a datetime type is used as the sync marker.

For cases in the above example, because the DATE_UPDATED column is a DateTime field, we use the comparison operator >= in the WHERE clause. The connector will take care of deduplication before upserting tags to WiseTime. In any case, upserting a tag is an idempotent operation.

For the keywords query in the above example, if the sync_marker field is an auto incremented integer field, then we can simply use > as the comparison operator. In this case, the clause AND [PRJ_ID] NOT IN (:skipped_ids) is redundant. However, we must still use the placeholder because the connector expects it when it generates the query.

Tag SQL Configuration Hot Reloading

The connector will detect changes to the tag SQL configuration file and automatically use the updated configuration. Sync state is reset and sync restarted if any of the following fields have changed for a configured query:

  • initialSyncMarker
  • skippedIds
  • sql
  • continuousResync

Optional Configuration Parameters

The following configuration parameters are optional.

Environment Variable Description
TAG_SCAN If unset, this defaults to ENABLED: Set mode for scanning external system for tags and uploading to WiseTime. Possible values: ENABLED, DISABLED.
ACTIVITY_TYPE_SCAN If unset, this defaults to DISABLED: Set mode for scanning external system for activity types and uploading to WiseTime. Possible values: ENABLED, DISABLED.
ACTIVITY_TYPE_SQL_FILE The path to a YAML configuration file containing the SQL queries to run to fetch all activity types to be propagated to WiseTime. The connector will watch the file for updates and is able to switch to the new queries as the file is updated, without restarting the connector. See below for file format.
DATA_DIR If set, the connector will use the directory as the location for storing data to keep track on the cases and projects it has synced. By default, WiseTime SQL Connector will create a temporary dir under /tmp as its data storage.
LOG_LEVEL Define log level. Available values are: TRACE, DEBUG, INFO, WARN, ERROR and OFF. Default is INFO.

ACTIVITY_TYPE_SQL_FILE Requirements

The yaml configuration file expects single SQL query to be provided.

Selecting an empty list will disable all the existing WiseTime activity types.

If there are any activity types you would like to skip syncing, you can use skippedCodes property. It's required in case of using sync_marker.

WiseTime supports 2 ways of activity types sync:

  • Using sync_marker
  • All in one sync

Activity type sync using sync_marker

This is a preferable way of activity type sync as it allows syncing activity types in batches, and do a slow loop sync. It can be used if there is any NOT updatable column or column updatable increasingly only. It should be used as sync_marker (e.g. updated_at, ID). The query must be sorted by sync_marker (e.g. ORDER BY [sync_marker]). The initialSyncMarker is required and specifies the first value to be used for :previous_sync_marker.

Here's an example:

initialSyncMarker: 0
skippedCodes:
  - 23456
sql: >
  SELECT TOP 100
  [ACTIVITYCODE] AS [code],
  [UPDATED_AT] AS [sync_marker],
  [ACTIVITYNAME] AS [label]
  [ACTIVITYDESCRIPTION] AS [description]
  FROM [dbo].[TEST_ACTIVITYCODES]
  WHERE [ACTIVITYCODE] NOT IN (:skipped_codes) AND [UPDATED_AT] >= :previous_sync_marker
  ORDER BY [sync_marker];

All in one sync

If there's no column you can use as sync_marker you should avoid it. You should also avoid using TOP/LIMIT in your query so connector will fetch all the activity types on each run and sync them if any has been changed/created/deleted since previous sync.

It's highly recommended to use ORDER BY in your query to reduce the potential load on WiseTime as we use a caching mechanism that is order-dependent

Here's an example:

sql: >
  SELECT
  [ACTIVITYCODE] AS [code],
  [ACTIVITYNAME] AS [label]
  [ACTIVITYDESCRIPTION] AS [description]
  FROM [dbo].[TEST_ACTIVITYCODES];
  ORDER BY [code];

Selected Fields

The ACTIVITY_TYPE_SQL_FILE must select the relevant information as code, label and description of the activity type.

Field Explanation
code Will be used as activity type code during time posting
label Used as the WiseTime console label of the created activity type
description Used as the WiseTime console description of the created activity type
sync_marker Used as the sync position marker so that the connector remembers which records it has already synced. Should be comparable. Should NOT be updatable if it's not a date.

Running the WiseTime SQL Connector

The easiest way to run the SQL Connector is using Docker. For example:

docker run -d \
    --restart=unless-stopped \
    -e API_KEY=yourwisetimeapikey \
    -e TAG_UPSERT_PATH=/My Connected System/ \
    -e TAG_SQL_FILE=/connector/tag_sql.yaml \
    -e ACTIVITY_TYPE_SQL_FILE=/connector/activity_type_sql.yaml \
    -e JDBC_URL="jdbc:sqlserver://HOST:PORT;databaseName=DATABASE_NAME;ssl=request;useCursors=true" \
    -e JDBC_USER=dbuser \
    -e JDBC_PASSWORD=dbpass \
    wisetime/wisetime-sql-connector

The SQL connector runs self-checks to determine whether it is healthy. If health check fails, the connector will shutdown. This gives us a chance to automatically re-initialise the application through the Docker restart policy.

Building

FIXME: There is no 'docker' target in Makefile, also no Dockerfile, how can we run make docker? The blow instructions are out of date?

To build a Docker image of the WiseTime SQL Connector, run:

make docker

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Connects a SQL database to WiseTime for automatic tag creation

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