Dagster’s asset definitions bear several similarities to dbt models. An asset definition contains an asset key, a set of upstream asset keys, and an operation that is responsible for computing the asset from its upstream dependencies. Models defined in a dbt project can be interpreted as Dagster asset definitions:
The asset key for a dbt model is (by default) the name of the model.
The upstream dependencies of a dbt model are defined with ref or source calls within the model's definition.
The computation required to compute the asset from its upstream dependencies is the SQL within the model's definition.
These similarities make it natural to interact with dbt models as asset definitions. Let’s take a look at a dbt model and an asset definition, in code:
Here's what's happening in this example:
The first code block is a dbt model
As dbt models are named using file names, this model is named orders
The data for this model comes from a dependency named raw_orders
The second code block is a Dagster asset
The asset key corresponds to the name of the dbt model, orders
raw_orders is provided as an argument to the asset, defining it as a dependency
This creates a directory called project_dagster/ inside the current directory. The project_dagster/ directory contains a set of files that define a Dagster project that loads the dbt project at the path defined by --dbt-project-dir. The path to the dbt project must contain a dbt_project.yml.
The dagster-dbt library offers @dbt_assets to define Dagster assets for dbt models. It requires a dbt manifest, or manifest.json, to be created from your dbt project to parse your dbt project's representation.
The manifest can be created in two ways:
At run time: A dbt manifest is generated when your Dagster definitions are loaded, or
At build time: A dbt manifest is generated before loading your Dagster definitions and is included as part of your Python package.
When deploying your Dagster project to production, we recommend generating the manifest at build time to avoid the overhead of recompiling your dbt project every time your Dagster code is executed. A manifest.json should be precompiled and included in the Python package for your Dagster code.
The easiest way to handle the creation of your manifest file is to use DbtProject.
In the Dagster project created by the dagster-dbt project scaffold command, the creation of your manifest is handled at run time during development:
from pathlib import Path
from dagster_dbt import DbtProject
my_dbt_project = DbtProject(
project_dir=Path(__file__).joinpath("..","..","..").resolve(),
packaged_project_dir=Path(__file__).joinpath("..","..","dbt-project").resolve(),)
my_dbt_project.prepare_if_dev()
The manifest path can then be accessed with my_dbt_project.manifest_path.
When developing locally, you can run the following command to generate the manifest at run time for your dbt and Dagster project:
Got questions about our recommendations or something to add? Join our GitHub discussion to share how you deploy your Dagster code with your dbt project.
When deploying your Dagster project to production, your dbt project must be present alongside your Dagster project so that dbt commands can be executed. As a result, we recommend that you set up your continuous integration and continuous deployment (CI/CD) workflows to package the dbt project with your Dagster project.
Deploying a dbt project from a separate git repository#
If you are managing your Dagster project in a separate git repository from your dbt project, you should include the following steps in your CI/CD workflows.
In your CI/CD workflows for your Dagster project:
Include any secrets that are required by your dbt project in your CI/CD environment.
Clone the dbt project repository as a subdirectory of your Dagster project.
Run dagster-dbt project prepare-and-package --file path/to/project.py to
Build your dbt project's dependencies,
Create a dbt manifest for your Dagster project, and
Package your dbt project
In the CI/CD workflows for your dbt project, set up a dispatch action to trigger a deployment of your Dagster project when your dbt project changes.
With Dagster+, we streamline this option. As part of our Dagster+ onboarding for dbt users, we can automatically create a Dagster project in an existing dbt project repository.
If you are managing your Dagster project in the same git repository as your dbt project, you should include the following steps in your CI/CD workflows.
In your CI/CD workflows for your Dagster and dbt project:
Include any secrets that are required by your dbt project in your CI/CD environment.
Run dagster-dbt project prepare-and-package --file path/to/project.py to
Build your dbt project's dependencies,
Create a dbt manifest for your Dagster project, and
This feature requires the `DAGSTER_BUILD_STATEDIR` environment variable to be set in your CI/CD. Learn more about required environment variables in CI/CD for Dagster+ here.
It is possible to leverage dbt defer by passing a state_path to DbtProject. This is useful for testing recent changes made in development against the state of the dbt project in production. Using dbt defer, you can run a subset of models or tests, those that have been changed between development and production, without having to build their upstream parents first.
In practice, this is most useful when combined with branch deployments in Dagster+, to test changes made in your branches. This can be done by updating your CI/CD files and your Dagster code.
First, let's take a look at your CI/CD files. You might have one or two CI/CD files to manage your production and branch deployments. In these files, find the steps related to your dbt project - refer to the Deploying a Dagster project with a dbt project section for more information.
Once your dbt steps are located, add the following step to manage the state of your dbt project.
dagster-cloud ci dagster-dbt project manage-state --file path/to/project.py
The dagster-cloud ci dagster-dbt project manage-state CLI command fetches the manifest.json file from your production branch and saves it to a state directory, in order to power the dbt defer command.
In practice, this command fetches the manifest.json file from your production branch and add it to the state directory set to the state_path of the DbtProject found in path/to/project.py. The production manifest.json file can then be used as the deferred dbt artifacts.
Now that your CI/CD files are updated to manage the state of your dbt project using the dagster-cloud CLI, we need to update the Dagster code to pass a state directory to the DbtProject.
Update your Dagster code to pass a state_path to your DbtProject object. Note that value passed to state_path must be a path, relative to the dbt project directory, to a state directory of dbt artifacts. In the code below, we set the state_path to 'state/'. If this directory does not exist in your project structure, it will be created by Dagster.
Also, update the dbt command in your @dbt_assets definition to pass the defer args using get_defer_args.
import os
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import DbtCliResource, DbtProject, dbt_assets
my_dbt_project = DbtProject(
project_dir=Path(__file__).joinpath("..","..","..").resolve(),
packaged_project_dir=Path(__file__).joinpath("..","..","dbt-project").resolve(),
state_path=Path("state"),)
my_dbt_project.prepare_if_dev()@dbt_assets(manifest=my_dbt_project.manifest_path)defmy_dbt_assets(
context: AssetExecutionContext,
dbt: DbtCliResource,):yieldfrom dbt.cli(["build",*dbt.get_defer_args()], context=context).stream()
Like for a standard [software-defined asset], @dbt_assets can use a config system to enable run configuration. This allows to provide parameters to jobs at the time they're executed.
In the context of dbt, this can be useful if you want to run commands or flags for specific use cases. For instance, you may want to add the --full-refresh flag to your dbt commands in some cases. Using a config system, the @dbt_assets object can be easily modified to support this use case.
In this example, we use the build_schedule_from_dbt_selection function to create a job, daily_dbt_models, as well as a schedule which will execute this job once a day. We define the set of models we'd like to execute using dbt's selection syntax, in this case selecting only the models with the tag daily.
from dagster_dbt import build_schedule_from_dbt_selection, dbt_assets
@dbt_assets(manifest=manifest)defmy_dbt_assets():...
daily_dbt_assets_schedule = build_schedule_from_dbt_selection([my_dbt_assets],
job_name="daily_dbt_models",
cron_schedule="@daily",
dbt_select="tag:daily",# If your definition of `@dbt_assets` has Dagster Configuration, you can specify it here.# config=RunConfig(ops={"my_dbt_assets": MyDbtConfig(full_refresh=True)}),)
Scheduling jobs that contain dbt assets and non-dbt assets#
In many cases, it's useful to be able to schedule dbt assets alongside non-dbt assets. In this example, we build an AssetSelection of dbt assets using build_dbt_asset_selection, then select all assets (dbt-related or not) which are downstream of these dbt models. From there, we create a job that targets that selection of assets and schedule it to run daily.
from dagster import define_asset_job, ScheduleDefinition
from dagster_dbt import build_dbt_asset_selection, dbt_assets
@dbt_assets(manifest=manifest)defmy_dbt_assets():...# selects all models tagged with "daily", and all their downstream asset dependencies
daily_selection = build_dbt_asset_selection([my_dbt_assets], dbt_select="tag:daily").downstream()
daily_dbt_assets_and_downstream_schedule = ScheduleDefinition(
job=define_asset_job("daily_assets", selection=daily_selection),
cron_schedule="@daily",)
In Dagster, each asset definition has attributes. Dagster automatically generates these attributes for each asset definition loaded from the dbt project. These attributes can optionally be overridden by the user.
Overriding Dagster's asset key generation by implementing a custom DagsterDbtTranslator.
To override an asset key generated by Dagster for a dbt node, you can define a meta key on your dbt node's .yml file. The following example overrides the asset key for a source and table as snowflake/jaffle_shop/orders:
Alternatively, to override the asset key generation for all dbt nodes in your dbt project, you can create a custom DagsterDbtTranslator and implement DagsterDbtTranslator.get_asset_key. The following example adds a snowflake prefix to the default generated asset key:
from pathlib import Path
from dagster import AssetKey, AssetExecutionContext
from dagster_dbt import DagsterDbtTranslator, DbtCliResource, DbtProject, dbt_assets
from typing import Any, Mapping
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))classCustomDagsterDbtTranslator(DagsterDbtTranslator):defget_asset_key(self, dbt_resource_props: Mapping[str, Any])-> AssetKey:returnsuper().get_asset_key(dbt_resource_props).with_prefix("snowflake")@dbt_assets(
manifest=my_dbt_project.manifest_path,
dagster_dbt_translator=CustomDagsterDbtTranslator(),)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
Overriding Dagster's group name generation by implementing a custom DagsterDbtTranslator
To override the group name generated by Dagster for a dbt node, you can define a meta key in your dbt project file, on your dbt node's property file, or on the node's in-file config block. The following example overrides the Dagster group name for the following model as marketing:
Alternatively, to override the Dagster group name generation for all dbt nodes in your dbt project, you can create a custom DagsterDbtTranslator and implement DagsterDbtTranslator.get_group_name. The following example defines snowflake as the group name for all dbt nodes:
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import DagsterDbtTranslator, DbtCliResource, DbtProject, dbt_assets
from typing import Any, Mapping, Optional
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))classCustomDagsterDbtTranslator(DagsterDbtTranslator):defget_group_name(
self, dbt_resource_props: Mapping[str, Any])-> Optional[str]:return"snowflake"@dbt_assets(
manifest=my_dbt_project.manifest_path,
dagster_dbt_translator=CustomDagsterDbtTranslator(),)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
Overriding Dagster's generation of owners by implementing a custom DagsterDbtTranslator
To override the owners generated by Dagster for a dbt node, you can define a meta key in your dbt project file, on your dbt node's property file, or on the node's in-file config block. The following example overrides the Dagster owners for the following model as owner@company.com and team:data@company.com:
Alternatively, to override the Dagster generation of owners for all dbt nodes in your dbt project, you can create a custom DagsterDbtTranslator and implement DagsterDbtTranslator.get_group_name. The following example defines owner@company.com and team:data@company.com as the owners for all dbt nodes:
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import DagsterDbtTranslator, DbtCliResource, DbtProject, dbt_assets
from typing import Any, Mapping, Optional, Sequence
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))classCustomDagsterDbtTranslator(DagsterDbtTranslator):defget_owners(
self, dbt_resource_props: Mapping[str, Any])-> Optional[Sequence[str]]:return["owner@company.com","team:data@company.com"]@dbt_assets(
manifest=my_dbt_project.manifest_path,
dagster_dbt_translator=CustomDagsterDbtTranslator(),)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
For dbt models, seeds, and snapshots, the default Dagster description will be the dbt node's description.
To override the Dagster description for all dbt nodes in your dbt project, you can create a custom DagsterDbtTranslator and implement DagsterDbtTranslator.get_description. The following example defines the raw SQL of the dbt node as the Dagster description:
import textwrap
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import DagsterDbtTranslator, DbtCliResource, DbtProject, dbt_assets
from typing import Any, Mapping
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))classCustomDagsterDbtTranslator(DagsterDbtTranslator):defget_description(self, dbt_resource_props: Mapping[str, Any])->str:return textwrap.indent(dbt_resource_props.get("raw_sql",""),"\t")@dbt_assets(
manifest=my_dbt_project.manifest_path,
dagster_dbt_translator=CustomDagsterDbtTranslator(),)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
For dbt models, seeds, and snapshots, the default Dagster definition metadata will be the dbt node's declared column schema.
To override the Dagster definition metadata for all dbt nodes in your dbt project, you can create a custom DagsterDbtTranslator and implement DagsterDbtTranslator.get_metadata. The following example defines the metadata of the dbt node as the Dagster metadata, using MetadataValue:
from pathlib import Path
from dagster import MetadataValue, AssetExecutionContext
from dagster_dbt import DagsterDbtTranslator, DbtCliResource, DbtProject, dbt_assets
from typing import Any, Mapping
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))classCustomDagsterDbtTranslator(DagsterDbtTranslator):defget_metadata(
self, dbt_resource_props: Mapping[str, Any])-> Mapping[str, Any]:return{"dbt_metadata": MetadataValue.json(dbt_resource_props.get("meta",{}))}@dbt_assets(
manifest=my_dbt_project.manifest_path,
dagster_dbt_translator=CustomDagsterDbtTranslator(),)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
Dagster also supports fetching additional metadata at dbt execution time to attach to asset materializations. For more information, see the Customizing asset materialization metadata section.
Dagster's dbt integration can automatically attach code reference metadata to the SQL files backing your dbt assets. To enable this feature, set the enable_code_references parameter to True in the DagsterDbtTranslatorSettings passed to your DagsterDbtTranslator:
from pathlib import Path
from dagster_dbt import(
DagsterDbtTranslator,
DagsterDbtTranslatorSettings,
DbtCliResource,
DbtProject,
dbt_assets,)from dagster import AssetExecutionContext, Definitions, with_source_code_references
my_project = DbtProject(project_dir=Path("path/to/dbt_project"))# links to dbt model source code from assets
dagster_dbt_translator = DagsterDbtTranslator(
settings=DagsterDbtTranslatorSettings(enable_code_references=True))@dbt_assets(
manifest=my_project.manifest_path,
dagster_dbt_translator=dagster_dbt_translator,
project=my_project,)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
defs = Definitions(assets=with_source_code_references([my_dbt_assets]))
In Dagster, tags are key-value pairs. However, in dbt, tags are strings. To bridge this divide, the dbt tag string is used as the Dagster tag key, and the Dagster tag value is set to the empty string,"". Any dbt tags that don't match Dagster's supported tag key format (e.g. they contain unsupported characters) will be ignored by default.
For dbt models, seeds, and snapshots, the default Dagster tags will be the dbt node's configured tags.
Any dbt tags that don't match Dagster's supported tag key format (e.g. they contain unsupported characters) will be ignored.
To override the Dagster tags for all dbt nodes in your dbt project, you can create a custom DagsterDbtTranslator and implement DagsterDbtTranslator.get_tags. The following converts dbt tags of the form foo=bar to key/value pairs:
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import DagsterDbtTranslator, DbtCliResource, DbtProject, dbt_assets
from typing import Any, Mapping
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))classCustomDagsterDbtTranslator(DagsterDbtTranslator):defget_tags(self, dbt_resource_props: Mapping[str, Any])-> Mapping[str,str]:
dbt_tags = dbt_resource_props.get("tags",[])
dagster_tags ={}for tag in dbt_tags:
key, _, value = tag.partition("=")
dagster_tags[key]= value if value else""return dagster_tags
@dbt_assets(
manifest=my_dbt_project.manifest_path,
dagster_dbt_translator=CustomDagsterDbtTranslator(),)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
Note that Dagster allows the optional specification of a code_version for each asset definition, which are used to track changes. The code_version for an asset arising from a dbt model is defined automatically as the hash of the SQL defining the DBT model. This allows the asset graph in the UI to use the "Unsynced" status to indicate which dbt models have new SQL since they were last materialized.
Dagster uses dbt indirect selection to select dbt tests. By default, Dagster won't set DBT_INDIRECT_SELECTION so that the set of tests selected by Dagster is the same as the selected by dbt. When required, Dagster will override DBT_INDIRECT_SELECTION to empty in order to explicitly select dbt tests. For example:
Materializing dbt assets and excluding their asset checks
Executing dbt asset checks without materializing their assets
Dagster will load both generic and singular tests as asset checks. In the event that your singular test depends on multiple dbt models, you can use dbt metadata to specify which Dagster asset it should target. These fields can be filled in as they would be for the dbt ref function. The configuration can be supplied in a config block for the singular test.
dbt-core version 1.6 or later is required for Dagster to read this metadata.
If this metadata isn't provided, Dagster won't ingest the test as an asset check. It will still run the test and emit a AssetObservation events with the test results.
You can disable modeling your dbt tests as asset checks. The tests will still run and will be emitted as AssetObservation events. To do so you'll need to define a DagsterDbtTranslator with DagsterDbtTranslatorSettings that have asset checks disabled. The following example disables asset checks when using @dbt_assets:
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import(
DagsterDbtTranslator,
DagsterDbtTranslatorSettings,
DbtCliResource,
DbtProject,
dbt_assets,)
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))
dagster_dbt_translator = DagsterDbtTranslator(
settings=DagsterDbtTranslatorSettings(enable_asset_checks=False))@dbt_assets(
manifest=my_dbt_project.manifest_path,
dagster_dbt_translator=dagster_dbt_translator,)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream()
Dagster supports fetching additional metadata at dbt execution time to attach as materialization metadata, which is recorded each time your models are rebuilt and displayed in the Dagster UI.
Emitting row count data for dbt models is currently an experimental feature. To use this feature, you'll need to be on at least dagster>=0.17.6 anddagster-dbt>=0.23.6.
Dagster can automatically fetch row counts for dbt-generated tables and emit them as materialization metadata to be displayed in the Dagster UI.
Row counts are fetched in parallel to the execution of your dbt models. To enable this feature, call fetch_row_counts() on the DbtEventIterator returned by the stream() dbt CLI call:
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import DbtProject, DbtCliResource, dbt_assets
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))@dbt_assets(
manifest=my_dbt_project.manifest_path,)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom dbt.cli(["build"], context=context).stream().fetch_row_counts()
Once your dbt models have been materialized, you can view the row count data in the metadata table.
Emitting column-level metadata for dbt models is currently an experimental feature. To use this feature, you'll need to be on at least dagster>=1.8.0 anddagster-dbt>=0.24.0.
With this metadata, you can view documentation in Dagster for all columns, not just columns described in your dbt project.
Column-level metadata is fetched in parallel to the execution of your dbt models. To enable this feature, call fetch_column_metadata() on the DbtEventIterator returned by the stream() dbt CLI call:
from pathlib import Path
from dagster import AssetExecutionContext
from dagster_dbt import DbtProject, DbtCliResource, dbt_assets
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))@dbt_assets(
manifest=my_dbt_project.manifest_path,)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):yieldfrom(
dbt.cli(["build"], context=context).stream().fetch_column_metadata())
Defining an asset as an upstream dependency of a dbt model#
Dagster allows you to define existing assets as upstream dependencies of dbt models. For example, say you have the following asset with asset key upstream:
from dagster import asset
@assetdefupstream():...
In order to define this asset as an upstream dependency for a dbt model, you'll need to first declare it as a data source in the sources.yml file. Here, you can explicitly provide your asset key to a source table:
Dagster parses information about assets that are upstream of specific dbt models from the dbt project itself. Whenever a model is downstream of a dbt source, that source will be parsed as an upstream asset.
For example, if you defined a source in your sources.yml file like this:
sources:-name: jaffle_shop
tables:-name: orders
and use it in a model:
select*from {{ source("jaffle_shop","orders") }}
where foo=1
Then this model has an upstream source with the jaffle_shop/orders asset key.
In order to manage this upstream asset with Dagster, you can define it by passing the key into an asset definition via get_asset_key_for_source:
from dagster import asset, AssetExecutionContext
from dagster_dbt import DbtCliResource, get_asset_key_for_source, dbt_assets
@dbt_assets(manifest=MANIFEST_PATH)defmy_dbt_assets(context: AssetExecutionContext, dbt: DbtCliResource):...@asset(key=get_asset_key_for_source([my_dbt_assets],"jaffle_shop"))deforders():return...
This allows you to change asset keys within your dbt project without having to update the corresponding Dagster definitions.
The get_asset_key_for_source method is used when a source has only one table. However, if a source contains multiple tables, like this example:
sources:-name: clients_data
tables:-name: names
-name: history
Dagster allows you to define assets that are downstream of specific dbt models via get_asset_key_for_model. The below example defines my_downstream_asset as a downstream dependency of my_dbt_model:
from dagster_dbt import get_asset_key_for_model
from dagster import asset
@asset(deps=[get_asset_key_for_model([my_dbt_assets],"my_dbt_model")])defmy_downstream_asset():...
In the downstream asset, you may want direct access to the contents of the dbt model. To do so, you can customize the code within your @asset-decorated function to load upstream data.
Dagster alternatively allows you to delegate loading data to an I/O manager. For example, if you wanted to consume a dbt model with the asset key my_dbt_model as a Pandas dataframe, that would look something like the following:
from dagster_dbt import get_asset_key_for_model
from dagster import AssetIn, asset
@asset(
ins={"my_dbt_model": AssetIn(
input_manager_key="pandas_df_manager",
key=get_asset_key_for_model([my_dbt_assets],"my_dbt_model"),)},)defmy_downstream_asset(my_dbt_model):# my_dbt_model is a Pandas dataframereturn my_dbt_model.where(foo="bar")
You can define a Dagster PartitionDefinition alongside dbt in order to build incremental models.
Partitioned assets will be able to access the TimeWindow's start and end dates, and these can be passed to dbt's CLI as variables which can be used to filter incremental models.
When a partition definition to passed to the @dbt_assets decorator, all assets are defined to operate on the same partitions. With this in mind, we can retrieve any time window from AssetExecutionContext.partition_time_window property in order to get the current start and end partitions.
import json
from pathlib import Path
from dagster import DailyPartitionsDefinition, OpExecutionContext
from dagster_dbt import DbtCliResource, DbtProject, dbt_assets
my_dbt_project = DbtProject(project_dir=Path("path/to/dbt_project"))@dbt_assets(
manifest=my_dbt_project.manifest_path,
partitions_def=DailyPartitionsDefinition(start_date="2023-01-01"),)defpartitionshop_dbt_assets(context: OpExecutionContext, dbt: DbtCliResource):
start, end = context.partition_time_window
dbt_vars ={"min_date": start.isoformat(),"max_date": end.isoformat()}
dbt_build_args =["build","--vars", json.dumps(dbt_vars)]yieldfrom dbt.cli(dbt_build_args, context=context).stream()
With the variables defined, we can now reference min_date and max_date in our SQL and configure the dbt model as incremental. Here, we define an incremental run to operate on rows with order_date that is between our min_date and max_date.
-- Configure the model as incremental, use a unique_key and the delete+insert strategy to ensure the pipeline is idempotent.
{{ config(materialized='incremental', unique_key='order_date', incremental_strategy="delete+insert") }}
select*from {{ ref('my_model') }}
-- Use the Dagster partition variables to filter rows on an incremental run
{%if is_incremental()%}
where order_date >='{{ var('min_date') }}'and order_date <='{{ var('max_date') }}'
{% endif %}