DuckDB is an embedded database, similar to SQLite, but designed for OLAP-style analytics. It is crazy fast and allows you to read and write data stored in CSV, JSON, and Parquet files directly, without requiring you to load them into the database first.
dbt is the best way to manage a collection of data transformations written in SQL or Python for analytics
and data science. dbt-duckdb
is the project that ties DuckDB and dbt together, allowing you to create a Modern Data Stack In
A Box or a simple and powerful data lakehouse with Python.
This project is hosted on PyPI, so you should be able to install it and the necessary dependencies via:
pip3 install dbt-duckdb
The latest supported version targets dbt-core
1.7.x and duckdb
version 0.10.x, but we work hard to ensure that newer
versions of DuckDB will continue to work with the adapter as they are released. If you would like to use our new (and experimental!)
support for persisting the tables that DuckDB creates to the AWS Glue Catalog, you should install
dbt-duckdb[glue]
in order to get the AWS dependencies as well.
A super-minimal dbt-duckdb profile only needs one setting:
default:
outputs:
dev:
type: duckdb
target: dev
This will run your dbt-duckdb pipeline against an in-memory DuckDB database that will not be persisted after your run completes. This may not seem very useful at first, but it turns out to be a powerful tool for a) testing out data pipelines, either locally or in CI jobs and b) running data pipelines that operate purely on external CSV, Parquet, or JSON files. More details on how to work with external data files in dbt-duckdb are provided in the docs on reading and writing external files.
To have your dbt pipeline persist relations in a DuckDB file, set the path
field in your profile to the path
of the DuckDB file that you would like to read and write on your local filesystem. (For in-memory pipelines, the path
is automatically set to the special value :memory:
).
dbt-duckdb
also supports common profile fields like schema
and threads
, but the database
property is special: its value is automatically set
to the basename of the file in the path
argument with the suffix removed. For example, if the path
is /tmp/a/dbfile.duckdb
, the database
field will be set to dbfile
. If you are running in in-memory mode, then the database
property will be automatically set to memory
.
As of dbt-duckdb
1.5.2, you can connect to a DuckDB instance running on MotherDuck by setting your path
to use a md: connection string, just as you would with the DuckDB CLI
or the Python API.
MotherDuck databases generally work the same way as local DuckDB databases from the perspective of dbt, but there are a few differences to be aware of:
- Currently, MotherDuck requires a specific version of DuckDB, often the latest, as specified in MotherDuck's documentation
- MotherDuck databases do not suppport transactions, so there is a new
disable_transactions
profile. option that will be automatically enabled if you are connecting to a MotherDuck database in yourpath
. - MotherDuck preloads a set of the most common DuckDB extensions for you, but does not support loading custom extensions or user-defined functions.
- A small subset of advanced SQL features are currently unsupported; the only impact of this on the dbt adapter is that the dbt.listagg macro and foreign-key constraints will work against a local DuckDB database, but will not work against a MotherDuck database.
You can load any supported DuckDB extensions by listing them in
the extensions
field in your profile. You can also set any additional DuckDB configuration options
via the settings
field, including options that are supported in any loaded extensions. For example, to be able to connect to S3 and read/write
Parquet files using an AWS access key and secret, your profile would look something like this:
default:
outputs:
dev:
type: duckdb
path: /tmp/dbt.duckdb
extensions:
- httpfs
- parquet
settings:
s3_region: my-aws-region
s3_access_key_id: "{{ env_var('S3_ACCESS_KEY_ID') }}"
s3_secret_access_key: "{{ env_var('S3_SECRET_ACCESS_KEY') }}"
target: dev
As of version 1.4.1
, we have added (experimental!) support for DuckDB's (experimental!) support for filesystems
implemented via fsspec. The fsspec
library provides
support for reading and writing files from a variety of cloud data storage systems
including S3, GCS, and Azure Blob Storage. You can configure a list of fsspec-compatible implementations for use with your dbt-duckdb project by installing the relevant Python modules
and configuring your profile like so:
default:
outputs:
dev:
type: duckdb
path: /tmp/dbt.duckdb
filesystems:
- fs: s3
anon: false
key: "{{ env_var('S3_ACCESS_KEY_ID') }}"
secret: "{{ env_var('S3_SECRET_ACCESS_KEY') }}"
client_kwargs:
endpoint_url: "http://localhost:4566"
target: dev
Here, the filesystems
property takes a list of configurations, where each entry must have a property named fs
that indicates which fsspec
protocol
to load (so s3
, gcs
, abfs
, etc.) and then an arbitrary set of other key-value pairs that are used to configure the fsspec
implementation. You can see a simple example project that
illustrates the usage of this feature to connect to a Localstack instance running S3 from dbt-duckdb here.
Instead of specifying the credentials through the settings block, you can also use the use_credential_provider property. If you set this to aws
(currently the only supported implementation) and you have boto3
installed in your python environment, we will fetch your AWS credentials using the credential provider chain as described here. This means that you can use any supported mechanism from AWS to obtain credentials (e.g., web identity tokens).
DuckDB version 0.7.0
added support for attaching additional databases to your dbt-duckdb run so that you can read
and write from multiple databases. Additional databases may be configured using dbt run hooks or via the attach
argument
in your profile that was added in dbt-duckdb 1.4.0
:
default:
outputs:
dev:
type: duckdb
path: /tmp/dbt.duckdb
attach:
- path: /tmp/other.duckdb
- path: ./yet/another.duckdb
alias: yet_another
- path: s3://yep/even/this/works.duckdb
read_only: true
- path: sqlite.db
type: sqlite
The attached databases may be referred to in your dbt sources and models by either the basename of the database file minus its suffix (e.g., /tmp/other.duckdb
is the other
database
and s3://yep/even/this/works.duckdb
is the works
database) or by an alias that you specify (so the ./yet/another.duckdb
database in the above configuration is referred to
as yet_another
instead of another
.) Note that these additional databases do not necessarily have to be DuckDB files: DuckDB's storage and catalog engines are pluggable, and
DuckDB 0.7.0
ships with support for reading and writing from attached SQLite databases. You can indicate the type of the database you are connecting to via the type
argument,
which currently supports duckdb
and sqlite
.
dbt-duckdb has its own plugin system to enable advanced users to extend dbt-duckdb with additional functionality, including:
- Defining custom Python UDFs on the DuckDB database connection so that they can be used in your SQL models
- Loading source data from Excel, Google Sheets, or SQLAlchemy tables
You can find more details on how to write your own plugins here. To configure a plugin for use
in your dbt project, use the plugins
property on the profile:
default:
outputs:
dev:
type: duckdb
path: /tmp/dbt.duckdb
plugins:
- module: gsheet
config:
method: oauth
- module: sqlalchemy
alias: sql
config:
connection_url: "{{ env_var('DBT_ENV_SECRET_SQLALCHEMY_URI') }}"
- module: path.to.custom_udf_module
Every plugin must have a module
property that indicates where the Plugin
class to load is defined. There is
a set of built-in plugins that are defined in dbt.adapters.duckdb.plugins that
may be referenced by their base filename (e.g., excel
or gsheet
), while user-defined plugins (which are
described later in this document) should be referred to via their full module path name (e.g. a lib.my.custom
module that defines a class named Plugin
.)
Each plugin instance has a name for logging and reference purposes that defaults to the name of the module
but that may be overridden by the user by setting the alias
property in the configuration. Finally,
modules may be initialized using an arbitrary set of key-value pairs that are defined in the
config
dictionary. In this example, we initialize the gsheet
plugin with the setting method: oauth
and we
initialize the sqlalchemy
plugin (aliased as "sql") with a connection_url
that is set via an environment variable.
Please remember that using plugins may require you to add additional dependencies to the Python environment that your dbt-duckdb pipeline runs in:
excel
depends onpandas
, andopenpyxl
orxlsxwriter
to perform writesgsheet
depends ongspread
andpandas
iceberg
depends onpyiceberg
and Python >= 3.8sqlalchemy
depends onpandas
,sqlalchemy
, and the driver(s) you need
Experimental:
delta
depends ondeltalake
, an example project
Note: Be aware that experimental features can change over time, and we would like your feedback on config and possible different use cases.
In dbt-duckdb 1.6.0, we added a new profile setting named module_paths
that allows users to specify a list
of paths on the filesystem that contain additional Python modules that should be added to the Python processes'
sys.path
property. This allows users to include additional helper Python modules in their dbt projects that
can be accessed by the running dbt process and used to define custom dbt-duckdb Plugins or library code that is
helpful for creating dbt Python models.
One of DuckDB's most powerful features is its ability to read and write CSV, JSON, and Parquet files directly, without needing to import/export them from the database first.
You may reference external files in your dbt models either directly or as dbt source
s by configuring the external_location
in either the meta
or the config
option on the source definition. The difference is that settings under the meta
option
will be propagated to the documentation for the source generated via dbt docs generate
, but the settings under the config
option will not be. Any source settings that should be excluded from the docs should be specified via config
, while any
options that you would like to be included in the generated documentation should live under meta
.
sources:
- name: external_source
meta:
external_location: "s3://my-bucket/my-sources/{name}.parquet"
tables:
- name: source1
- name: source2
Here, the meta
options on external_source
defines external_location
as an f-string that
allows us to express a pattern that indicates the location of any of the tables defined for that source. So a dbt model like:
SELECT *
FROM {{ source('external_source', 'source1') }}
will be compiled as:
SELECT *
FROM 's3://my-bucket/my-sources/source1.parquet'
If one of the source tables deviates from the pattern or needs some other special handling, then the external_location
can also be set on the meta
options for the table itself, for example:
sources:
- name: external_source
meta:
external_location: "s3://my-bucket/my-sources/{name}.parquet"
tables:
- name: source1
- name: source2
config:
external_location: "read_parquet(['s3://my-bucket/my-sources/source2a.parquet', 's3://my-bucket/my-sources/source2b.parquet'])"
In this situation, the external_location
setting on the source2
table will take precedence, so a dbt model like:
SELECT *
FROM {{ source('external_source', 'source2') }}
will be compiled to the SQL query:
SELECT *
FROM read_parquet(['s3://my-bucket/my-sources/source2a.parquet', 's3://my-bucket/my-sources/source2b.parquet'])
Note that the value of the external_location
property does not need to be a path-like string; it can also be a function
call, which is helpful in the case that you have an external source that is a CSV file which requires special handling for DuckDB to load it correctly:
sources:
- name: flights_source
tables:
- name: flights
config:
external_location: "read_csv('flights.csv', types={'FlightDate': 'DATE'}, names=['FlightDate', 'UniqueCarrier'])"
formatter: oldstyle
Note that we need to override the default str.format
string formatting strategy for this example
because the types={'FlightDate': 'DATE'}
argument to the read_csv
function will be interpreted by
str.format
as a template to be matched on, which will cause a KeyError: "'FlightDate'"
when we attempt
to parse the source in a dbt model. The formatter
configuration option for the source indicates whether
we should use newstyle
string formatting (the default), oldstyle
string formatting, or template
string
formatting. You can read up on the strategies the various string formatting techniques use at this
Stack Overflow answer and see examples of their use
in this dbt-duckdb integration test.
We support creating dbt models that are backed by external files via the external
materialization strategy:
{{ config(materialized='external', location='local/directory/file.parquet') }}
SELECT m.*, s.id IS NOT NULL as has_source_id
FROM {{ ref('upstream_model') }} m
LEFT JOIN {{ source('upstream', 'source') }} s USING (id)
Option | Default | Description |
---|---|---|
location | external_location macro | The path to write the external materialization to. See below for more details. |
format | parquet | The format of the external file (parquet, csv, or json) |
delimiter | , | For CSV files, the delimiter to use for fields. |
options | None | Any other options to pass to DuckDB's COPY operation (e.g., partition_by , codec , etc.) |
glue_register | false | If true, try to register the file created by this model with the AWS Glue Catalog. |
glue_database | default | The name of the AWS Glue database to register the model with. |
If the location
argument is specified, it must be a filename (or S3 bucket/path), and dbt-duckdb will attempt to infer
the format
argument from the file extension of the location
if the format
argument is unspecified (this functionality was
added in version 1.4.1.)
If the location
argument is not specified, then the external file will be named after the model.sql (or model.py) file that defined it
with an extension that matches the format
argument (parquet
, csv
, or json
). By default, the external files are created
relative to the current working directory, but you can change the default directory (or S3 bucket/prefix) by specifying the
external_root
setting in your DuckDB profile.
dbt-duckdb supports the delete+insert
and append
strategies for incremental table
models, but unfortunately it does not yet support incremental materialization strategies for external
models.
When using :memory:
as the DuckDB database, subsequent dbt runs can fail when selecting a subset of models that depend on external tables. This is because external files are only registered as DuckDB views when they are created, not when they are referenced. To overcome this issue we have provided the register_upstream_external_models
macro that can be triggered at the beginning of a run. To enable this automatic registration, place the following in your dbt_project.yml
file:
on-run-start:
- "{{ register_upstream_external_models() }}"
dbt added support for Python models in version 1.3.0. For most data platforms,
dbt will package up the Python code defined in a .py
file and ship it off to be executed in whatever Python environment that
data platform supports (e.g., Snowpark for Snowflake or Dataproc for BigQuery.) In dbt-duckdb, we execute Python models in the same
process that owns the connection to the DuckDB database, which by default, is the Python process that is created when you run dbt.
To execute the Python model, we treat the .py
file that your model is defined in as a Python module and load it into the
running process using importlib. We then construct the arguments to the model
function that you defined (a dbt
object that contains the names of any ref
and source
information your model needs and a
DuckDBPyConnection
object for you to interact with the underlying DuckDB database), call the model
function, and then materialize
the returned object as a table in DuckDB.
The value of the dbt.ref
and dbt.source
functions inside of a Python model will be a DuckDB Relation
object that can be easily converted into a Pandas/Polars DataFrame or an Arrow table. The return value of the model
function can be
any Python object that DuckDB knows how to turn into a table, including a Pandas/Polars DataFrame
, a DuckDB Relation
, or an Arrow Table
,
Dataset
, RecordBatchReader
, or Scanner
.
As of version 1.6.1, it is possible to both read and write data in chunks, which allows for larger-than-memory datasets to be manipulated in Python models. Here is a basic example:
import pyarrow as pa
def batcher(batch_reader: pa.RecordBatchReader):
for batch in batch_reader:
df = batch.to_pandas()
# Do some operations on the DF...
# ...then yield back a new batch
yield pa.RecordBatch.from_pandas(df)
def model(dbt, session):
big_model = dbt.ref("big_model")
batch_reader = big_model.record_batch(100_000)
batch_iter = batcher(batch_reader)
return pa.RecordBatchReader.from_batches(batch_reader.schema, batch_iter)
Defining your own dbt-duckdb plugin is as simple as creating a python module that defines a class named Plugin
that
inherits from dbt.adapters.duckdb.plugins.BasePlugin. There are currently
four methods that may be implemented in your Plugin class:
initialize
: Takes in theconfig
dictionary for the plugin that is defined in the profile to enable any additional configuration for the module based on the project; this method is called once when an instance of thePlugin
class is created.configure_connection
: Takes an instance of theDuckDBPyConnection
object used to connect to the DuckDB database and may perform any additional configuration of that object that is needed by the plugin, like defining custom user-defined functions.load
: Takes a SourceConfig instance, which encapsulates the configuration for a a dbt source and can optionally return a DataFrame-like object that DuckDB knows how to turn into a table (this is similar to a dbt-duckdb Python model, but without the ability toref
any models or access any information beyond the source config.)store
: Takes a TargetConfig instance, which encapsulates the configuration for anexternal
materialization and can perform additional operations once the CSV/Parquet/JSON file is written. The glue and sqlalchemy are examples that demonstrate how to use thestore
operation to register an AWS Glue database table or upload a DataFrame to an external database, respectively.
dbt-duckdb ships with a number of built-in plugins that can be used as examples for implementing your own.
Things that we would like to add in the near future:
- Support for Delta and Iceberg external table formats (both as sources and destinations)
- Make dbt's incremental models and snapshots work with external materializations