IO Managers are user-provided objects that store asset and op outputs and load them as inputs to downstream assets and ops.
Name | Description |
---|---|
@io_manager | A decorator used to define IO managers. |
IOManager | Base class for user-provided IO managers. |
build_input_context | Function for directly constructing a InputContext , to be passed to the IOManager.load_input method. This is designed primarily for testing purposes. |
build_output_context | Function for directly constructing a OutputContext , to be passed to the IOManager.handle_output method. This is designed primarily for testing purposes. |
Dagster ops have inputs and outputs. When an op returns an output and a downstream op takes that output as an input, where does the data live in between? IOManagers
let the user decide. Similarly, IOManagers
are responsible for storing asset outputs and loading inputs in downstream assets.
The IO manager APIs make it easy to separate code that's responsible for logical data transformation from code that's responsible for reading and writing the results. Assets and ops can focus on business logic, while IO managers handle I/O. This separation makes it easier to test the business logic and run it in different environments.
Not all inputs depend on upstream outputs. The Unconnected Inputs overview covers DagsterTypeLoaders
and writing IO managers to load inputs with no corresponding output. This lets you decide how inputs at the beginning of a job are loaded.
IOManagers
are user-provided objects that are responsible for storing the output of an asset or op and loading it as input to downstream assets or ops. For example, an IO Manager might store and load objects from files on a filesystem.For ops, each op output can have its own IO manager, or multiple op outputs can share an IO manager. The IO manager that's used for handling a particular op output is automatically used for loading it in downstream ops.
This diagram shows a job with two IO managers, each of which is shared across a few inputs and outputs.
For assets, each asset can have its own IO manager. In the multi-asset case where multiple assets are outputted, each outputted asset can be handled with a different IO manager.
The default IO manager, fs_io_manager
, stores and retrieves values in the filesystem while pickling. If a job is invoked via JobDefinition.execute_in_process
, the default IO manager is switched to mem_io_manager
, which stores outputs in memory.
Dagster provides out-of-the-box IO managers that pickle objects and save them. These are s3_pickle_io_manager
, adls2_pickle_io_manager
, or gcs_pickle_io_manager
. These filesystem IO managers, along with fs_io_manager
, store op outputs at a unique path identified by the run ID, step key, and output name. These IO managers will output assets at a unique path identified by the asset key.
IO managers are resources, which means users can supply different IO managers for the same op outputs in different situations. For example, you might use an in-memory IO manager for unit-testing a job and an S3 IO manager in production.
By default, materializing an asset will pickle it to a local file named my_asset
in a temporary directory. You can specify this directory by providing a value for the local_artifact_storage
property in your dagster.yaml
file.
IO managers enable fully overriding this behavior and storing asset contents in any way you wish - e.g. writing them as tables in a database or as objects in a cloud object store. You can use one of Dagster's built-in IO managers that pickle assets to popular services - AWS S3 (s3_pickle_io_manager
), Azure Blob Storage (adls2_pickle_io_manager
), or GCS (gcs_pickle_io_manager
) - or you can write your own.
To apply an IO manager to a set of assets, you can use with_resources
:
from dagster_aws.s3 import s3_pickle_io_manager, s3_resource
from dagster import asset, with_resources
@asset
def upstream_asset():
return [1, 2, 3]
@asset
def downstream_asset(upstream_asset):
return upstream_asset + [4]
assets_with_io_manager = with_resources(
[upstream_asset, downstream_asset],
resource_defs={"io_manager": s3_pickle_io_manager, "s3": s3_resource},
)
This example also includes "s3": s3_resource
because the s3_pickle_io_manager
depends on an S3 resource.
When upstream_asset
is materialized, the value [1, 2, 3]
will be pickled and stored in an object on S3. When downstream_asset
is materialized, the value of upstream_asset
will be read from S3 and depickled, and [1, 2, 3, 4]
will be pickled and stored in a different object on S3.
Different assets can have different IO managers:
from dagster_aws.s3 import s3_pickle_io_manager, s3_resource
from dagster import asset, fs_io_manager, with_resources
@asset(io_manager_key="s3_io_manager")
def upstream_asset():
return [1, 2, 3]
@asset(io_manager_key="fs_io_manager")
def downstream_asset(upstream_asset):
return upstream_asset + [4]
assets_with_io_managers = with_resources(
[upstream_asset, downstream_asset],
resource_defs={
"s3_io_manager": s3_pickle_io_manager,
"s3": s3_resource,
"fs_io_manager": fs_io_manager,
},
)
When upstream_asset
is materialized, the value [1, 2, 3]
will be pickled and stored in an object on S3. When downstream_asset
is materialized, the value of upstream_asset
will be read from S3 and depickled, and [1, 2, 3, 4]
will be pickled and stored in a file on the local filesystem.
In the multi-asset case, you can customize how each asset is materialized by specifying an io_manager_key
on each output of the multi-asset.
from dagster import Out, multi_asset
@multi_asset(
outs={
"s3_asset": Out(io_manager_key="s3_io_manager"),
"adls_asset": Out(io_manager_key="adls2_io_manager"),
},
)
def my_assets():
return "store_me_on_s3", "store_me_on_adls2"
The same assets can be bound to different resources and IO managers in different environments. For example, for local development, you might want to store assets on your local filesystem while in production, you might want to store the assets in S3.
from dagster_aws.s3 import s3_pickle_io_manager, s3_resource
from dagster import asset, fs_io_manager, with_resources
@asset
def upstream_asset():
return [1, 2, 3]
@asset
def downstream_asset(upstream_asset):
return upstream_asset + [4]
prod_assets = with_resources(
[upstream_asset, downstream_asset],
resource_defs={"io_manager": s3_pickle_io_manager, "s3": s3_resource},
)
local_assets = with_resources(
[upstream_asset, downstream_asset],
resource_defs={"io_manager": fs_io_manager},
)
In some cases you may need to load the input to an asset with different logic than that specified by the upstream asset's IO manager.
To set an IO manager for a particular input, use the input_manager_key
argument on AssetIn
.
In this example,first_asset
and second_asset
will be stored using the default IO manager, but will be loaded as inputs to third_asset
using the logic defined in the pandas_series_io_manager
(in this case loading as Pandas Series rather than python lists).
@asset
def first_asset():
return [1, 2, 3]
@asset
def second_asset():
return [4, 5, 6]
@asset(
ins={
"first_asset": AssetIn(input_manager_key="pandas_series"),
"second_asset": AssetIn(input_manager_key="pandas_series"),
}
)
def third_asset(first_asset, second_asset):
return pd.concat([first_asset, second_asset, pd.Series([7, 8])])
assets_with_io_managers = with_resources(
[first_asset, second_asset, third_asset],
resource_defs={
"pandas_series": pandas_series_io_manager,
},
)
By default, all the inputs and outputs in a job use the same IO manager. This IO manager is determined by the ResourceDefinition
provided for the "io_manager"
resource key. "io_manager"
is a resource key that Dagster reserves specifically for this purpose.
Here’s how to specify that all op outputs are stored using the fs_io_manager
, which pickles outputs and stores them on the local filesystem. It stores files in a directory with the run ID in the path, so that outputs from prior runs will never be overwritten.
from dagster import fs_io_manager, job, op
@op
def op_1():
return 1
@op
def op_2(a):
return a + 1
@job(resource_defs={"io_manager": fs_io_manager})
def my_job():
op_2(op_1())
Not all the outputs in a job should necessarily be stored the same way. Maybe some of the outputs should live on the filesystem so they can be inspected, and others can be transiently stored in memory.
To select the IO manager for a particular output, you can set an io_manager_key
on Out
, and then refer to that io_manager_key
when setting IO managers in your job. In this example, the output of op_1
will go to fs_io_manager
and the output of op_2
will go to s3_pickle_io_manager
.
from dagster_aws.s3 import s3_pickle_io_manager, s3_resource
from dagster import Out, fs_io_manager, job, op
@op(out=Out(io_manager_key="fs"))
def op_1():
return 1
@op(out=Out(io_manager_key="s3_io"))
def op_2(a):
return a + 1
@job(
resource_defs={
"fs": fs_io_manager,
"s3_io": s3_pickle_io_manager,
"s3": s3_resource,
}
)
def my_job():
op_2(op_1())
Just as with the inputs to assets, the inputs to ops can be loaded using custom logic if you want to override the IO manager of the upstream output. To set an IO manager for a particular input, use the input_manager_key
argument on In
.
In this example, the output of op_1
will be stored using the default IO manager, but will be loaded in op_2
using the logic defined in the pandas_series_io_manager
(in this case loading as Pandas Series rather than python lists).
@op
def op_1():
return [1, 2, 3]
@op(ins=In(input_manager_key="pandas_series"))
def op_2(a):
return pd.concat([a, pd.Series([4, 5, 6])])
@job(resource_defs={"pandas_series": pd_series_io_manager})
def a_job():
op_2(op_1())
If you have specific requirements for where and how your outputs should be stored and retrieved, you can define your own IO manager. This boils down to implementing two functions: one that stores outputs and one that loads inputs.
To define an IO manager, use the @io_manager
decorator.
class MyIOManager(IOManager):
def handle_output(self, context, obj):
write_csv("some/path")
def load_input(self, context):
return read_csv("some/path")
@io_manager
def my_io_manager(init_context):
return MyIOManager()
The io_manager
decorator behaves nearly identically to the resource
decorator. It yields an IOManagerDefinition
, which is a subclass of ResourceDefinition
that will produce an IOManager
.
The provided context
argument for handle_output
is an OutputContext
. The provided context
argument for load_input
is an InputContext
. The linked API documentation lists all the fields that are available on these objects.
IO managers interoperate smoothly with partitions. You can access the partition key for the current run using the context
for both load_input
and handle_output
. If working with assets, you can also access the asset-specific partition key or partition key range, though most of the time the run partition key will be equal to the asset partition key.
from dagster import IOManager
class MyPartitionedIOManager(IOManager):
def path_for_partition(self, partition_key):
return f"some/path/{partition_key}.csv"
# `context.partition_key` is the run-scoped partition key
def handle_output(self, context, obj):
write_csv(self.path_for_partition(context.partition_key), obj)
# `context.asset_partition_key` is set to the partition key for an asset
# (if the `IOManager` is handling an asset). This is usually equal to the
# run `partition_key`.
def load_input(self, context):
return read_csv(self.path_for_partition(context.asset_partition_key))
In some cases you may find that you need to load an input in a way other than the load_input
function of the corresponding output's IO manager. For example, let's say Team A has an op that returns an output as a Pandas DataFrame and specifies an IO manager that knows how to store and load Pandas DataFrames. Your team is interested in using this output for a new op, but you are required to use PySpark to analyze the data. Unfortunately, you don't have permission to modify Team A's IO manager to support this case. Instead, you can specify an input manager on your op that will override some of the behavior of Team A's IO manager.
Since the method for loading an input is directly affected by the way the corresponding output was stored, we recommend defining your input managers as subclasses of existing IO managers and just updating the load_input
method. In this example, we load an input as a NumPy array rather than a Pandas DataFrame by writing the following:
# in this case PandasIOManager is an existing IO Manager
class MyNumpyLoader(PandasIOManager):
def load_input(self, context):
file_path = "path/to/dataframe"
array = np.genfromtxt(file_path, delimiter=",", dtype=None)
return array
@io_manager
def numpy_io_manager():
return MyNumpyLoader()
@op(ins={"np_array_input": In(input_manager_key="numpy_manager")})
def analyze_as_numpy(np_array_input: np.ndarray):
assert isinstance(np_array_input, np.ndarray)
@job(resource_defs={"numpy_manager": numpy_io_manager, "io_manager": pandas_io_manager})
def my_job():
df = produce_pandas_output()
analyze_as_numpy(df)
This may quickly run into issues if the owner of PandasIOManager
changes the path at which they store outputs. We recommend splitting out path defining logic (or other computations shared by handle_output
and load_input
) into new methods that are called when needed.
# this IO Manager is owned by a different team
class BetterPandasIOManager(IOManager):
def _get_path(self, output_context):
return os.path.join(
self.base_dir,
"storage",
f"{output_context.step_key}_{output_context.name}.csv",
)
def handle_output(self, context, obj: pd.DataFrame):
file_path = self._get_path(context)
os.makedirs(os.path.dirname(file_path), exist_ok=True)
if obj is not None:
obj.to_csv(file_path, index=False)
def load_input(self, context) -> pd.DataFrame:
return pd.read_csv(self._get_path(context.upstream_output)) # type: ignore
# write a subclass that uses _get_path for your custom loading logic
class MyBetterNumpyLoader(PandasIOManager):
def load_input(self, context):
file_path = self._get_path(context.upstream_output)
array = np.genfromtxt(file_path, delimiter=",", dtype=None)
return array
@io_manager
def better_numpy_io_manager():
return MyBetterNumpyLoader()
@op(ins={"np_array_input": In(input_manager_key="better_numpy_manager")})
def better_analyze_as_numpy(np_array_input: np.ndarray):
assert isinstance(np_array_input, np.ndarray)
@job(
resource_defs={
"numpy_manager": better_numpy_io_manager,
"io_manager": pandas_io_manager,
}
)
def my_better_job():
df = produce_pandas_output()
better_analyze_as_numpy(df)
If your ops produce Pandas DataFrames that populate tables in a data warehouse, you might write something like the following. This IO manager uses the name assigned to the output as the name of the table to write the output to.
from dagster import IOManager, io_manager
class DataframeTableIOManager(IOManager):
def handle_output(self, context, obj):
# name is the name given to the Out that we're storing for
table_name = context.name
write_dataframe_to_table(name=table_name, dataframe=obj)
def load_input(self, context):
# upstream_output.name is the name given to the Out that we're loading for
table_name = context.upstream_output.name
return read_dataframe_from_table(name=table_name)
@io_manager
def df_table_io_manager(_):
return DataframeTableIOManager()
@job(resource_defs={"io_manager": df_table_io_manager})
def my_job():
op_2(op_1())
When launching a run, you might want to parameterize how particular outputs are stored.
For example, if your job produces DataFrames to populate tables in a data warehouse, you might want to specify the table that each output goes to at run launch time.
To accomplish this, you can define an output_config_schema
on the IO manager definition. The IO manager methods can access this config when storing or loading data, via the OutputContext
.
class MyIOManager(IOManager):
def handle_output(self, context, obj):
table_name = context.config["table"]
write_dataframe_to_table(name=table_name, dataframe=obj)
def load_input(self, context):
table_name = context.upstream_output.config["table"]
return read_dataframe_from_table(name=table_name)
@io_manager(output_config_schema={"table": str})
def my_io_manager(_):
return MyIOManager()
Then, when executing a job, you can pass in this per-output config.
def execute_my_job_with_config():
@job(resource_defs={"io_manager": my_io_manager})
def my_job():
op_2(op_1())
my_job.execute_in_process(
run_config={
"ops": {
"op_1": {"outputs": {"result": {"table": "table1"}}},
"op_2": {"outputs": {"result": {"table": "table2"}}},
}
},
)
You might want to provide static metadata that controls how particular outputs are stored. You don't plan to change the metadata at runtime, so it makes more sense to attach it to a definition rather than expose it as a configuration option.
For example, if your job produces DataFrames to populate tables in a data warehouse, you might want to specify that each output always goes to a particular table. To accomplish this, you can define metadata
on each Out
:
@op(out=Out(metadata={"schema": "some_schema", "table": "some_table"}))
def op_1():
"""Return a Pandas DataFrame"""
@op(out=Out(metadata={"schema": "other_schema", "table": "other_table"}))
def op_2(_input_dataframe):
"""Return a Pandas DataFrame"""
The IO manager can then access this metadata when storing or retrieving data, via the OutputContext
.
In this case, the table names are encoded in the job definition. If, instead, you want to be able to set them at run time, the next section describes how.
class MyIOManager(IOManager):
def handle_output(self, context, obj):
table_name = context.metadata["table"]
schema = context.metadata["schema"]
write_dataframe_to_table(name=table_name, schema=schema, dataframe=obj)
def load_input(self, context):
table_name = context.upstream_output.metadata["table"]
schema = context.upstream_output.metadata["schema"]
return read_dataframe_from_table(name=table_name, schema=schema)
@io_manager
def my_io_manager(_):
return MyIOManager()
Let's say you have an asset that is set to store and load as a Pandas DataFrame, but you want to write a new asset that processes the first asset as a NumPy array. Rather than update the IO manager of the first asset to be able to load as a Pandas DataFrame and a NumPy array, you can write a new loader for the new asset.
In this example, we store upstream_asset
as a Pandas DataFrame, and we write a new IO manager to load is as a NumPy array in downstream_asset
class PandasAssetIOManager(IOManager):
def handle_output(self, context, obj):
file_path = self._get_path(context)
store_pandas_dataframe(name=file_path, table=obj)
def _get_path(self, context):
return os.path.join(
"storage",
f"{context.asset_key.path[-1]}.csv",
)
def load_input(self, context):
file_path = self._get_path(context)
return load_pandas_dataframe(name=file_path)
@io_manager
def pandas_asset_io_manager():
return PandasAssetIOManager()
class NumpyAssetIOManager(PandasAssetIOManager):
def load_input(self, context):
file_path = self._get_path(context)
return load_numpy_array(name=file_path)
@io_manager
def numpy_asset_io_manager():
return NumpyAssetIOManager()
@asset(io_manager_key="pandas_manager")
def upstream_asset():
return pd.DataFrame([1, 2, 3])
@asset(
ins={"upstream": AssetIn(key_prefix="public", input_manager_key="numpy_manager")}
)
def downstream_asset(upstream):
return upstream.shape
assets_with_io_managers = with_resources(
[upstream_asset, downstream_asset],
resource_defs={
"pandas_manager": pandas_asset_io_manager,
"numpy_manager": numpy_asset_io_manager,
},
)
The easiest way to test an IO manager is to construct an OutputContext
or InputContext
and pass it to the handle_output
or load_input
method of the IO manager. The build_output_context
and build_input_context
functions allow for easy construction of these contexts.
Here's an example for a simple IO manager that stores outputs in an in-memory dictionary that's keyed on the step and name of the output.
from dagster import IOManager, build_input_context, build_output_context, io_manager
class MyIOManager(IOManager):
def __init__(self):
self.storage_dict = {}
def handle_output(self, context, obj):
self.storage_dict[(context.step_key, context.name)] = obj
def load_input(self, context):
return self.storage_dict[
(context.upstream_output.step_key, context.upstream_output.name)
]
@io_manager
def my_io_manager(_):
return MyIOManager()
def test_my_io_manager_handle_output():
manager = my_io_manager(None)
context = build_output_context(name="abc", step_key="123")
manager.handle_output(context, 5)
assert manager.storage_dict[("123", "abc")] == 5
def test_my_io_manager_load_input():
manager = my_io_manager(None)
manager.storage_dict[("123", "abc")] = 5
context = build_input_context(
upstream_output=build_output_context(name="abc", step_key="123")
)
assert manager.load_input(context) == 5
Sometimes, you may want to record some metadata while handling an output in an IO manager. To do this, you can invoke OutputContext.add_output_metadata
from within the body of the handle_output
function. Using this, we can modify one of the above examples to now include some helpful metadata in the log:
class DataframeTableIOManagerWithMetadata(IOManager):
def handle_output(self, context, obj):
table_name = context.name
write_dataframe_to_table(name=table_name, dataframe=obj)
context.add_output_metadata({"num_rows": len(obj), "table_name": table_name})
def load_input(self, context):
table_name = context.upstream_output.name
return read_dataframe_from_table(name=table_name)
Any entries yielded this way will be attached to the Handled Output
event for this output.
Additionally, if the handled output is part of a software-defined asset, these metadata entries will also be attached to the materialization event created for that asset and show up on the Asset Details page for the asset.
For more examples of IO Managers, check out the following in our Hacker News example:
Our Type and Metadata example also covers writing custom IO managers.