Metadata-Version: 2.4
Name: linepipe
Version: 0.2.0
Summary: Composable, linear pipelines
License: MIT
License-File: LICENSE
Keywords: pipeline,data-processing
Author: Marek Kancir
Author-email: kancir.marek@gmail.com
Requires-Python: >=3.11, !=2.7.*, !=3.0.*, !=3.1.*, !=3.2.*, !=3.3.*, !=3.4.*, !=3.5.*, !=3.6.*, !=3.7.*, !=3.8.*, !=3.9.*, !=3.10.*
Classifier: Development Status :: 3 - Alpha
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Classifier: Programming Language :: Python :: 3.13
Classifier: Programming Language :: Python :: 3.14
Provides-Extra: memory
Provides-Extra: plot
Requires-Dist: memory-profiler (==0.61.0) ; extra == "memory"
Requires-Dist: networkx (==3.6.1) ; extra == "plot"
Requires-Dist: plotly (==6.5.2) ; extra == "plot"
Project-URL: Homepage, https://github.com/marek-kan/linepipe
Project-URL: Repository, https://github.com/marek-kan/linepipe
Description-Content-Type: text/markdown

# linepipe

`linepipe` sits between ad-hoc Python scripts and full orchestration frameworks.
It is best suited for batch pipelines, feature engineering, and reproducible data workflows where simplicity and clarity matter more than scale.

It focuses on:

* clear data dependencies
* reproducible execution (linear pipelines)
* fast iteration and debugging thanks to (local / in-memory) caching
* simple mental models

Example of a pipeline:

Each node consumes named inputs and produces named outputs, which are stored in an internal registry and made available to downstream nodes.

```python
pipeline = Pipeline(
    nodes=[
        Node(
            func=nodes.create_db_engine,
            inputs=["config.db"],
            outputs=["conn"],
        ),
        Node(
            func=nodes.load_data,
            inputs=["conn"],
            outputs=["df"],
        ),
        Node(
            func=nodes.preprocess_data,
            inputs=["df", "config.preprocessing"],
            outputs=["df_processed"],
        ),
        Node(
            func=nodes.feature_engineering,
            inputs=["df_processed", "config.feature_engineering"],
            outputs=["df_features"],
        ),
        Node(
            func=nodes.train,
            inputs=["df_features", "config.model_params"],
            outputs=["model"],
        ),
    ],
    config=config
)

pipeline.run()
```

A minimal end-to-end example is available as a Jupyter notebook:

- `examples/basic_usage.ipynb`

It walks through:
- defining nodes
- building a pipeline
- running it and inspecting outputs

---

## Installation

`pip install linepipe`

Optionally:
 - `pip install linepipe[memory]` - [memory profiling](#optional-memory-profiling) nodes
 - `pip install linepipe[plot]` - plotly instead default string [pipeline graph](#pipeline-visualization)

---

## Why linepipe?

Many pipeline tools are powerful but come with:

* large configuration surfaces
* implicit data catalogs
* steep learning curves

`linepipe` intentionally keeps things simple:

* **Explicit > implicit**
* **Minimal surface area**
* **Easy to reason about**
* **Easy to debug**

### Non-goals

* Distributed execution
* Dynamic DAG scheduling
* Dataset catalogs
* Orchestration / scheduling

`linepipe` is a *building block*, not a platform.

---

## Core concepts

### Node

A `Node` wraps a Python callable and declares:

* which **inputs** it consumes
* which **outputs** it produces

```python
from linepipe.node import Node

def add(a, b):
    return a + b

node = Node(
    func=add,
    inputs=["x", "y"],
    outputs=["sum"],
)
```

Nodes are executed sequentially inside a `Pipeline`.

---

### Pipeline

A `Pipeline` executes a list of `Node`s in order, resolving inputs from:

1. configuration
2. cached / in-memory outputs
3. runtime objects

```python
from linepipe.pipeline import Pipeline

pipeline = Pipeline(
    nodes=[node],
    config={},
    x=2,
    y=3,
)

pipeline.run()
```

Intermediate results can be cached automatically.

### Object Registry

During execution, `linepipe` maintains an internal object registry that:

- stores intermediate node outputs
  - optionally persists them to disk
- holds runtime-only objects (e.g. DB connections)
- injects runtime constants into the pipeline

The registry is created per pipeline run and closed automatically after run is finished.
Users can reopen in with `pipeline.get_obj_registry()`.

---

## Inputs and outputs

Resolution rules:

1) Inputs starting with `config.` or equal to `config` are resolved from the pipeline configuration.
2) All other inputs are resolved from the pipeline's internal object registry (which may contain persisted or in-memory objects)
3) Runtime constants are injected into the registry at pipeline creation time

### Name collisions

Each name in a pipeline must uniquely refer to a single object.

If a name exists both as:
- a runtime constant, and
- a persisted cached object

the pipeline will fail fast with an error.

This prevents subtle bugs caused by stale cache values overriding runtime state.

### Explicit data flow

Each node declares **string-named inputs and outputs**:

```python
Node(
    func=transform,
    inputs=["raw_data"],
    outputs=["features"],
)
```

---

### Config injection

Configuration values can be injected using `config.<attr>` or you can pass whole `config` object with `"config"`:

```python
class Config:
    window = 5

Node(
    func=rolling_average,
    inputs=["data", "config.window"],
    outputs=["features"],
)
```

---

## Caching

### Persistent cache

You can turn on a disk-backed cache (`shelve`) to store intermediate results with `use_persistent_cache=True`.

```python
pipeline = Pipeline(
    nodes=nodes,
    config=config,
    cache_storage_path="./.cache/pipeline.db",
    use_persistent_cache=True,
)
```

* Cached outputs can be reused across runs, as long as output names do not conflict with runtime constants.
* When persistent caching is enabled, cached objects from previous runs are automatically restored at startup.
* The cache is closed automatically at the end of execution (i.e. `pipeline.run()`)

You can reopen it for inspection:

```python
ds = pipeline.get_obj_registry()
# placement of registred objects:
print(registry.placement)
registry.close()
```

---

## Side-effect nodes (writers)

Nodes may have **no outputs**, useful for:

* database writes
* file exports
* logging

```python
def write_to_db(df):
    ...

Node(
    func=write_to_db,
    inputs=["features"],
    outputs=[],
)
```

---

## Named partial functions

`linepipe` provides a helper to adapt generic functions into distinct pipeline nodes.

```python
from linepipe.node import create_named_partial_function
from my_package.pipelines.outputs import nodes

write_val_metrics = Node(
    func=create_named_partial_function(
        func=nodes.write_pipeline_output,
        func_name="write_val_metrics",
        table_name="metrics",
        schema="ml"
    ),
    inputs=["val_metrics"],
    outputs=[],
)

write_predictions = Node(
    func=create_named_partial_function(
        func=nodes.write_pipeline_output,
        func_name="write_predictions",
        table_name="predictions",
        schema="ml"
    ),
    inputs=["predictions"],
    outputs=[],
)
```

This:

* pre-binds keyword arguments
* gives the node a stable, readable name
* improves logging, history, and introspection

---

## Pipeline composition

Pipelines can be combined using `+`:

```python
full_pipeline = feature_pipeline + writer_pipeline
full_pipeline.run()
```

Composition:

* preserves execution order
* prevents output name collisions
* merges runtime constants and configuration
* Gives you pipeline reusability, for example, same feature-generation pipeline in train and predict

---

## Pipeline visualization

`linepipe.viz` provides simple, no-dependency ascii graph drawing function `draw_ascii_pipeline`. It draws nodes in order they are defined along with their inputs and outputs - good for quick check.

```python
from linepipe import viz

print(viz.draw_ascii_pipeline(pipeline))
```

Output can look like this:
```
Pipeline (5 nodes)

[load_data]
  outputs:
    - raw_data
      |
      v
[clean_data]
  inputs:
    - raw_data
  outputs:
    - clean_data
      |
      v
[rolling_goals]
  inputs:
    - clean_data
    - config.window
    - config.min_periods
  outputs:
    - rolling_features
      |
      v
[merge]
  inputs:
    - clean_data
    - rolling_features
  outputs:
    - features
      |
      v
[write_features]
  inputs:
    - features
  (no outputs)
```

If you need something more visual for documentation purposes you can install optional dependency - `plotly` (`pip install linepipe[plot]`) and use `plot_pipeline` function - however, this function is experimental. Graph of pipeline above would look like:

`viz.plot_pipeline_graph(full_pipeline)`

![Pipeline plot](pipeline_plot.png)

---

## History tracking

Enable execution history for debugging:

```python
pipeline = Pipeline(
    nodes=nodes,
    config=config,
    track_history=True,  # in-memory persistent after `run()` is finished
    use_persistent_cache=False,  # (if True) disk persistent after `run()` is finished
)
```

After execution:

```python
pipeline.history
```

Each entry contains:

* node name
* resolved inputs
* outputs

Inputs and outputs are deep-copied at execution time to preserve snapshots. For large objects, this can significantly increase memory usage.

---

## [Optional] Memory profiling

If you wish to profile your nodes you can install optional `memory_profiler` dependency with `pip install linepipe[memory]`. This gives you ability to log memory usage during run of a node. For example:

```python
pipeline = Pipeline(
    nodes= [
        Node(
            func=nodes.expensive_function,
            inputs=["df"],
            outputs=["df_processed"],
            profile=True
        )
    ]
)
pipeline.run()
```

This will produce logs like:

`[expensive_function] ΔMem: 0.94 MiB | Peak: 0.94 MiB`

Structure is `[node_name] ΔMem: {float} MiB | Peak: {float} MiB`

 * ΔMem: delta between first and last recorded value
 * Peak: delta between maximum recorded value and first recorded value

---

## License

MIT License.

