diffusers/docs/source/en/modular_diffusers/quickstart.md

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# Quickstart

Modular Diffusers is a framework for quickly building flexible and customizable pipelines. These pipelines can go beyond what standard `DiffusionPipeline`s can do. At the core of Modular Diffusers are [`ModularPipelineBlocks`] that can be combined with other blocks to adapt to new workflows. The blocks are converted into a [`ModularPipeline`], a friendly user-facing interface for running generation tasks.

This guide shows you how to run a modular pipeline, understand its structure, and customize it by modifying the blocks that compose it.

## Run a pipeline

[`ModularPipeline`] is the main interface for loading, running, and managing modular pipelines.
```py
import torch
from diffusers import ModularPipeline, ComponentsManager

# Use ComponentsManager to enable auto CPU offloading for memory efficiency
manager = ComponentsManager()
manager.enable_auto_cpu_offload(device="cuda:0")

pipe = ModularPipeline.from_pretrained("Qwen/Qwen-Image", components_manager=manager)
pipe.load_components(torch_dtype=torch.bfloat16)

image = pipe(
    prompt="cat wizard with red hat, gandalf, lord of the rings, detailed, fantasy, cute, adorable, Pixar, Disney",
).images[0]
image
```

[`~ModularPipeline.from_pretrained`] uses lazy loading - it reads the configuration to learn where to load each component from, but doesn't actually load the model weights until you call [`~ModularPipeline.load_components`]. This gives you control over when and how components are loaded.

> [!TIP]
> `ComponentsManager` with `enable_auto_cpu_offload` automatically moves models between CPU and GPU as needed, reducing memory usage for large models like Qwen-Image. Learn more in the [ComponentsManager](./components_manager) guide.
>
> If you don't need offloading, remove the `components_manager` argument and move the pipeline to your device manually with `to("cuda")`.

Learn more about creating and loading pipelines in the [Creating a pipeline](https://huggingface.co/docs/diffusers/modular_diffusers/modular_pipeline#creating-a-pipeline) and [Loading components](https://huggingface.co/docs/diffusers/modular_diffusers/modular_pipeline#loading-components) guides.

## Understand the structure

A [`ModularPipeline`] has two parts: a **definition** (the blocks) and a **state** (the loaded components and configs).

Print the pipeline to see its state — the components and their loading status and configuration.
```py
print(pipe)
```
```
QwenImageModularPipeline {
  "_blocks_class_name": "QwenImageAutoBlocks",
  "_class_name": "QwenImageModularPipeline",
  "_diffusers_version": "0.37.0.dev0",
  "transformer": [
    "diffusers",
    "QwenImageTransformer2DModel",
    {
      "pretrained_model_name_or_path": "Qwen/Qwen-Image",
      "revision": null,
      "subfolder": "transformer",
      "type_hint": [
        "diffusers",
        "QwenImageTransformer2DModel"
      ],
      "variant": null
    }
  ],
  ...
}
```

Access the definition through `pipe.blocks` — this is the [`~modular_pipelines.ModularPipelineBlocks`] that defines the pipeline's workflows, inputs, outputs, and computation logic.
```py
print(pipe.blocks)
```
```
QwenImageAutoBlocks(
  Class: SequentialPipelineBlocks

  Description: Auto Modular pipeline for text-to-image, image-to-image, inpainting, and controlnet tasks using QwenImage.
      
      Supported workflows:
        - `text2image`: requires `prompt`
        - `image2image`: requires `prompt`, `image`
        - `inpainting`: requires `prompt`, `mask_image`, `image`
        - `controlnet_text2image`: requires `prompt`, `control_image`
        ...

  Components:
      text_encoder (`Qwen2_5_VLForConditionalGeneration`)
      vae (`AutoencoderKLQwenImage`)
      transformer (`QwenImageTransformer2DModel`)
      ...

  Sub-Blocks:
    [0] text_encoder (QwenImageAutoTextEncoderStep)
    [1] vae_encoder (QwenImageAutoVaeEncoderStep)
    [2] controlnet_vae_encoder (QwenImageOptionalControlNetVaeEncoderStep)
    [3] denoise (QwenImageAutoCoreDenoiseStep)
    [4] decode (QwenImageAutoDecodeStep)
)
```

The output returns:
- The supported workflows (text2image, image2image, inpainting, etc.)
- The Sub-Blocks it's composed of (text_encoder, vae_encoder, denoise, decode)

### Workflows

This pipeline supports multiple workflows and adapts its behavior based on the inputs you provide. For example, if you pass `image` to the pipeline, it runs an image-to-image workflow instead of text-to-image. Learn more about how this works under the hood in the [AutoPipelineBlocks](https://huggingface.co/docs/diffusers/modular_diffusers/auto_pipeline_blocks) guide.

```py
from diffusers.utils import load_image

input_image = load_image("https://github.com/Trgtuan10/Image_storage/blob/main/cute_cat.png?raw=true")

image = pipe(
    prompt="cat wizard with red hat, gandalf, lord of the rings, detailed, fantasy, cute, adorable, Pixar, Disney",
    image=input_image,
).images[0]
```

Use `get_workflow()` to extract the blocks for a specific workflow. Pass the workflow name (e.g., `"image2image"`, `"inpainting"`, `"controlnet_text2image"`) to get only the blocks relevant to that workflow. This is useful when you want to customize or debug a specific workflow. You can check `pipe.blocks.available_workflows` to see all available workflows.
```py
img2img_blocks = pipe.blocks.get_workflow("image2image")
```


### Sub-blocks

Blocks can contain other blocks. `pipe.blocks` gives you the top-level block definition (here, `QwenImageAutoBlocks`), while `sub_blocks` lets you access the smaller blocks inside it.

`QwenImageAutoBlocks` is composed of: `text_encoder`, `vae_encoder`, `controlnet_vae_encoder`, `denoise`, and `decode`.

These sub-blocks run one after another and data flows linearly from one block to the next — each block's `intermediate_outputs` become available as `inputs` to the next block. This is how [`SequentialPipelineBlocks`](./sequential_pipeline_blocks) work.

You can access them through the `sub_blocks` property. The `doc` property is useful for seeing the full documentation of any block, including its inputs, outputs, and components.
```py
vae_encoder_block = pipe.blocks.sub_blocks["vae_encoder"]
print(vae_encoder_block.doc)
```

This block can be converted to a pipeline so that it can run on its own with [`~ModularPipelineBlocks.init_pipeline`].
```py
vae_encoder_pipe = vae_encoder_block.init_pipeline()

# Reuse the VAE we already loaded, we can reuse it with update_components() method
vae_encoder_pipe.update_components(vae=pipe.vae)

# Run just this block
image_latents = vae_encoder_pipe(image=input_image).image_latents
print(image_latents.shape)
```

It reuses the VAE from our original pipeline instead of reloading it, keeping memory usage efficient. Learn more in the [Loading components](https://huggingface.co/docs/diffusers/modular_diffusers/modular_pipeline#loading-components) guide.

Since blocks are composable, you can modify the pipeline's definition by adding, removing, or swapping blocks to create new workflows. In the next section, we'll add a canny edge detection block to a ControlNet pipeline, so you can pass a regular image instead of a pre-processed canny edge map.

## Compose new workflows

Let's add a canny edge detection block to a ControlNet pipeline. First, load a pre-built canny block from the Hub (see [Building Custom Blocks](https://huggingface.co/docs/diffusers/modular_diffusers/custom_blocks) to create your own).
```py
from diffusers.modular_pipelines import ModularPipelineBlocks

# Load a canny block from the Hub
canny_block = ModularPipelineBlocks.from_pretrained(
    "diffusers-internal-dev/canny-filtering",
    trust_remote_code=True,
)

print(canny_block.doc)
```
```
class CannyBlock

  Inputs:
      image (`Union[Image, ndarray]`):
          Image to compute canny filter on
      low_threshold (`int`, *optional*, defaults to 50):
          Low threshold for the canny filter.
      high_threshold (`int`, *optional*, defaults to 200):
          High threshold for the canny filter.
      ...

  Outputs:
      control_image (`PIL.Image`):
          Canny map for input image
```

Use `get_workflow` to extract the ControlNet workflow from [`QwenImageAutoBlocks`].
```py
# Get the controlnet workflow that we want to work with
blocks = pipe.blocks.get_workflow("controlnet_text2image")
print(blocks.doc)
```
```
class SequentialPipelineBlocks

  Inputs:
      prompt (`str`):
          The prompt or prompts to guide image generation.
      control_image (`Image`):
          Control image for ControlNet conditioning.
      ...
```


The extracted workflow is a [`SequentialPipelineBlocks`](./sequential_pipeline_blocks) and it currently requires `control_image` as input. Insert the canny block at the beginning so the pipeline accepts a regular image instead.
```py
# Insert canny at the beginning
blocks.sub_blocks.insert("canny", canny_block, 0)

# Check the updated structure: CannyBlock is now listed as first sub-block
print(blocks)
# Check the updated doc
print(blocks.doc)
```
```
class SequentialPipelineBlocks

  Inputs:
      image (`Union[Image, ndarray]`):
          Image to compute canny filter on
      low_threshold (`int`, *optional*, defaults to 50):
          Low threshold for the canny filter.
      high_threshold (`int`, *optional*, defaults to 200):
          High threshold for the canny filter.
      prompt (`str`):
          The prompt or prompts to guide image generation.
      ...
```

Now the pipeline takes `image` as input instead of `control_image`. Because blocks in a sequence share data automatically, the canny block's output (`control_image`) flows to the denoise block that needs it, and the canny block's input (`image`) becomes a pipeline input since no earlier block provides it.

Create a pipeline from the modified blocks and load a ControlNet model. The ControlNet isn't part of the original model repository, so load it separately and add it with [`~ModularPipeline.update_components`].
```py
pipeline = blocks.init_pipeline("Qwen/Qwen-Image", components_manager=manager)

pipeline.load_components(torch_dtype=torch.bfloat16)

# Load the ControlNet model
controlnet_spec = pipeline.get_component_spec("controlnet")
controlnet_spec.pretrained_model_name_or_path = "InstantX/Qwen-Image-ControlNet-Union"
controlnet = controlnet_spec.load(torch_dtype=torch.bfloat16)
pipeline.update_components(controlnet=controlnet)
```

Now run the pipeline - the canny block preprocesses the image for ControlNet.
```py
from diffusers.utils import load_image

prompt = "cat wizard with red hat, gandalf, lord of the rings, detailed, fantasy, cute, adorable, Pixar, Disney"
image = load_image("https://github.com/Trgtuan10/Image_storage/blob/main/cute_cat.png?raw=true")

output = pipeline(
    prompt=prompt,
    image=image,
).images[0]
output
```

## Next steps

<hfoptions id="next">
<hfoption id="Learn the basics">

Understand the core building blocks of Modular Diffusers:

- [ModularPipelineBlocks](./pipeline_block): The basic unit for defining a step in a pipeline.
- [SequentialPipelineBlocks](./sequential_pipeline_blocks): Chain blocks to run in sequence.
- [AutoPipelineBlocks](./auto_pipeline_blocks): Create pipelines that support multiple workflows.
- [States](./modular_diffusers_states): How data is shared between blocks.

</hfoption>
<hfoption id="Build custom blocks">

Learn how to create your own blocks with custom logic in the [Building Custom Blocks](./custom_blocks) guide.

</hfoption>
<hfoption id="Share components">

Use [`ComponentsManager`](./components_manager) to share models across multiple pipelines and manage memory efficiently.

</hfoption>
<hfoption id="Visual interface">

Connect modular pipelines to [Mellon](https://github.com/cubiq/Mellon), a visual node-based interface for building workflows. Custom blocks built with Modular Diffusers work out of the box with Mellon - no UI code required. Read more in the Mellon guide.

</hfoption>
</hfoptions>