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--- |
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library_name: pytorch |
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license: apache-2.0 |
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pipeline_tag: unconditional-image-generation |
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tags: |
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- generative_ai |
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- quantized |
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- android |
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--- |
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![](https://qaihub-public-assets.s3.us-west-2.amazonaws.com/qai-hub-models/models/controlnet_quantized/web-assets/model_demo.png) |
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# ControlNet: Optimized for Mobile Deployment |
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## Generating visual arts from text prompt and input guiding image |
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On-device, high-resolution image synthesis from text and image prompts. ControlNet guides Stable-diffusion with provided input image to generate accurate images from given input prompt. |
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This model is an implementation of ControlNet found [here]({source_repo}). |
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This repository provides scripts to run ControlNet on Qualcomm® devices. |
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More details on model performance across various devices, can be found |
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[here](https://aihub.qualcomm.com/models/controlnet_quantized). |
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### Model Details |
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- **Model Type:** Image generation |
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- **Model Stats:** |
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- Input: Text prompt and input image as a reference |
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- Conditioning Input: Canny-Edge |
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- Text Encoder Number of parameters: 340M |
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- UNet Number of parameters: 865M |
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- VAE Decoder Number of parameters: 83M |
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- ControlNet Number of parameters: 361M |
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- Model size: 1.4GB |
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| Model | Device | Chipset | Target Runtime | Inference Time (ms) | Peak Memory Range (MB) | Precision | Primary Compute Unit | Target Model |
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|---|---|---|---|---|---|---|---|---| |
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| TextEncoder_Quantized | Samsung Galaxy S23 | Snapdragon® 8 Gen 2 | QNN | 11.394 ms | 0 - 74 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/TextEncoder_Quantized.bin) | |
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| TextEncoder_Quantized | Samsung Galaxy S24 | Snapdragon® 8 Gen 3 | QNN | 8.08 ms | 0 - 137 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/TextEncoder_Quantized.bin) | |
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| TextEncoder_Quantized | QCS8550 (Proxy) | QCS8550 Proxy | QNN | 10.982 ms | 0 - 1 MB | UINT16 | NPU | Use Export Script | |
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| UNet_Quantized | Samsung Galaxy S23 | Snapdragon® 8 Gen 2 | QNN | 262.52 ms | 11 - 17 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/UNet_Quantized.bin) | |
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| UNet_Quantized | Samsung Galaxy S24 | Snapdragon® 8 Gen 3 | QNN | 192.789 ms | 3 - 1247 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/UNet_Quantized.bin) | |
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| UNet_Quantized | QCS8550 (Proxy) | QCS8550 Proxy | QNN | 260.158 ms | 14 - 15 MB | UINT16 | NPU | Use Export Script | |
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| VAEDecoder_Quantized | Samsung Galaxy S23 | Snapdragon® 8 Gen 2 | QNN | 390.243 ms | 0 - 36 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/VAEDecoder_Quantized.bin) | |
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| VAEDecoder_Quantized | Samsung Galaxy S24 | Snapdragon® 8 Gen 3 | QNN | 294.404 ms | 0 - 88 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/VAEDecoder_Quantized.bin) | |
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| VAEDecoder_Quantized | QCS8550 (Proxy) | QCS8550 Proxy | QNN | 379.548 ms | 0 - 1 MB | UINT16 | NPU | Use Export Script | |
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| ControlNet_Quantized | Samsung Galaxy S23 | Snapdragon® 8 Gen 2 | QNN | 100.33 ms | 2 - 68 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/ControlNet_Quantized.bin) | |
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| ControlNet_Quantized | Samsung Galaxy S24 | Snapdragon® 8 Gen 3 | QNN | 76.94 ms | 0 - 533 MB | UINT16 | NPU | [ControlNet.bin](https://huggingface.co/qualcomm/ControlNet/blob/main/ControlNet_Quantized.bin) | |
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| ControlNet_Quantized | QCS8550 (Proxy) | QCS8550 Proxy | QNN | 103.52 ms | 2 - 3 MB | UINT16 | NPU | Use Export Script | |
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## Installation |
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This model can be installed as a Python package via pip. |
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```bash |
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pip install "qai-hub-models[controlnet_quantized]" |
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``` |
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## Configure Qualcomm® AI Hub to run this model on a cloud-hosted device |
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Sign-in to [Qualcomm® AI Hub](https://app.aihub.qualcomm.com/) with your |
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Qualcomm® ID. Once signed in navigate to `Account -> Settings -> API Token`. |
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With this API token, you can configure your client to run models on the cloud |
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hosted devices. |
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```bash |
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qai-hub configure --api_token API_TOKEN |
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``` |
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Navigate to [docs](https://app.aihub.qualcomm.com/docs/) for more information. |
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## Demo on-device |
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The package contains a simple end-to-end demo that downloads pre-trained |
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weights and runs this model on a sample input. |
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```bash |
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python -m qai_hub_models.models.controlnet_quantized.demo |
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``` |
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The above demo runs a reference implementation of pre-processing, model |
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inference, and post processing. |
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**NOTE**: If you want running in a Jupyter Notebook or Google Colab like |
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environment, please add the following to your cell (instead of the above). |
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``` |
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%run -m qai_hub_models.models.controlnet_quantized.demo |
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``` |
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### Run model on a cloud-hosted device |
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In addition to the demo, you can also run the model on a cloud-hosted Qualcomm® |
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device. This script does the following: |
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* Performance check on-device on a cloud-hosted device |
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* Downloads compiled assets that can be deployed on-device for Android. |
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* Accuracy check between PyTorch and on-device outputs. |
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```bash |
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python -m qai_hub_models.models.controlnet_quantized.export |
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``` |
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``` |
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Profiling Results |
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------------------------------------------------------------ |
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TextEncoder_Quantized |
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Device : Samsung Galaxy S23 (13) |
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Runtime : QNN |
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Estimated inference time (ms) : 11.4 |
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Estimated peak memory usage (MB): [0, 74] |
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Total # Ops : 570 |
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Compute Unit(s) : NPU (570 ops) |
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------------------------------------------------------------ |
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UNet_Quantized |
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Device : Samsung Galaxy S23 (13) |
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Runtime : QNN |
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Estimated inference time (ms) : 262.5 |
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Estimated peak memory usage (MB): [11, 17] |
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Total # Ops : 5434 |
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Compute Unit(s) : NPU (5434 ops) |
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------------------------------------------------------------ |
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VAEDecoder_Quantized |
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Device : Samsung Galaxy S23 (13) |
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Runtime : QNN |
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Estimated inference time (ms) : 390.2 |
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Estimated peak memory usage (MB): [0, 36] |
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Total # Ops : 409 |
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Compute Unit(s) : NPU (409 ops) |
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------------------------------------------------------------ |
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ControlNet_Quantized |
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Device : Samsung Galaxy S23 (13) |
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Runtime : QNN |
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Estimated inference time (ms) : 100.3 |
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Estimated peak memory usage (MB): [2, 68] |
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Total # Ops : 2406 |
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Compute Unit(s) : NPU (2406 ops) |
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``` |
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## How does this work? |
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This [export script](https://aihub.qualcomm.com/models/controlnet_quantized/qai_hub_models/models/ControlNet/export.py) |
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leverages [Qualcomm® AI Hub](https://aihub.qualcomm.com/) to optimize, validate, and deploy this model |
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on-device. Lets go through each step below in detail: |
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Step 1: **Upload compiled model** |
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Upload compiled models from `qai_hub_models.models.controlnet_quantized` on hub. |
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```python |
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import torch |
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import qai_hub as hub |
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from qai_hub_models.models.controlnet_quantized import Model |
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# Load the model |
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model = Model.from_precompiled() |
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model_textencoder_quantized = hub.upload_model(model.text_encoder.get_target_model_path()) |
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model_unet_quantized = hub.upload_model(model.unet.get_target_model_path()) |
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model_vaedecoder_quantized = hub.upload_model(model.vae_decoder.get_target_model_path()) |
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model_controlnet_quantized = hub.upload_model(model.controlnet.get_target_model_path()) |
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``` |
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Step 2: **Performance profiling on cloud-hosted device** |
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After uploading compiled models from step 1. Models can be profiled model on-device using the |
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`target_model`. Note that this scripts runs the model on a device automatically |
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provisioned in the cloud. Once the job is submitted, you can navigate to a |
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provided job URL to view a variety of on-device performance metrics. |
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```python |
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# Device |
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device = hub.Device("Samsung Galaxy S23") |
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profile_job_textencoder_quantized = hub.submit_profile_job( |
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model=model_textencoder_quantized, |
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device=device, |
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) |
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profile_job_unet_quantized = hub.submit_profile_job( |
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model=model_unet_quantized, |
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device=device, |
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) |
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profile_job_vaedecoder_quantized = hub.submit_profile_job( |
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model=model_vaedecoder_quantized, |
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device=device, |
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) |
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profile_job_controlnet_quantized = hub.submit_profile_job( |
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model=model_controlnet_quantized, |
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device=device, |
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) |
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``` |
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Step 3: **Verify on-device accuracy** |
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To verify the accuracy of the model on-device, you can run on-device inference |
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on sample input data on the same cloud hosted device. |
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```python |
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input_data_textencoder_quantized = model.text_encoder.sample_inputs() |
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inference_job_textencoder_quantized = hub.submit_inference_job( |
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model=model_textencoder_quantized, |
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device=device, |
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inputs=input_data_textencoder_quantized, |
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) |
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on_device_output_textencoder_quantized = inference_job_textencoder_quantized.download_output_data() |
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input_data_unet_quantized = model.unet.sample_inputs() |
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inference_job_unet_quantized = hub.submit_inference_job( |
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model=model_unet_quantized, |
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device=device, |
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inputs=input_data_unet_quantized, |
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) |
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on_device_output_unet_quantized = inference_job_unet_quantized.download_output_data() |
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input_data_vaedecoder_quantized = model.vae_decoder.sample_inputs() |
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inference_job_vaedecoder_quantized = hub.submit_inference_job( |
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model=model_vaedecoder_quantized, |
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device=device, |
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inputs=input_data_vaedecoder_quantized, |
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) |
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on_device_output_vaedecoder_quantized = inference_job_vaedecoder_quantized.download_output_data() |
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input_data_controlnet_quantized = model.controlnet.sample_inputs() |
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inference_job_controlnet_quantized = hub.submit_inference_job( |
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model=model_controlnet_quantized, |
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device=device, |
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inputs=input_data_controlnet_quantized, |
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) |
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on_device_output_controlnet_quantized = inference_job_controlnet_quantized.download_output_data() |
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``` |
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With the output of the model, you can compute like PSNR, relative errors or |
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spot check the output with expected output. |
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**Note**: This on-device profiling and inference requires access to Qualcomm® |
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AI Hub. [Sign up for access](https://myaccount.qualcomm.com/signup). |
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## Deploying compiled model to Android |
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The models can be deployed using multiple runtimes: |
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- TensorFlow Lite (`.tflite` export): [This |
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tutorial](https://www.tensorflow.org/lite/android/quickstart) provides a |
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guide to deploy the .tflite model in an Android application. |
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- QNN ( `.so` / `.bin` export ): This [sample |
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app](https://docs.qualcomm.com/bundle/publicresource/topics/80-63442-50/sample_app.html) |
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provides instructions on how to use the `.so` shared library or `.bin` context binary in an Android application. |
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## View on Qualcomm® AI Hub |
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Get more details on ControlNet's performance across various devices [here](https://aihub.qualcomm.com/models/controlnet_quantized). |
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Explore all available models on [Qualcomm® AI Hub](https://aihub.qualcomm.com/) |
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## License |
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* The license for the original implementation of ControlNet can be found [here](https://github.com/lllyasviel/ControlNet/blob/main/LICENSE). |
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* The license for the compiled assets for on-device deployment can be found [here](https://github.com/lllyasviel/ControlNet/blob/main/LICENSE) |
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## References |
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* [Adding Conditional Control to Text-to-Image Diffusion Models](https://arxiv.org/abs/2302.05543) |
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* [Source Model Implementation](https://github.com/lllyasviel/ControlNet) |
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## Community |
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* Join [our AI Hub Slack community](https://aihub.qualcomm.com/community/slack) to collaborate, post questions and learn more about on-device AI. |
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* For questions or feedback please [reach out to us](mailto:[email protected]). |
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## Usage and Limitations |
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Model may not be used for or in connection with any of the following applications: |
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- Accessing essential private and public services and benefits; |
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- Administration of justice and democratic processes; |
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- Assessing or recognizing the emotional state of a person; |
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- Biometric and biometrics-based systems, including categorization of persons based on sensitive characteristics; |
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- Education and vocational training; |
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- Employment and workers management; |
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- Exploitation of the vulnerabilities of persons resulting in harmful behavior; |
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- General purpose social scoring; |
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- Law enforcement; |
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- Management and operation of critical infrastructure; |
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- Migration, asylum and border control management; |
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- Predictive policing; |
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- Real-time remote biometric identification in public spaces; |
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- Recommender systems of social media platforms; |
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- Scraping of facial images (from the internet or otherwise); and/or |
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- Subliminal manipulation |
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