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|
|
| # Reproducibility |
|
|
| Diffusion is a random process that generates a different output every time. For certain situations like testing and replicating results, you want to generate the same result each time, across releases and platforms within a certain tolerance range. |
|
|
| This guide will show you how to control sources of randomness and enable deterministic algorithms. |
|
|
| ## Generator |
|
|
| Pipelines rely on [torch.randn](https://pytorch.org/docs/stable/generated/torch.randn.html), which uses a different random seed each time, to create the initial noisy tensors. To generate the same output on a CPU or GPU, use a [Generator](https://docs.pytorch.org/docs/stable/generated/torch.Generator.html) to manage how random values are generated. |
|
|
| > [!TIP] |
| > If reproducibility is important to your use case, we recommend always using a CPU `Generator`. The performance loss is often negligible and you'll generate more similar values. |
|
|
| <hfoptions id="generator"> |
| <hfoption id="GPU"> |
|
|
| The GPU uses a different random number generator than the CPU. Diffusers solves this issue with the [`~utils.torch_utils.randn_tensor`] function to create the random tensor on a CPU and then moving it to the GPU. This function is used everywhere inside the pipeline and you don't need to explicitly call it. |
|
|
| Use [manual_seed](https://docs.pytorch.org/docs/stable/generated/torch.manual_seed.html) as shown below to set a seed. |
|
|
| ```py |
| import torch |
| import numpy as np |
| from diffusers import DDIMPipeline |
| |
| ddim = DDIMPipeline.from_pretrained("google/ddpm-cifar10-32", device_map="cuda") |
| generator = torch.manual_seed(0) |
| image = ddim(num_inference_steps=2, output_type="np", generator=generator).images |
| print(np.abs(image).sum()) |
| ``` |
|
|
| </hfoption> |
| <hfoption id="CPU"> |
|
|
| Set `device="cpu"` in the `Generator` and use [manual_seed](https://docs.pytorch.org/docs/stable/generated/torch.manual_seed.html) to set a seed for generating random numbers. |
|
|
| ```py |
| import torch |
| import numpy as np |
| from diffusers import DDIMPipeline |
| |
| ddim = DDIMPipeline.from_pretrained("google/ddpm-cifar10-32") |
| generator = torch.Generator(device="cpu").manual_seed(0) |
| image = ddim(num_inference_steps=2, output_type="np", generator=generator).images |
| print(np.abs(image).sum()) |
| ``` |
|
|
| </hfoption> |
| </hfoptions> |
|
|
| The `Generator` object should be passed to the pipeline instead of an integer seed. `Generator` maintains a *random state* that is consumed and modified when used. Once consumed, the same `Generator` object produces different results in subsequent calls, even across different pipelines, because its *state* has changed. |
|
|
| ```py |
| generator = torch.manual_seed(0) |
| |
| for _ in range(5): |
| - image = pipeline(prompt, generator=generator) |
| + image = pipeline(prompt, generator=torch.manual_seed(0)) |
| ``` |
|
|
| ## Deterministic algorithms |
|
|
| PyTorch supports [deterministic algorithms](https://docs.pytorch.org/docs/stable/notes/randomness.html#avoiding-nondeterministic-algorithms) - where available - for certain operations so they produce the same results. Deterministic algorithms may be slower and decrease performance. |
|
|
| Use Diffusers' [enable_full_determinism](https://github.com/huggingface/diffusers/blob/142f353e1c638ff1d20bd798402b68f72c1ebbdd/src/diffusers/utils/testing_utils.py#L861) function to enable deterministic algorithms. |
|
|
| ```py |
| import torch |
| from diffusers_utils import enable_full_determinism |
| |
| enable_full_determinism() |
| ``` |
|
|
| Under the hood, `enable_full_determinism` works by: |
|
|
| - Setting the environment variable [CUBLAS_WORKSPACE_CONFIG](https://docs.nvidia.com/cuda/cublas/index.html#results-reproducibility) to `:16:8` to only use one buffer size during rntime. Non-deterministic behavior occurs when operations are used in more than one CUDA stream. |
| - Disabling benchmarking to find the fastest convolution operation by setting `torch.backends.cudnn.benchmark=False`. Non-deterministic behavior occurs because the benchmark may select different algorithms each time depending on hardware or benchmarking noise. |
| - Disabling TensorFloat32 (TF32) operations in favor of more precise and consistent full-precision operations. |
|
|
|
|
| ## Resources |
|
|
| We strongly recommend reading PyTorch's developer notes about [Reproducibility](https://docs.pytorch.org/docs/stable/notes/randomness.html). You can try to limit randomness, but it is not *guaranteed* even with an identical seed. |