from typing import cast from warnings import warn import pytest from torch import Generator, Tensor, allclose, device as Device, equal, isclose, randn, tensor from refiners.fluxion import manual_seed from refiners.foundationals.latent_diffusion.solvers import ( DDIM, DDPM, DPMSolver, Euler, FrankenSolver, LCMSolver, ModelPredictionType, NoiseSchedule, Solver, SolverParams, TimestepSpacing, ) def test_ddpm_diffusers(): from diffusers import DDPMScheduler # type: ignore diffusers_scheduler = DDPMScheduler(beta_schedule="scaled_linear", beta_start=0.00085, beta_end=0.012) diffusers_scheduler.set_timesteps(1000) solver = DDPM(num_inference_steps=1000) assert equal(diffusers_scheduler.timesteps, solver.timesteps) @pytest.mark.parametrize("n_steps, last_step_first_order", [(5, False), (5, True), (30, False), (30, True)]) def test_dpm_solver_diffusers(n_steps: int, last_step_first_order: bool): from diffusers import DPMSolverMultistepScheduler as DiffuserScheduler # type: ignore manual_seed(0) diffusers_scheduler = DiffuserScheduler( beta_schedule="scaled_linear", beta_start=0.00085, beta_end=0.012, lower_order_final=False, euler_at_final=last_step_first_order, final_sigmas_type="sigma_min", # default before Diffusers 0.26.0 ) diffusers_scheduler.set_timesteps(n_steps) solver = DPMSolver( num_inference_steps=n_steps, last_step_first_order=last_step_first_order, ) assert equal(solver.timesteps, diffusers_scheduler.timesteps) sample = randn(1, 3, 32, 32) predicted_noise = randn(1, 3, 32, 32) for step, timestep in enumerate(diffusers_scheduler.timesteps): diffusers_output = cast(Tensor, diffusers_scheduler.step(predicted_noise, timestep, sample).prev_sample) # type: ignore refiners_output = solver(x=sample, predicted_noise=predicted_noise, step=step) assert allclose(diffusers_output, refiners_output, rtol=0.01), f"outputs differ at step {step}" def test_ddim_diffusers(): from diffusers import DDIMScheduler # type: ignore manual_seed(0) diffusers_scheduler = DDIMScheduler( beta_end=0.012, beta_schedule="scaled_linear", beta_start=0.00085, num_train_timesteps=1000, steps_offset=1, clip_sample=False, ) diffusers_scheduler.set_timesteps(30) solver = DDIM(num_inference_steps=30) assert equal(solver.timesteps, diffusers_scheduler.timesteps) sample = randn(1, 4, 32, 32) predicted_noise = randn(1, 4, 32, 32) for step, timestep in enumerate(diffusers_scheduler.timesteps): diffusers_output = cast(Tensor, diffusers_scheduler.step(predicted_noise, timestep, sample).prev_sample) # type: ignore refiners_output = solver(x=sample, predicted_noise=predicted_noise, step=step) assert allclose(diffusers_output, refiners_output, rtol=0.01), f"outputs differ at step {step}" @pytest.mark.parametrize("model_prediction_type", [ModelPredictionType.NOISE, ModelPredictionType.SAMPLE]) def test_euler_diffusers(model_prediction_type: ModelPredictionType): from diffusers import EulerDiscreteScheduler # type: ignore manual_seed(0) diffusers_prediction_type = "epsilon" if model_prediction_type == ModelPredictionType.NOISE else "sample" diffusers_scheduler = EulerDiscreteScheduler( beta_end=0.012, beta_schedule="scaled_linear", beta_start=0.00085, num_train_timesteps=1000, steps_offset=1, timestep_spacing="linspace", use_karras_sigmas=False, prediction_type=diffusers_prediction_type, ) diffusers_scheduler.set_timesteps(30) solver = Euler(num_inference_steps=30, params=SolverParams(model_prediction_type=model_prediction_type)) assert equal(solver.timesteps, diffusers_scheduler.timesteps) sample = randn(1, 4, 32, 32) predicted_noise = randn(1, 4, 32, 32) ref_init_noise_sigma = diffusers_scheduler.init_noise_sigma # type: ignore assert isinstance(ref_init_noise_sigma, Tensor) assert isclose(ref_init_noise_sigma, solver.init_noise_sigma), "init_noise_sigma differ" for step, timestep in enumerate(diffusers_scheduler.timesteps): diffusers_output = cast(Tensor, diffusers_scheduler.step(predicted_noise, timestep, sample).prev_sample) # type: ignore refiners_output = solver(x=sample, predicted_noise=predicted_noise, step=step) assert allclose(diffusers_output, refiners_output, rtol=0.02), f"outputs differ at step {step}" def test_franken_diffusers(): from diffusers import EulerDiscreteScheduler # type: ignore manual_seed(0) params = { "beta_end": 0.012, "beta_schedule": "scaled_linear", "beta_start": 0.00085, "num_train_timesteps": 1000, "steps_offset": 1, "timestep_spacing": "linspace", "use_karras_sigmas": False, } diffusers_scheduler = EulerDiscreteScheduler(**params) # type: ignore diffusers_scheduler.set_timesteps(30) diffusers_scheduler_2 = EulerDiscreteScheduler(**params) # type: ignore solver = FrankenSolver(lambda: diffusers_scheduler_2, num_inference_steps=30) assert equal(solver.timesteps, diffusers_scheduler.timesteps) sample = randn(1, 4, 32, 32) predicted_noise = randn(1, 4, 32, 32) ref_init_noise_sigma = diffusers_scheduler.init_noise_sigma # type: ignore assert isinstance(ref_init_noise_sigma, Tensor) init_noise_sigma = solver.scale_model_input(tensor(1), step=-1) assert equal(ref_init_noise_sigma, init_noise_sigma), "init_noise_sigma differ" for step, timestep in enumerate(diffusers_scheduler.timesteps): diffusers_output = cast(Tensor, diffusers_scheduler.step(predicted_noise, timestep, sample).prev_sample) # type: ignore refiners_output = solver(x=sample, predicted_noise=predicted_noise, step=step) assert equal(diffusers_output, refiners_output), f"outputs differ at step {step}" def test_lcm_diffusers(): from diffusers import LCMScheduler # type: ignore manual_seed(0) # LCMScheduler is stochastic, make sure we use identical generators diffusers_generator = Generator().manual_seed(42) refiners_generator = Generator().manual_seed(42) diffusers_scheduler = LCMScheduler() diffusers_scheduler.set_timesteps(4) solver = LCMSolver(num_inference_steps=4) assert equal(solver.timesteps, diffusers_scheduler.timesteps) sample = randn(1, 4, 32, 32) predicted_noise = randn(1, 4, 32, 32) for step, timestep in enumerate(diffusers_scheduler.timesteps): alpha_prod_t = diffusers_scheduler.alphas_cumprod[timestep] diffusers_noise_ratio = (1 - alpha_prod_t).sqrt() diffusers_scale_factor = alpha_prod_t.sqrt() refiners_scale_factor = solver.cumulative_scale_factors[timestep] refiners_noise_ratio = solver.noise_std[timestep] assert refiners_scale_factor == diffusers_scale_factor assert refiners_noise_ratio == diffusers_noise_ratio d_out = diffusers_scheduler.step(predicted_noise, timestep, sample, generator=diffusers_generator) # type: ignore diffusers_output = cast(Tensor, d_out.prev_sample) # type: ignore refiners_output = solver( x=sample, predicted_noise=predicted_noise, step=step, generator=refiners_generator, ) assert allclose(refiners_output, diffusers_output, rtol=0.01), f"outputs differ at step {step}" def test_solver_remove_noise(): from diffusers import DDIMScheduler # type: ignore manual_seed(0) diffusers_scheduler = DDIMScheduler( beta_end=0.012, beta_schedule="scaled_linear", beta_start=0.00085, num_train_timesteps=1000, steps_offset=1, clip_sample=False, ) diffusers_scheduler.set_timesteps(30) solver = DDIM(num_inference_steps=30) sample = randn(1, 4, 32, 32) noise = randn(1, 4, 32, 32) for step, timestep in enumerate(diffusers_scheduler.timesteps): diffusers_output = cast(Tensor, diffusers_scheduler.step(noise, timestep, sample).pred_original_sample) # type: ignore refiners_output = solver.remove_noise(x=sample, noise=noise, step=step) assert allclose(diffusers_output, refiners_output, rtol=0.01), f"outputs differ at step {step}" def test_solver_device(test_device: Device): if test_device.type == "cpu": warn("not running on CPU, skipping") pytest.skip() scheduler = DDIM(num_inference_steps=30, device=test_device) x = randn(1, 4, 32, 32, device=test_device) noise = randn(1, 4, 32, 32, device=test_device) noised = scheduler.add_noise(x, noise, scheduler.first_inference_step) assert noised.device == test_device def test_solver_add_noise(test_device: Device): scheduler = DDIM(num_inference_steps=30, device=test_device) latent = randn(1, 4, 32, 32, device=test_device) noise = randn(1, 4, 32, 32, device=test_device) noised = scheduler.add_noise( x=latent, noise=noise, step=0, ) noised_double = scheduler.add_noise( x=latent.repeat(2, 1, 1, 1), noise=noise.repeat(2, 1, 1, 1), step=[0, 0], ) assert allclose(noised, noised_double[0]) assert allclose(noised, noised_double[1]) @pytest.mark.parametrize("noise_schedule", [NoiseSchedule.UNIFORM, NoiseSchedule.QUADRATIC, NoiseSchedule.KARRAS]) def test_solver_noise_schedules(noise_schedule: NoiseSchedule, test_device: Device): scheduler = DDIM( num_inference_steps=30, params=SolverParams(noise_schedule=noise_schedule), device=test_device, ) assert len(scheduler.scale_factors) == 1000 assert scheduler.scale_factors[0] == 1 - scheduler.params.initial_diffusion_rate assert scheduler.scale_factors[-1] == 1 - scheduler.params.final_diffusion_rate def test_solver_timestep_spacing(): # Tests we get the results from [[arXiv:2305.08891] Common Diffusion Noise Schedules and Sample Steps are Flawed](https://arxiv.org/abs/2305.08891) table 2. linspace_int = Solver.generate_timesteps( spacing=TimestepSpacing.LINSPACE_ROUNDED, num_inference_steps=10, num_train_timesteps=1000, offset=1, ) assert equal(linspace_int, tensor([1000, 889, 778, 667, 556, 445, 334, 223, 112, 1])) leading = Solver.generate_timesteps( spacing=TimestepSpacing.LEADING, num_inference_steps=10, num_train_timesteps=1000, offset=1, ) assert equal(leading, tensor([901, 801, 701, 601, 501, 401, 301, 201, 101, 1])) trailing = Solver.generate_timesteps( spacing=TimestepSpacing.TRAILING, num_inference_steps=10, num_train_timesteps=1000, offset=1, ) assert equal(trailing, tensor([1000, 900, 800, 700, 600, 500, 400, 300, 200, 100]))