# Copyright (c) 2022-2026, The Isaac Lab Project Developers (https://github.com/isaac-sim/IsaacLab/blob/main/CONTRIBUTORS.md). # All rights reserved. # # SPDX-License-Identifier: BSD-3-Clause """Launch Isaac Sim Simulator first.""" from isaaclab.app import AppLauncher # launch omniverse app simulation_app = AppLauncher(headless=True).app """Rest everything follows.""" import pytest import torch import isaaclab.utils.noise as noise @pytest.mark.parametrize("device", ["cpu", "cuda:0"]) @pytest.mark.parametrize("noise_device", ["cpu", "cuda:0"]) @pytest.mark.parametrize("op", ["add", "scale", "abs"]) def test_gaussian_noise(device, noise_device, op): """Test guassian_noise function.""" # create random data set data = torch.rand(10000, 3, device=device) # define standard deviation and mean std = torch.tensor([0.1, 0.2, 0.3], device=noise_device) mean = torch.tensor([0.4, 0.5, 0.6], device=noise_device) # create noise config noise_cfg = noise.GaussianNoiseCfg(std=std, mean=mean, operation=op) for i in range(10): # apply noise noisy_data = noise_cfg.func(data, cfg=noise_cfg) # calculate resulting noise compared to original data set if op == "add": std_result, mean_result = torch.std_mean(noisy_data - data, dim=0) elif op == "scale": std_result, mean_result = torch.std_mean(noisy_data / data, dim=0) elif op == "abs": std_result, mean_result = torch.std_mean(noisy_data, dim=0) assert str(noise_cfg.mean.device) == device assert str(noise_cfg.std.device) == device torch.testing.assert_close(noise_cfg.std, std_result, atol=1e-2, rtol=1e-2) torch.testing.assert_close(noise_cfg.mean, mean_result, atol=1e-2, rtol=1e-2) @pytest.mark.parametrize("device", ["cpu", "cuda:0"]) @pytest.mark.parametrize("noise_device", ["cpu", "cuda:0"]) @pytest.mark.parametrize("op", ["add", "scale", "abs"]) def test_uniform_noise(device, noise_device, op): """Test uniform_noise function.""" # create random data set data = torch.rand(10000, 3, device=device) # define uniform minimum and maximum n_min = torch.tensor([0.1, 0.2, 0.3], device=noise_device) n_max = torch.tensor([0.4, 0.5, 0.6], device=noise_device) # create noise config noise_cfg = noise.UniformNoiseCfg(n_max=n_max, n_min=n_min, operation=op) for i in range(10): # apply noise noisy_data = noise_cfg.func(data, cfg=noise_cfg) # calculate resulting noise compared to original data set if op == "add": min_result, _ = torch.min(noisy_data - data, dim=0) max_result, _ = torch.max(noisy_data - data, dim=0) elif op == "scale": min_result, _ = torch.min(torch.div(noisy_data, data), dim=0) max_result, _ = torch.max(torch.div(noisy_data, data), dim=0) elif op == "abs": min_result, _ = torch.min(noisy_data, dim=0) max_result, _ = torch.max(noisy_data, dim=0) assert str(noise_cfg.n_min.device) == device assert str(noise_cfg.n_max.device) == device # add a small epsilon to accommodate for floating point error assert all(torch.le(noise_cfg.n_min - 1e-5, min_result).tolist()) assert all(torch.ge(noise_cfg.n_max + 1e-5, max_result).tolist()) @pytest.mark.parametrize("device", ["cpu", "cuda:0"]) @pytest.mark.parametrize("noise_device", ["cpu", "cuda:0"]) @pytest.mark.parametrize("op", ["add", "scale", "abs"]) def test_constant_noise(device, noise_device, op): """Test constant_noise""" # create random data set data = torch.rand(10000, 3, device=device) # define a bias bias = torch.tensor([0.1, 0.2, 0.3], device=noise_device) # create noise config noise_cfg = noise.ConstantNoiseCfg(bias=bias, operation=op) for i in range(10): # apply noise noisy_data = noise_cfg.func(data, cfg=noise_cfg) # calculate resulting noise compared to original data set if op == "add": bias_result = noisy_data - data elif op == "scale": bias_result = noisy_data / data elif op == "abs": bias_result = noisy_data assert str(noise_cfg.bias.device) == device torch.testing.assert_close(noise_cfg.bias.repeat(data.shape[0], 1), bias_result)