# Copyright 2013 The Android Open Source Project # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """Verifies android.sensor.exposureTime parameter.""" import logging import os.path import matplotlib from matplotlib import pylab from mobly import test_runner import its_base_test import camera_properties_utils import capture_request_utils import image_processing_utils import its_session_utils import target_exposure_utils _COLORS = ('R', 'G', 'B') _EXP_MULT_FACTORS = (0.8, 0.9, 1.0, 1.1, 1.2) # vary exposure +/- 20% _NAME = os.path.splitext(os.path.basename(__file__))[0] _PATCH_H = 0.1 # center 10% _PATCH_W = 0.1 _PATCH_X = 0.5 - _PATCH_W/2 _PATCH_Y = 0.5 - _PATCH_H/2 class ParamExposureTimeTest(its_base_test.ItsBaseTest): """Test that the android.sensor.exposureTime parameter is applied.""" def test_param_exposure_time(self): logging.debug('Starting %s', _NAME) exp_times = [] r_means = [] g_means = [] b_means = [] with its_session_utils.ItsSession( device_id=self.dut.serial, camera_id=self.camera_id, hidden_physical_id=self.hidden_physical_id) as cam: props = cam.get_camera_properties() props = cam.override_with_hidden_physical_camera_props(props) log_path = self.log_path name_with_log_path = os.path.join(log_path, _NAME) # check SKIP conditions camera_properties_utils.skip_unless( camera_properties_utils.compute_target_exposure(props)) # Load chart for scene its_session_utils.load_scene( cam, props, self.scene, self.tablet, its_session_utils.CHART_DISTANCE_NO_SCALING) # Create requests sync_latency = camera_properties_utils.sync_latency(props) largest_yuv = capture_request_utils.get_largest_yuv_format(props) match_ar = (largest_yuv['width'], largest_yuv['height']) fmt = capture_request_utils.get_near_vga_yuv_format( props, match_ar=match_ar) e, s = target_exposure_utils.get_target_exposure_combos( log_path, cam)['midExposureTime'] # Do captures & process images for i, e_mult in enumerate(_EXP_MULT_FACTORS): req = capture_request_utils.manual_capture_request( s, e * e_mult, 0.0, True, props) cap = its_session_utils.do_capture_with_latency( cam, req, sync_latency, fmt) img = image_processing_utils.convert_capture_to_rgb_image(cap) image_processing_utils.write_image( img, f'{name_with_log_path}_frame{i}.jpg') patch = image_processing_utils.get_image_patch( img, _PATCH_X, _PATCH_Y, _PATCH_W, _PATCH_H) rgb_means = image_processing_utils.compute_image_means(patch) logging.debug('RGB means: %s', str(rgb_means)) exp_times.append(e * e_mult) r_means.append(rgb_means[0]) g_means.append(rgb_means[1]) b_means.append(rgb_means[2]) # Draw plot pylab.figure(_NAME) for ch, means in enumerate([r_means, g_means, b_means]): pylab.plot(exp_times, means, '-'+'rgb'[ch]+'o') pylab.ylim([0, 1]) pylab.title(_NAME) pylab.xlabel('Exposure times (ns)') pylab.ylabel('RGB means') matplotlib.pyplot.savefig(f'{name_with_log_path}_plot_means.png') # Assert each shot is brighter than previous. for ch, means in enumerate([r_means, g_means, b_means]): for i in range(len(_EXP_MULT_FACTORS)-1): if means[i+1] <= means[i]: raise AssertionError(f'{_COLORS[ch]} not increasing in brightness! ' f'{_COLORS[ch]}[i+1]: {means[i+1]:.4f}, ' f'{_COLORS[ch]}[i]: {means[i]:.4f}') if __name__ == '__main__': test_runner.main()