# 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. import its.image import its.caps import its.device import its.objects import its.target import pylab import numpy import os.path import matplotlib import matplotlib.pyplot def main(): """Test that a constant exposure is seen as ISO and exposure time vary. Take a series of shots that have ISO and exposure time chosen to balance each other; result should be the same brightness, but over the sequence the images should get noisier. """ NAME = os.path.basename(__file__).split(".")[0] THRESHOLD_MAX_OUTLIER_DIFF = 0.1 THRESHOLD_MIN_LEVEL = 0.1 THRESHOLD_MAX_LEVEL = 0.9 THRESHOLD_MAX_LEVEL_DIFF = 0.03 THRESHOLD_MAX_LEVEL_DIFF_WIDE_RANGE = 0.05 THRESHOLD_ROUND_DOWN_GAIN = 0.1 THRESHOLD_ROUND_DOWN_EXP = 0.05 mults = [] r_means = [] g_means = [] b_means = [] threshold_max_level_diff = THRESHOLD_MAX_LEVEL_DIFF with its.device.ItsSession() as cam: props = cam.get_camera_properties() its.caps.skip_unless(its.caps.compute_target_exposure(props) and its.caps.per_frame_control(props)) e,s = its.target.get_target_exposure_combos(cam)["minSensitivity"] s_e_product = s*e expt_range = props['android.sensor.info.exposureTimeRange'] sens_range = props['android.sensor.info.sensitivityRange'] m = 1.0 while s*m < sens_range[1] and e/m > expt_range[0]: mults.append(m) s_test = round(s*m) e_test = s_e_product / s_test print "Testing s:", s_test, "e:", e_test req = its.objects.manual_capture_request(s_test, e_test, True, props) cap = cam.do_capture(req) s_res = cap["metadata"]["android.sensor.sensitivity"] e_res = cap["metadata"]["android.sensor.exposureTime"] assert(0 <= s_test - s_res < s_test * THRESHOLD_ROUND_DOWN_GAIN) assert(0 <= e_test - e_res < e_test * THRESHOLD_ROUND_DOWN_EXP) s_e_product_res = s_res * e_res request_result_ratio = s_e_product / s_e_product_res print "Capture result s:", s_test, "e:", e_test img = its.image.convert_capture_to_rgb_image(cap) its.image.write_image(img, "%s_mult=%3.2f.jpg" % (NAME, m)) tile = its.image.get_image_patch(img, 0.45, 0.45, 0.1, 0.1) rgb_means = its.image.compute_image_means(tile) # Adjust for the difference between request and result r_means.append(rgb_means[0] * request_result_ratio) g_means.append(rgb_means[1] * request_result_ratio) b_means.append(rgb_means[2] * request_result_ratio) # Test 3 steps per 2x gain m = m * pow(2, 1.0 / 3) # Allow more threshold for devices with wider exposure range if m >= 64.0: threshold_max_level_diff = THRESHOLD_MAX_LEVEL_DIFF_WIDE_RANGE # Draw a plot. pylab.plot(mults, r_means, 'r.-') pylab.plot(mults, g_means, 'g.-') pylab.plot(mults, b_means, 'b.-') pylab.ylim([0,1]) matplotlib.pyplot.savefig("%s_plot_means.png" % (NAME)) # Check for linearity. Verify sample pixel mean values are close to each # other. Also ensure that the images aren't clamped to 0 or 1 # (which would make them look like flat lines). for chan in xrange(3): values = [r_means, g_means, b_means][chan] m, b = numpy.polyfit(mults, values, 1).tolist() max_val = max(values) min_val = min(values) max_diff = max_val - min_val print "Channel %d line fit (y = mx+b): m = %f, b = %f" % (chan, m, b) print "Channel max %f min %f diff %f" % (max_val, min_val, max_diff) assert(max_diff < threshold_max_level_diff) assert(b > THRESHOLD_MIN_LEVEL and b < THRESHOLD_MAX_LEVEL) for v in values: assert(v > THRESHOLD_MIN_LEVEL and v < THRESHOLD_MAX_LEVEL) assert(abs(v - b) < THRESHOLD_MAX_OUTLIER_DIFF) if __name__ == '__main__': main()