apps/CameraITS/tests/scene1/test_reprocess_noise_reduction.py - platform/cts - Git at Google

 # Copyright 2015 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 math
 import matplotlib
 import matplotlib.pyplot
 import numpy
 import os.path
 import pylab

 def main():
     """Test that the android.noiseReduction.mode param is applied when set for
        reprocessing requests.

     Capture reprocessed images with the camera dimly lit. Uses a high analog
     gain to ensure the captured image is noisy.

     Captures three reprocessed images, for NR off, "fast", and "high quality".
     Also captures a reprocessed image with low gain and NR off, and uses the
     variance of this as the baseline.
     """

     NAME = os.path.basename(__file__).split(".")[0]

     RELATIVE_ERROR_TOLERANCE = 0.1

     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) and
                              its.caps.noise_reduction_mode(props, 0) and
                              (its.caps.yuv_reprocess(props) or
                               its.caps.private_reprocess(props)))

         # If reprocessing is supported, ZSL NR mode must be avaiable.
         assert(its.caps.noise_reduction_mode(props, 4))

         reprocess_formats = []
         if (its.caps.yuv_reprocess(props)):
             reprocess_formats.append("yuv")
         if (its.caps.private_reprocess(props)):
             reprocess_formats.append("private")

         for reprocess_format in reprocess_formats:
             # List of variances for R, G, B.
             variances = []
             nr_modes_reported = []

             # NR mode 0 with low gain
             e, s = its.target.get_target_exposure_combos(cam)["minSensitivity"]
             req = its.objects.manual_capture_request(s, e)
             req["android.noiseReduction.mode"] = 0

             # Test reprocess_format->JPEG reprocessing
             # TODO: Switch to reprocess_format->YUV when YUV reprocessing is
             #       supported.
             size = its.objects.get_available_output_sizes("jpg", props)[0]
             out_surface = {"width":size[0], "height":size[1], "format":"jpg"}
             cap = cam.do_capture(req, out_surface, reprocess_format)
             img = its.image.decompress_jpeg_to_rgb_image(cap["data"])
             its.image.write_image(img, "%s_low_gain_fmt=jpg.jpg" % (NAME))
             tile = its.image.get_image_patch(img, 0.45, 0.45, 0.1, 0.1)
             ref_variance = its.image.compute_image_variances(tile)
             print "Ref variances:", ref_variance

             for nr_mode in range(5):
                 # Skip unavailable modes
                 if not its.caps.noise_reduction_mode(props, nr_mode):
                     nr_modes_reported.append(nr_mode)
                     variances.append(0)
                     continue

                 # NR modes with high gain
                 e, s = its.target.get_target_exposure_combos(cam) \
                     ["maxSensitivity"]
                 req = its.objects.manual_capture_request(s, e)
                 req["android.noiseReduction.mode"] = nr_mode
                 cap = cam.do_capture(req, out_surface, reprocess_format)
                 nr_modes_reported.append(
                     cap["metadata"]["android.noiseReduction.mode"])

                 img = its.image.decompress_jpeg_to_rgb_image(cap["data"])
                 its.image.write_image(
                     img, "%s_high_gain_nr=%d_fmt=jpg.jpg" % (NAME, nr_mode))
                 tile = its.image.get_image_patch(img, 0.45, 0.45, 0.1, 0.1)
                 # Get the variances for R, G, and B channels
                 variance = its.image.compute_image_variances(tile)
                 variances.append(
                     [variance[chan] / ref_variance[chan] for chan in range(3)])
             print "Variances with NR mode [0,1,2,3,4]:", variances

             # Draw a plot.
             for chan in range(3):
                 line = []
                 for nr_mode in range(5):
                     line.append(variances[nr_mode][chan])
                 pylab.plot(range(5), line, "rgb"[chan])

             matplotlib.pyplot.savefig("%s_plot_%s_variances.png" %
                                       (NAME, reprocess_format))

             assert(nr_modes_reported == [0,1,2,3,4])

             for j in range(3):
                 # Smaller variance is better
                 # Verify OFF(0) is not better than FAST(1)
                 assert(variances[0][j] >
                        variances[1][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
                 # Verify FAST(1) is not better than HQ(2)
                 assert(variances[1][j] >
                        variances[2][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
                 # Verify HQ(2) is better than OFF(0)
                 assert(variances[0][j] > variances[2][j])
                 if its.caps.noise_reduction_mode(props, 3):
                     # Verify OFF(0) is not better than MINIMAL(3)
                     assert(variances[0][j] >
                            variances[3][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
                     # Verify MINIMAL(3) is not better than HQ(2)
                     assert(variances[3][j] >
                            variances[2][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
                     # Verify ZSL(4) is close to MINIMAL(3)
                     assert(numpy.isclose(variances[4][j], variances[3][j],
                                          RELATIVE_ERROR_TOLERANCE))
                 else:
                     # Verify ZSL(4) is close to OFF(0)
                     assert(numpy.isclose(variances[4][j], variances[0][j],
                                          RELATIVE_ERROR_TOLERANCE))

 if __name__ == '__main__':
     main()
	# Copyright 2015 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 math
	import matplotlib
	import matplotlib.pyplot
	import numpy
	import os.path
	import pylab

	def main():
	"""Test that the android.noiseReduction.mode param is applied when set for
	reprocessing requests.

	Capture reprocessed images with the camera dimly lit. Uses a high analog
	gain to ensure the captured image is noisy.

	Captures three reprocessed images, for NR off, "fast", and "high quality".
	Also captures a reprocessed image with low gain and NR off, and uses the
	variance of this as the baseline.
	"""

	NAME = os.path.basename(__file__).split(".")[0]

	RELATIVE_ERROR_TOLERANCE = 0.1

	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) and
	its.caps.noise_reduction_mode(props, 0) and
	(its.caps.yuv_reprocess(props) or
	its.caps.private_reprocess(props)))

	# If reprocessing is supported, ZSL NR mode must be avaiable.
	assert(its.caps.noise_reduction_mode(props, 4))

	reprocess_formats = []
	if (its.caps.yuv_reprocess(props)):
	reprocess_formats.append("yuv")
	if (its.caps.private_reprocess(props)):
	reprocess_formats.append("private")

	for reprocess_format in reprocess_formats:
	# List of variances for R, G, B.
	variances = []
	nr_modes_reported = []

	# NR mode 0 with low gain
	e, s = its.target.get_target_exposure_combos(cam)["minSensitivity"]
	req = its.objects.manual_capture_request(s, e)
	req["android.noiseReduction.mode"] = 0

	# Test reprocess_format->JPEG reprocessing
	# TODO: Switch to reprocess_format->YUV when YUV reprocessing is
	# supported.
	size = its.objects.get_available_output_sizes("jpg", props)[0]
	out_surface = {"width":size[0], "height":size[1], "format":"jpg"}
	cap = cam.do_capture(req, out_surface, reprocess_format)
	img = its.image.decompress_jpeg_to_rgb_image(cap["data"])
	its.image.write_image(img, "%s_low_gain_fmt=jpg.jpg" % (NAME))
	tile = its.image.get_image_patch(img, 0.45, 0.45, 0.1, 0.1)
	ref_variance = its.image.compute_image_variances(tile)
	print "Ref variances:", ref_variance

	for nr_mode in range(5):
	# Skip unavailable modes
	if not its.caps.noise_reduction_mode(props, nr_mode):
	nr_modes_reported.append(nr_mode)
	variances.append(0)
	continue

	# NR modes with high gain
	e, s = its.target.get_target_exposure_combos(cam) \
	["maxSensitivity"]
	req = its.objects.manual_capture_request(s, e)
	req["android.noiseReduction.mode"] = nr_mode
	cap = cam.do_capture(req, out_surface, reprocess_format)
	nr_modes_reported.append(
	cap["metadata"]["android.noiseReduction.mode"])

	img = its.image.decompress_jpeg_to_rgb_image(cap["data"])
	its.image.write_image(
	img, "%s_high_gain_nr=%d_fmt=jpg.jpg" % (NAME, nr_mode))
	tile = its.image.get_image_patch(img, 0.45, 0.45, 0.1, 0.1)
	# Get the variances for R, G, and B channels
	variance = its.image.compute_image_variances(tile)
	variances.append(
	[variance[chan] / ref_variance[chan] for chan in range(3)])
	print "Variances with NR mode [0,1,2,3,4]:", variances

	# Draw a plot.
	for chan in range(3):
	line = []
	for nr_mode in range(5):
	line.append(variances[nr_mode][chan])
	pylab.plot(range(5), line, "rgb"[chan])

	matplotlib.pyplot.savefig("%s_plot_%s_variances.png" %
	(NAME, reprocess_format))

	assert(nr_modes_reported == [0,1,2,3,4])

	for j in range(3):
	# Smaller variance is better
	# Verify OFF(0) is not better than FAST(1)
	assert(variances[0][j] >
	variances[1][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
	# Verify FAST(1) is not better than HQ(2)
	assert(variances[1][j] >
	variances[2][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
	# Verify HQ(2) is better than OFF(0)
	assert(variances[0][j] > variances[2][j])
	if its.caps.noise_reduction_mode(props, 3):
	# Verify OFF(0) is not better than MINIMAL(3)
	assert(variances[0][j] >
	variances[3][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
	# Verify MINIMAL(3) is not better than HQ(2)
	assert(variances[3][j] >
	variances[2][j] * (1.0 - RELATIVE_ERROR_TOLERANCE))
	# Verify ZSL(4) is close to MINIMAL(3)
	assert(numpy.isclose(variances[4][j], variances[3][j],
	RELATIVE_ERROR_TOLERANCE))
	else:
	# Verify ZSL(4) is close to OFF(0)
	assert(numpy.isclose(variances[4][j], variances[0][j],
	RELATIVE_ERROR_TOLERANCE))

	if __name__ == '__main__':
	main()