diff options
Diffstat (limited to 'utils')
-rwxr-xr-x | utils/raspberrypi/ctt/ctt.py | 823 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_alsc.py | 297 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_awb.py | 374 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_ccm.py | 221 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_config_example.json | 16 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_geq.py | 179 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_image_load.py | 428 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_lux.py | 58 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_macbeth_locator.py | 748 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_noise.py | 123 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_pretty_print_json.py | 70 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_ransac.py | 69 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_ref.pgm | 5 | ||||
-rw-r--r-- | utils/raspberrypi/ctt/ctt_tools.py | 141 |
14 files changed, 3552 insertions, 0 deletions
diff --git a/utils/raspberrypi/ctt/ctt.py b/utils/raspberrypi/ctt/ctt.py new file mode 100755 index 00000000..5fe22e14 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt.py @@ -0,0 +1,823 @@ +#!/usr/bin/env python3 +# +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt.py - camera tuning tool + +import os +import sys +from ctt_image_load import * +from ctt_ccm import * +from ctt_awb import * +from ctt_alsc import * +from ctt_lux import * +from ctt_noise import * +from ctt_geq import * +from ctt_pretty_print_json import * +import random +import json +import re + +""" +This file houses the camera object, which is used to perform the calibrations. +The camera object houses all the calibration images as attributes in two lists: + - imgs (macbeth charts) + - imgs_alsc (alsc correction images) +Various calibrations are methods of the camera object, and the output is stored +in a dictionary called self.json. +Once all the caibration has been completed, the Camera.json is written into a +json file. +The camera object initialises its json dictionary by reading from a pre-written +blank json file. This has been done to avoid reproducing the entire json file +in the code here, thereby avoiding unecessary clutter. +""" + +""" +Get the colour and lux values from the strings of each inidvidual image +""" +def get_col_lux(string): + """ + Extract colour and lux values from filename + """ + col = re.search('([0-9]+)[kK](\.(jpg|jpeg|brcm|dng)|_.*\.(jpg|jpeg|brcm|dng))$',string) + lux = re.search('([0-9]+)[lL](\.(jpg|jpeg|brcm|dng)|_.*\.(jpg|jpeg|brcm|dng))$',string) + try: + col = col.group(1) + except AttributeError: + """ + Catch error if images labelled incorrectly and pass reasonable defaults + """ + return None,None + try: + lux = lux.group(1) + except AttributeError: + """ + Catch error if images labelled incorrectly and pass reasonable defaults + Still returns colour if that has been found. + """ + return col,None + return int( col ),int( lux ) + +""" +Camera object that is the backbone of the tuning tool. +Input is the desired path of the output json. +""" +class Camera: + def __init__(self,jfile): + self.path = os.path.dirname(os.path.expanduser(__file__)) + '/' + if self.path == '/': + self.path = '' + self.imgs = [] + self.imgs_alsc = [] + self.log = 'Log created : '+ time.asctime(time.localtime(time.time())) + self.log_separator = '\n'+'-'*70+'\n' + self.jf = jfile + """ + initial json dict populated by uncalibrated values + """ + self.json = { + "rpi.black_level" : { + "black_level" : 4096 + }, + "rpi.dpc" : { + }, + "rpi.lux" : { + "reference_shutter_speed": 10000, + "reference_gain": 1, + "reference_aperture": 1.0 + }, + "rpi.noise" : { + }, + "rpi.geq" : { + }, + "rpi.sdn": { + }, + "rpi.awb": { + "priors" : [ + {"lux": 0,"prior":[ 2000, 1.0, 3000, 0.0, 13000, 0.0]}, + {"lux": 800,"prior":[ 2000, 0.0, 6000, 2.0, 13000, 2.0]}, + {"lux": 1500,"prior":[ 2000, 0.0, 4000, 1.0, 6000, 6.0, 6500, 7.0, 7000, 1.0, 13000, 1.0]} + ], + "modes" : { + "auto" : { "lo" : 2500, "hi" : 8000 }, + "incandescent" : { "lo" : 2500, "hi" : 3000 }, + "tungsten" : { "lo" : 3000, "hi" : 3500 }, + "fluorescent" : { "lo" : 4000, "hi" : 4700 }, + "indoor" : { "lo" : 3000, "hi" : 5000 }, + "daylight" : { "lo" : 5500, "hi" : 6500 }, + "cloudy" : { "lo" : 7000, "hi" : 8600 } + }, + "bayes" : 1 + }, + "rpi.agc" : { + "metering_modes" : { + "centre-weighted" : { + "weights" : [3, 3, 3, 2, 2, 2, 2, 1, 1, 1, 1, 0, 0, 0, 0] + }, + "spot" : { + "weights" : [2, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0] + }, + "matrix": { + "weights" : [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1] + } + }, + "exposure_modes" : { + "normal" : { + "shutter" : [100, 10000, 30000, 60000, 120000], + "gain" : [1.0, 2.0, 4.0, 6.0, 6.0] + }, + "sport": { + "shutter": [ 100, 5000, 10000, 20000, 120000 ], + "gain": [ 1.0, 2.0, 4.0, 6.0, 6.0 ] + } + }, + "constraint_modes" : { + "normal" : [ + {"bound" : "LOWER", "q_lo" : 0.98, "q_hi" : 1.0, "y_target" : [0, 0.5, 1000, 0.5]} + ], + "highlight": [ + { "bound": "LOWER", "q_lo": 0.98, "q_hi": 1.0, "y_target": [ 0, 0.5, 1000, 0.5 ] }, + { "bound": "UPPER", "q_lo": 0.98, "q_hi": 1.0, "y_target": [ 0, 0.8, 1000, 0.8 ] } + ] + }, + "y_target" : [0, 0.16, 1000, 0.165, 10000, 0.17] + }, + "rpi.alsc": { + 'omega' : 1.3, + 'n_iter' : 100, + 'luminance_strength' : 0.7, + }, + "rpi.contrast" : { + "ce_enable": 1, + "gamma_curve": [ + 0, 0, + 1024, 5040, + 2048, 9338, + 3072, 12356, + 4096, 15312, + 5120, 18051, + 6144, 20790, + 7168, 23193, + 8192, 25744, + 9216, 27942, + 10240, 30035, + 11264, 32005, + 12288, 33975, + 13312, 35815, + 14336, 37600, + 15360, 39168, + 16384, 40642, + 18432, 43379, + 20480, 45749, + 22528, 47753, + 24576, 49621, + 26624, 51253, + 28672, 52698, + 30720, 53796, + 32768, 54876, + 36864, 57012, + 40960, 58656, + 45056, 59954, + 49152, 61183, + 53248, 62355, + 57344, 63419, + 61440, 64476, + 65535, 65535 + ] + }, + "rpi.ccm": { + }, + "rpi.sharpen":{ + } + } + + + """ + Perform colour correction calibrations by comparing macbeth patch colours + to standard macbeth chart colours. + """ + def ccm_cal(self,do_alsc_colour): + if 'rpi.ccm' in self.disable: + return 1 + print('\nStarting CCM calibration') + self.log_new_sec('CCM') + """ + if image is greyscale then CCm makes no sense + """ + if self.grey: + print('\nERROR: Can\'t do CCM on greyscale image!') + self.log += '\nERROR: Cannot perform CCM calibration ' + self.log += 'on greyscale image!\nCCM aborted!' + del self.json['rpi.ccm'] + return 0 + a = time.time() + """ + Check if alsc tables have been generated, if not then do ccm without + alsc + """ + if (not "rpi.alsc" in self.disable) and do_alsc_colour: + """ + case where ALSC colour has been done, so no errors should be + expected... + """ + try: + cal_cr_list = self.json['rpi.alsc']['calibrations_Cr'] + cal_cb_list = self.json['rpi.alsc']['calibrations_Cb'] + self.log += '\nALSC tables found successfully' + except KeyError: + cal_cr_list,cal_cb_list=None,None + print('WARNING! No ALSC tables found for CCM!') + print('Performing CCM calibrations without ALSC correction...') + self.log += '\nWARNING: No ALSC tables found.\nCCM calibration ' + self.log += 'performed without ALSC correction...' + else: + """ + case where config options result in CCM done without ALSC colour tables + """ + cal_cr_list,cal_cb_list=None,None + self.log += '\nWARNING: No ALSC tables found.\nCCM calibration ' + self.log += 'performed without ALSC correction...' + + """ + Do CCM calibration + """ + try: + ccms = ccm(self,cal_cr_list,cal_cb_list) + except ArithmeticError: + print('ERROR: Matrix is singular!\nTake new pictures and try again...') + self.log += '\nERROR: Singular matrix encountered during fit!' + self.log += '\nCCM aborted!' + return 1 + """ + Write output to json + """ + self.json['rpi.ccm']['ccms'] = ccms + self.log += '\nCCM calibration written to json file' + print('Finished CCM calibration') + + """ + Auto white balance calibration produces a colour curve for + various colour temperatures, as well as providing a maximum 'wiggle room' + distance from this curve (transverse_neg/pos). + """ + def awb_cal(self,greyworld,do_alsc_colour): + if 'rpi.awb' in self.disable: + return 1 + print('\nStarting AWB calibration') + self.log_new_sec('AWB') + """ + if image is greyscale then AWB makes no sense + """ + if self.grey: + print('\nERROR: Can\'t do AWB on greyscale image!') + self.log += '\nERROR: Cannot perform AWB calibration ' + self.log += 'on greyscale image!\nAWB aborted!' + del self.json['rpi.awb'] + return 0 + """ + optional set greyworld (e.g. for noir cameras) + """ + if greyworld: + self.json['rpi.awb']['bayes'] = 0 + self.log += '\nGreyworld set' + """ + Check if alsc tables have been generated, if not then do awb without + alsc correction + """ + if (not "rpi.alsc" in self.disable) and do_alsc_colour: + try: + cal_cr_list = self.json['rpi.alsc']['calibrations_Cr'] + cal_cb_list = self.json['rpi.alsc']['calibrations_Cb'] + self.log += '\nALSC tables found successfully' + except KeyError: + cal_cr_list,cal_cb_list=None,None + print('ERROR, no ALSC calibrations found for AWB') + print('Performing AWB without ALSC tables') + self.log += '\nWARNING: No ALSC tables found.\nAWB calibration ' + self.log += 'performed without ALSC correction...' + else: + cal_cr_list,cal_cb_list=None,None + self.log += '\nWARNING: No ALSC tables found.\nAWB calibration ' + self.log += 'performed without ALSC correction...' + """ + call calibration function + """ + plot = "rpi.awb" in self.plot + awb_out = awb(self,cal_cr_list,cal_cb_list,plot) + ct_curve,transverse_neg,transverse_pos = awb_out + """ + write output to json + """ + self.json['rpi.awb']['ct_curve'] = ct_curve + self.json['rpi.awb']['sensitivity_r'] = 1.0 + self.json['rpi.awb']['sensitivity_b'] = 1.0 + self.json['rpi.awb']['transverse_pos'] = transverse_pos + self.json['rpi.awb']['transverse_neg'] = transverse_neg + self.log += '\nAWB calibration written to json file' + print('Finished AWB calibration') + + """ + Auto lens shading correction completely mitigates the effects of lens shading for ech + colour channel seperately, and then partially corrects for vignetting. + The extent of the correction depends on the 'luminance_strength' parameter. + """ + def alsc_cal(self,luminance_strength,do_alsc_colour): + if 'rpi.alsc' in self.disable: + return 1 + print('\nStarting ALSC calibration') + self.log_new_sec('ALSC') + """ + check if alsc images have been taken + """ + if len(self.imgs_alsc) == 0: + print('\nError:\nNo alsc calibration images found') + self.log += '\nERROR: No ALSC calibration images found!' + self.log += '\nALSC calibration aborted!' + return 1 + self.json['rpi.alsc']['luminance_strength'] = luminance_strength + if self.grey and do_alsc_colour: + print('Greyscale camera so only luminance_lut calculated') + do_alsc_colour = False + self.log += '\nWARNING: ALSC colour correction cannot be done on ' + self.log += 'greyscale image!\nALSC colour corrections forced off!' + """ + call calibration function + """ + plot = "rpi.alsc" in self.plot + alsc_out = alsc_all(self,do_alsc_colour,plot) + cal_cr_list,cal_cb_list,luminance_lut,av_corn = alsc_out + """ + write ouput to json and finish if not do_alsc_colour + """ + if not do_alsc_colour: + self.json['rpi.alsc']['luminance_lut'] = luminance_lut + self.json['rpi.alsc']['n_iter'] = 0 + self.log += '\nALSC calibrations written to json file' + self.log += '\nNo colour calibrations performed' + print('Finished ALSC calibrations') + return 1 + + self.json['rpi.alsc']['calibrations_Cr'] = cal_cr_list + self.json['rpi.alsc']['calibrations_Cb'] = cal_cb_list + self.json['rpi.alsc']['luminance_lut'] = luminance_lut + self.log += '\nALSC colour and luminance tables written to json file' + + """ + The sigmas determine the strength of the adaptive algorithm, that + cleans up any lens shading that has slipped through the alsc. These are + determined by measuring a 'worst-case' difference between two alsc tables + that are adjacent in colour space. If, however, only one colour + temperature has been provided, then this difference can not be computed + as only one table is available. + To determine the sigmas you would have to estimate the error of an alsc + table with only the image it was taken on as a check. To avoid circularity, + dfault exaggerated sigmas are used, which can result in too much alsc and + is therefore not advised. + In general, just take another alsc picture at another colour temperature! + """ + + if len(self.imgs_alsc) == 1: + self.json['rpi.alsc']['sigma'] = 0.005 + self.json['rpi.alsc']['sigma_Cb'] = 0.005 + print('\nWarning:\nOnly one alsc calibration found' + + '\nStandard sigmas used for adaptive algorithm.') + print('Finished ALSC calibrations') + self.log += '\nWARNING: Only one colour temperature found in ' + self.log += 'calibration images.\nStandard sigmas used for adaptive ' + self.log += 'algorithm!' + return 1 + + """ + obtain worst-case scenario residual sigmas + """ + sigma_r,sigma_b = get_sigma(self,cal_cr_list,cal_cb_list) + """ + write output to json + """ + self.json['rpi.alsc']['sigma'] = np.round(sigma_r,5) + self.json['rpi.alsc']['sigma_Cb'] = np.round(sigma_b,5) + self.log += '\nCalibrated sigmas written to json file' + print('Finished ALSC calibrations') + + """ + Green equalisation fixes problems caused by discrepancies in green + channels. This is done by measuring the effect on macbeth chart patches, + which ideally would have the same green values throughout. + An upper bound linear model is fit, fixing a threshold for the green + differences that are corrected. + """ + def geq_cal(self): + if 'rpi.geq' in self.disable: + return 1 + print('\nStarting GEQ calibrations') + self.log_new_sec('GEQ') + """ + perform calibration + """ + plot = 'rpi.geq' in self.plot + slope,offset = geq_fit(self,plot) + """ + write output to json + """ + self.json['rpi.geq']['offset'] = offset + self.json['rpi.geq']['slope'] = slope + self.log += '\nGEQ calibrations written to json file' + print('Finished GEQ calibrations') + + """ + Lux calibrations allow the lux level of a scene to be estimated by a ratio + calculation. Lux values are used in the pipeline for algorithms such as AGC + and AWB + """ + def lux_cal(self): + if 'rpi.lux' in self.disable: + return 1 + print('\nStarting LUX calibrations') + self.log_new_sec('LUX') + """ + The lux calibration is done on a single image. For best effects, the + image with lux level closest to 1000 is chosen. + """ + luxes = [Img.lux for Img in self.imgs] + argmax = luxes.index(min(luxes, key=lambda l:abs(1000-l))) + Img = self.imgs[argmax] + self.log += '\nLux found closest to 1000: {} lx'.format(Img.lux) + self.log += '\nImage used: ' + Img.name + if Img.lux < 50: + self.log += '\nWARNING: Low lux could cause inaccurate calibrations!' + """ + do calibration + """ + lux_out,shutter_speed,gain = lux(self,Img) + """ + write output to json + """ + self.json['rpi.lux']['reference_shutter_speed'] = shutter_speed + self.json['rpi.lux']['reference_gain'] = gain + self.json['rpi.lux']['reference_lux'] = Img.lux + self.json['rpi.lux']['reference_Y'] = lux_out + self.log += '\nLUX calibrations written to json file' + print('Finished LUX calibrations') + + """ + Noise alibration attempts to describe the noise profile of the sensor. The + calibration is run on macbeth images and the final output is taken as the average + """ + def noise_cal(self): + if 'rpi.noise' in self.disable: + return 1 + print('\nStarting NOISE calibrations') + self.log_new_sec('NOISE') + """ + run calibration on all images and sort by slope. + """ + plot = "rpi.noise" in self.plot + noise_out = sorted([noise(self,Img,plot) for Img in self.imgs], key = lambda x:x[0]) + self.log += '\nFinished processing images' + """ + take the average of the interquartile + """ + l = len(noise_out) + noise_out = np.mean(noise_out[l//4:1+3*l//4],axis=0) + self.log += '\nAverage noise profile: constant = {} '.format(int(noise_out[1])) + self.log += 'slope = {:.3f}'.format(noise_out[0]) + """ + write to json + """ + self.json['rpi.noise']['reference_constant'] = int(noise_out[1]) + self.json['rpi.noise']['reference_slope'] = round(noise_out[0],3) + self.log += '\nNOISE calibrations written to json' + print('Finished NOISE calibrations') + + """ + Removes json entries that are turned off + """ + def json_remove(self,disable): + self.log_new_sec('Disabling Options',cal=False) + if len(self.disable) == 0: + self.log += '\nNothing disabled!' + return 1 + for key in disable: + try: + del self.json[key] + self.log += '\nDisabled: '+key + except KeyError: + self.log += '\nERROR: '+key +' not found!' + """ + writes the json dictionary to the raw json file then make pretty + """ + def write_json(self): + """ + Write json dictionary to file + """ + jstring = json.dumps(self.json,sort_keys=False) + """ + make it pretty :) + """ + pretty_print_json(jstring,self.jf) + + """ + add a new section to the log file + """ + def log_new_sec(self,section,cal=True): + self.log += '\n'+self.log_separator + self.log += section + if cal: + self.log += ' Calibration' + self.log += self.log_separator + + """ + write script arguments to log file + """ + def log_user_input(self,json_output,directory,config,log_output): + self.log_new_sec('User Arguments',cal=False) + self.log += '\nJson file output: ' + json_output + self.log += '\nCalibration images directory: ' + directory + if config == None: + self.log += '\nNo configuration file input... using default options' + elif config == False: + self.log += '\nWARNING: Invalid configuration file path...' + self.log += ' using default options' + elif config == True: + self.log += '\nWARNING: Invalid syntax in configuration file...' + self.log += ' using default options' + else: + self.log += '\nConfiguration file: ' + config + if log_output == None: + self.log += '\nNo log file path input... using default: ctt_log.txt' + else: + self.log += '\nLog file output: ' + log_output + + # if log_output + + """ + write log file + """ + def write_log(self,filename): + if filename == None: + filename = 'ctt_log.txt' + self.log += '\n' + self.log_separator + with open(filename,'w') as logfile: + logfile.write(self.log) + + """ + Add all images from directory, pass into relevant list of images and + extrace lux and temperature values. + """ + def add_imgs(self,directory,mac_config,blacklevel=-1): + self.log_new_sec('Image Loading',cal=False) + img_suc_msg = 'Image loaded successfully!' + print('\n\nLoading images from '+directory) + self.log += '\nDirectory: ' + directory + """ + get list of files + """ + filename_list = get_photos(directory) + print("Files found: {}".format(len(filename_list))) + self.log += '\nFiles found: {}'.format(len(filename_list)) + """ + iterate over files + """ + filename_list.sort() + for filename in filename_list: + address = directory + filename + print('\nLoading image: '+filename) + self.log += '\n\nImage: ' + filename + """ + obtain colour and lux value + """ + col,lux = get_col_lux(filename) + """ + Check if image is an alsc calibration image + """ + if 'alsc' in filename: + Img = load_image(self,address,mac=False) + self.log += '\nIdentified as an ALSC image' + """ + check if imagae data has been successfully unpacked + """ + if Img == 0: + print('\nDISCARDED') + self.log += '\nImage discarded!' + continue + """ + check that image colour temperature has been successfuly obtained + """ + elif col != None: + """ + if successful, append to list and continue to next image + """ + Img.col = col + Img.name = filename + self.log += '\nColour temperature: {} K'.format(col) + self.imgs_alsc.append(Img) + if blacklevel != -1: + Img.blacklevel_16 = blacklevel + print(img_suc_msg) + continue + else: + print('Error! No colour temperature found!') + self.log += '\nWARNING: Error reading colour temperature' + self.log += '\nImage discarded!' + print('DISCARDED') + else: + self.log += '\nIdentified as macbeth chart image' + """ + if image isn't an alsc correction then it must have a lux and a + colour temperature value to be useful + """ + if lux == None: + print('DISCARDED') + self.log += '\nWARNING: Error reading lux value' + self.log += '\nImage discarded!' + continue + Img = load_image(self,address,mac_config) + """ + check that image data has been successfuly unpacked + """ + if Img == 0: + print('DISCARDED') + self.log += '\nImage discarded!' + continue + else: + """ + if successful, append to list and continue to next image + """ + Img.col,Img.lux = col,lux + Img.name = filename + self.log += '\nColour temperature: {} K'.format(col) + self.log += '\nLux value: {} lx'.format(lux) + if blacklevel != -1: + Img.blacklevel_16 = blacklevel + print(img_suc_msg) + self.imgs.append(Img) + + print('\nFinished loading images') + + """ + Check that usable images have been found + Possible errors include: + - no macbeth chart + - incorrect filename/extension + - images from different cameras + """ + def check_imgs(self): + self.log += '\n\nImages found:' + self.log += '\nMacbeth : {}'.format(len(self.imgs)) + self.log += '\nALSC : {} '.format(len(self.imgs_alsc)) + self.log += '\n\nCamera metadata' + """ + check usable images found + """ + if len(self.imgs) == 0: + print('\nERROR: No usable macbeth chart images found') + self.log += '\nERROR: No usable macbeth chart images found' + return 0 + """ + Double check that every image has come from the same camera... + """ + all_imgs = self.imgs + self.imgs_alsc + camNames = list(set([Img.camName for Img in all_imgs])) + patterns = list(set([Img.pattern for Img in all_imgs])) + sigbitss = list(set([Img.sigbits for Img in all_imgs])) + blacklevels = list(set([Img.blacklevel_16 for Img in all_imgs])) + sizes = list(set([(Img.w,Img.h) for Img in all_imgs])) + + if len(camNames)==1 and len(patterns)==1 and len(sigbitss)==1 and len(blacklevels) ==1 and len(sizes)== 1: + self.grey = (patterns[0] == 128) + self.blacklevel_16 = blacklevels[0] + self.log += '\nName: {}'.format(camNames[0]) + self.log += '\nBayer pattern case: {}'.format(patterns[0]) + if self.grey: + self.log += '\nGreyscale camera identified' + self.log += '\nSignificant bits: {}'.format(sigbitss[0]) + self.log += '\nBlacklevel: {}'.format(blacklevels[0]) + self.log += '\nImage size: w = {} h = {}'.format(sizes[0][0],sizes[0][1]) + return 1 + else: + print('\nERROR: Images from different cameras') + self.log += '\nERROR: Images are from different cameras' + return 0 + +def run_ctt(json_output,directory,config,log_output): + """ + check input files are jsons + """ + if json_output[-5:] != '.json': + raise ArgError('\n\nError: Output must be a json file!') + if config != None: + """ + check if config file is actually a json + """ + if config[-5:] != '.json': + raise ArgError('\n\nError: Config file must be a json file!') + """ + read configurations + """ + try: + with open(config,'r') as config_json: + configs = json.load(config_json) + except FileNotFoundError: + configs = {} + config = False + except json.decoder.JSONDecodeError: + configs = {} + config = True + + else: + configs = {} + """ + load configurations from config file, if not given then set default + """ + disable = get_config(configs,"disable",[],'list') + plot = get_config(configs,"plot",[],'list') + awb_d = get_config(configs,"awb",{},'dict') + greyworld = get_config(awb_d,"greyworld",0,'bool') + alsc_d = get_config(configs,"alsc",{},'dict') + do_alsc_colour = get_config(alsc_d,"do_alsc_colour",1,'bool') + luminance_strength = get_config(alsc_d,"luminance_strength",0.5,'num') + blacklevel = get_config(configs,"blacklevel",-1,'num') + macbeth_d = get_config(configs,"macbeth",{},'dict') + mac_small = get_config(macbeth_d,"small",0,'bool') + mac_show = get_config(macbeth_d,"show",0,'bool') + mac_config = (mac_small,mac_show) + + if blacklevel < -1 or blacklevel >= 2**16: + print('\nInvalid blacklevel, defaulted to 64') + blacklevel = -1 + + if luminance_strength < 0 or luminance_strength > 1: + print('\nInvalid luminance_strength strength, defaulted to 0.5') + luminance_strength = 0.5 + + """ + sanitise directory path + """ + if directory[-1] != '/': + directory += '/' + """ + initialise tuning tool and load images + """ + try: + Cam = Camera(json_output) + Cam.log_user_input(json_output,directory,config,log_output) + Cam.disable = disable + Cam.plot = plot + Cam.add_imgs(directory,mac_config,blacklevel) + except FileNotFoundError: + raise ArgError('\n\nError: Input image directory not found!') + + + """ + preform calibrations as long as check_imgs returns True + If alsc is activated then it must be done before awb and ccm since the alsc + tables are used in awb and ccm calibrations + ccm also technically does an awb but it measures this from the macbeth + chart in the image rather than using calibration data + """ + if Cam.check_imgs(): + Cam.json['rpi.black_level']['black_level'] = Cam.blacklevel_16 + Cam.json_remove(disable) + print('\nSTARTING CALIBRATIONS') + Cam.alsc_cal(luminance_strength,do_alsc_colour) + Cam.geq_cal() + Cam.lux_cal() + Cam.noise_cal() + Cam.awb_cal(greyworld,do_alsc_colour) + Cam.ccm_cal(do_alsc_colour) + print('\nFINISHED CALIBRATIONS') + Cam.write_json() + Cam.write_log(log_output) + print('\nCalibrations written to: '+json_output) + if log_output == None: + log_output = 'ctt_log.txt' + print('Log file written to: '+log_output) + pass + else: + Cam.write_log(log_output) + +if __name__ == '__main__': + """ + initialise calibration + """ + if len(sys.argv) == 1: + print(""" + Pisp Camera Tuning Tool version 1.0 + + Required Arguments: + '-i' : Calibration image directory. + '-o' : Name of output json file. + + Optional Arguments: + '-c' : Config file for the CTT. If not passed, default parameters used. + '-l' : Name of output log file. If not passed, 'ctt_log.txt' used. + """) + quit(0) + else: + """ + parse input arguments + """ + json_output,directory,config,log_output = parse_input() + run_ctt(json_output,directory,config,log_output) diff --git a/utils/raspberrypi/ctt/ctt_alsc.py b/utils/raspberrypi/ctt/ctt_alsc.py new file mode 100644 index 00000000..fe1cff65 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_alsc.py @@ -0,0 +1,297 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_alsc.py - camera tuning tool for ALSC (auto lens shading correction) + +from ctt_image_load import * +import matplotlib.pyplot as plt +from matplotlib import cm +from mpl_toolkits.mplot3d import Axes3D + +""" +preform alsc calibration on a set of images +""" +def alsc_all(Cam,do_alsc_colour,plot): + imgs_alsc = Cam.imgs_alsc + """ + create list of colour temperatures and associated calibration tables + """ + list_col = [] + list_cr = [] + list_cb = [] + list_cg = [] + for Img in imgs_alsc: + col,cr,cb,cg,size = alsc(Cam,Img,do_alsc_colour,plot) + list_col.append(col) + list_cr.append(cr) + list_cb.append(cb) + list_cg.append(cg) + Cam.log += '\n' + Cam.log += '\nFinished processing images' + w,h,dx,dy = size + Cam.log += '\nChannel dimensions: w = {} h = {}'.format(int(w),int(h)) + Cam.log += '\n16x12 grid rectangle size: w = {} h = {}'.format(dx,dy) + + """ + convert to numpy array for data manipulation + """ + list_col = np.array(list_col) + list_cr = np.array(list_cr) + list_cb = np.array(list_cb) + list_cg = np.array(list_cg) + + cal_cr_list = [] + cal_cb_list = [] + + """ + only do colour calculations if required + """ + if do_alsc_colour: + Cam.log += '\nALSC colour tables' + for ct in sorted(set(list_col)): + Cam.log += '\nColour temperature: {} K'.format(ct) + """ + average tables for the same colour temperature + """ + indices = np.where(list_col == ct) + ct = int(ct) + t_r = np.mean(list_cr[indices],axis=0) + t_b = np.mean(list_cb[indices],axis=0) + """ + force numbers to be stored to 3dp.... :( + """ + t_r = np.where((100*t_r)%1<=0.05, t_r+0.001,t_r) + t_b = np.where((100*t_b)%1<=0.05, t_b+0.001,t_b) + t_r = np.where((100*t_r)%1>=0.95, t_r-0.001,t_r) + t_b = np.where((100*t_b)%1>=0.95, t_b-0.001,t_b) + t_r = np.round(t_r,3) + t_b = np.round(t_b,3) + r_corners = (t_r[0],t_r[15],t_r[-1],t_r[-16]) + b_corners = (t_b[0],t_b[15],t_b[-1],t_b[-16]) + r_cen = t_r[5*16+7]+t_r[5*16+8]+t_r[6*16+7]+t_r[6*16+8] + r_cen = round(r_cen/4,3) + b_cen = t_b[5*16+7]+t_b[5*16+8]+t_b[6*16+7]+t_b[6*16+8] + b_cen = round(b_cen/4,3) + Cam.log += '\nRed table corners: {}'.format(r_corners) + Cam.log += '\nRed table centre: {}'.format(r_cen) + Cam.log += '\nBlue table corners: {}'.format(b_corners) + Cam.log += '\nBlue table centre: {}'.format(b_cen) + cr_dict = { + 'ct':ct, + 'table':list(t_r) + } + cb_dict = { + 'ct':ct, + 'table':list(t_b) + } + cal_cr_list.append(cr_dict) + cal_cb_list.append(cb_dict) + Cam.log += '\n' + else: + cal_cr_list,cal_cb_list = None,None + + """ + average all values for luminance shading and return one table for all temperatures + """ + lum_lut = np.mean(list_cg,axis=0) + lum_lut = np.where((100*lum_lut)%1<=0.05,lum_lut+0.001,lum_lut) + lum_lut = np.where((100*lum_lut)%1>=0.95,lum_lut-0.001,lum_lut) + lum_lut = list(np.round(lum_lut,3)) + + """ + calculate average corner for lsc gain calculation further on + """ + corners = (lum_lut[0],lum_lut[15],lum_lut[-1],lum_lut[-16]) + Cam.log += '\nLuminance table corners: {}'.format(corners) + l_cen = lum_lut[5*16+7]+lum_lut[5*16+8]+lum_lut[6*16+7]+lum_lut[6*16+8] + l_cen = round(l_cen/4,3) + Cam.log += '\nLuminance table centre: {}'.format(l_cen) + av_corn = np.sum(corners)/4 + + return cal_cr_list,cal_cb_list,lum_lut,av_corn + + +""" +calculate g/r and g/b for 32x32 points arranged in a grid for a single image +""" +def alsc(Cam,Img,do_alsc_colour,plot=False): + Cam.log += '\nProcessing image: ' + Img.name + """ + get channel in correct order + """ + channels = [Img.channels[i] for i in Img.order] + """ + calculate size of single rectangle. + -(-(w-1)//32) is a ceiling division. w-1 is to deal robustly with the case + where w is a multiple of 32. + """ + w,h = Img.w/2,Img.h/2 + dx,dy = int(-(-(w-1)//16)),int(-(-(h-1)//12)) + """ + average the green channels into one + """ + av_ch_g = np.mean((channels[1:2]),axis = 0) + if do_alsc_colour: + """ + obtain 16x12 grid of intensities for each channel and subtract black level + """ + g = get_16x12_grid(av_ch_g,dx,dy) - Img.blacklevel_16 + r = get_16x12_grid(channels[0],dx,dy) - Img.blacklevel_16 + b = get_16x12_grid(channels[3],dx,dy) - Img.blacklevel_16 + """ + calculate ratios as 32 bit in order to be supported by medianBlur function + """ + cr = np.reshape(g/r,(12,16)).astype('float32') + cb = np.reshape(g/b,(12,16)).astype('float32') + cg = np.reshape(1/g,(12,16)).astype('float32') + """ + median blur to remove peaks and save as float 64 + """ + cr = cv2.medianBlur(cr,3).astype('float64') + cb = cv2.medianBlur(cb,3).astype('float64') + cg = cv2.medianBlur(cg,3).astype('float64') + cg = cg/np.min(cg) + + """ + debugging code showing 2D surface plot of vignetting. Quite useful for + for sanity check + """ + if plot: + hf = plt.figure(figsize=(8,8)) + ha = hf.add_subplot(311, projection='3d') + """ + note Y is plotted as -Y so plot has same axes as image + """ + X,Y = np.meshgrid(range(16),range(12)) + ha.plot_surface(X,-Y,cr,cmap=cm.coolwarm,linewidth=0) + ha.set_title('ALSC Plot\nImg: {}\n\ncr'.format(Img.str)) + hb = hf.add_subplot(312, projection='3d') + hb.plot_surface(X,-Y,cb,cmap=cm.coolwarm,linewidth=0) + hb.set_title('cb') + hc = hf.add_subplot(313, projection='3d') + hc.plot_surface(X,-Y,cg,cmap=cm.coolwarm,linewidth=0) + hc.set_title('g') + # print(Img.str) + plt.show() + + return Img.col,cr.flatten(),cb.flatten(),cg.flatten(),(w,h,dx,dy) + + else: + """ + only perform calculations for luminance shading + """ + g = get_16x12_grid(av_ch_g,dx,dy) - Img.blacklevel_16 + cg = np.reshape(1/g,(12,16)).astype('float32') + cg = cv2.medianBlur(cg,3).astype('float64') + cg = cg/np.min(cg) + + if plot: + hf = plt.figure(figssize=(8,8)) + ha = hf.add_subplot(1,1,1,projection='3d') + X,Y = np.meashgrid(range(16),range(12)) + ha.plot_surface(X,-Y,cg,cmap=cm.coolwarm,linewidth=0) + ha.set_title('ALSC Plot (Luminance only!)\nImg: {}\n\ncg').format(Img.str) + plt.show() + + return Img.col,None,None,cg.flatten(),(w,h,dx,dy) + + +""" +Compresses channel down to a 16x12 grid +""" +def get_16x12_grid(chan,dx,dy): + grid = [] + """ + since left and bottom border will not necessarily have rectangles of + dimension dx x dy, the 32nd iteration has to be handled separately. + """ + for i in range(11): + for j in range(15): + grid.append(np.mean(chan[dy*i:dy*(1+i),dx*j:dx*(1+j)])) + grid.append(np.mean(chan[dy*i:dy*(1+i),15*dx:])) + for j in range(15): + grid.append(np.mean(chan[11*dy:,dx*j:dx*(1+j)])) + grid.append(np.mean(chan[11*dy:,15*dx:])) + """ + return as np.array, ready for further manipulation + """ + return np.array(grid) + +""" +obtains sigmas for red and blue, effectively a measure of the 'error' +""" +def get_sigma(Cam,cal_cr_list,cal_cb_list): + Cam.log += '\nCalculating sigmas' + """ + provided colour alsc tables were generated for two different colour + temperatures sigma is calculated by comparing two calibration temperatures + adjacent in colour space + """ + """ + create list of colour temperatures + """ + cts = [cal['ct'] for cal in cal_cr_list] + # print(cts) + """ + calculate sigmas for each adjacent cts and return worst one + """ + sigma_rs = [] + sigma_bs = [] + for i in range(len(cts)-1): + sigma_rs.append(calc_sigma(cal_cr_list[i]['table'],cal_cr_list[i+1]['table'])) + sigma_bs.append(calc_sigma(cal_cb_list[i]['table'],cal_cb_list[i+1]['table'])) + Cam.log += '\nColour temperature interval {} - {} K'.format(cts[i],cts[i+1]) + Cam.log += '\nSigma red: {}'.format(sigma_rs[-1]) + Cam.log += '\nSigma blue: {}'.format(sigma_bs[-1]) + + """ + return maximum sigmas, not necessarily from the same colour temperature + interval + """ + sigma_r = max(sigma_rs) if sigma_rs else 0.005 + sigma_b = max(sigma_bs) if sigma_bs else 0.005 + Cam.log += '\nMaximum sigmas: Red = {} Blue = {}'.format(sigma_r, sigma_b) + + + # print(sigma_rs,sigma_bs) + # print(sigma_r,sigma_b) + return sigma_r,sigma_b + +""" +calculate sigma from two adjacent gain tables +""" +def calc_sigma(g1,g2): + """ + reshape into 16x12 matrix + """ + g1 = np.reshape(g1,(12,16)) + g2 = np.reshape(g2,(12,16)) + """ + apply gains to gain table + """ + gg = g1/g2 + if np.mean(gg) < 1: + gg = 1/gg + """ + for each internal patch, compute average difference between it and its 4 + neighbours, then append to list + """ + diffs = [] + for i in range(10): + for j in range(14): + """ + note indexing is incremented by 1 since all patches on borders are + not counted + """ + diff = np.abs(gg[i+1][j+1]-gg[i][j+1]) + diff += np.abs(gg[i+1][j+1]-gg[i+2][j+1]) + diff += np.abs(gg[i+1][j+1]-gg[i+1][j]) + diff += np.abs(gg[i+1][j+1]-gg[i+1][j+2]) + diffs.append(diff/4) + + """ + return mean difference + """ + mean_diff = np.mean(diffs) + return(np.round(mean_diff,5)) diff --git a/utils/raspberrypi/ctt/ctt_awb.py b/utils/raspberrypi/ctt/ctt_awb.py new file mode 100644 index 00000000..d3130612 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_awb.py @@ -0,0 +1,374 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_awb.py - camera tuning tool for AWB + +from ctt_image_load import * +import matplotlib.pyplot as plt +from bisect import bisect_left +from scipy.optimize import fmin + +""" +obtain piecewise linear approximation for colour curve +""" +def awb(Cam,cal_cr_list,cal_cb_list,plot): + imgs = Cam.imgs + """ + condense alsc calibration tables into one dictionary + """ + if cal_cr_list == None: + colour_cals = None + else: + colour_cals = {} + for cr,cb in zip(cal_cr_list,cal_cb_list): + cr_tab = cr['table'] + cb_tab = cb['table'] + """ + normalise tables so min value is 1 + """ + cr_tab= cr_tab/np.min(cr_tab) + cb_tab= cb_tab/np.min(cb_tab) + colour_cals[cr['ct']] = [cr_tab,cb_tab] + """ + obtain data from greyscale macbeth patches + """ + rb_raw = [] + rbs_hat = [] + for Img in imgs: + Cam.log += '\nProcessing '+Img.name + """ + get greyscale patches with alsc applied if alsc enabled. + Note: if alsc is disabled then colour_cals will be set to None and the + function will just return the greyscale patches + """ + r_patchs,b_patchs,g_patchs = get_alsc_patches(Img,colour_cals) + """ + calculate ratio of r,b to g + """ + r_g = np.mean(r_patchs/g_patchs) + b_g = np.mean(b_patchs/g_patchs) + Cam.log += '\n r : {:.4f} b : {:.4f}'.format(r_g,b_g) + """ + The curve tends to be better behaved in so-called hatspace. + R,B,G represent the individual channels. The colour curve is plotted in + r,b space, where: + r = R/G + b = B/G + This will be referred to as dehatspace... (sorry) + Hatspace is defined as: + r_hat = R/(R+B+G) + b_hat = B/(R+B+G) + To convert from dehatspace to hastpace (hat operation): + r_hat = r/(1+r+b) + b_hat = b/(1+r+b) + To convert from hatspace to dehatspace (dehat operation): + r = r_hat/(1-r_hat-b_hat) + b = b_hat/(1-r_hat-b_hat) + Proof is left as an excercise to the reader... + Throughout the code, r and b are sometimes referred to as r_g and b_g + as a reminder that they are ratios + """ + r_g_hat = r_g/(1+r_g+b_g) + b_g_hat = b_g/(1+r_g+b_g) + Cam.log += '\n r_hat : {:.4f} b_hat : {:.4f}'.format(r_g_hat,b_g_hat) + rbs_hat.append((r_g_hat,b_g_hat,Img.col)) + rb_raw.append((r_g,b_g)) + Cam.log += '\n' + + Cam.log += '\nFinished processing images' + """ + sort all lits simultaneously by r_hat + """ + rbs_zip = list(zip(rbs_hat,rb_raw)) + rbs_zip.sort(key=lambda x:x[0][0]) + rbs_hat,rb_raw = list(zip(*rbs_zip)) + """ + unzip tuples ready for processing + """ + rbs_hat = list(zip(*rbs_hat)) + rb_raw = list(zip(*rb_raw)) + """ + fit quadratic fit to r_g hat and b_g_hat + """ + a,b,c = np.polyfit(rbs_hat[0],rbs_hat[1],2) + Cam.log += '\nFit quadratic curve in hatspace' + """ + the algorithm now approximates the shortest distance from each point to the + curve in dehatspace. Since the fit is done in hatspace, it is easier to + find the actual shortest distance in hatspace and use the projection back + into dehatspace as an overestimate. + The distance will be used for two things: + 1) In the case that colour temperature does not strictly decrease with + increasing r/g, the closest point to the line will be chosen out of an + increasing pair of colours. + + 2) To calculate transverse negative an dpositive, the maximum positive + and negative distance from the line are chosen. This benefits from the + overestimate as the transverse pos/neg are upper bound values. + """ + """ + define fit function + """ + def f(x): + return a*x**2 + b*x + c + """ + iterate over points (R,B are x and y coordinates of points) and calculate + distance to line in dehatspace + """ + dists = [] + for i, (R,B) in enumerate(zip(rbs_hat[0],rbs_hat[1])): + """ + define function to minimise as square distance between datapoint and + point on curve. Squaring is monotonic so minimising radius squared is + equivalent to minimising radius + """ + def f_min(x): + y = f(x) + return((x-R)**2+(y-B)**2) + """ + perform optimisation with scipy.optmisie.fmin + """ + x_hat = fmin(f_min,R,disp=0)[0] + y_hat = f(x_hat) + """ + dehat + """ + x = x_hat/(1-x_hat-y_hat) + y = y_hat/(1-x_hat-y_hat) + rr = R/(1-R-B) + bb = B/(1-R-B) + """ + calculate euclidean distance in dehatspace + """ + dist = ((x-rr)**2+(y-bb)**2)**0.5 + """ + return negative if point is below the fit curve + """ + if (x+y) > (rr+bb): + dist *= -1 + dists.append(dist) + Cam.log += '\nFound closest point on fit line to each point in dehatspace' + """ + calculate wiggle factors in awb. 10% added since this is an upper bound + """ + transverse_neg = - np.min(dists) * 1.1 + transverse_pos = np.max(dists) * 1.1 + Cam.log += '\nTransverse pos : {:.5f}'.format(transverse_pos) + Cam.log += '\nTransverse neg : {:.5f}'.format(transverse_neg) + """ + set minimum transverse wiggles to 0.1 . + Wiggle factors dictate how far off of the curve the algorithm searches. 0.1 + is a suitable minimum that gives better results for lighting conditions not + within calibration dataset. Anything less will generalise poorly. + """ + if transverse_pos < 0.01: + transverse_pos = 0.01 + Cam.log += '\nForced transverse pos to 0.01' + if transverse_neg < 0.01: + transverse_neg = 0.01 + Cam.log += '\nForced transverse neg to 0.01' + + """ + generate new b_hat values at each r_hat according to fit + """ + r_hat_fit = np.array(rbs_hat[0]) + b_hat_fit = a*r_hat_fit**2 + b*r_hat_fit + c + """ + transform from hatspace to dehatspace + """ + r_fit = r_hat_fit/(1-r_hat_fit-b_hat_fit) + b_fit = b_hat_fit/(1-r_hat_fit-b_hat_fit) + c_fit = np.round(rbs_hat[2],0) + """ + round to 4dp + """ + r_fit = np.where((1000*r_fit)%1<=0.05,r_fit+0.0001,r_fit) + r_fit = np.where((1000*r_fit)%1>=0.95,r_fit-0.0001,r_fit) + b_fit = np.where((1000*b_fit)%1<=0.05,b_fit+0.0001,b_fit) + b_fit = np.where((1000*b_fit)%1>=0.95,b_fit-0.0001,b_fit) + r_fit = np.round(r_fit,4) + b_fit = np.round(b_fit,4) + """ + The following code ensures that colour temperature decreases with + increasing r/g + """ + """ + iterate backwards over list for easier indexing + """ + i = len(c_fit) - 1 + while i > 0 : + if c_fit[i] > c_fit[i-1]: + Cam.log += '\nColour temperature increase found\n' + Cam.log += '{} K at r = {} to '.format(c_fit[i-1],r_fit[i-1]) + Cam.log += '{} K at r = {}'.format(c_fit[i],r_fit[i]) + """ + if colour temperature increases then discard point furthest from + the transformed fit (dehatspace) + """ + error_1 = abs(dists[i-1]) + error_2 = abs(dists[i]) + Cam.log += '\nDistances from fit:\n' + Cam.log += '{} K : {:.5f} , '.format(c_fit[i],error_1) + Cam.log += '{} K : {:.5f}'.format(c_fit[i-1],error_2) + """ + find bad index + note that in python false = 0 and true = 1 + """ + bad = i - (error_1<error_2) + Cam.log += '\nPoint at {} K deleted as '.format(c_fit[bad]) + Cam.log += 'it is furthest from fit' + """ + delete bad point + """ + r_fit = np.delete(r_fit,bad) + b_fit = np.delete(b_fit,bad) + c_fit = np.delete(c_fit,bad).astype(np.uint16) + """ + note that if a point has been discarded then the length has decreased + by one, meaning that decreasing the index by one will reassess the kept + point against the next point. It is therefore possible, in theory, for + two adjacent points to be discarded, although probably rare + """ + i -= 1 + + """ + return formatted ct curve, ordered by increasing colour temperature + """ + ct_curve = list(np.array(list(zip(b_fit,r_fit,c_fit))).flatten())[::-1] + Cam.log += '\nFinal CT curve:' + for i in range(len(ct_curve)//3): + j = 3*i + Cam.log += '\n ct: {} '.format(ct_curve[j]) + Cam.log += ' r: {} '.format(ct_curve[j+1]) + Cam.log += ' b: {} '.format(ct_curve[j+2]) + + """ + plotting code for debug + """ + if plot: + x = np.linspace(np.min(rbs_hat[0]),np.max(rbs_hat[0]),100) + y = a*x**2 + b*x + c + plt.subplot(2,1,1) + plt.title('hatspace') + plt.plot(rbs_hat[0],rbs_hat[1],ls='--',color='blue') + plt.plot(x,y,color='green',ls='-') + plt.scatter(rbs_hat[0],rbs_hat[1],color='red') + for i, ct in enumerate(rbs_hat[2]): + plt.annotate(str(ct),(rbs_hat[0][i],rbs_hat[1][i])) + plt.xlabel('$\hat{r}$') + plt.ylabel('$\hat{b}$') + """ + optional set axes equal to shortest distance so line really does + looks perpendicular and everybody is happy + """ + # ax = plt.gca() + # ax.set_aspect('equal') + plt.grid() + plt.subplot(2,1,2) + plt.title('dehatspace - indoors?') + plt.plot(r_fit,b_fit,color='blue') + plt.scatter(rb_raw[0],rb_raw[1],color='green') + plt.scatter(r_fit,b_fit,color='red') + for i,ct in enumerate(c_fit): + plt.annotate(str(ct),(r_fit[i],b_fit[i])) + plt.xlabel('$r$') + plt.ylabel('$b$') + """ + optional set axes equal to shortest distance so line really does + looks perpendicular and everybody is happy + """ + # ax = plt.gca() + # ax.set_aspect('equal') + plt.subplots_adjust(hspace=0.5) + plt.grid() + plt.show() + """ + end of plotting code + """ + return(ct_curve,np.round(transverse_pos,5),np.round(transverse_neg,5)) + +""" +obtain greyscale patches and perform alsc colour correction +""" +def get_alsc_patches(Img,colour_cals,grey=True): + """ + get patch centre coordinates, image colour and the actual + patches for each channel,remembering to subtract blacklevel + If grey then only greyscale patches considered + """ + if grey: + cen_coords = Img.cen_coords[3::4] + col = Img.col + patches = [np.array(Img.patches[i]) for i in Img.order] + r_patchs = patches[0][3::4] - Img.blacklevel_16 + b_patchs = patches[3][3::4] - Img.blacklevel_16 + """ + note two green channels are averages + """ + g_patchs = (patches[1][3::4]+patches[2][3::4])/2 - Img.blacklevel_16 + else: + cen_coords = Img.cen_coords + col = Img.col + patches = [np.array(Img.patches[i]) for i in Img.order] + r_patchs = patches[0] - Img.blacklevel_16 + b_patchs = patches[3] - Img.blacklevel_16 + g_patchs = (patches[1]+patches[2])/2 - Img.blacklevel_16 + + if colour_cals == None: + return r_patchs,b_patchs,g_patchs + """ + find where image colour fits in alsc colour calibration tables + """ + cts = list(colour_cals.keys()) + pos = bisect_left(cts,col) + """ + if img colour is below minimum or above maximum alsc calibration colour, simply + pick extreme closest to img colour + """ + if pos%(len(cts)) == 0: + """ + this works because -0 = 0 = first and -1 = last index + """ + col_tabs = np.array(colour_cals[cts[-pos//len(cts)]]) + """ + else, perform linear interpolation between existing alsc colour + calibration tables + """ + else: + bef = cts[pos-1] + aft = cts[pos] + da = col-bef + db = aft-col + bef_tabs = np.array(colour_cals[bef]) + aft_tabs = np.array(colour_cals[aft]) + col_tabs = (bef_tabs*db + aft_tabs*da)/(da+db) + col_tabs = np.reshape(col_tabs,(2,12,16)) + """ + calculate dx,dy used to calculate alsc table + """ + w,h = Img.w/2,Img.h/2 + dx,dy = int(-(-(w-1)//16)),int(-(-(h-1)//12)) + """ + make list of pairs of gains for each patch by selecting the correct value + in alsc colour calibration table + """ + patch_gains = [] + for cen in cen_coords: + x,y = cen[0]//dx, cen[1]//dy + # We could probably do with some better spatial interpolation here? + col_gains = (col_tabs[0][y][x],col_tabs[1][y][x]) + patch_gains.append(col_gains) + + """ + multiply the r and b channels in each patch by the respective gain, finally + performing the alsc colour correction + """ + for i,gains in enumerate(patch_gains): + r_patchs[i] = r_patchs[i] * gains[0] + b_patchs[i] = b_patchs[i] * gains[1] + + """ + return greyscale patches, g channel and correct r,b channels + """ + return r_patchs,b_patchs,g_patchs diff --git a/utils/raspberrypi/ctt/ctt_ccm.py b/utils/raspberrypi/ctt/ctt_ccm.py new file mode 100644 index 00000000..8200a27f --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_ccm.py @@ -0,0 +1,221 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_ccm.py - camera tuning tool for CCM (colour correction matrix) + +from ctt_image_load import * +from ctt_awb import get_alsc_patches + +""" +takes 8-bit macbeth chart values, degammas and returns 16 bit +""" +def degamma(x): + x = x / ((2**8)-1) + x = np.where(x < 0.04045, x/12.92, ((x+0.055)/1.055)**2.4) + x = x * ((2**16)-1) + return x + +""" +FInds colour correction matrices for list of images +""" +def ccm(Cam,cal_cr_list,cal_cb_list): + imgs = Cam.imgs + """ + standard macbeth chart colour values + """ + m_rgb = np.array([ # these are in sRGB + [116, 81, 67], # dark skin + [199, 147, 129], # light skin + [91, 122, 156], # blue sky + [90, 108, 64], # foliage + [130, 128, 176], # blue flower + [92, 190, 172], # bluish green + [224, 124, 47], # orange + [68, 91,170], # purplish blue + [198, 82, 97], # moderate red + [94, 58, 106], # purple + [159, 189, 63], # yellow green + [230, 162, 39], # orange yellow + [35, 63, 147], # blue + [67, 149, 74], # green + [180, 49, 57], # red + [238, 198, 20], # yellow + [193, 84, 151], # magenta + [0, 136, 170], # cyan (goes out of gamut) + [245, 245, 243], # white 9.5 + [200, 202, 202], # neutral 8 + [161, 163, 163], # neutral 6.5 + [121, 121, 122], # neutral 5 + [82, 84, 86], # neutral 3.5 + [49, 49, 51] # black 2 + ]) + + """ + convert reference colours from srgb to rgb + """ + m_srgb = degamma(m_rgb) + """ + reorder reference values to match how patches are ordered + """ + m_srgb = np.array([m_srgb[i::6] for i in range(6)]).reshape((24,3)) + + """ + reformat alsc correction tables or set colour_cals to None if alsc is + deactivated + """ + if cal_cr_list == None: + colour_cals = None + else: + colour_cals = {} + for cr,cb in zip(cal_cr_list,cal_cb_list): + cr_tab = cr['table'] + cb_tab = cb['table'] + """ + normalise tables so min value is 1 + """ + cr_tab= cr_tab/np.min(cr_tab) + cb_tab= cb_tab/np.min(cb_tab) + colour_cals[cr['ct']] = [cr_tab,cb_tab] + + """ + for each image, perform awb and alsc corrections. + Then calculate the colour correction matrix for that image, recording the + ccm and the colour tempertaure. + """ + ccm_tab = {} + for Img in imgs: + Cam.log += '\nProcessing image: ' + Img.name + """ + get macbeth patches with alsc applied if alsc enabled. + Note: if alsc is disabled then colour_cals will be set to None and no + the function will simply return the macbeth patches + """ + r,b,g = get_alsc_patches(Img,colour_cals,grey=False) + """ + do awb + Note: awb is done by measuring the macbeth chart in the image, rather + than from the awb calibration. This is done so the awb will be perfect + and the ccm matrices will be more accurate. + """ + r_greys,b_greys,g_greys = r[3::4],b[3::4],g[3::4] + r_g = np.mean(r_greys/g_greys) + b_g = np.mean(b_greys/g_greys) + r = r / r_g + b = b / b_g + + """ + normalise brightness wrt reference macbeth colours and then average + each channel for each patch + """ + gain = np.mean(m_srgb)/np.mean((r,g,b)) + Cam.log += '\nGain with respect to standard colours: {:.3f}'.format(gain) + r = np.mean(gain*r,axis=1) + b = np.mean(gain*b,axis=1) + g = np.mean(gain*g,axis=1) + + """ + calculate ccm matrix + """ + ccm = do_ccm(r,g,b,m_srgb) + + """ + if a ccm has already been calculated for that temperature then don't + overwrite but save both. They will then be averaged later on + """ + if Img.col in ccm_tab.keys(): + ccm_tab[Img.col].append(ccm) + else: + ccm_tab[Img.col] = [ccm] + Cam.log += '\n' + + Cam.log += '\nFinished processing images' + """ + average any ccms that share a colour temperature + """ + for k,v in ccm_tab.items(): + tab = np.mean(v,axis=0) + tab = np.where((10000*tab)%1<=0.05,tab+0.00001,tab) + tab = np.where((10000*tab)%1>=0.95,tab-0.00001,tab) + ccm_tab[k] = list(np.round(tab,5)) + Cam.log += '\nMatrix calculated for colour temperature of {} K'.format(k) + + """ + return all ccms with respective colour temperature in the correct format, + sorted by their colour temperature + """ + sorted_ccms = sorted(ccm_tab.items(),key=lambda kv: kv[0]) + ccms = [] + for i in sorted_ccms: + ccms.append({ + 'ct' : i[0], + 'ccm' : i[1] + }) + return ccms + +""" +calculates the ccm for an individual image. +ccms are calculate in rgb space, and are fit by hand. Although it is a 3x3 +matrix, each row must add up to 1 in order to conserve greyness, simplifying +calculation. +Should you want to fit them in another space (e.g. LAB) we wish you the best of +luck and send us the code when you are done! :-) +""" +def do_ccm(r,g,b,m_srgb): + rb = r-b + gb = g-b + rb_2s = (rb*rb) + rb_gbs = (rb*gb) + gb_2s = (gb*gb) + + r_rbs = ( rb * (m_srgb[...,0] - b) ) + r_gbs = ( gb * (m_srgb[...,0] - b) ) + g_rbs = ( rb * (m_srgb[...,1] - b) ) + g_gbs = ( gb * (m_srgb[...,1] - b) ) + b_rbs = ( rb * (m_srgb[...,2] - b) ) + b_gbs = ( gb * (m_srgb[...,2] - b) ) + + """ + Obtain least squares fit + """ + rb_2 = np.sum(rb_2s) + gb_2 = np.sum(gb_2s) + rb_gb = np.sum(rb_gbs) + r_rb = np.sum(r_rbs) + r_gb = np.sum(r_gbs) + g_rb = np.sum(g_rbs) + g_gb = np.sum(g_gbs) + b_rb = np.sum(b_rbs) + b_gb = np.sum(b_gbs) + + det = rb_2*gb_2 - rb_gb*rb_gb + + """ + Raise error if matrix is singular... + This shouldn't really happen with real data but if it does just take new + pictures and try again, not much else to be done unfortunately... + """ + if det < 0.001: + raise ArithmeticError + + r_a = (gb_2*r_rb - rb_gb*r_gb)/det + r_b = (rb_2*r_gb - rb_gb*r_rb)/det + """ + Last row can be calculated by knowing the sum must be 1 + """ + r_c = 1 - r_a - r_b + + g_a = (gb_2*g_rb - rb_gb*g_gb)/det + g_b = (rb_2*g_gb - rb_gb*g_rb)/det + g_c = 1 - g_a - g_b + + b_a = (gb_2*b_rb - rb_gb*b_gb)/det + b_b = (rb_2*b_gb - rb_gb*b_rb)/det + b_c = 1 - b_a - b_b + + """ + format ccm + """ + ccm = [r_a,r_b,r_c,g_a,g_b,g_c,b_a,b_b,b_c] + + return ccm diff --git a/utils/raspberrypi/ctt/ctt_config_example.json b/utils/raspberrypi/ctt/ctt_config_example.json new file mode 100644 index 00000000..c7f90761 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_config_example.json @@ -0,0 +1,16 @@ +{ + "disable": [], + "plot": [], + "alsc": { + "do_alsc_colour": 1, + "luminance_strength": 0.5 + }, + "awb": { + "greyworld": 0 + }, + "blacklevel": -1, + "macbeth": { + "small": 0, + "show": 0 + } +}
\ No newline at end of file diff --git a/utils/raspberrypi/ctt/ctt_geq.py b/utils/raspberrypi/ctt/ctt_geq.py new file mode 100644 index 00000000..dd798f4a --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_geq.py @@ -0,0 +1,179 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_geq.py - camera tuning tool for GEQ (green equalisation) + +from ctt_tools import * +import matplotlib.pyplot as plt +import scipy.optimize as optimize + +""" +Uses green differences in macbeth patches to fit green equalisation threshold +model. Ideally, all macbeth chart centres would fall below the threshold as +these should be corrected by geq. +""" +def geq_fit(Cam,plot): + imgs = Cam.imgs + """ + green equalisation to mitigate mazing. + Fits geq model by looking at difference + between greens in macbeth patches + """ + geqs = np.array([ geq(Cam,Img)*Img.againQ8_norm for Img in imgs ]) + Cam.log += '\nProcessed all images' + geqs = geqs.reshape((-1,2)) + """ + data is sorted by green difference and top half is selected since higher + green difference data define the decision boundary. + """ + geqs = np.array(sorted(geqs,key = lambda r:np.abs((r[1]-r[0])/r[0]))) + + length = len(geqs) + g0 = geqs[length//2:,0] + g1 = geqs[length//2:,1] + gdiff = np.abs(g0-g1) + """ + find linear fit by minimising asymmetric least square errors + in order to cover most of the macbeth images. + the philosophy here is that every macbeth patch should fall within the + threshold, hence the upper bound approach + """ + def f(params): + m,c = params + a = gdiff - (m*g0+c) + """ + asymmetric square error returns: + 1.95 * a**2 if a is positive + 0.05 * a**2 if a is negative + """ + return(np.sum(a**2+0.95*np.abs(a)*a)) + + initial_guess = [0.01,500] + """ + Nelder-Mead is usually not the most desirable optimisation method + but has been chosen here due to its robustness to undifferentiability + (is that a word?) + """ + result = optimize.minimize(f,initial_guess,method='Nelder-Mead') + """ + need to check if the fit worked correectly + """ + if result.success: + slope,offset = result.x + Cam.log += '\nFit result: slope = {:.5f} '.format(slope) + Cam.log += 'offset = {}'.format(int(offset)) + """ + optional plotting code + """ + if plot: + x = np.linspace(max(g0)*1.1,100) + y = slope*x + offset + plt.title('GEQ Asymmetric \'Upper Bound\' Fit') + plt.plot(x,y,color='red',ls='--',label='fit') + plt.scatter(g0,gdiff,color='b',label='data') + plt.ylabel('Difference in green channels') + plt.xlabel('Green value') + + """ + This upper bound asymmetric gives correct order of magnitude values. + The pipeline approximates a 1st derivative of a gaussian with some + linear piecewise functions, introducing arbitrary cutoffs. For + pessimistic geq, the model parameters have been increased by a + scaling factor/constant. + + Feel free to tune these or edit the json files directly if you + belive there are still mazing effects left (threshold too low) or if you + think it is being overcorrected (threshold too high). + We have gone for a one size fits most approach that will produce + acceptable results in most applications. + """ + slope *= 1.5 + offset += 201 + Cam.log += '\nFit after correction factors: slope = {:.5f}'.format(slope) + Cam.log += ' offset = {}'.format(int(offset)) + """ + clamp offset at 0 due to pipeline considerations + """ + if offset < 0: + Cam.log += '\nOffset raised to 0' + offset = 0 + """ + optional plotting code + """ + if plot: + y2 = slope*x + offset + plt.plot(x,y2,color='green',ls='--',label='scaled fit') + plt.grid() + plt.legend() + plt.show() + + """ + the case where for some reason the fit didn't work correctly + + Transpose data and then least squares linear fit. Transposing data + makes it robust to many patches where green difference is the same + since they only contribute to one error minimisation, instead of dragging + the entire linear fit down. + """ + + else: + print('\nError! Couldn\'t fit asymmetric lest squares') + print(result.message) + Cam.log += '\nWARNING: Asymmetric least squares fit failed! ' + Cam.log += 'Standard fit used could possibly lead to worse results' + fit = np.polyfit(gdiff,g0,1) + offset,slope = -fit[1]/fit[0],1/fit[0] + Cam.log += '\nFit result: slope = {:.5f} '.format(slope) + Cam.log += 'offset = {}'.format(int(offset)) + """ + optional plotting code + """ + if plot: + x = np.linspace(max(g0)*1.1,100) + y = slope*x + offset + plt.title('GEQ Linear Fit') + plt.plot(x,y,color='red',ls='--',label='fit') + plt.scatter(g0,gdiff,color='b',label='data') + plt.ylabel('Difference in green channels') + plt.xlabel('Green value') + """ + Scaling factors (see previous justification) + The model here will not be an upper bound so scaling factors have + been increased. + This method of deriving geq model parameters is extremely arbitrary + and undesirable. + """ + slope *= 2.5 + offset += 301 + Cam.log += '\nFit after correction factors: slope = {:.5f}'.format(slope) + Cam.log += ' offset = {}'.format(int(offset)) + + if offset < 0: + Cam.log += '\nOffset raised to 0' + offset = 0 + + """ + optional plotting code + """ + if plot: + y2 = slope*x + offset + plt.plot(x,y2,color='green',ls='--',label='scaled fit') + plt.legend() + plt.grid() + plt.show() + + return round(slope,5),int(offset) + +"""" +Return green channels of macbeth patches +returns g0,g1 where +> g0 is green next to red +> g1 is green next to blue +""" +def geq(Cam,Img): + Cam.log += '\nProcessing image {}'.format(Img.name) + patches = [Img.patches[i] for i in Img.order][1:3] + g_patches = np.array([(np.mean(patches[0][i]),np.mean(patches[1][i])) for i in range(24)]) + Cam.log += '\n' + return(g_patches) diff --git a/utils/raspberrypi/ctt/ctt_image_load.py b/utils/raspberrypi/ctt/ctt_image_load.py new file mode 100644 index 00000000..dd7adb16 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_image_load.py @@ -0,0 +1,428 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019-2020, Raspberry Pi (Trading) Limited +# +# ctt_image_load.py - camera tuning tool image loading + +from ctt_tools import * +from ctt_macbeth_locator import * +import json +import pyexiv2 as pyexif +import rawpy as raw + + +""" +Image class load image from raw data and extracts metadata. + +Once image is extracted from data, it finds 24 16x16 patches for each +channel, centred at the macbeth chart squares +""" +class Image: + def __init__(self,buf): + self.buf = buf + self.patches = None + self.saturated = False + + ''' + obtain metadata from buffer + ''' + def get_meta(self): + self.ver = ba_to_b(self.buf[4:5]) + self.w = ba_to_b(self.buf[0xd0:0xd2]) + self.h = ba_to_b(self.buf[0xd2:0xd4]) + self.pad = ba_to_b(self.buf[0xd4:0xd6]) + self.fmt = self.buf[0xf5] + self.sigbits = 2*self.fmt + 4 + self.pattern = self.buf[0xf4] + self.exposure = ba_to_b(self.buf[0x90:0x94]) + self.againQ8 = ba_to_b(self.buf[0x94:0x96]) + self.againQ8_norm = self.againQ8/256 + camName = self.buf[0x10:0x10+128] + camName_end = camName.find(0x00) + self.camName = self.buf[0x10:0x10+128][:camName_end].decode() + + """ + Channel order depending on bayer pattern + """ + bayer_case = { + 0 : (0,1,2,3), #red + 1 : (2,0,3,1), #green next to red + 2 : (3,2,1,0), #green next to blue + 3 : (1,0,3,2), #blue + 128 : (0,1,2,3) #arbitrary order for greyscale casw + } + self.order = bayer_case[self.pattern] + + ''' + manual blacklevel - not robust + ''' + if 'ov5647' in self.camName: + self.blacklevel = 16 + else: + self.blacklevel = 64 + self.blacklevel_16 = self.blacklevel << (6) + return 1 + + ''' + print metadata for debug + ''' + def print_meta(self): + print('\nData:') + print(' ver = {}'.format(self.ver)) + print(' w = {}'.format(self.w)) + print(' h = {}'.format(self.h)) + print(' pad = {}'.format(self.pad)) + print(' fmt = {}'.format(self.fmt)) + print(' sigbits = {}'.format(self.sigbits)) + print(' pattern = {}'.format(self.pattern)) + print(' exposure = {}'.format(self.exposure)) + print(' againQ8 = {}'.format(self.againQ8)) + print(' againQ8_norm = {}'.format(self.againQ8_norm)) + print(' camName = {}'.format(self.camName)) + print(' blacklevel = {}'.format(self.blacklevel)) + print(' blacklevel_16 = {}'.format(self.blacklevel_16)) + + return 1 + + """ + get image from raw scanline data + """ + def get_image(self,raw): + self.dptr = [] + """ + check if data is 10 or 12 bits + """ + if self.sigbits == 10: + """ + calc length of scanline + """ + lin_len = ((((((self.w+self.pad+3)>>2)) * 5)+31)>>5) * 32 + """ + stack scan lines into matrix + """ + raw = np.array(raw).reshape(-1,lin_len).astype(np.int64)[:self.h,...] + """ + separate 5 bits in each package, stopping when w is satisfied + """ + ba0 = raw[...,0:5*((self.w+3)>>2):5] + ba1 = raw[...,1:5*((self.w+3)>>2):5] + ba2 = raw[...,2:5*((self.w+3)>>2):5] + ba3 = raw[...,3:5*((self.w+3)>>2):5] + ba4 = raw[...,4:5*((self.w+3)>>2):5] + """ + assemble 10 bit numbers + """ + ch0 = np.left_shift((np.left_shift(ba0,2) + (ba4%4)),6) + ch1 = np.left_shift((np.left_shift(ba1,2) + (np.right_shift(ba4,2)%4)),6) + ch2 = np.left_shift((np.left_shift(ba2,2) + (np.right_shift(ba4,4)%4)),6) + ch3 = np.left_shift((np.left_shift(ba3,2) + (np.right_shift(ba4,6)%4)),6) + """ + interleave bits + """ + mat = np.empty((self.h,self.w),dtype=ch0.dtype) + + mat[...,0::4] = ch0 + mat[...,1::4] = ch1 + mat[...,2::4] = ch2 + mat[...,3::4] = ch3 + + """ + There is som eleaking memory somewhere in the code. This code here + seemed to make things good enough that the code would run for + reasonable numbers of images, however this is techincally just a + workaround. (sorry) + """ + ba0,ba1,ba2,ba3,ba4 = None,None,None,None,None + del ba0,ba1,ba2,ba3,ba4 + ch0,ch1,ch2,ch3 = None,None,None,None + del ch0,ch1,ch2,ch3 + + """ + same as before but 12 bit case + """ + elif self.sigbits == 12: + lin_len = ((((((self.w+self.pad+1)>>1)) * 3)+31)>>5) * 32 + raw = np.array(raw).reshape(-1,lin_len).astype(np.int64)[:self.h,...] + ba0 = raw[...,0:3*((self.w+1)>>1):3] + ba1 = raw[...,1:3*((self.w+1)>>1):3] + ba2 = raw[...,2:3*((self.w+1)>>1):3] + ch0 = np.left_shift((np.left_shift(ba0,4) + ba2%16),4) + ch1 = np.left_shift((np.left_shift(ba1,4) + (np.right_shift(ba2,4))%16),4) + mat = np.empty((self.h,self.w),dtype=ch0.dtype) + mat[...,0::2] = ch0 + mat[...,1::2] = ch1 + + else: + """ + data is neither 10 nor 12 or incorrect data + """ + print('ERROR: wrong bit format, only 10 or 12 bit supported') + return 0 + + """ + separate bayer channels + """ + c0 = mat[0::2,0::2] + c1 = mat[0::2,1::2] + c2 = mat[1::2,0::2] + c3 = mat[1::2,1::2] + self.channels = [c0,c1,c2,c3] + return 1 + + """ + obtain 16x16 patch centred at macbeth square centre for each channel + """ + def get_patches(self,cen_coords,size=16): + """ + obtain channel widths and heights + """ + ch_w,ch_h = self.w,self.h + cen_coords = list(np.array((cen_coords[0])).astype(np.int32)) + self.cen_coords = cen_coords + """ + squares are ordered by stacking macbeth chart columns from + left to right. Some useful patch indices: + white = 3 + black = 23 + 'reds' = 9,10 + 'blues' = 2,5,8,20,22 + 'greens' = 6,12,17 + greyscale = 3,7,11,15,19,23 + """ + all_patches = [] + for ch in self.channels: + ch_patches = [] + for cen in cen_coords: + ''' + macbeth centre is placed at top left of central 2x2 patch + to account for rounding + Patch pixels are sorted by pixel brightness so spatial + information is lost. + ''' + patch = ch[cen[1]-7:cen[1]+9,cen[0]-7:cen[0]+9].flatten() + patch.sort() + if patch[-5] == (2**self.sigbits-1)*2**(16-self.sigbits): + self.saturated = True + ch_patches.append(patch) + # print('\nNew Patch\n') + all_patches.append(ch_patches) + # print('\n\nNew Channel\n\n') + self.patches = all_patches + return 1 + +def brcm_load_image(Cam, im_str): + """ + Load image where raw data and metadata is in the BRCM format + """ + try: + """ + create byte array + """ + with open(im_str,'rb') as image: + f = image.read() + b = bytearray(f) + """ + return error if incorrect image address + """ + except FileNotFoundError: + print('\nERROR:\nInvalid image address') + Cam.log += '\nWARNING: Invalid image address' + return 0 + + """ + return error if problem reading file + """ + if f == None: + print('\nERROR:\nProblem reading file') + Cam.log += '\nWARNING: Problem readin file' + return 0 + + # print('\nLooking for EOI and BRCM header') + """ + find end of image followed by BRCM header by turning + bytearray into hex string and string matching with regexp + """ + start = -1 + match = bytearray(b'\xff\xd9@BRCM') + match_str = binascii.hexlify(match) + b_str = binascii.hexlify(b) + """ + note index is divided by two to go from string to hex + """ + indices = [m.start()//2 for m in re.finditer(match_str,b_str)] + # print(indices) + try: + start = indices[0] + 3 + except IndexError: + print('\nERROR:\nNo Broadcom header found') + Cam.log += '\nWARNING: No Broadcom header found!' + return 0 + """ + extract data after header + """ + # print('\nExtracting data after header') + buf = b[start:start+32768] + Img = Image(buf) + Img.str = im_str + # print('Data found successfully') + + """ + obtain metadata + """ + # print('\nReading metadata') + Img.get_meta() + Cam.log += '\nExposure : {} us'.format(Img.exposure) + Cam.log += '\nNormalised gain : {}'.format(Img.againQ8_norm) + # print('Metadata read successfully') + + """ + obtain raw image data + """ + # print('\nObtaining raw image data') + raw = b[start+32768:] + Img.get_image(raw) + """ + delete raw to stop memory errors + """ + raw = None + del raw + # print('Raw image data obtained successfully') + + return Img + +def dng_load_image(Cam, im_str): + try: + Img = Image(None) + + # RawPy doesn't load all the image tags that we need, so we use py3exiv2 + metadata = pyexif.ImageMetadata(im_str) + metadata.read() + + Img.ver = 100 # random value + Img.w = metadata['Exif.SubImage1.ImageWidth'].value + Img.pad = 0 + Img.h = metadata['Exif.SubImage1.ImageLength'].value + white = metadata['Exif.SubImage1.WhiteLevel'].value + Img.sigbits = int(white).bit_length() + Img.fmt = (Img.sigbits - 4) // 2 + Img.exposure = int(metadata['Exif.Photo.ExposureTime'].value*1000000) + Img.againQ8 = metadata['Exif.Photo.ISOSpeedRatings'].value*256/100 + Img.againQ8_norm = Img.againQ8 / 256 + Img.camName = metadata['Exif.Image.Model'].value + Img.blacklevel = int(metadata['Exif.SubImage1.BlackLevel'].value[0]) + Img.blacklevel_16 = Img.blacklevel << (16 - Img.sigbits) + bayer_case = { + '0 1 1 2': (0, (0, 1, 2, 3)), + '1 2 0 1': (1, (2, 0, 3, 1)), + '2 1 1 0': (2, (3, 2, 1, 0)), + '1 0 2 1': (3, (1, 0, 3, 2)) + } + cfa_pattern = metadata['Exif.SubImage1.CFAPattern'].value + Img.pattern = bayer_case[cfa_pattern][0] + Img.order = bayer_case[cfa_pattern][1] + + # Now use RawPy tp get the raw Bayer pixels + raw_im = raw.imread(im_str) + raw_data = raw_im.raw_image + shift = 16 - Img.sigbits + c0 = np.left_shift(raw_data[0::2,0::2].astype(np.int64), shift) + c1 = np.left_shift(raw_data[0::2,1::2].astype(np.int64), shift) + c2 = np.left_shift(raw_data[1::2,0::2].astype(np.int64), shift) + c3 = np.left_shift(raw_data[1::2,1::2].astype(np.int64), shift) + Img.channels = [c0, c1, c2, c3] + + except: + print("\nERROR: failed to load DNG file", im_str) + print("Either file does not exist or is incompatible") + Cam.log += '\nERROR: DNG file does not exist or is incompatible' + raise + + return Img + + +''' +load image from file location and perform calibration +check correct filetype + +mac boolean is true if image is expected to contain macbeth chart and false +if not (alsc images don't have macbeth charts) +''' +def load_image(Cam,im_str,mac_config=None,show=False,mac=True,show_meta=False): + """ + check image is correct filetype + """ + if '.jpg' in im_str or '.jpeg' in im_str or '.brcm' in im_str or '.dng' in im_str: + if '.dng' in im_str: + Img = dng_load_image(Cam, im_str) + else: + Img = brcm_load_image(Cam, im_str) + if show_meta: + Img.print_meta() + + if mac: + """ + find macbeth centres, discarding images that are too dark or light + """ + av_chan = (np.mean(np.array(Img.channels),axis=0)/(2**16)) + av_val = np.mean(av_chan) + # print(av_val) + if av_val < Img.blacklevel_16/(2**16)+1/64: + macbeth = None + print('\nError: Image too dark!') + Cam.log += '\nWARNING: Image too dark!' + else: + macbeth = find_macbeth(Cam,av_chan,mac_config) + + """ + if no macbeth found return error + """ + if macbeth == None: + print('\nERROR: No macbeth chart found') + return 0 + mac_cen_coords = macbeth[1] + # print('\nMacbeth centres located successfully') + + """ + obtain image patches + """ + # print('\nObtaining image patches') + Img.get_patches(mac_cen_coords) + if Img.saturated: + print('\nERROR: Macbeth patches have saturated') + Cam.log += '\nWARNING: Macbeth patches have saturated!' + return 0 + + """ + clear memory + """ + Img.buf = None + del Img.buf + + # print('Image patches obtained successfully') + + """ + optional debug + """ + if show and __name__ == '__main__': + copy = sum(Img.channels)/2**18 + copy = np.reshape(copy,(Img.h//2,Img.w//2)).astype(np.float64) + copy,_ = reshape(copy,800) + represent(copy) + + return Img + + """ + return error if incorrect filetype + """ + else: + # print('\nERROR:\nInvalid file extension') + return 0 + +""" +bytearray splice to number little endian +""" +def ba_to_b(b): + total = 0 + for i in range(len(b)): + total += 256**i * b[i] + return total diff --git a/utils/raspberrypi/ctt/ctt_lux.py b/utils/raspberrypi/ctt/ctt_lux.py new file mode 100644 index 00000000..8a16d346 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_lux.py @@ -0,0 +1,58 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_lux.py - camera tuning tool for lux level + +from ctt_tools import * +""" +Find lux values from metadata and calculate Y +""" +def lux(Cam,Img): + shutter_speed = Img.exposure + gain = Img.againQ8_norm + aperture = 1 + Cam.log += '\nShutter speed = {}'.format(shutter_speed) + Cam.log += '\nGain = {}'.format(gain) + Cam.log += '\nAperture = {}'.format(aperture) + patches = [Img.patches[i] for i in Img.order] + channels = [Img.channels[i] for i in Img.order] + return lux_calc(Cam,Img,patches,channels),shutter_speed,gain + +""" +perform lux calibration on bayer channels +""" +def lux_calc(Cam,Img,patches,channels): + """ + find means color channels on grey patches + """ + ap_r = np.mean(patches[0][3::4]) + ap_g = (np.mean(patches[1][3::4])+np.mean(patches[2][3::4]))/2 + ap_b = np.mean(patches[3][3::4]) + Cam.log += '\nAverage channel values on grey patches:' + Cam.log += '\nRed = {:.0f} Green = {:.0f} Blue = {:.0f}'.format(ap_r,ap_b,ap_g) + # print(ap_r,ap_g,ap_b) + """ + calculate channel gains + """ + gr = ap_g/ap_r + gb = ap_g/ap_b + Cam.log += '\nChannel gains: Red = {:.3f} Blue = {:.3f}'.format(gr,gb) + + """ + find means color channels on image and scale by gain + note greens are averaged together (treated as one channel) + """ + a_r = np.mean(channels[0])*gr + a_g = (np.mean(channels[1])+np.mean(channels[2]))/2 + a_b = np.mean(channels[3])*gb + Cam.log += '\nAverage channel values over entire image scaled by channel gains:' + Cam.log += '\nRed = {:.0f} Green = {:.0f} Blue = {:.0f}'.format(a_r,a_b,a_g) + # print(a_r,a_g,a_b) + """ + Calculate y with top row of yuv matrix + """ + y = 0.299*a_r + 0.587*a_g + 0.114*a_b + Cam.log += '\nY value calculated: {}'.format(int(y)) + # print(y) + return int(y) diff --git a/utils/raspberrypi/ctt/ctt_macbeth_locator.py b/utils/raspberrypi/ctt/ctt_macbeth_locator.py new file mode 100644 index 00000000..583d5a69 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_macbeth_locator.py @@ -0,0 +1,748 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_macbeth_locator.py - camera tuning tool Macbeth chart locator + +from ctt_ransac import * +from ctt_tools import * +import warnings + +""" +NOTE: some custom functions have been used here to make the code more readable. +These are defined in tools.py if they are needed for reference. +""" + +""" +Some inconsistencies between packages cause runtime warnings when running +the clustering algorithm. This catches these warnings so they don't flood the +output to the console +""" +def fxn(): + warnings.warn("runtime",RuntimeWarning) + +""" +Define the success message +""" +success_msg = 'Macbeth chart located successfully' + +def find_macbeth(Cam,img,mac_config=(0,0)): + small_chart,show = mac_config + print('Locating macbeth chart') + Cam.log += '\nLocating macbeth chart' + """ + catch the warnings + """ + warnings.simplefilter("ignore") + fxn() + + """ + Reference macbeth chart is created that will be correlated with the located + macbeth chart guess to produce a confidence value for the match. + """ + ref = cv2.imread(Cam.path +'ctt_ref.pgm',flags=cv2.IMREAD_GRAYSCALE) + ref_w = 120 + ref_h = 80 + rc1 = (0,0) + rc2 = (0,ref_h) + rc3 = (ref_w,ref_h) + rc4 = (ref_w,0) + ref_corns = np.array((rc1,rc2,rc3,rc4),np.float32) + ref_data = (ref,ref_w,ref_h,ref_corns) + + """ + locate macbeth chart + """ + cor,mac,coords,msg = get_macbeth_chart(img,ref_data) + + """ + following bits of code tries to fix common problems with simple + techniques. + If now or at any point the best correlation is of above 0.75, then + nothing more is tried as this is a high enough confidence to ensure + reliable macbeth square centre placement. + """ + + """ + brighten image 2x + """ + if cor < 0.75: + a = 2 + img_br = cv2.convertScaleAbs(img,alpha=a,beta=0) + cor_b,mac_b,coords_b,msg_b = get_macbeth_chart(img_br,ref_data) + if cor_b > cor: + cor,mac,coords,msg = cor_b,mac_b,coords_b,msg_b + + """ + brighten image 4x + """ + if cor < 0.75: + a = 4 + img_br = cv2.convertScaleAbs(img,alpha=a,beta=0) + cor_b,mac_b,coords_b,msg_b = get_macbeth_chart(img_br,ref_data) + if cor_b > cor: + cor,mac,coords,msg = cor_b,mac_b,coords_b,msg_b + + """ + In case macbeth chart is too small, take a selection of the image and + attempt to locate macbeth chart within that. The scale increment is + root 2 + """ + """ + These variables will be used to transform the found coordinates at smaller + scales back into the original. If ii is still -1 after this section that + means it was not successful + """ + ii = -1 + w_best = 0 + h_best = 0 + d_best = 100 + """ + d_best records the scale of the best match. Macbeth charts are only looked + for at one scale increment smaller than the current best match in order to avoid + unecessarily searching for macbeth charts at small scales. + If a macbeth chart ha already been found then set d_best to 0 + """ + if cor != 0: + d_best = 0 + + """ + scale 3/2 (approx root2) + """ + if cor < 0.75: + imgs = [] + """ + get size of image + """ + shape = list(img.shape[:2]) + w,h = shape + """ + set dimensions of the subselection and the step along each axis between + selections + """ + w_sel = int(2*w/3) + h_sel = int(2*h/3) + w_inc = int(w/6) + h_inc = int(h/6) + """ + for each subselection, look for a macbeth chart + """ + for i in range(3): + for j in range(3): + w_s,h_s = i*w_inc,j*h_inc + img_sel = img[w_s:w_s+w_sel,h_s:h_s+h_sel] + cor_ij,mac_ij,coords_ij,msg_ij = get_macbeth_chart(img_sel,ref_data) + """ + if the correlation is better than the best then record the + scale and current subselection at which macbeth chart was + found. Also record the coordinates, macbeth chart and message. + """ + if cor_ij > cor: + cor = cor_ij + mac,coords,msg = mac_ij,coords_ij,msg_ij + ii,jj = i,j + w_best,h_best = w_inc,h_inc + d_best = 1 + + + """ + scale 2 + """ + if cor < 0.75: + imgs = [] + shape = list(img.shape[:2]) + w,h = shape + w_sel = int(w/2) + h_sel = int(h/2) + w_inc = int(w/8) + h_inc = int(h/8) + for i in range(5): + for j in range(5): + w_s,h_s = i*w_inc,j*h_inc + img_sel = img[w_s:w_s+w_sel,h_s:h_s+h_sel] + cor_ij,mac_ij,coords_ij,msg_ij = get_macbeth_chart(img_sel,ref_data) + if cor_ij > cor: + cor = cor_ij + mac,coords,msg = mac_ij,coords_ij,msg_ij + ii,jj = i,j + w_best,h_best = w_inc,h_inc + d_best = 2 + + """ + The following code checks for macbeth charts at even smaller scales. This + slows the code down significantly and has therefore been omitted by default, + however it is not unusably slow so might be useful if the macbeth chart + is too small to be picked up to by the current subselections. + Use this for macbeth charts with side lengths around 1/5 image dimensions + (and smaller...?) it is, however, recommended that macbeth charts take up as + large as possible a proportion of the image. + """ + + if small_chart: + + if cor < 0.75 and d_best > 1 : + imgs = [] + shape = list(img.shape[:2]) + w,h = shape + w_sel = int(w/3) + h_sel = int(h/3) + w_inc = int(w/12) + h_inc = int(h/12) + for i in range(9): + for j in range(9): + w_s,h_s = i*w_inc,j*h_inc + img_sel = img[w_s:w_s+w_sel,h_s:h_s+h_sel] + cor_ij,mac_ij,coords_ij,msg_ij = get_macbeth_chart(img_sel,ref_data) + if cor_ij > cor: + cor = cor_ij + mac,coords,msg = mac_ij,coords_ij,msg_ij + ii,jj = i,j + w_best,h_best = w_inc,h_inc + d_best = 3 + + if cor < 0.75 and d_best > 2: + imgs = [] + shape = list(img.shape[:2]) + w,h = shape + w_sel = int(w/4) + h_sel = int(h/4) + w_inc = int(w/16) + h_inc = int(h/16) + for i in range(13): + for j in range(13): + w_s,h_s = i*w_inc,j*h_inc + img_sel = img[w_s:w_s+w_sel,h_s:h_s+h_sel] + cor_ij,mac_ij,coords_ij,msg_ij = get_macbeth_chart(img_sel,ref_data) + if cor_ij > cor: + cor = cor_ij + mac,coords,msg = mac_ij,coords_ij,msg_ij + ii,jj = i,j + w_best,h_best = w_inc,h_inc + + """ + Transform coordinates from subselection to original image + """ + if ii != -1: + for a in range(len(coords)): + for b in range(len(coords[a][0])): + coords[a][0][b][1] += ii*w_best + coords[a][0][b][0] += jj*h_best + + """ + initialise coords_fit variable + """ + coords_fit = None + # print('correlation: {}'.format(cor)) + """ + print error or success message + """ + print(msg) + Cam.log += '\n' + msg + if msg == success_msg: + coords_fit = coords + Cam.log += '\nMacbeth chart vertices:\n' + Cam.log += '{}'.format(2*np.round(coords_fit[0][0]),0) + """ + if correlation is lower than 0.75 there may be a risk of macbeth chart + corners not having been located properly. It might be worth running + with show set to true to check where the macbeth chart centres have + been located. + """ + print('Confidence: {:.3f}'.format(cor)) + Cam.log += '\nConfidence: {:.3f}'.format(cor) + if cor < 0.75: + print('Caution: Low confidence guess!') + Cam.log += 'WARNING: Low confidence guess!' + # cv2.imshow('MacBeth',mac) + # represent(mac,'MacBeth chart') + + """ + extract data from coords_fit and plot on original image + """ + if show and coords_fit != None: + copy = img.copy() + verts = coords_fit[0][0] + cents = coords_fit[1][0] + + """ + draw circles at vertices of macbeth chart + """ + for vert in verts: + p = tuple(np.round(vert).astype(np.int32)) + cv2.circle(copy,p,10,1,-1) + """ + draw circles at centres of squares + """ + for i in range(len(cents)): + cent = cents[i] + p = tuple(np.round(cent).astype(np.int32)) + """ + draw black circle on white square, white circle on black square an + grey circle everywhere else. + """ + if i == 3: + cv2.circle(copy,p,8,0,-1) + elif i == 23: + cv2.circle(copy,p,8,1,-1) + else: + cv2.circle(copy,p,8,0.5,-1) + copy,_ = reshape(copy,400) + represent(copy) + + return(coords_fit) + +def get_macbeth_chart(img,ref_data): + """ + function returns coordinates of macbeth chart vertices and square centres, + along with an error/success message for debugging purposes. Additionally, + it scores the match with a confidence value. + + Brief explanation of the macbeth chart locating algorithm: + - Find rectangles within image + - Take rectangles within percentage offset of median perimeter. The + assumption is that these will be the macbeth squares + - For each potential square, find the 24 possible macbeth centre locations + that would produce a square in that location + - Find clusters of potential macbeth chart centres to find the potential + macbeth centres with the most votes, i.e. the most likely ones + - For each potential macbeth centre, use the centres of the squares that + voted for it to find macbeth chart corners + - For each set of corners, transform the possible match into normalised + space and correlate with a reference chart to evaluate the match + - Select the highest correlation as the macbeth chart match, returning the + correlation as the confidence score + """ + + """ + get reference macbeth chart data + """ + (ref,ref_w,ref_h,ref_corns) = ref_data + + """ + the code will raise and catch a MacbethError in case of a problem, trying + to give some likely reasons why the problem occred, hence the try/except + """ + try: + """ + obtain image, convert to grayscale and normalise + """ + src = img + src,factor = reshape(src,200) + original=src.copy() + a = 125/np.average(src) + src_norm = cv2.convertScaleAbs(src,alpha=a,beta=0) + """ + This code checks if there are seperate colour channels. In the past the + macbeth locator ran on jpgs and this makes it robust to different + filetypes. Note that running it on a jpg has 4x the pixels of the + average bayer channel so coordinates must be doubled. + + This is best done in img_load.py in the get_patches method. The + coordinates and image width,height must be divided by two if the + macbeth locator has been run on a demosaicked image. + """ + if len(src_norm.shape) == 3: + src_bw = cv2.cvtColor(src_norm,cv2.COLOR_BGR2GRAY) + else: + src_bw = src_norm + original_bw = src_bw.copy() + """ + obtain image edges + """ + sigma=2 + src_bw = cv2.GaussianBlur(src_bw,(0,0),sigma) + t1,t2 = 50,100 + edges = cv2.Canny(src_bw,t1,t2) + """ + dilate edges to prevent self-intersections in contours + """ + k_size = 2 + kernel = np.ones((k_size,k_size)) + its = 1 + edges = cv2.dilate(edges,kernel,iterations=its) + """ + find Contours in image + """ + conts,_ = cv2.findContours(edges, + cv2.RETR_TREE, + cv2.CHAIN_APPROX_NONE) + if len(conts) == 0: + raise MacbethError( + '\nWARNING: No macbeth chart found!' + '\nNo contours found in image\n' + 'Possible problems:\n' + '- Macbeth chart is too dark or bright\n' + '- Macbeth chart is occluded\n' + ) + """ + find quadrilateral contours + """ + epsilon = 0.07 + conts_per = [] + for i in range(len(conts)): + per = cv2.arcLength(conts[i],True) + poly = cv2.approxPolyDP(conts[i], + epsilon*per,True) + if len(poly) == 4 and cv2.isContourConvex(poly): + conts_per.append((poly,per)) + + if len(conts_per) == 0: + raise MacbethError( + '\nWARNING: No macbeth chart found!' + '\nNo quadrilateral contours found' + '\nPossible problems:\n' + '- Macbeth chart is too dark or bright\n' + '- Macbeth chart is occluded\n' + '- Macbeth chart is out of camera plane\n' + ) + + """ + sort contours by perimeter and get perimeters within percent of median + """ + conts_per = sorted(conts_per,key=lambda x:x[1]) + med_per = conts_per[int(len(conts_per)/2)][1] + side = med_per/4 + perc = 0.1 + med_low,med_high = med_per*(1-perc),med_per*(1+perc) + squares = [] + for i in conts_per: + if med_low <= i[1] and med_high >= i[1]: + squares.append(i[0]) + + """ + obtain coordinates of nomralised macbeth and squares + """ + square_verts,mac_norm = get_square_verts(0.06) + """ + for each square guess, find 24 possible macbeth chart centres + """ + mac_mids = [] + squares_raw = [] + for i in range(len(squares)): + square = squares[i] + squares_raw.append(square) + """ + convert quads to rotated rectangles. This is required as the + 'squares' are usually quite irregular quadrilaterls, so performing + a transform would result in exaggerated warping and inaccurate + macbeth chart centre placement + """ + rect = cv2.minAreaRect(square) + square = cv2.boxPoints(rect).astype(np.float32) + """ + reorder vertices to prevent 'hourglass shape' + """ + square = sorted(square,key=lambda x:x[0]) + square_1 = sorted(square[:2],key=lambda x:x[1]) + square_2 = sorted(square[2:],key=lambda x:-x[1]) + square = np.array(np.concatenate((square_1,square_2)),np.float32) + square = np.reshape(square,(4,2)).astype(np.float32) + squares[i] = square + """ + find 24 possible macbeth chart centres by trasnforming normalised + macbeth square vertices onto candidate square vertices found in image + """ + for j in range(len(square_verts)): + verts = square_verts[j] + p_mat = cv2.getPerspectiveTransform(verts,square) + mac_guess = cv2.perspectiveTransform(mac_norm,p_mat) + mac_guess = np.round(mac_guess).astype(np.int32) + """ + keep only if candidate macbeth is within image border + (deprecated) + """ + in_border = True + # for p in mac_guess[0]: + # pptest = cv2.pointPolygonTest( + # img_con, + # tuple(p), + # False + # ) + # if pptest == -1: + # in_border = False + # break + + if in_border: + mac_mid = np.mean(mac_guess, + axis=1) + mac_mids.append([mac_mid,(i,j)]) + + if len(mac_mids) == 0: + raise MacbethError( + '\nWARNING: No macbeth chart found!' + '\nNo possible macbeth charts found within image' + '\nPossible problems:\n' + '- Part of the macbeth chart is outside the image\n' + '- Quadrilaterals in image background\n' + ) + + """ + reshape data + """ + for i in range(len(mac_mids)): + mac_mids[i][0] = mac_mids[i][0][0] + + """ + find where midpoints cluster to identify most likely macbeth centres + """ + clustering = cluster.AgglomerativeClustering( + n_clusters=None, + compute_full_tree = True, + distance_threshold = side*2 + ) + mac_mids_list = [x[0] for x in mac_mids] + + if len(mac_mids_list)==1: + """ + special case of only one valid centre found (probably not needed) + """ + clus_list = [] + clus_list.append([mac_mids,len(mac_mids)]) + + else: + clustering.fit(mac_mids_list) + # try: + # clustering.fit(mac_mids_list) + # except RuntimeWarning as error: + # return(0,None,None,error) + + """ + create list of all clusters + """ + clus_list = [] + if clustering.n_clusters_ >1: + for i in range(clustering.labels_.max()+1): + indices = [j for j,x in enumerate(clustering.labels_) if x == i] + clus = [] + for index in indices: + clus.append(mac_mids[index]) + clus_list.append([clus,len(clus)]) + clus_list.sort(key=lambda x:-x[1]) + + elif clustering.n_clusters_ == 1: + """ + special case of only one cluster found + """ + # print('only 1 cluster') + clus_list.append([mac_mids,len(mac_mids)]) + else: + raise MacbethError( + '\nWARNING: No macebth chart found!' + '\nNo clusters found' + '\nPossible problems:\n' + '- NA\n' + ) + + """ + keep only clusters with enough votes + """ + clus_len_max = clus_list[0][1] + clus_tol= 0.7 + for i in range(len(clus_list)): + if clus_list[i][1] < clus_len_max * clus_tol: + clus_list = clus_list[:i] + break + cent = np.mean(clus_list[i][0],axis=0)[0] + clus_list[i].append(cent) + + """ + represent most popular cluster centroids + """ + # copy = original_bw.copy() + # copy = cv2.cvtColor(copy,cv2.COLOR_GRAY2RGB) + # copy = cv2.resize(copy,None,fx=2,fy=2) + # for clus in clus_list: + # centroid = tuple(2*np.round(clus[2]).astype(np.int32)) + # cv2.circle(copy,centroid,7,(255,0,0),-1) + # cv2.circle(copy,centroid,2,(0,0,255),-1) + # represent(copy) + + """ + get centres of each normalised square + """ + reference = get_square_centres(0.06) + + """ + for each possible macbeth chart, transform image into + normalised space and find correlation with reference + """ + max_cor = 0 + best_map = None + best_fit = None + best_cen_fit = None + best_ref_mat = None + + for clus in clus_list: + clus = clus[0] + sq_cents = [] + ref_cents = [] + i_list = [p[1][0] for p in clus] + for point in clus: + i,j = point[1] + """ + remove any square that voted for two different points within + the same cluster. This causes the same point in the image to be + mapped to two different reference square centres, resulting in + a very distorted perspective transform since cv2.findHomography + simply minimises error. + This phenomenon is not particularly likely to occur due to the + enforced distance threshold in the clustering fit but it is + best to keep this in just in case. + """ + if i_list.count(i) == 1: + square = squares_raw[i] + sq_cent = np.mean(square,axis=0) + ref_cent = reference[j] + sq_cents.append(sq_cent) + ref_cents.append(ref_cent) + + """ + At least three squares need to have voted for a centre in + order for a transform to be found + """ + if len(sq_cents) < 3: + raise MacbethError( + '\nWARNING: No macbeth chart found!' + '\nNot enough squares found' + '\nPossible problems:\n' + '- Macbeth chart is occluded\n' + '- Macbeth chart is too dark of bright\n' + ) + + ref_cents = np.array(ref_cents) + sq_cents = np.array(sq_cents) + """ + find best fit transform from normalised centres to image + """ + h_mat,mask = cv2.findHomography(ref_cents,sq_cents) + if 'None' in str(type(h_mat)): + raise MacbethError( + '\nERROR\n' + ) + + """ + transform normalised corners and centres into image space + """ + mac_fit = cv2.perspectiveTransform(mac_norm,h_mat) + mac_cen_fit = cv2.perspectiveTransform(np.array([reference]),h_mat) + """ + transform located corners into reference space + """ + ref_mat = cv2.getPerspectiveTransform( + mac_fit, + np.array([ref_corns]) + ) + map_to_ref = cv2.warpPerspective( + original_bw,ref_mat, + (ref_w,ref_h) + ) + """ + normalise brigthness + """ + a = 125/np.average(map_to_ref) + map_to_ref = cv2.convertScaleAbs(map_to_ref,alpha=a,beta=0) + """ + find correlation with bw reference macbeth + """ + cor = correlate(map_to_ref,ref) + """ + keep only if best correlation + """ + if cor > max_cor: + max_cor = cor + best_map = map_to_ref + best_fit = mac_fit + best_cen_fit = mac_cen_fit + best_ref_mat = ref_mat + + """ + rotate macbeth by pi and recorrelate in case macbeth chart is + upside-down + """ + mac_fit_inv = np.array( + ([[mac_fit[0][2],mac_fit[0][3], + mac_fit[0][0],mac_fit[0][1]]]) + ) + mac_cen_fit_inv = np.flip(mac_cen_fit,axis=1) + ref_mat = cv2.getPerspectiveTransform( + mac_fit_inv, + np.array([ref_corns]) + ) + map_to_ref = cv2.warpPerspective( + original_bw,ref_mat, + (ref_w,ref_h) + ) + a = 125/np.average(map_to_ref) + map_to_ref = cv2.convertScaleAbs(map_to_ref,alpha=a,beta=0) + cor = correlate(map_to_ref,ref) + if cor > max_cor: + max_cor = cor + best_map = map_to_ref + best_fit = mac_fit_inv + best_cen_fit = mac_cen_fit_inv + best_ref_mat = ref_mat + + """ + Check best match is above threshold + """ + cor_thresh = 0.6 + if max_cor < cor_thresh: + raise MacbethError( + '\nWARNING: Correlation too low' + '\nPossible problems:\n' + '- Bad lighting conditions\n' + '- Macbeth chart is occluded\n' + '- Background is too noisy\n' + '- Macbeth chart is out of camera plane\n' + ) + """ + Following code is mostly representation for debugging purposes + """ + + + """ + draw macbeth corners and centres on image + """ + copy = original.copy() + copy = cv2.resize(original,None,fx=2,fy=2) + # print('correlation = {}'.format(round(max_cor,2))) + for point in best_fit[0]: + point = np.array(point,np.float32) + point = tuple(2*np.round(point).astype(np.int32)) + cv2.circle(copy,point,4,(255,0,0),-1) + for point in best_cen_fit[0]: + point = np.array(point,np.float32) + point = tuple(2*np.round(point).astype(np.int32)) + cv2.circle(copy,point,4,(0,0,255),-1) + copy = copy.copy() + cv2.circle(copy,point,4,(0,0,255),-1) + + """ + represent coloured macbeth in reference space + """ + best_map_col = cv2.warpPerspective( + original,best_ref_mat,(ref_w,ref_h) + ) + best_map_col = cv2.resize( + best_map_col,None,fx=4,fy=4 + ) + a = 125/np.average(best_map_col) + best_map_col_norm = cv2.convertScaleAbs( + best_map_col,alpha=a,beta=0 + ) + # cv2.imshow('Macbeth',best_map_col) + # represent(copy) + + + """ + rescale coordinates to original image size + """ + fit_coords = (best_fit/factor,best_cen_fit/factor) + + return(max_cor,best_map_col_norm,fit_coords,success_msg) + + """ + catch macbeth errors and continue with code + """ + except MacbethError as error: + return(0,None,None,error) diff --git a/utils/raspberrypi/ctt/ctt_noise.py b/utils/raspberrypi/ctt/ctt_noise.py new file mode 100644 index 00000000..b84cf0ca --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_noise.py @@ -0,0 +1,123 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_noise.py - camera tuning tool noise calibration + +from ctt_image_load import * +import matplotlib.pyplot as plt + +""" +Find noise standard deviation and fit to model: + + noise std = a + b*sqrt(pixel mean) +""" +def noise(Cam,Img,plot): + Cam.log += '\nProcessing image: {}'.format(Img.name) + stds = [] + means = [] + """ + iterate through macbeth square patches + """ + for ch_patches in Img.patches: + for patch in ch_patches: + """ + renormalise patch + """ + patch = np.array(patch) + patch = (patch-Img.blacklevel_16)/Img.againQ8_norm + std = np.std(patch) + mean = np.mean(patch) + stds.append(std) + means.append(mean) + + """ + clean data and ensure all means are above 0 + """ + stds = np.array(stds) + means = np.array(means) + means = np.clip(np.array(means),0,None) + sq_means = np.sqrt(means) + + + """ + least squares fit model + """ + fit = np.polyfit(sq_means,stds,1) + Cam.log += '\nBlack level = {}'.format(Img.blacklevel_16) + Cam.log += '\nNoise profile: offset = {}'.format(int(fit[1])) + Cam.log += ' slope = {:.3f}'.format(fit[0]) + """ + remove any values further than std from the fit + + anomalies most likely caused by: + > ucharacteristically noisy white patch + > saturation in the white patch + """ + fit_score = np.abs(stds - fit[0]*sq_means - fit[1]) + fit_std = np.std(stds) + fit_score_norm = fit_score - fit_std + anom_ind = np.where(fit_score_norm > 1) + fit_score_norm.sort() + sq_means_clean = np.delete(sq_means,anom_ind) + stds_clean = np.delete(stds,anom_ind) + removed = len(stds) - len(stds_clean) + if removed != 0: + Cam.log += '\nIdentified and removed {} anomalies.'.format(removed) + Cam.log += '\nRecalculating fit' + """ + recalculate fit with outliers removed + """ + fit = np.polyfit(sq_means_clean,stds_clean,1) + Cam.log += '\nNoise profile: offset = {}'.format(int(fit[1])) + Cam.log += ' slope = {:.3f}'.format(fit[0]) + + """ + if fit const is < 0 then force through 0 by + dividing by sq_means and fitting poly order 0 + """ + corrected = 0 + if fit[1] < 0: + corrected = 1 + ones = np.ones(len(means)) + y_data = stds/sq_means + fit2 = np.polyfit(ones,y_data,0) + Cam.log += '\nOffset below zero. Fit recalculated with zero offset' + Cam.log += '\nNoise profile: offset = 0' + Cam.log += ' slope = {:.3f}'.format(fit2[0]) + # print('new fit') + # print(fit2) + + """ + plot fit for debug + """ + if plot: + x = np.arange(sq_means.max()//0.88) + fit_plot = x*fit[0] + fit[1] + plt.scatter(sq_means,stds,label='data',color='blue') + plt.scatter(sq_means[anom_ind],stds[anom_ind],color='orange',label='anomalies') + plt.plot(x,fit_plot,label='fit',color='red',ls=':') + if fit[1] < 0: + fit_plot_2 = x*fit2[0] + plt.plot(x,fit_plot_2,label='fit 0 intercept',color='green',ls='--') + plt.plot(0,0) + plt.title('Noise Plot\nImg: {}'.format(Img.str)) + plt.legend(loc = 'upper left') + plt.xlabel('Sqrt Pixel Value') + plt.ylabel('Noise Standard Deviation') + plt.grid() + plt.show() + """ + End of plotting code + """ + + """ + format output to include forced 0 constant + """ + Cam.log += '\n' + if corrected: + fit = [fit2[0],0] + return fit + + else: + return fit diff --git a/utils/raspberrypi/ctt/ctt_pretty_print_json.py b/utils/raspberrypi/ctt/ctt_pretty_print_json.py new file mode 100644 index 00000000..44a9311b --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_pretty_print_json.py @@ -0,0 +1,70 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_pretty_print_json.py - camera tuning tool JSON formatter + +""" +takes a collapsed json file and makes it more readable +""" +def process_file(string, fout, state): + for c in string: + process_char(c, fout, state) + +def print_newline(fout, state): + fout.write('\n') + fout.write(' '*state["indent"]*4) + +def process_char(c, fout, state): + if c == '{': + if not state["skipnewline"]: print_newline(fout, state) + fout.write(c) + state["indent"] += 1 + print_newline(fout, state) + elif c == '}': + state["indent"] -= 1 + print_newline(fout, state) + fout.write(c) + elif c == '[': + print_newline(fout, state) + fout.write(c) + state["indent"] += 1 + print_newline(fout, state) + state["inarray"] = [True] + state["inarray"] + state["arraycount"] = [0] + state["arraycount"] + elif c == ']': + state["indent"] -= 1 + print_newline(fout, state) + state["inarray"].pop(0) + state["arraycount"].pop(0) + fout.write(c) + elif c == ':': + fout.write(c) + fout.write(' ') + elif c == ' ': + pass + elif c == ',': + if not state["inarray"][0]: + fout.write(c) + fout.write(' ') + print_newline(fout, state) + else: + fout.write(c) + state["arraycount"][0] += 1 + if state["arraycount"][0] == 16: + state["arraycount"][0] = 0 + print_newline(fout, state) + else: + fout.write(' ') + else: + fout.write(c) + state["skipnewline"] = (c == '[') + +def pretty_print_json(str_in, output_filename): + state = {"indent": 0, "inarray": [False], "arraycount": [], "skipnewline" : True} + with open(output_filename, "w") as fout: + process_file(str_in, fout, state) + + +if __name__ == '__main__': + pretty_print_json("../ctt/ref_json/final_imx477.json", "pretty.json") diff --git a/utils/raspberrypi/ctt/ctt_ransac.py b/utils/raspberrypi/ctt/ctt_ransac.py new file mode 100644 index 00000000..e7c57137 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_ransac.py @@ -0,0 +1,69 @@ +# SPDX-License-Identifier: BSD-2-Clause +# +# Copyright (C) 2019, Raspberry Pi (Trading) Limited +# +# ctt_ransac.py - camera tuning tool RANSAC selector for Macbeth chart locator + +import numpy as np + +scale = 2 + +""" +constructs normalised macbeth chart corners for ransac algorithm +""" +def get_square_verts(c_err = 0.05,scale = scale): + """ + define macbeth chart corners + """ + b_bord_x,b_bord_y = scale*8.5,scale*13 + s_bord = 6*scale + side = 41*scale + x_max = side*6 + 5*s_bord + 2*b_bord_x + y_max = side*4 + 3*s_bord + 2*b_bord_y + c1 = (0,0) + c2 = (0,y_max) + c3 = (x_max,y_max) + c4 = (x_max,0) + mac_norm = np.array((c1,c2,c3,c4),np.float32) + mac_norm = np.array([ mac_norm ]) + + square_verts = [] + square_0 = np.array(((0,0),(0,side), + (side,side),(side,0)),np.float32) + offset_0 = np.array((b_bord_x,b_bord_y),np.float32) + c_off = side * c_err + offset_cont = np.array(((c_off,c_off),(c_off,-c_off), + (-c_off,-c_off),(-c_off,c_off)),np.float32) + square_0 += offset_0 + square_0 += offset_cont + """ + define macbeth square corners + """ + for i in range(6): + shift_i = np.array(((i*side,0),(i*side,0), + (i*side,0),(i*side,0)),np.float32) + shift_bord =np.array(((i*s_bord,0),(i*s_bord,0), + (i*s_bord,0),(i*s_bord,0)),np.float32) + square_i = square_0 + shift_i + shift_bord + for j in range(4): + shift_j = np.array(((0,j*side),(0,j*side), + (0,j*side),(0,j*side)),np.float32) + shift_bord = np.array(((0,j*s_bord), + (0,j*s_bord),(0,j*s_bord), + (0,j*s_bord)),np.float32) + square_j = square_i + shift_j + shift_bord + square_verts.append(square_j) + # print('square_verts') + # print(square_verts) + return np.array(square_verts,np.float32),mac_norm + +def get_square_centres(c_err = 0.05,scale=scale): + """ + define macbeth square centres + """ + verts,mac_norm = get_square_verts(c_err,scale=scale) + + centres = np.mean(verts,axis = 1) + # print('centres') + # print(centres) + return np.array(centres,np.float32) diff --git a/utils/raspberrypi/ctt/ctt_ref.pgm b/utils/raspberrypi/ctt/ctt_ref.pgm new file mode 100644 index 00000000..9b9f4920 --- /dev/null +++ b/utils/raspberrypi/ctt/ctt_ref.pgm @@ -0,0 +1,5 @@ +P5 +# Reference macbeth chart +120 80 +255 + !#!" #!"&&$#$#'"%&#+2///..../.........-()))))))))))))))))))(((-,*)'(&)#($%(%"###""!%""&"&&!$" #!$ !"! $&**" !#5.,%+,-5"0<HBAA54" %##((()*+,---.........+*)))))))))))))))-.,,--+))('((''('%'%##"!""!"!""""#! ! %/vz:Lc,!#""%%''')**+)-../..../.-*)))))))))))))**,,)**'(''&'((&&%%##$! !!!! ! ! ! 5*"-)&7(1.75Rnge`\`$ ""!"%%%'')())++--/---,-..,-.,++**))))())*)*)''%'%&%&'&%%""""" ! !!$&$$&##(+*,,/10122126545./66402006486869650*.1.***)*+)()&((('('##)('&%%&%$$$#$%$%$ (((*))('((('('(&%V0;>>;@@>@AAAACBCB=&<<5x|64RYVTSRRRMMNLKJJLH+&0gijgdeffmmnpnkji`#3bY! 3FHHIIIHIJIIJHIII@#?=7}:5Wcbcbdcb`^^`^^_^Y,'6r'<l%2FHHIIHJJJJJJIIJI?%;>7|;8Xfeeegeccb`^aba]Z+)<r)>q#3GHIIIIJIIJJIHIJI@&5=8~;8Zgghggedbdcbda^\Z+(;y)9z"3GIIJJJJJKJJJJJJJ@'4>9|=8Zhighgeeeedeca__[/)Bv&:|#3GJJIIJKKKJJJKKJK@&6>9~<8Yghegggffihccab^\/*Cz'9$ 6IKJJMMMKMKKMKKMLC&2@9<9Yghhhhijiegdcebc^0)G(7% 6JLMMNMMKMMNMMMMMD&2@:~=9Xfghhjiigdgddedc`1)M}(:¾& "8LNOONNOMONNMMNOND'3@;=:Ziiigheegegegggdc1,Q~)8%# "9NNNPPPQOOOOONNOOD'0?;=;[iigeeegghgdedgea0-P(8Ý' "#$:NNOQPPRPQPOOPQPPD*1A;;:Yfghgghgghghhdggc3.\~);¤(&%%;OQQQRSSRPQQQQSQQF)3B<=:Wfhghhhihggghfhee4/f*:ä&%%%?RSSSSSTTTTSSSTTRE)5B=@:Ygiihhiiiihihiiif72p}(9Ʃ'#%&?TUTTTUUQSTTTTTVSF*3F>A;[ghjiihiiiihihije50r)6ƫ& &#%?SVVVUUUUUTUUVVUUG*5F=A;Yhijiiijjiiiiijje81t~)5ư' '$$=OQRRQQPRSRSSSSSSG+6D@?;Wefgggggfffgeeefc41x{*5( &&&'++++,,*-,-00-0100*-SUX\]]`_ffgiooopo=;X\bedbadbca`]\]ZZ;;<::8:;9983433110/-,...1//12410/..--+)"",---,-./,,.-/-0-( &&%+/0103322011223233)(34534767::;;==:=B9;BFGEEGIKJKIJGIJCD=<:76566554111/0/1.*+00233300/00//..,+*#")(*)++,++))*++**'!!&$*w¼1-_addc`ceccdccedbb?A|B>=>?@@?====;<:;:<:11r+.( !'%*zɠ42gjmllklomooonpopmHGD>AEDEFEECEECCCDDEC460:Ѿ,!!&&,|ʡ61inknnoopoppoqqrqoEEFACGFFFFFFDFDDDDDDC5709+!"%%-~ʡ42inopppppoqqqrrsrnABC?DGGGGFFFFDFFDDEDC481;+!!"#*|ʡ62imoppppqqqqrtrqtrGDH?CGGGGGGGGFFFFFFDB381<Խ, !)}ˢ63mooppqqqqqqrrtvtoDHJACHHGGHGGFFFDDGGFD293>, $){ˢ53jpppqprqrrrttuvuo>HJAFHHHHHGGHGGFGGFFE283:ڽ- "*{̣53loqpqsqrrrtrutsvrAHHCGHIHHHHHHGFGHGGGD5;28, +}ʡ52mqoqpqrttttttuurpFIOCEHHIHHHHGHGGFFIGF8<48ۿ, (|ʢ41krqpqqqrrtrtuvtuoEHPBHHIIIHIIHIHGHGHHE7<58* (zʡ63kpqprqqstttutrvvoFOLEHHIIHIHHHIGHGIHGF4=5<* 'zȡ62lppqrqrrrtttuttvpAGMGHIIIIHIIIHHIIJHHG4<4<+ !){Ƞ62jopqqqqqrtttutttrEHOHFIIIIIJIIIIHIHIHI7>5;, !)zƟ53lppqqrqrtttuuuutsFIRHGJIJHJKJJJIIIIIIH9>5;+ !({Ŝ41joppprqrrrutttvvrIHTHCJJJJJIJIJJIJJJIH7=5;+ (u65gjlmmmnoopnpprpqoIHOIBIJJJIJJJJIIIHHHG8929ʾ' "&,-*)-01/,0/12102-+04448789<>>??AFAD@DBCIJNRWTSUXT[WUQUOKFEBBABA?>>=<<;;67942:<<<>9999864565363&(13335422./1/-+..+ !"&$$""$"&$%'()(''*+-0124688:<>>??A>?EBCHKOLJLNOSQOXQQVMLACGHGHIGFHGDCCBB@??7432233210111.,++,++%(++)*(''%%%$$#%&$# ")0/001120024455520+-U]`addcdhefeekecYGFJRXYYVWWZWVXXVZTOBF}K7Ybccddfeg`^]^]\[Z[*)OTTPPQPOKOLLJJLIK !1;:9:<<===;=???A@9*/FJmxyxwyzzzxyzzz{zxLO]=.-y# !!2><=;==>=<<>@@@@A9-0IKnz||{|{||{}}~}}{zLO]>..~% $2==;<>>?===>@A@AB;+1JJo{|y{||}{||}}}}}yMT_>-.}# %2<=;=<@?>==>?A@AA9+3FMlz{{y|}}}}||}|}}{MTd>-,# %1<<<;==<<=>?A?@AA:,3INo{{y{||||}|}}|~}{RTd=/-}#!$0<<<=<<==>A@@>@AA:-2HInzz{{||{{}~~}}|}zMRd=++~# "$/;<==>;===@@@@>AA:+2KHn||y|||||{}~}|}|xMSd=+,}# ! 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They ar collated here to attempt to improve code +readability in the main files. +""" + +""" +obtain config values, unless it doesnt exist, in which case pick default +Furthermore, it can check if the input is the correct type +""" +def get_config(dictt,key,default,ttype): + try: + val = dictt[key] + if ttype == 'string': + val = str(val) + elif ttype == 'num': + if 'int' not in str(type(val)): + if 'float' not in str(type(val)): + raise ValueError + elif ttype == 'dict': + if type(val) != type(dictt): + raise ValueError + elif ttype == 'list': + if type(val) != type([]): + raise ValueError + elif ttype == 'bool': + ttype = int(bool(ttype)) + else: + val = dictt[key] + except (KeyError, ValueError): + val = default + return val +""" +argument parser +""" +def parse_input(): + arguments = sys.argv[1:] + if len(arguments)%2 != 0: + raise ArgError('\n\nERROR! Enter value for each arguent passed.') + params = arguments [0::2] + vals = arguments [1::2] + args_dict = dict(zip(params,vals)) + json_output = get_config(args_dict,'-o',None,'string') + directory = get_config(args_dict,'-i',None,'string') + config = get_config(args_dict,'-c',None,'string') + log_path = get_config(args_dict,'-l',None,'string') + if directory == None: + raise ArgError('\n\nERROR! No input directory given.') + if json_output == None: + raise ArgError('\n\nERROR! No output json given.') + return json_output,directory,config,log_path +""" +custom arg and macbeth error class +""" +class ArgError(Exception): + pass +class MacbethError(Exception): + pass + +""" +correlation function to quantify match +""" +def correlate(im1,im2): + f1 = im1.flatten() + f2 = im2.flatten() + cor = np.corrcoef(f1,f2) + return cor[0][1] + +""" +get list of files from directory +""" +def get_photos(directory='photos'): + filename_list = [] + for filename in os.listdir(directory): + if 'jp' in filename or '.dng' in filename: + filename_list.append(filename) + return filename_list + +""" +display image for debugging... read at your own risk... +""" +def represent(img,name='image'): + # if type(img) == tuple or type(img) == list: + # for i in range(len(img)): + # name = 'image {}'.format(i) + # cv2.imshow(name,img[i]) + # else: + # cv2.imshow(name,img) + # cv2.waitKey(0) + # cv2.destroyAllWindows() + # return 0 + """ + code above displays using opencv, but this doesn't catch users pressing 'x' + with their mouse to close the window.... therefore matplotlib is used.... + (thanks a lot opencv) + """ + grid = plt.GridSpec(22,1) + plt.subplot(grid[:19,0]) + plt.imshow(img,cmap='gray') + plt.axis('off') + plt.subplot(grid[21,0]) + plt.title('press \'q\' to continue') + plt.axis('off') + plt.show() + + # f = plt.figure() + # ax = f.add_subplot(211) + # ax2 = f.add_subplot(122) + # ax.imshow(img,cmap='gray') + # ax.axis('off') + # ax2.set_figheight(2) + # ax2.title('press \'q\' to continue') + # ax2.axis('off') + # plt.show() + + +""" +reshape image to fixed width without distorting +returns image and scale factor +""" +def reshape(img,width): + factor = width/img.shape[0] + return cv2.resize(img,None,fx=factor,fy=factor),factor |