geetools_VH/extract_shorelines_test.py

# -*- coding: utf-8 -*-

#==========================================================#
# Extract shorelines from Landsat images
#==========================================================#

# Initial settings
import os
import numpy as np
import matplotlib.pyplot as plt
import ee
import pdb

# other modules
from osgeo import gdal, ogr, osr
import pickle
import matplotlib.cm as cm
from pylab import ginput

# image processing modules
import skimage.filters as filters 
import skimage.exposure as exposure
import skimage.transform as transform
import sklearn.decomposition as decomposition
import skimage.measure as measure
import skimage.morphology as morphology

# machine learning modules
from sklearn.model_selection import train_test_split
from sklearn.neural_network import MLPClassifier
from sklearn.preprocessing import StandardScaler, Normalizer 
from sklearn.externals import joblib

# import own modules
import functions.utils as utils
import functions.sds as sds

# some settings
np.seterr(all='ignore') # raise/ignore divisions by 0 and nans
plt.rcParams['axes.grid'] = True
plt.rcParams['figure.max_open_warning'] = 100
ee.Initialize()

# parameters
cloud_thresh = 0.5      # threshold for cloud cover
plot_bool = False      # if you want the plots
min_contour_points = 100# minimum number of points contained in each water line
output_epsg = 28356     # GDA94 / MGA Zone 56
buffer_size = 10        # radius (in pixels) of disk for buffer (pixel classification)
min_beach_size = 50     # number of pixels in a beach (pixel classification)

# load metadata (timestamps and epsg code) for the collection
satname = 'L8'
sitename = 'NARRA'
#sitename = 'OLDBAR'

# Load metadata
filepath = os.path.join(os.getcwd(), 'data', satname, sitename)
with open(os.path.join(filepath, sitename + '_timestamps' + '.pkl'), 'rb') as f:
    timestamps = pickle.load(f)
with open(os.path.join(filepath, sitename + '_accuracy_georef' + '.pkl'), 'rb') as f:
    acc_georef = pickle.load(f) 
with open(os.path.join(filepath, sitename + '_epsgcode' + '.pkl'), 'rb') as f:
    input_epsg = pickle.load(f)
with open(os.path.join(filepath, sitename + '_refpoints' + '.pkl'), 'rb') as f:
    refpoints = pickle.load(f)
# sort timestamps and georef accuracy (dowloaded images are sorted by date in directory)
timestamps_sorted = sorted(timestamps)
idx_sorted = sorted(range(len(timestamps)), key=timestamps.__getitem__)
acc_georef_sorted = [acc_georef[j] for j in idx_sorted]

# path to images
file_path_pan = os.path.join(os.getcwd(), 'data', satname, sitename, 'pan')
file_path_ms = os.path.join(os.getcwd(), 'data', satname, sitename, 'ms')
file_names_pan = os.listdir(file_path_pan)
file_names_ms = os.listdir(file_path_ms)
N = len(file_names_pan)

# initialise some variables
cloud_cover_ts = []
date_acquired_ts = []
acc_georef_ts = []
idx_skipped = []
idx_nocloud = []
t = []
shorelines = []

#%%
for i in range(1):
    i = 0
    # read pan image
    fn_pan = os.path.join(file_path_pan, file_names_pan[i])
    data = gdal.Open(fn_pan, gdal.GA_ReadOnly)
    georef = np.array(data.GetGeoTransform())
    bands = [data.GetRasterBand(i + 1).ReadAsArray() for i in range(data.RasterCount)]
    im_pan = np.stack(bands, 2)[:,:,0]
    nrows = im_pan.shape[0]
    ncols = im_pan.shape[1]
    # read ms image
    fn_ms = os.path.join(file_path_ms, file_names_ms[i])
    data = gdal.Open(fn_ms, gdal.GA_ReadOnly)
    bands = [data.GetRasterBand(i + 1).ReadAsArray() for i in range(data.RasterCount)]
    im_ms = np.stack(bands, 2)
    
    # cloud mask
    im_qa = im_ms[:,:,5]
    cloud_mask = sds.create_cloud_mask(im_qa, satname, plot_bool)
    cloud_mask = transform.resize(cloud_mask, (im_pan.shape[0], im_pan.shape[1]),
                                order=0, preserve_range=True, 
                                mode='constant').astype('bool_')    
    # resize the image using bilinear interpolation (order 1)
    im_ms = transform.resize(im_ms,(im_pan.shape[0], im_pan.shape[1]),
                             order=1, preserve_range=True, mode='constant')
    
    # check if -inf or nan values and add to cloud mask
    im_inf = np.isin(im_ms[:,:,0], -np.inf)
    im_nan = np.isnan(im_ms[:,:,0])
    cloud_mask = np.logical_or(np.logical_or(cloud_mask, im_inf), im_nan)
    
    # calculate cloud cover and skip image if too high
    cloud_cover = sum(sum(cloud_mask.astype(int)))/(cloud_mask.shape[0]*cloud_mask.shape[1])
    if cloud_cover > cloud_thresh:
        print('skip ' + str(i) + ' - cloudy (' + str(cloud_cover) + ')')
        idx_skipped.append(i)
        continue
    idx_nocloud.append(i)
    
    # check if image for that date is already present
    if file_names_pan[i][len(satname)+1+len(sitename)+1:len(satname)+1+len(sitename)+1+10] in date_acquired_ts:
        
        # find the index of the image that is repeated
        idx_samedate = utils.find_indices(date_acquired_ts, lambda e : e == file_names_pan[i][9:19])
        idx_samedate = idx_samedate[0]
        print('cloud cover ' + str(cloud_cover) + ' - ' + str(cloud_cover_ts[idx_samedate]))
        print('acc georef ' + str(acc_georef_sorted[i]) + ' - ' + str(acc_georef_ts[idx_samedate]))
        
        # keep image with less cloud cover or best georeferencing accuracy
        if cloud_cover < cloud_cover_ts[idx_samedate] - 0.01: 
            skip = False
        elif acc_georef_sorted[i] < acc_georef_ts[idx_samedate]:
            skip = False
        else:
            skip = True
            
        if skip:
            print('skip ' + str(i) + ' - repeated')
            idx_skipped.append(i)
            continue
        else:
            del shorelines[idx_samedate]
            del t[idx_samedate]
            del cloud_cover_ts[idx_samedate]
            del date_acquired_ts[idx_samedate]
            del acc_georef_ts[idx_samedate]
            print('keep ' + str(i) + ' - deleted ' + str(idx_samedate))
            
    # pansharpen rgb image
    im_ms_ps = sds.pansharpen(im_ms[:,:,[0,1,2]], im_pan, cloud_mask, plot_bool)
    im_display = sds.rescale_image_intensity(im_ms_ps[:,:,[2,1,0]], cloud_mask, 100, False)
    # add down-sized bands for NIR and SWIR (since pansharpening is not possible)
    im_ms_ps = np.append(im_ms_ps, im_ms[:,:,[3,4]], axis=2) 
    
    # classify image in 4 classes (sand, whitewater, water, other) with NN classifier
    im_classif = sds.classify_image_NN(im_ms_ps, im_pan, cloud_mask, True)
    # labels
    im_sand = im_classif == 1
    im_swash = im_classif == 2
    im_water = im_classif == 3
    vec_sand = im_sand.reshape(ncols*nrows)
    vec_water = im_water.reshape(ncols*nrows)
    vec_swash = im_swash.reshape(ncols*nrows)
    
    t.append(timestamps_sorted[i])
    cloud_cover_ts.append(cloud_cover)
    acc_georef_ts.append(acc_georef_sorted[i])
    date_acquired_ts.append(file_names_pan[i][9:19])
    
    # calculate indices
    im_ndwi = sds.nd_index(im_ms_ps[:,:,3], im_ms_ps[:,:,1], cloud_mask, plot_bool)
    im_ndmwi = sds.nd_index(im_ms_ps[:,:,4], im_ms_ps[:,:,1], cloud_mask, plot_bool)
    im_nir = im_ms_ps[:,:,3]
    im_swir = im_ms_ps[:,:,4]
    im_ind = np.stack((im_ndwi, im_ndmwi), axis=-1)
    vec_ind = im_ind.reshape(nrows*ncols,2)
    # keep only beach
    morphology.remove_small_objects(im_sand, min_size=50, connectivity=2, in_place=True)
    # buffer around beach
    buffer_size = 7
    se = morphology.disk(buffer_size)
    im_buffer = morphology.binary_dilation(im_sand, se)
    vec_buffer = im_buffer.reshape(nrows*ncols)

    
    im = np.copy(im_display)
    im[~im_buffer,0] = 0
    im[~im_buffer,1] = 0
    im[~im_buffer,2] = 0
    plt.figure()
    plt.imshow(im)
    plt.draw()
    
    int_water = vec_ind[np.logical_and(vec_buffer,vec_water),:]
    int_sand = vec_ind[np.logical_and(vec_buffer,vec_sand),:]
    int_swash = vec_ind[np.logical_and(vec_buffer,vec_swash),:]
    
    fig, ax = plt.subplots(2,1, sharex=True)
    ax[0].hist(int_water[:,0], bins=100, label='water')
    ax[0].hist(int_sand[:,0], bins=100, alpha=0.5, label='sand')
    ax[0].hist(int_swash[:,0], bins=100, alpha=0.5, label='swash')
    ax[0].legend()
    ax[0].set_title('Water Index NIR-G')
    ax[1].hist(int_water[:,1], bins=100, label='water')
    ax[1].hist(int_sand[:,1], bins=100, alpha=0.5, label='sand')
    ax[1].hist(int_swash[:,1], bins=100, alpha=0.5, label='swash')
    ax[1].legend()
    ax[1].set_title('Modified Water Index SWIR-G')
    plt.draw()
    
    int_all = np.append(int_water,int_sand, axis=0)
    t1 = filters.threshold_otsu(int_all[:,0])
    t2 = filters.threshold_otsu(int_all[:,1])

    contours1 = measure.find_contours(im_ndwi, t1)
    contours2 = measure.find_contours(im_ndmwi, t1)
    
    plt.figure()
    plt.imshow(im_display)
    for i,contour in enumerate(contours1): plt.plot(contour[:, 1], contour[:, 0], linewidth=3, color='c')
    for i,contour in enumerate(contours2): plt.plot(contour[:, 1], contour[:, 0], linewidth=3, color='m')
    plt.draw()
    
    
    plt.figure()
    ax1 = plt.subplot(1,5,1)
    plt.imshow(im_display)
    plt.xticks([])
    plt.yticks([])
    plt.axis('off')
    plt.title('RGB')
    plt.subplot(1,5,2, sharex=ax1, sharey=ax1)
    plt.imshow(im_ndwi, cmap='seismic')
    plt.xticks([])
    plt.yticks([])
    plt.axis('off')
    plt.title('NDWI')
    plt.subplot(1,5,3, sharex=ax1, sharey=ax1)
    plt.imshow(im_ndmwi, cmap='seismic')
    plt.xticks([])
    plt.yticks([])
    plt.axis('off')
    plt.title('NDMWI')
    plt.subplot(1,5,4, sharex=ax1, sharey=ax1)
    plt.imshow(im_nir, cmap='seismic')
    plt.xticks([])
    plt.yticks([])
    plt.axis('off')
    plt.title('NIR')
    plt.subplot(1,5,5, sharex=ax1, sharey=ax1)
    plt.imshow(im_swir, cmap='seismic')
    plt.xticks([])
    plt.yticks([])
    plt.axis('off')
    plt.title('SWIR')
    
    fig, (ax1,ax2,ax3,ax4) = plt.subplots(4,2, figsize = (8,6))
    ax1[0].set_title('Probability density function')
    ax1[1].set_title('Cumulative distribution')
    
    im = im_ndwi
    t1 = filters.threshold_otsu(im)
    vals = ax1[0].hist(im.reshape(nrows*ncols), bins=300)
    ax1[0].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    vals = ax1[1].hist(im.reshape(nrows*ncols), bins=300, cumulative=True, histtype='step')
    ax1[1].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    ax1[0].set_ylabel('NDWI')
    
    im = im_ndmwi
    t1 = filters.threshold_otsu(im)
    vals = ax2[0].hist(im.reshape(nrows*ncols), bins=300)
    ax2[0].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    vals = ax2[1].hist(im.reshape(nrows*ncols), bins=300, cumulative=True, histtype='step')
    ax2[1].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    ax2[0].set_ylabel('NDMWI')
    
    im = im_nir
    t1 = filters.threshold_otsu(im)
    vals = ax3[0].hist(im.reshape(nrows*ncols), bins=300)
    ax3[0].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    vals = ax3[1].hist(im.reshape(nrows*ncols), bins=300, cumulative=True, histtype='step')
    ax3[1].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    ax3[0].set_ylabel('NIR')
    
    im = im_swir
    t1 = filters.threshold_otsu(im)
    vals = ax4[0].hist(im.reshape(nrows*ncols), bins=300)
    ax4[0].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    vals = ax4[1].hist(im.reshape(nrows*ncols), bins=300, cumulative=True, histtype='step')
    ax4[1].plot([t1, t1],[0, np.max(vals[0])], 'r-', label='Otsu threshold')
    ax4[0].set_ylabel('SWIR')
    
    plt.draw()
    
   

#%%  
    
    
    # calculate NDWI
    im_ndwi = sds.nd_index(im_ms_ps[:,:,3], im_ms_ps[:,:,1], cloud_mask, plot_bool)
    # detect edges
    wl_pix = sds.find_wl_contours(im_ndwi, cloud_mask, min_contour_points, True)
    # convert from pixels to world coordinates
    wl_coords = sds.convert_pix2world(wl_pix, georef)
    # convert to output epsg spatial reference
    wl = sds.convert_epsg(wl_coords, input_epsg, output_epsg)
    # classify sand pixels
    im_sand = sds.classify_sand_unsupervised(im_ms_ps, im_pan, cloud_mask, wl_pix, False, min_beach_size, plot_bool)
    
    # plot a figure to select the correct water line and discard cloudy images
    plt.figure()
    cmap = cm.get_cmap('jet')
    plt.subplot(121)
    plt.imshow(im_ms_ps[:,:,[2,1,0]])
    for j,contour in enumerate(wl_pix):
        colours = cmap(np.linspace(0, 1, num=len(wl_pix)))
        plt.plot(contour[:, 1], contour[:, 0], linewidth=2, color=colours[j,:])
    plt.axis('image')
    plt.title(file_names_pan[i])
    plt.subplot(122)
    centroids = []
    for j,contour in enumerate(wl):
        colours = cmap(np.linspace(0, 1, num=len(wl)))
        centroids.append([np.mean(contour[:, 0]),np.mean(contour[:, 1])])
        plt.plot(contour[:, 0], contour[:, 1], linewidth=2, color=colours[j,:])
        plt.plot(np.mean(contour[:, 0]), np.mean(contour[:, 1]), 'o', color=colours[j,:])
    plt.plot(refpoints[:,0], refpoints[:,1], 'k.')
    plt.axis('equal')
    plt.title(file_names_pan[i])
    mng = plt.get_current_fig_manager()                                         
    mng.window.showMaximized()
    plt.tight_layout()   
    plt.draw()
    # click on the left image to discard, otherwise on the closest centroid in the right image
    pt_in = np.array(ginput(n=1, timeout=1000))
    if pt_in[0][0] < 10000:
        print('skip ' + str(i) + ' - manual')
        idx_skipped.append(i)
        continue
    # get contour that was selected (click closest to centroid)
    dist_centroid = [np.linalg.norm(_ - pt_in) for _ in centroids]
    shorelines.append(wl[np.argmin(dist_centroid)])
    

    

# plot all shorelines
plt.figure()
plt.axis('equal')
for j in range(len(shorelines)):
    plt.plot(shorelines[j][:,0], shorelines[j][:,1])
plt.draw()
    
output = {'t':t, 'shorelines':shorelines, 'cloud_cover':cloud_cover_ts, 'acc_georef':acc_georef_ts}

#with open(os.path.join(filepath, sitename + '_output' + '.pkl'), 'wb') as f:
#    pickle.dump(output, f)
#    
#with open(os.path.join(filepath, sitename + '_skipped' + '.pkl'), 'wb') as f:
#    pickle.dump(idx_skipped, f)
#
#with open(os.path.join(filepath, sitename + '_idxnocloud' + '.pkl'), 'wb') as f:
#    pickle.dump(idx_nocloud, f)