microproduct/backScattering/BackScatteringAlg.py

# -*- coding: UTF-8 -*-
"""
@Project ：microproduct
@File ：BackscatteringAlg.py
@Author ：KHZ
@Date ：2021/9/2 11:14 
@Version ：1.0.0
修改历史：
[修改序列]   [修改日期]    [修改者]     [修改内容]
   1       2022-6-29     石海军      1.int16矩阵转float32；2.对数形式（单位dB）转指数形式（无单位）
"""
import os
import numpy as np
from tool.algorithm.algtools.MetaDataHandler import MetaDataHandler
from tool.algorithm.image.ImageHandle import ImageHandler
from osgeo import gdal, gdalconst
from concurrent.futures import ThreadPoolExecutor, as_completed
# env_str = os.getcwd()
# os.environ['PROJ_LIB'] = env_str

class ScatteringAlg:
    def __init__(self):
        pass

    @staticmethod
    def sar_backscattering_coef(in_sar_tif, meta_file_path, out_sar_tif, replece_VV = False, is_DB = True):

        # 读取原始SAR影像
        proj, geotrans, in_data = ImageHandler.read_img(in_sar_tif)

        # 计算强度信息
        I = np.array(in_data[0], dtype="float32")
        Q = np.array(in_data[1], dtype="float32")

        where_9999_0 = np.where(I == -9999)
        where_9999_1 = np.where(Q == -9999)
        I[where_9999_0] = 1.0
        Q[where_9999_1] = 1.0

        I2 = np.square(I)
        Q2 = np.square(Q)
        intensity_arr = I2 + Q2

        # 获取极化类型
        if 'HH' in os.path.basename(in_sar_tif):
            polarization = 'HH'
        elif 'HV' in os.path.basename(in_sar_tif):
            polarization = 'HV'
        elif 'VH' in os.path.basename(in_sar_tif):
            polarization = 'VH'
        elif 'VV' in os.path.basename(in_sar_tif):
            polarization = 'VV'
            if replece_VV:
                polarization = 'HV' #土壤水分算法中可能会用HV替换VV
        else:
            raise Exception ('there are not HH、HV、VH、VV in path:',in_sar_tif)

        # 获取参数
        QualifyValue = MetaDataHandler.get_QualifyValue(meta_file_path, polarization)
        Kdb = MetaDataHandler.get_Kdb(meta_file_path, polarization)

        # 10 * (alog10((b1 * b1 + b2 * b2) * ((3690.385986 / 32767) * (3690.385986 / 32767)))) - 32.565000
        # 计算后向散射系数
        #对数形式
        coef_arr = 10 * (np.log10(intensity_arr * ((QualifyValue/32767)**2))) - Kdb
        coef_arr[np.isnan(coef_arr)] = -9999
        coef_arr[np.isinf(coef_arr)] = -9999
        coef_arr[where_9999_0] = -9999
        coef_arr[where_9999_1] = -9999
        # 输出的SAR后向散射系数产品
        ImageHandler.write_img(out_sar_tif, proj, geotrans, coef_arr, -9999)
        return True


###############
# RPC 模块
###############

def parse_rpc_file(rpc_file):
    # rpc_file:.rpc文件的绝对路径
    # rpc_dict：符号RPC域下的16个关键字的字典
    # 参考网址：http://geotiff.maptools.org/rpc_prop.html；
    # https://www.osgeo.cn/gdal/development/rfc/rfc22_rpc.html
 
    rpc_dict = {}
    with open(rpc_file) as f:
        text = f.read()
 
    # .rpc文件中的RPC关键词
    words = ['errBias', 'errRand', 'lineOffset', 'sampOffset', 'latOffset',
             'longOffset', 'heightOffset', 'lineScale', 'sampScale', 'latScale',
             'longScale', 'heightScale', 'lineNumCoef', 'lineDenCoef','sampNumCoef', 'sampDenCoef',]
 
    # GDAL库对应的RPC关键词
    keys = ['ERR_BIAS', 'ERR_RAND', 'LINE_OFF', 'SAMP_OFF', 'LAT_OFF', 'LONG_OFF',
            'HEIGHT_OFF', 'LINE_SCALE', 'SAMP_SCALE', 'LAT_SCALE',
            'LONG_SCALE', 'HEIGHT_SCALE', 'LINE_NUM_COEFF', 'LINE_DEN_COEFF',
            'SAMP_NUM_COEFF', 'SAMP_DEN_COEFF']
 
    for old, new in zip(words, keys):
        text = text.replace(old, new)
    # 以‘;\n’作为分隔符
    text_list = text.split(';\n')
    # 删掉无用的行
    text_list = text_list[3:-2]
    #
    text_list[0] = text_list[0].split('\n')[1]
    # 去掉制表符、换行符、空格
    text_list = [item.strip('\t').replace('\n', '').replace(' ', '') for item in text_list]
 
    for item in text_list:
        # 去掉‘=’
        key, value = item.split('=')
        # 去掉多余的括号‘(’，‘)’
        if '(' in value:
            value = value.replace('(', '').replace(')', '')
        rpc_dict[key] = value
 
    for key in keys[:12]:
        # 为正数添加符号‘+’
        if not rpc_dict[key].startswith('-'):
            rpc_dict[key] = '+' + rpc_dict[key]
        # 为归一化项和误差标志添加单位
        if key in ['LAT_OFF', 'LONG_OFF', 'LAT_SCALE', 'LONG_SCALE']:
            rpc_dict[key] = rpc_dict[key] + ' degrees'
        if key in ['LINE_OFF', 'SAMP_OFF', 'LINE_SCALE', 'SAMP_SCALE']:
            rpc_dict[key] = rpc_dict[key] + ' pixels'
        if key in ['ERR_BIAS', 'ERR_RAND', 'HEIGHT_OFF', 'HEIGHT_SCALE']:
            rpc_dict[key] = rpc_dict[key] + ' meters'
 
    # 处理有理函数项
    for key in keys[-4:]:
        values = []
        for item in rpc_dict[key].split(','):
            #print(item)
            if not item.startswith('-'):
                values.append('+'+item)
            else:
                values.append(item)
            rpc_dict[key] = ' '.join(values)
    return rpc_dict


def write_rpc_to_tiff(inputpath,rpc_file,ap = True,outpath = None):
    rpc_dict = parse_rpc_file(rpc_file)
    if ap:
        # 可修改读取
        dataset = gdal.Open(inputpath,gdal.GA_Update)
        # 向tif影像写入rpc域信息
        # 注意，这里虽然写入了RPC域信息，但实际影像还没有进行实际的RPC校正
        # 尽管有些RS/GIS能加载RPC域信息，并进行动态校正
        for k in rpc_dict.keys():
            dataset.SetMetadataItem(k, rpc_dict[k], 'RPC')
        dataset.FlushCache()
        del dataset
    else:
        dataset = gdal.Open(inputpath,gdal.GA_Update)
        tiff_driver= gdal.GetDriverByName('Gtiff')
        out_ds = tiff_driver.CreateCopy(outpath, dataset, 1) 
        for k in rpc_dict.keys():
            out_ds.SetMetadataItem(k, rpc_dict[k], 'RPC')
            out_ds.FlushCache()


def rpc_correction(inputpath,rpc_file,corrtiff,dem_tif_file = None):
    ## 设置rpc校正的参数
    # 原图像和输出影像缺失值设置为0，输出影像坐标系为WGS84(EPSG:4326), 重采样方法为双线性插值（bilinear，还有最邻近‘near’、三次卷积‘cubic’等可选)
    # 注意DEM的覆盖范围要比原影像的范围大，此外，DEM不能有缺失值，有缺失值会报错
    # 通常DEM在水域是没有值的（即缺失值的情况），因此需要将其填充设置为0，否则在RPC校正时会报错
    # 这里使用的DEM是填充0值后的SRTM V4.1 3秒弧度的DEM(分辨率为90m)
    # RPC_DEMINTERPOLATION=bilinear  表示对DEM重采样使用双线性插值算法
    # 如果要修改输出的坐标系，则要修改dstSRS参数值，使用该坐标系统的EPSG代码
    # 可以在网址https://spatialreference.org/ref/epsg/32650/  查询得到EPSG代码
    
    write_rpc_to_tiff(inputpath,rpc_file,ap = True,outpath = None)
    
    if dem_tif_file is None:
        wo = gdal.WarpOptions(srcNodata=0, dstNodata=0, dstSRS='EPSG:4326', resampleAlg='bilinear', 
                          format='Gtiff',rpc=True, warpOptions=["INIT_DEST=NO_DATA"])
        
        wr = gdal.Warp(corrtiff,  inputpath, options=wo)
        print("RPC_GEOcorr>>>")
    else:
        wo = gdal.WarpOptions(srcNodata=0, dstNodata=0, dstSRS='EPSG:4326', resampleAlg='bilinear', format='Gtiff',rpc=True, warpOptions=["INIT_DEST=NO_DATA"],
                 transformerOptions=["RPC_DEM=%s"%(dem_tif_file), "RPC_DEMINTERPOLATION=bilinear"])     
        wr = gdal.Warp(corrtiff,  inputpath, options=wo)   
        print("RPC_GEOcorr>>>")
    ## 对于全海域的影像或者不使用DEM校正的话，可以将transformerOptions有关的RPC DEM关键字删掉
    ## 即将上面gdal.WarpOptions注释掉，将下面的语句取消注释，无DEM时，影像范围的高程默认全为0
    del wr


##########################
# 输出RPC 行列号到 经纬度的变换
##########################
 #最大迭代次数超过则报错
class MaxLocalizationIterationsError(Exception):
     """
     Custom rpcm Exception.
     """
     pass

def apply_poly(poly, x, y, z):
     """
     Evaluates a 3-variables polynom of degree 3 on a triplet of numbers.
     将三次多项式的统一模式构建为一个单独的函数
     Args:
         poly: list of the 20 coefficients of the 3-variate degree 3 polynom,
             ordered following the RPC convention.
         x, y, z: triplet of floats. They may be numpy arrays of same length.
     Returns:
         the value(s) of the polynom on the input point(s).
     """
     out = 0
     out += poly[0]
     out += poly[1]*y + poly[2]*x + poly[3]*z
     out += poly[4]*y*x + poly[5]*y*z +poly[6]*x*z
     out += poly[7]*y*y + poly[8]*x*x + poly[9]*z*z
     out += poly[10]*x*y*z
     out += poly[11]*y*y*y
     out += poly[12]*y*x*x + poly[13]*y*z*z + poly[14]*y*y*x
     out += poly[15]*x*x*x
     out += poly[16]*x*z*z + poly[17]*y*y*z + poly[18]*x*x*z
     out += poly[19]*z*z*z
     return out

def apply_rfm(num, den, x, y, z):
     """
     Evaluates a Rational Function Model (rfm), on a triplet of numbers.
     执行20个参数的分子和20个参数的除法
     Args:
         num: list of the 20 coefficients of the numerator
         den: list of the 20 coefficients of the denominator
             All these coefficients are ordered following the RPC convention.
         x, y, z: triplet of floats. They may be numpy arrays of same length.
 
     Returns:
         the value(s) of the rfm on the input point(s).
     """
     return apply_poly(num, x, y, z) / apply_poly(den, x, y, z)

def rpc_from_geotiff(geotiff_path):
     """
     Read the RPC coefficients from a GeoTIFF file and return an RPCModel object.
     该函数返回影像的Gdal格式的影像和RPCmodel
     Args:
         geotiff_path (str): path or url to a GeoTIFF file
 
     Returns:
         instance of the rpc_model.RPCModel class
     """
     # with rasterio.open(geotiff_path, 'r') as src:
     #
     dataset = gdal.Open(geotiff_path, gdal.GA_ReadOnly)
     rpc_dict = dataset.GetMetadata("RPC")
     # 同时返回影像与rpc
     return dataset, RPCModel(rpc_dict,'geotiff')


def read_rpc_file(rpc_file):
     """
     Read RPC from a RPC_txt file and return a RPCmodel
     从TXT中直接单独读取RPC模型
     Args:
         rpc_file: RPC sidecar file path
 
     Returns:
         dictionary read from the RPC file, or an empty dict if fail
 
     """
     rpc = parse_rpc_file(rpc_file)
     return RPCModel(rpc)

class RPCModel:
    def __init__(self, d, dict_format="geotiff"):
         """
         Args:
             d (dict): dictionary read from a geotiff file with
                 rasterio.open('/path/to/file.tiff', 'r').tags(ns='RPC'),
                 or from the .__dict__ of an RPCModel object.
             dict_format (str): format of the dictionary passed in `d`.
                 Either "geotiff" if read from the tags of a geotiff file,
                 or "rpcm" if read from the .__dict__ of an RPCModel object.
         """
         if dict_format == "geotiff":
             self.row_offset = float(d['LINE_OFF'][0:d['LINE_OFF'].rfind(' ')])
             self.col_offset = float(d['SAMP_OFF'][0:d['SAMP_OFF'].rfind(' ')])
             self.lat_offset = float(d['LAT_OFF'][0:d['LAT_OFF'].rfind(' ')])
             self.lon_offset = float(d['LONG_OFF'][0:d['LONG_OFF'].rfind(' ')])
             self.alt_offset = float(d['HEIGHT_OFF'][0:d['HEIGHT_OFF'].rfind(' ')])

             self.row_scale = float(d['LINE_SCALE'][0:d['LINE_SCALE'].rfind(' ')])
             self.col_scale = float(d['SAMP_SCALE'][0:d['SAMP_SCALE'].rfind(' ')])
             self.lat_scale = float(d['LAT_SCALE'][0:d['LAT_SCALE'].rfind(' ')])
             self.lon_scale = float(d['LONG_SCALE'][0:d['LONG_SCALE'].rfind(' ')])
             self.alt_scale = float(d['HEIGHT_SCALE'][0:d['HEIGHT_SCALE'].rfind(' ')])

             self.row_num = list(map(float, d['LINE_NUM_COEFF'].split()))
             self.row_den = list(map(float, d['LINE_DEN_COEFF'].split()))
             self.col_num = list(map(float, d['SAMP_NUM_COEFF'].split()))
             self.col_den = list(map(float, d['SAMP_DEN_COEFF'].split()))

             if 'LON_NUM_COEFF' in d:
                 self.lon_num = list(map(float, d['LON_NUM_COEFF'].split()))
                 self.lon_den = list(map(float, d['LON_DEN_COEFF'].split()))
                 self.lat_num = list(map(float, d['LAT_NUM_COEFF'].split()))
                 self.lat_den = list(map(float, d['LAT_DEN_COEFF'].split()))

         elif dict_format == "rpcm":
             self.__dict__ = d

         else:
             raise ValueError(
                 "dict_format '{}' not supported. "
                 "Should be {{'geotiff','rpcm'}}".format(dict_format)
             )


    def projection(self, lon, lat, alt):
         """
         Convert geographic coordinates of 3D points into image coordinates.
         正投影：从地理坐标到图像坐标
         Args:
             lon (float or list): longitude(s) of the input 3D point(s)
             lat (float or list): latitude(s) of the input 3D point(s)
             alt (float or list): altitude(s) of the input 3D point(s)

         Returns:
             float or list: horizontal image coordinate(s) (column index, ie x)
             float or list: vertical image coordinate(s) (row index, ie y)
         """
         nlon = (np.asarray(lon) - self.lon_offset) / self.lon_scale
         nlat = (np.asarray(lat) - self.lat_offset) / self.lat_scale
         nalt = (np.asarray(alt) - self.alt_offset) / self.alt_scale

         col = apply_rfm(self.col_num, self.col_den, nlat, nlon, nalt)
         row = apply_rfm(self.row_num, self.row_den, nlat, nlon, nalt)

         col = col * self.col_scale + self.col_offset
         row = row * self.row_scale + self.row_offset

         return col, row


    def localization(self, col, row, alt, return_normalized=False):
         """
         Convert image coordinates plus altitude into geographic coordinates.
         反投影：从图像坐标到地理坐标
         Args:
             col (float or list): x image coordinate(s) of the input point(s)
             row (float or list): y image coordinate(s) of the input point(s)
             alt (float or list): altitude(s) of the input point(s)

         Returns:
             float or list: longitude(s)
             float or list: latitude(s)
         """
         ncol = (np.asarray(col) - self.col_offset) / self.col_scale
         nrow = (np.asarray(row) - self.row_offset) / self.row_scale
         nalt = (np.asarray(alt) - self.alt_offset) / self.alt_scale

         if not hasattr(self, 'lat_num'):
             lon, lat = self.localization_iterative(ncol, nrow, nalt)
         else:
             lon = apply_rfm(self.lon_num, self.lon_den, nrow, ncol, nalt)
             lat = apply_rfm(self.lat_num, self.lat_den, nrow, ncol, nalt)

         if not return_normalized:
             lon = lon * self.lon_scale + self.lon_offset
             lat = lat * self.lat_scale + self.lat_offset

         return lon, lat


    def localization_iterative(self, col, row, alt):
         """
         Iterative estimation of the localization function (image to ground),
         for a list of image points expressed in image coordinates.
         逆投影时的迭代函数
         Args:
             col, row: normalized image coordinates (between -1 and 1)
             alt: normalized altitude (between -1 and 1) of the corresponding 3D
                 point

         Returns:
             lon, lat: normalized longitude and latitude

         Raises:
             MaxLocalizationIterationsError: if the while loop exceeds the max
                 number of iterations, which is set to 100.
         """
         # target point: Xf (f for final)
         Xf = np.vstack([col, row]).T

         # use 3 corners of the lon, lat domain and project them into the image
         # to get the first estimation of (lon, lat)
         # EPS is 2 for the first iteration, then 0.1.
         lon = -col ** 0  # vector of ones
         lat = -col ** 0
         EPS = 2
         x0 = apply_rfm(self.col_num, self.col_den, lat, lon, alt)
         y0 = apply_rfm(self.row_num, self.row_den, lat, lon, alt)
         x1 = apply_rfm(self.col_num, self.col_den, lat, lon + EPS, alt)
         y1 = apply_rfm(self.row_num, self.row_den, lat, lon + EPS, alt)
         x2 = apply_rfm(self.col_num, self.col_den, lat + EPS, lon, alt)
         y2 = apply_rfm(self.row_num, self.row_den, lat + EPS, lon, alt)

         n = 0
         while not np.all((x0 - col) ** 2 + (y0 - row) ** 2 < 1e-18):

             if n > 100:
                 raise MaxLocalizationIterationsError("Max localization iterations (100) exceeded")

             X0 = np.vstack([x0, y0]).T
             X1 = np.vstack([x1, y1]).T
             X2 = np.vstack([x2, y2]).T
             e1 = X1 - X0
             e2 = X2 - X0
             u  = Xf - X0

             # project u on the base (e1, e2): u = a1*e1 + a2*e2
             # the exact computation is given by:
             #   M = np.vstack((e1, e2)).T
             #   a = np.dot(np.linalg.inv(M), u)
             # but I don't know how to vectorize this.
             # Assuming that e1 and e2 are orthogonal, a1 is given by
             # <u, e1> / <e1, e1>
             num = np.sum(np.multiply(u, e1), axis=1)
             den = np.sum(np.multiply(e1, e1), axis=1)
             a1 = np.divide(num, den).squeeze()

             num = np.sum(np.multiply(u, e2), axis=1)
             den = np.sum(np.multiply(e2, e2), axis=1)
             a2 = np.divide(num, den).squeeze()

             # use the coefficients a1, a2 to compute an approximation of the
             # point on the gound which in turn will give us the new X0
             lon += a1 * EPS
             lat += a2 * EPS

             # update X0, X1 and X2
             EPS = .1
             x0 = apply_rfm(self.col_num, self.col_den, lat, lon, alt)
             y0 = apply_rfm(self.row_num, self.row_den, lat, lon, alt)
             x1 = apply_rfm(self.col_num, self.col_den, lat, lon + EPS, alt)
             y1 = apply_rfm(self.row_num, self.row_den, lat, lon + EPS, alt)
             x2 = apply_rfm(self.col_num, self.col_den, lat + EPS, lon, alt)
             y2 = apply_rfm(self.row_num, self.row_den, lat + EPS, lon, alt)
             n += 1
             
         return lon, lat
#############################################
# 校正影像 输出影像转换表
#############################################

"""
[pool.putRequest(req) for req in requests]等同于
　　for req in requests:  
　　　　 pool.putRequest(req) 
"""

def rpc_row_col(params):
    rpc_mdl,r_block,c_block,ati_block,i,block_shape=params
    r_block ,c_block = rpc_mdl.localization(r_block.reshape(-1).astype(np.int32),c_block.reshape(-1).astype(np.int32) ,ati_block ) 
    return [i,r_block ,c_block,block_shape]

def getRCImageRC(inputPath,out_rpc_rc_path,rpc_file_path):
    rpc_tool = read_rpc_file(rpc_file_path)
    #shutil.copy2(inputPath, out_rpc_rc_path)
    # 创建重采样输出文件（设置投影及六参数）
    input_rpc_sar=gdal.Open(inputPath)

    driver = gdal.GetDriverByName('GTiff')
    output = driver.Create(out_rpc_rc_path, input_rpc_sar.RasterXSize,input_rpc_sar.RasterYSize, 2,gdal.GDT_Float32)
    output.SetGeoTransform(list(input_rpc_sar.GetGeoTransform()))
    output.SetProjection(input_rpc_sar.GetProjection())
    # 参数说明 输入数据集、输出文件、输入投影、参考投影、重采样方法(最邻近内插\双线性内插\三次卷积等)、回调函数
    
    rpc_rc_img=output
    # 计算行列号
    rc_height=rpc_rc_img.RasterYSize
    rc_width=rpc_rc_img.RasterXSize     

    with ThreadPoolExecutor(max_workers=8) as t:
        plist=[]
        for i in range(0,rc_height,100):
            c_block=np.ones((100,rc_width)).astype(np.float32)*(np.array(list(range(rc_width))).reshape(1,rc_width))
            r_block=np.ones((100,rc_width)).astype(np.float32)*(np.array(list(range(100))).reshape(100,1))
            r_block=r_block+i
            if not rc_height-i>100:
                num=rc_height-i
                r_block=r_block[:num,:].astype(np.float32)
                c_block=c_block[:num,:].astype(np.float32)        
            block_shape=r_block.shape
            
            plist.append(t.submit(rpc_row_col,[rpc_tool,r_block.reshape(-1).astype(np.int32),c_block.reshape(-1).astype(np.int32) ,c_block.reshape(-1)*0+0,i,block_shape]))
        for future in as_completed(plist):    
            data = future.result()
            i,r_block ,c_block,block_shape=data
            rpc_rc_img.GetRasterBand(1).WriteArray(r_block.reshape(block_shape).astype(np.float32),0,i)
            rpc_rc_img.GetRasterBand(2).WriteArray(c_block.reshape(block_shape).astype(np.float32),0,i)
    del rpc_rc_img,output,input_rpc_sar