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vad_reader.py
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from __future__ import print_function
import numpy as np
import struct
from datetime import datetime, timedelta
from wsr88d import build_has_name
try:
from urllib.request import urlopen, URLError
except ImportError:
from urllib2 import urlopen, URLError
try:
from io import BytesIO
except ImportError:
from BytesIO import BytesIO
import re
_base_url = "ftp://tgftp.nws.noaa.gov/SL.us008001/DF.of/DC.radar/DS.48vwp/"
class VADFile(object):
fields = ['wind_dir', 'wind_spd', 'rms_error', 'divergence', 'slant_range', 'elev_angle']
def __init__(self, file):
self._rpg = file
self._data = None
self._read_headers()
has_symbology_block, has_graphic_block, has_tabular_block = self._read_product_description_block()
if has_symbology_block:
self._read_product_symbology_block()
if has_graphic_block:
pass
if has_tabular_block:
self._read_tabular_block()
self._data = self._get_data()
return
def _read_headers(self):
wmo_header = self._read('s30')
message_code = self._read('h')
message_date = self._read('h')
message_time = self._read('i')
message_length = self._read('i')
source_id = self._read('h')
dest_id = self._read('h')
num_blocks = self._read('h')
return
def _read_product_description_block(self):
self._read('h') # Block separator
self._radar_latitude = self._read('i') / 1000.
self._radar_longitude = self._read('i') / 1000.
self._radar_elevation = self._read('h')
product_code = self._read('h')
if product_code != 48:
raise IOError("This isn't a VWP file.")
operational_mode = self._read('h')
self._vcp = self._read('h')
req_sequence_number = self._read('h')
vol_sequence_number = self._read('h')
scan_date = self._read('h')
scan_time = self._read('i')
product_date = self._read('h')
product_time = self._read('i')
self._read('h') # Product-dependent variable 1 (unused)
self._read('h') # Product-dependent variable 2 (unused)
self._read('h') # Elevation (unused)
self._read('h') # Product-dependent variable 3 (unused)
self._read('16h') # Product-dependent thresholds (how do I interpret these?)
self._read('7h') # Product-dependent variables 4-10 (mostly unused ... do I need the max?)
version = self._read('b')
spot_blank = self._read('b')
offset_symbology = self._read('i')
offset_graphic = self._read('i')
offset_tabular = self._read('i')
self._time = datetime(1969, 12, 31, 0, 0, 0) + timedelta(days=scan_date, seconds=scan_time)
return offset_symbology > 0, offset_graphic > 0, offset_tabular > 0
def _read_product_symbology_block(self):
self._read('h') # Block separator
block_id = self._read('h')
if block_id != 1:
raise IOError("This isn't the product symbology block.")
block_length = self._read('i')
num_layers = self._read('h')
layer_separator = self._read('h')
layer_num_bytes = self._read('i')
block_data = self._read('%dh' % int(layer_num_bytes / struct.calcsize('h')))
packet_code = -1
packet_size = -1
packet_counter = -1
packet_value = -1
packet = []
for item in block_data:
if packet_code == -1:
packet_code = item
elif packet_size == -1:
packet_size = item
packet_counter = 0
elif packet_value == -1:
packet_value = item
packet_counter += struct.calcsize('h')
else:
packet.append(item)
packet_counter += struct.calcsize('h')
if packet_counter == packet_size:
if packet_code == 8:
str_data = struct.pack('>%dh' % int(packet_size / struct.calcsize('h') - 3), *packet[2:])
elif packet_code == 4:
pass
packet = []
packet_code = -1
packet_size = -1
packet_counter = -1
packet_value = -1
return
def _read_tabular_block(self):
self._read('h')
block_id = self._read('h')
if block_id != 3:
raise IOError("This isn't the tabular block.")
block_size = self._read('i')
self._read('h')
self._read('h')
self._read('i')
self._read('i')
self._read('h')
self._read('h')
self._read('h')
self._read('h')
self._read('i')
self._read('i')
self._read('h')
product_code = self._read('h')
operational_mode = self._read('h')
vcp = self._read('h')
req_sequence_number = self._read('h')
vol_sequence_number = self._read('h')
scan_date = self._read('h')
scan_time = self._read('i')
product_date = self._read('h')
product_time = self._read('i')
self._read('h') # Product-dependent variable 1 (unused)
self._read('h') # Product-dependent variable 2 (unused)
self._read('h') # Elevation (unused)
self._read('h') # Product-dependent variable 3 (unused)
self._read('16h') # Product-dependent thresholds (how do I interpret these?)
self._read('7h') # Product-dependent variables 4-10 (mostly unused ... do I need the max?)
version = self._read('b')
spot_blank = self._read('b')
offset_symbology = self._read('i')
offset_graphic = self._read('i')
offset_tabular = self._read('i')
self._read('h') # Block separator
num_pages = self._read('h')
self._text_message = []
for idx in range(num_pages):
num_chars = self._read('h')
self._text_message.append([])
while num_chars != -1:
self._text_message[-1].append(self._read("s%d" % num_chars))
num_chars = self._read('h')
return
def _read(self, type_string):
if type_string[0] != 's':
size = struct.calcsize(type_string)
data = struct.unpack(">%s" % type_string, self._rpg.read(size))
else:
size = int(type_string[1:])
data = tuple([ self._rpg.read(size).strip(b"\0").decode('utf-8') ])
if len(data) == 1:
return data[0]
else:
return list(data)
def _get_data(self):
vad_list = []
for page in self._text_message:
if (page[0].strip())[:20] == "VAD Algorithm Output":
vad_list.extend(page[3:])
data = dict((k, []) for k in VADFile.fields)
for line in vad_list:
values = line.strip().split()
data['wind_dir'].append(float(values[4]))
data['wind_spd'].append(float(values[5]))
data['rms_error'].append(float(values[6]))
data['divergence'].append(float(values[7]) if values[7] != 'NA' else np.nan)
data['slant_range'].append(float(values[8]))
data['elev_angle'].append(float(values[9]))
for key, val in data.items():
data[key] = np.array(val)
data['slant_range'] *= 6067.1 / 3281.
r_e = 4. / 3. * 6371
data['altitude'] = np.sqrt(r_e ** 2 + data['slant_range'] ** 2 + 2 * r_e * data['slant_range'] * np.sin(np.radians(data['elev_angle']))) - r_e
order = np.argsort(data['altitude'])
for key, val in data.items():
data[key] = val[order]
return data
def __getitem__(self, key):
if key == 'time':
val = self._time
else:
val = self._data[key]
return val
def add_surface_wind(self, sfc_wind):
sfc_dir, sfc_spd = sfc_wind
keys = ['wind_dir', 'wind_spd', 'rms_error', 'altitude']
vals = [float(sfc_dir), float(sfc_spd), 0., 0.01]
for key, val in zip(keys, vals):
self._data[key] = np.append(val, self._data[key])
def find_file_times(rid):
url = "%s/SI.%s/" % (_base_url, rid.lower())
file_text = urlopen(url).read().decode('utf-8')
file_list = re.findall("([\w]{3} [\d]{1,2} [\d]{2}:[\d]{2}) (sn.[\d]{4})", file_text)
file_times, file_names = list(zip(*file_list))
file_names = list(file_names)
year = datetime.utcnow().year
file_dts = []
for ft in file_times:
ft_dt = datetime.strptime("%d %s" % (year, ft), "%Y %b %d %H:%M")
if ft_dt > datetime.utcnow():
ft_dt = datetime.strptime("%d %s" % (year - 1, ft), "%Y %b %d %H:%M")
file_dts.append(ft_dt)
file_list = list(zip(file_names, file_dts))
file_list.sort(key=lambda fl: fl[1])
file_names, file_dts = list(zip(*file_list))
file_names = list(file_names)
# The files are only moved into place when the next one is generated, so shift the
# file names by one index to account for that.
file_names[:-1] = file_names[1:]
file_names[-1] = 'sn.last'
return list(zip(file_names, file_dts))[::-1]
def download_vad(rid, time=None, file_id=None, cache_path=None):
if time is None:
if file_id is None:
url = "%s/SI.%s/sn.last" % (_base_url, rid.lower())
else:
url = "%s/SI.%s/sn.%04d" % (_base_url, rid.lower(), file_id)
else:
file_name = ""
for fn, ft in find_file_times(rid):
if ft <= time:
file_name = fn
break
if file_name == "":
raise ValueError("No VAD files before %s." % time.strftime("%d %B %Y %H%M UTC"))
url = "%s/SI.%s/%s" % (_base_url, rid.lower(), file_name)
try:
frem = urlopen(url)
except URLError:
raise ValueError("Could not find radar site '%s'" % rid.upper())
if cache_path is None:
vad = VADFile(frem)
else:
bio = BytesIO(frem.read())
vad = VADFile(bio)
iname = build_has_name(rid, vad['time'])
with open("%s/%s" % (cache_path, iname), 'wb') as floc:
floc.write(bio.getvalue())
return vad