Mercurial > templog
view web/log.py @ 132:97aad4471593
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author | Matt Johnston <matt@ucc.asn.au> |
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date | Sun, 14 Oct 2012 21:51:55 +0800 |
parents | 6a9419ac8f77 |
children | 719d5669ab27 |
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# -*- coding: utf-8 -*- #:vim:et:ts=4:sts=4:sw=4: import rrdtool import os import os.path import sys import glob import hashlib import tempfile import time import syslog import sqlite3 import traceback import datetime import struct import binascii from colorsys import hls_to_rgb import config def sensor_rrd_path(s): return '%s/sensor_%s.rrd' % (config.DATA_PATH, s) # returns (path, sensor_name) tuples def all_sensors(): return [(r, os.path.basename(r[:-4])) for r in glob.glob('%s/*.rrd' % config.DATA_PATH)] def create_rrd(sensor_id): # start date of 10 seconds into 1970 is used so that we can # update with prior values straight away. if 'voltage' in sensor_id: args = [ '--step', '3600', 'DS:temp:GAUGE:7200:1:10', 'RRA:AVERAGE:0.5:1:87600'] elif 'fridge_on' in sensor_id: args = [ '--step', '300', 'DS:temp:GAUGE:600:-100:500', 'RRA:LAST:0.5:1:1051200'] else: args = [ '--step', '300', 'DS:temp:GAUGE:600:-100:500', 'RRA:AVERAGE:0.5:1:1051200'] rrdtool.create(sensor_rrd_path(sensor_id), '--start', 'now-60d', *args) # stolen from viewmtn, stolen from monotone-viz def colour_from_string(str): def f(off): return ord(hashval[off]) / 256.0 hashval = hashlib.sha1(str).digest() hue = f(5) li = f(1) * 0.15 + 0.55 sat = f(2) * 0.5 + .5 return ''.join(["%.2x" % int(x * 256) for x in hls_to_rgb(hue, li, sat)]) def graph_png(start, length): os.environ['MATT_PNG_BODGE_COMPRESS'] = '4' os.environ['MATT_PNG_BODGE_FILTER'] = 'paeth' rrds = all_sensors() graph_args = [] have_volts = False for n, (rrdfile, sensor) in enumerate(rrds): unit = None if 'avrtemp' in sensor: continue if 'voltage' in sensor: have_volts = True vname = 'scalevolts' graph_args.append('DEF:%(vname)s=%(rrdfile)s:temp:AVERAGE:step=3600' % locals()) unit = 'V' elif 'fridge_on' in sensor: vname = 'fridge_on' graph_args.append('DEF:raw%(vname)s=%(rrdfile)s:temp:LAST' % locals()) graph_args.append('CDEF:%(vname)s=raw%(vname)s,3,+' % locals()) else: vname = 'temp%d' % n graph_args.append('DEF:raw%(vname)s=%(rrdfile)s:temp:AVERAGE' % locals()) # limit max temp to 50 graph_args.append('CDEF:%(vname)s=raw%(vname)s,35,GT,UNKN,raw%(vname)s,0.1,*,2,+,IF' % locals()) unit = '<span face="Liberation Serif">ยบ</span>C' format_last_value = None if unit: try: last_value = float(rrdtool.info(rrdfile)['ds[temp].last_ds']) format_last_value = ('%f' % last_value).rstrip('0.') + unit except ValueError: pass width = config.LINE_WIDTH legend = config.SENSOR_NAMES.get(sensor, sensor) colour = config.SENSOR_COLOURS.get(legend, colour_from_string(sensor)) if format_last_value: print_legend = '%s (%s)' % (legend, format_last_value) else: print_legend = legend graph_args.append('LINE%(width)f:%(vname)s#%(colour)s:%(print_legend)s' % locals()) end = int(start+length) start = int(start) tempf = tempfile.NamedTemporaryFile() dateformat = '%H:%M:%S %Y-%m-%d' watermark = ("Now %s\t" "Start %s\t" "End %s" % ( datetime.datetime.now().strftime(dateformat), datetime.datetime.fromtimestamp(start).strftime(dateformat), datetime.datetime.fromtimestamp(end).strftime(dateformat) )) args = [tempf.name, '-s', str(start), '-e', str(end), '-w', str(config.GRAPH_WIDTH), '-h', str(config.GRAPH_HEIGHT), '--slope-mode', '--border', '0', # '--vertical-label', 'Voltage', '--y-grid', '0.1:1', '--dynamic-labels', '--grid-dash', '1:0', '--zoom', str(config.ZOOM), '--color', 'GRID#00000000', '--color', 'MGRID#aaaaaa', '--color', 'BACK#ffffff', '--disable-rrdtool-tag', '--pango-markup', '--watermark', watermark, '--imgformat', 'PNG'] \ + graph_args args += ['--font', 'DEFAULT:12:%s' % config.GRAPH_FONT] args += ['--font', 'WATERMARK:10:%s' % config.GRAPH_FONT] if have_volts: args += ['--right-axis', '10:-20', # matches the scalevolts CDEF above '--right-axis-format', '%.0lf', # '--right-axis-label', 'Temperature' ] print>>sys.stderr, ' '.join("'%s'" % s for s in args) rrdtool.graph(*args) #return tempf return tempf.read() def validate_values(measurements): for m in measurements: if m == 85: yield 'U' else: yield '%f' % m def sensor_update(sensor_id, measurements, first_real_time, time_step): try: open(sensor_rrd_path(sensor_id)) except IOError, e: create_rrd(sensor_id) if measurements: values = ['%d:%s' % p for p in zip((first_real_time + time_step*t for t in xrange(len(measurements))), validate_values(measurements))] rrdfile = sensor_rrd_path(sensor_id) # XXX what to do here when it fails... for v in values: try: rrdtool.update(rrdfile, v) except rrdtool.error, e: print>>sys.stderr, "Bad rrdtool update '%s': %s" % (v, str(e)) traceback.print_exc(file=sys.stderr) # be paranoid #f = file(rrdfile) #os.fsync(f.fileno()) def debug_file(mode='r'): return open('%s/debug.log' % config.DATA_PATH, mode) def record_debug(lines): f = debug_file('a+') f.write('===== %s =====\n' % time.strftime('%a, %d %b %Y %H:%M:%S')) f.writelines(('%s\n' % s for s in lines)) f.flush() return f def tail_debug_log(): f = debug_file() f.seek(0, 2) size = f.tell() f.seek(max(0, size-30000)) return '\n'.join(l.strip() for l in f.readlines()[-400:]) def convert_ds18b20_12bit(reading): value = struct.unpack('>h', binascii.unhexlify(reading))[0] return value * 0.0625 def time_rem(name, entries): val_ticks = int(entries[name]) val_rem = int(entries['%s_rem' % name]) tick_wake = int(entries['tick_wake']) + 1 tick_secs = int(entries['tick_secs']) return val_ticks + float(val_rem) * tick_secs / tick_wake def parse(lines): start_time = time.time() debugf = record_debug(lines) entries = dict(l.split('=', 1) for l in lines) if len(entries) != len(lines): raise Exception("Keys are not unique") num_sensors = int(entries['sensors']) num_measurements = int(entries['measurements']) sensors = [entries['sensor_id%d' % n] for n in xrange(num_sensors)] meas = [] for s in sensors: meas.append([]) for n in xrange(num_measurements): vals = [convert_ds18b20_12bit(x) for x in entries["meas%d" % n].strip().split()] if len(vals) != num_sensors: raise Exception("Wrong number of sensors for measurement %d" % n) # we make an array of values for each sensor for s in xrange(num_sensors): meas[s].append(vals[s]) avr_now = time_rem('now', entries) avr_first_time = time_rem('first_time', entries) avr_comms_time = time_rem('comms_time', entries) time_step = float(entries['time_step']) debugf.write('now %f, comms_time %f, first_time %f, delta %f\n' % (avr_now, avr_comms_time, avr_first_time, avr_now - avr_comms_time)) if 'avrtemp' in entries: avrtemp = val_scale(int(entries['avrtemp'])) sensor_update('avrtemp', [avrtemp], time.time(), 1) if 'voltage' in entries: voltage = 0.001 * int(entries['voltage']) sensor_update('voltage', [voltage], time.time(), 1) if 'fridge_status' in entries: fridge_on = int(entries['fridge_status']) sensor_update('fridge_on', [fridge_on], time.time(), 1) if 'fridge' in entries: fridge_setpoint = float(entries['fridge']) sensor_update('fridge_setpoint', [fridge_setpoint], time.time(), 1) #sqlite # - time # - voltage # - boot time first_real_time = time.time() - (avr_now - avr_first_time) for sensor_id, measurements in zip(sensors, meas): # XXX sqlite add sensor_update(sensor_id, measurements, first_real_time, time_step) timedelta = time.time() - start_time debugf.write("Updated %d sensors in %.2f secs\n" % (len(sensors), timedelta)) debugf.flush()