Mercurial > templog
view web/log.py @ 340:3baca8d980f4
- import zlib
author | Matt Johnston <matt@ucc.asn.au> |
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date | Fri, 15 Jun 2012 23:36:41 +0800 |
parents | 449272fc63a3 |
children | 8da0fdadc8d7 |
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import rrdtool import os import os.path import sys import glob import hashlib import tempfile 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): rrdtool.create(sensor_rrd_path(sensor_id), '-s', '300', 'DS:temp:GAUGE:600:-10:100', 'RRA:AVERAGE:0.5:1:1051200') # 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): rrds = all_sensors() graph_args = [] for n, (rrdfile, sensor) in enumerate(rrds): vname = 'temp%d' % n graph_args.append('DEF:%(vname)s=%(rrdfile)s:temp:AVERAGE' % locals()) width = config.LINE_WIDTH legend = config.SENSOR_NAMES.get(sensor, sensor) colour = config.SENSOR_COLOURS.get(legend, colour_from_string(sensor)) graph_args.append('LINE%(width)f:%(vname)s#%(colour)s:%(legend)s' % locals()) tempf = tempfile.NamedTemporaryFile() args = [tempf.name, '-s', str(int(start)), '-e', str(int(start+length)), '-w', str(config.GRAPH_WIDTH), '-h', str(config.GRAPH_HEIGHT), '--slope-mode', '--border', '0', '--color', 'BACK#ffffff', '--imgformat', 'PNG'] \ + graph_args if config.GRAPH_FONT: args += ['--font', 'DEFAULT:0:%s' % config.GRAPH_FONT] print>>sys.stderr, args rrdtool.graph(*args) return tempf.read() 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) values = ['%f:%f' % p for p in zip((first_real_time + time_step*t for t in xrange(len(measurements))), measurements)] rrdfile = sensor_rrd_path(sensor_id) rrdtool.update(rrdfile, *values) # be paranois f = file(rrdfile) os.fsync(f.fileno()) def record_debug(lines): f = open('%s/debug.log', config.DATA_PATH, 'a+') f.write('===== %s =====' % time.strftime('%a, %d %b %Y %H:%M:%S') f.writelines(('%s\n' % s for s in lines)) f.flush() return f def parse(lines): 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['sensors']) sensor_ids = [entries['sensor_id%d' % n] for n in xrange(num_sensors)] meas = [] for s in sensors: meas.append([]) def val_scale(v): # convert decidegrees to degrees return 0.1 * v for n in xrange(num_measurements): vals = [val_scale(int(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 = float(entries['now']) avr_first_time = float(entries['first_time']) time_step = float(entries['time_step']) first_real_time = time.time() - (avr_now - avr_first_time) for sensor_id, measurements in zip(sensors, meas): sensor_update(sensor_id, measurements, first_real_time, time_step) debugf.write("Updated %d sensors\n" % len(sensors) debugf.flush()