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graphing_ts.py
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graphing_ts.py
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import pickle
import numpy as np
from numpy import fft
import pandas as pd
import warnings
import matplotlib.pyplot as plt
warnings.filterwarnings("ignore")
from scipy.stats import chisquare
import collections
import bz2
def fourierExtrapolation(x, n_predict, n_harm):
n = x.size
#n_harm = 100 # number of harmonics in model
t = np.arange(0, n)
p = np.polyfit(t, x, 1) # find linear trend in x
x_notrend = x - p[0] * t # detrended x
x_freqdom = fft.fft(x_notrend) # detrended x in frequency domain
f = fft.fftfreq(n) # frequencies
indexes = np.arange(n).tolist()
# sort indexes by frequency, lower -> higher
indexes.sort(key = lambda i:np.absolute(f[i]))
t = np.arange(0, n + n_predict)
restored_sig = np.zeros(t.size)
for i in indexes[:1 + n_harm * 2]:
ampli = np.absolute(x_freqdom[i]) / n # amplitude
phase = np.angle(x_freqdom[i]) # phase
restored_sig += ampli * np.cos(2 * np.pi * f[i] * t + phase)
return restored_sig + p[0] * t
def fit_model(train, n_predict):
model = collections.namedtuple('model',['upper','lower','forecast'])
minimum = np.min(train)
stddev = np.std(train)
model.upper = np.max(train) + stddev
model.lower = minimum - stddev
if minimum > 0:
model.lower = max(0, model.lower)
# n_harm = 1/3 of number of data points was chosen by visual inspection
n_harm = int(len(train)/3)
model.forecast = fourierExtrapolation(train, n_predict, n_harm)
return model
def window_AD(forecast, test, win_size):
num_bins = 5
new_forecast = forecast[-len(test):]
# windows = [np.arange(win_size*i,win_size*(i+1)) for i in range(int(len(test)/win_size) + 1)]
# windows[-1] = np.arange(windows[-1][0], len(test))
win_test = test[1:win_size]
win_forecast = new_forecast[1:win_size]
p_vals = []
for j in range(0, len(test)):
print(j+len(forecast)-len(test))
win_test = test[1:win_size]
for i in range(0,len(test)):
test_hist, bin_edges = np.histogram(win_test, bins=num_bins)
big_vals = np.where(win_forecast > bin_edges[-1])
small_vals = np.where(win_forecast < bin_edges[0])
f_hist, bin_edges = np.histogram(win_forecast, bins=bin_edges)
# print(np.sum(test_hist))
# print(np.sum(f_hist))
f_hist[-1] = f_hist[-1] + len(big_vals)
f_hist[0] = f_hist[0] + len(small_vals)
test_hist = [x+1 for x in test_hist]
f_hist = [x+1 for x in f_hist]
# print(test_hist)
# print(f_hist)
vals = chisquare(f_hist, f_exp=test_hist )
# print(vals[1])
p_vals.append(vals[1])
# win_test = np.roll(win_test, 1)
new_forecast = np.roll(new_forecast, 1)
win_forecast = new_forecast[1:win_size]
# if p_val > .75:
# return True
print(np.max(np.array(p_vals)))
p_vals = []
test = np.roll(test, 1)
return False
def detect_anomalies(model, test):
if np.max(test) > model.upper:
print("yep")
#return "point-wise anomaly - upper bound exceeded\nbound: " + str(model.upper) + "\nexceeded value: " + str(np.max(test))
if np.min(test) < model.lower:
print('yep')
#return "point-wise anomaly - lower bound exceeded"
else:
# run histogram-based AD
if window_AD(model.forecast, test, 60):
return "5-min window anomaly detected"
return "running histogram-based AD"
return "no anomalies detected"
def graph(series):
x_series = np.arange(series.size)
plt.plot(x_series, series, 'b', label = 'x', linewidth = 3)
# pl.plot(x_test, test, 'g*', label = 'x', linewidth = 3)
#pl.plot(x_extrapolation, extrapolation, 'r', label = 'extrapolation')
plt.legend()
pkl_file = open("../pkl_data/http_request_duration_microseconds_quantile_dataframes.pkl", "rb")
dfs = pickle.load(pkl_file)
pkl_file.close()
print(type(dfs))
key_vals = list(dfs.keys())
print(len(key_vals))
pkl_file = open("../data/real_data_test.pkl", "wb")
pickle.dump(dfs, pkl_file)
pkl_file.close()
i = 0
for key in key_vals[0:800]:
print(key)
df = dfs["{'__name__': 'http_request_duration_microseconds', 'beta_kubernetes_io_arch': 'amd64', 'beta_kubernetes_io_instance_type': 'm4.xlarge', 'beta_kubernetes_io_os': 'linux', 'failure_domain_beta_kubernetes_io_region': 'us-east-2', 'failure_domain_beta_kubernetes_io_zone': 'us-east-2a', 'handler': 'prometheus', 'hostname': 'free-stg-node-compute-e0756', 'instance': 'ip-172-31-76-144.us-east-2.compute.internal', 'job': 'kubernetes-nodes-exporter', 'kubernetes_io_hostname': 'ip-172-31-76-144.us-east-2.compute.internal', 'logging_infra_fluentd': 'true', 'node_role_kubernetes_io_compute': 'true', 'quantile': '0.99', 'region': 'us-east-2', 'type': 'compute'}"]
# df = dfs[key]
df["values"] = df["values"].apply(pd.to_numeric)
df = df.sort_values(by=['timestamps'])
vals = np.array(df["values"].tolist())
# train = vals[0:int(0.7*len(vals))]
# test = vals[int(0.7*len(vals)):]
# print(np.max(test))
# print(np.where(test == np.max(test)))
# x_vals = np.arange(0,len(vals))
# x_test = x_vals[int(0.7*len(vals)):]
# x_train = x_vals[0:int(0.7*len(vals))]
# mdl = fit_model(train, len(test))
print(i)
i += 1
# print(detect_anomalies(mdl, test))
graph(vals)
# plt.show()
plt.savefig("../time_series_graphing/graphs_http_total/fourier_" + str(i) + ".png")
plt.close()