the-last-thing/code/expt/lmdk_sel_cmp.py

#!/usr/bin/env python3

import sys
sys.path.insert(1, '../lib')
import argparse
import lmdk_lib
import lmdk_sel
import exp_mech
import numpy as np
import os
from matplotlib import pyplot as plt
import time


def main(args):
  # Privacy goal
  epsilon = 1.0
  # Number of timestamps
  seq = lmdk_lib.get_seq(1, args.time)
  # Distribution type
  dist_type = np.array(range(0, 4))
  # Number of landmarks
  lmdk_n = np.array(range(int(.2*args.time), args.time, int(args.time/5)))
  # Initialize plot
  lmdk_lib.plot_init()
  # Width of bars
  bar_width = 1/(len(dist_type) + 1)
  # The x axis
  x_i = np.arange(len(lmdk_n))
  x_margin = bar_width*(len(dist_type)/2 + 1)
  plt.xticks(x_i, ((lmdk_n/len(seq))*100).astype(int))
  plt.xlabel('Landmarks (%)')  # Set x axis label.
  plt.xlim(x_i.min() - x_margin, x_i.max() + x_margin)
  # The y axis
  # plt.yscale('log')
  plt.ylabel('Euclidean distance')  # Set y axis label.
  # plt.ylabel('Wasserstein distance')  # Set y axis label.
  # Bar offset
  x_offset = -(bar_width/2)*(len(dist_type) - 1)
  for d_i, d in enumerate(dist_type):
    # Set label
    label = lmdk_lib.dist_type_to_str(d)
    if d_i == 1:
      label = 'Skewed'
    # Logging
    title =  label + ' landmark distribution'
    print('(%d/%d) %s... ' %(d_i + 1, len(dist_type), title), end='', flush=True)
    mae = np.zeros(len(lmdk_n))
    for n_i, n in enumerate(lmdk_n):
      for r in range(args.reps):
        lmdks = lmdk_lib.get_lmdks(seq, n, d)
        hist, h = lmdk_lib.get_hist(seq, lmdks)
        opts = lmdk_sel.get_opts_from_top_h(seq, lmdks)
        delta = 1.0
        res, _ = exp_mech.exponential(hist, opts, exp_mech.score, delta, epsilon)
        mae[n_i] += lmdk_lib.get_norm(hist, res)/args.reps  # Euclidean
        # mae[n_i] += lmdk_lib.get_emd(hist, res)/args.reps  # Wasserstein
    print('[OK]', flush=True)
    # Plot bar for current distribution
    plt.bar(
      x_i + x_offset,
      mae,
      bar_width,
      label=label,
      linewidth=lmdk_lib.line_width
    )
    # Change offset for next bar
    x_offset += bar_width
  path = str('../../rslt/lmdk_sel_cmp/' + 'lmdk_sel_cmp-norm')
  # path = str('../../rslt/lmdk_sel_cmp/' + 'lmdk_sel_cmp-emd')
  # Plot legend
  lmdk_lib.plot_legend()
  # Show plot
  # plt.show()
  # Save plot
  lmdk_lib.save_plot(path + '.pdf')


'''
  Parse arguments.

  Optional:
    reps - The number of repetitions.
    time - The time limit of the sequence.
'''
def parse_args():
  # Create argument parser.
  parser = argparse.ArgumentParser()

  # Mandatory arguments.

  # Optional arguments.
  parser.add_argument('-r', '--reps', help='The number of repetitions.', type=int, default=1)
  parser.add_argument('-t', '--time', help='The time limit of the sequence.', type=int, default=100)

  # Parse arguments.
  args = parser.parse_args()

  return args


if __name__ == '__main__':
  try:
    start_time = time.time()
    main(parse_args())
    end_time = time.time()
    print('##############################')
    print('Time elapsed: %s' % (time.strftime('%H:%M:%S', time.gmtime(end_time - start_time))))
    print('##############################')
  except KeyboardInterrupt:
    print('Interrupted by user.')
    exit()
lmdk_sel_cmp: Testing 2021-10-06 00:43:39 +02:00			`#!/usr/bin/env python3`

			`import sys`
			`sys.path.insert(1, '../lib')`
			`import argparse`
			`import lmdk_lib`
			`import lmdk_sel`
			`import exp_mech`
			`import numpy as np`
			`import os`
			`from matplotlib import pyplot as plt`
			`import time`


			`def main(args):`
			`# Privacy goal`
			`epsilon = 1.0`
			`# Number of timestamps`
			`seq = lmdk_lib.get_seq(1, args.time)`
			`# Distribution type`
			`dist_type = np.array(range(0, 4))`
			`# Number of landmarks`
			`lmdk_n = np.array(range(int(.2*args.time), args.time, int(args.time/5)))`
			`# Initialize plot`
			`lmdk_lib.plot_init()`
			`# Width of bars`
			`bar_width = 1/(len(dist_type) + 1)`
			`# The x axis`
			`x_i = np.arange(len(lmdk_n))`
			`x_margin = bar_width*(len(dist_type)/2 + 1)`
			`plt.xticks(x_i, ((lmdk_n/len(seq))*100).astype(int))`
			`plt.xlabel('Landmarks (%)') # Set x axis label.`
			`plt.xlim(x_i.min() - x_margin, x_i.max() + x_margin)`
			`# The y axis`
code: Comparing Wasserstein and Euclidean distance 2021-10-06 18:12:10 +02:00			`# plt.yscale('log')`
			`plt.ylabel('Euclidean distance') # Set y axis label.`
code: Various corrections 2021-10-07 12:54:25 +02:00			`# plt.ylabel('Wasserstein distance') # Set y axis label.`
lmdk_sel_cmp: Testing 2021-10-06 00:43:39 +02:00			`# Bar offset`
			`x_offset = -(bar_width/2)*(len(dist_type) - 1)`
			`for d_i, d in enumerate(dist_type):`
			`# Set label`
			`label = lmdk_lib.dist_type_to_str(d)`
			`if d_i == 1:`
			`label = 'Skewed'`
			`# Logging`
			`title = label + ' landmark distribution'`
			`print('(%d/%d) %s... ' %(d_i + 1, len(dist_type), title), end='', flush=True)`
			`mae = np.zeros(len(lmdk_n))`
			`for n_i, n in enumerate(lmdk_n):`
			`for r in range(args.reps):`
			`lmdks = lmdk_lib.get_lmdks(seq, n, d)`
			`hist, h = lmdk_lib.get_hist(seq, lmdks)`
			`opts = lmdk_sel.get_opts_from_top_h(seq, lmdks)`
			`delta = 1.0`
code: Comparing Wasserstein and Euclidean distance 2021-10-06 18:12:10 +02:00			`res, _ = exp_mech.exponential(hist, opts, exp_mech.score, delta, epsilon)`
			`mae[n_i] += lmdk_lib.get_norm(hist, res)/args.reps # Euclidean`
			`# mae[n_i] += lmdk_lib.get_emd(hist, res)/args.reps # Wasserstein`
lmdk_sel_cmp: Testing 2021-10-06 00:43:39 +02:00			`print('[OK]', flush=True)`
			`# Plot bar for current distribution`
			`plt.bar(`
			`x_i + x_offset,`
			`mae,`
			`bar_width,`
			`label=label,`
			`linewidth=lmdk_lib.line_width`
			`)`
			`# Change offset for next bar`
			`x_offset += bar_width`
code: Comparing Wasserstein and Euclidean distance 2021-10-06 18:12:10 +02:00			`path = str('../../rslt/lmdk_sel_cmp/' + 'lmdk_sel_cmp-norm')`
code: Various corrections 2021-10-07 12:54:25 +02:00			`# path = str('../../rslt/lmdk_sel_cmp/' + 'lmdk_sel_cmp-emd')`
lmdk_sel_cmp: Testing 2021-10-06 00:43:39 +02:00			`# Plot legend`
			`lmdk_lib.plot_legend()`
			`# Show plot`
			`# plt.show()`
			`# Save plot`
			`lmdk_lib.save_plot(path + '.pdf')`



			`'''`
			`Parse arguments.`

			`Optional:`
			`reps - The number of repetitions.`
			`time - The time limit of the sequence.`
			`'''`
			`def parse_args():`
			`# Create argument parser.`
			`parser = argparse.ArgumentParser()`

			`# Mandatory arguments.`

			`# Optional arguments.`
			`parser.add_argument('-r', '--reps', help='The number of repetitions.', type=int, default=1)`
			`parser.add_argument('-t', '--time', help='The time limit of the sequence.', type=int, default=100)`

			`# Parse arguments.`
			`args = parser.parse_args()`

			`return args`


			`if __name__ == '__main__':`
			`try:`
			`start_time = time.time()`
			`main(parse_args())`
			`end_time = time.time()`
			`print('##############################')`
			`print('Time elapsed: %s' % (time.strftime('%H:%M:%S', time.gmtime(end_time - start_time))))`
			`print('##############################')`
			`except KeyboardInterrupt:`
			`print('Interrupted by user.')`
			`exit()`