test/attdet.py - third_party/github.com/google/liblc3 - Git at Google

 #
 # Copyright 2022 Google LLC
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 #     http://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.
 #

 import numpy as np

 import lc3
 import tables as T, appendix_c as C


 ### ------------------------------------------------------------------------ ###

 class AttackDetector:

     def __init__(self, dt, sr):

         self.dt = dt
         self.sr = sr
         self.ms = T.DT_MS[dt]

         self.xn1 = 0
         self.xn2 = 0
         self.en1 = 0
         self.an1 = 0
         self.p_att = 0

     def is_enabled(self, nbytes):

         c1 = self.dt == T.DT_10M and \
              self.sr == T.SRATE_32K and nbytes > 80

         c2 = self.dt == T.DT_10M and \
              self.sr >= T.SRATE_48K and nbytes >= 100

         c3 = self.dt == T.DT_7M5 and \
              self.sr == T.SRATE_32K and nbytes >= 61 and nbytes < 150

         c4 = self.dt == T.DT_7M5 and \
              self.sr >= T.SRATE_48K and nbytes >= 75 and nbytes < 150

         return c1 or c2 or c3 or c4

     def run(self, nbytes, x):

         ### 3.3.6.2 Downsampling and filtering input

         mf = int(16 * self.ms)

         r = len(x) // mf
         x_att = np.array([ np.sum(x[i*r:(i+1)*r]) for i in range(mf) ])

         x_hp = np.empty(mf)
         x_hp[0 ] = 0.375 * x_att[0 ] - 0.5 * self.xn1    + 0.125 * self.xn2
         x_hp[1 ] = 0.375 * x_att[1 ] - 0.5 * x_att[0   ] + 0.125 * self.xn1
         x_hp[2:] = 0.375 * x_att[2:] - 0.5 * x_att[1:-1] + 0.125 * x_att[0:-2]
         self.xn2 = x_att[-2]
         self.xn1 = x_att[-1]

         ### 3.3.6.3 Energy calculation

         nb = int(self.ms / 2.5)

         e_att = np.array([ np.sum(np.square(x_hp[40*i:40*(i+1)]))
                            for i in range(nb) ])

         a_att = np.empty(nb)
         a_att[0] = np.maximum(0.25 * self.an1, self.en1)
         for i in range(1,nb):
             a_att[i] = np.maximum(0.25 * a_att[i-1], e_att[i-1])
         self.en1 = e_att[-1]
         self.an1 = a_att[-1]

         ### 3.3.6.4 Attack Detection

         p_att = -1
         flags = [ (e_att[i] > 8.5 * a_att[i]) for i in range(nb) ]

         for (i, f) in enumerate(flags):
             if f: p_att = i

         f_att = p_att >= 0 or self.p_att - 1 >= nb // 2
         self.p_att = 1 + p_att

         return self.is_enabled(nbytes) and f_att


 def initial_state():
     return { 'en1': 0.0, 'an1': 0.0, 'p_att': 0 }

 ### ------------------------------------------------------------------------ ###

 def check_enabling(rng, dt):

     ok = True

     for sr in range(T.SRATE_16K, T.NUM_SRATE):

         attdet = AttackDetector(dt, sr)

         for nbytes in [ 61, 61-1, 75-1, 75, 80, 80+1, 100-1, 100, 150-1, 150 ]:

             f_att = lc3.attdet_run(dt, sr, nbytes,
                 initial_state(), 2 * rng.random(T.NS[dt][sr]+6) - 1)

             ok = ok and f_att == attdet.is_enabled(nbytes)

     return ok

 def check_unit(rng, dt, sr):

     ns = T.NS[dt][sr]
     ok = True

     attdet = AttackDetector(dt, sr)

     state_c = initial_state()
     x_c = np.zeros(ns+6)

     for run in range(100):

         ### Generate noise, and an attack at random point

         x = ((2 * rng.random(ns)) - 1) * (2 ** 8 - 1)
         x[(ns * rng.random()).astype(int)] *= 2 ** 7

         ### Check Implementation

         f_att = attdet.run(100, x)

         x_c = np.append(x_c[-6:], x)
         f_att_c = lc3.attdet_run(dt, sr, 100, state_c, x_c)

         ok = ok and f_att_c == f_att
         ok = ok and np.amax(np.abs(1 - state_c['en1']/attdet.en1)) < 2
         ok = ok and np.amax(np.abs(1 - state_c['an1']/attdet.an1)) < 2
         ok = ok and state_c['p_att'] == attdet.p_att

     return ok

 def check_appendix_c(dt):

     sr = T.SRATE_48K

     state = initial_state()

     x = np.append(np.zeros(6), C.X_PCM_ATT[dt][0])
     f_att = lc3.attdet_run(dt, sr, C.NBYTES_ATT[dt], state, x)
     ok = f_att == C.F_ATT[dt][0]

     x = np.append(x[-6:], C.X_PCM_ATT[dt][1])
     f_att = lc3.attdet_run(dt, sr, C.NBYTES_ATT[dt], state, x)
     ok = f_att == C.F_ATT[dt][1]

     return ok

 def check():

     rng = np.random.default_rng(1234)
     ok = True

     for dt in range(T.NUM_DT):
         ok and check_enabling(rng, dt)

     for dt in range(T.NUM_DT):
         for sr in range(T.SRATE_32K, T.NUM_SRATE):
             ok = ok and check_unit(rng, dt, sr)

     for dt in range(T.NUM_DT):
         ok = ok and check_appendix_c(dt)

     return ok

 ### ------------------------------------------------------------------------ ###
	#
	# Copyright 2022 Google LLC
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# http://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.
	#

	import numpy as np

	import lc3
	import tables as T, appendix_c as C


	### ------------------------------------------------------------------------ ###

	class AttackDetector:

	def __init__(self, dt, sr):

	self.dt = dt
	self.sr = sr
	self.ms = T.DT_MS[dt]

	self.xn1 = 0
	self.xn2 = 0
	self.en1 = 0
	self.an1 = 0
	self.p_att = 0

	def is_enabled(self, nbytes):

	c1 = self.dt == T.DT_10M and \
	self.sr == T.SRATE_32K and nbytes > 80

	c2 = self.dt == T.DT_10M and \
	self.sr >= T.SRATE_48K and nbytes >= 100

	c3 = self.dt == T.DT_7M5 and \
	self.sr == T.SRATE_32K and nbytes >= 61 and nbytes < 150

	c4 = self.dt == T.DT_7M5 and \
	self.sr >= T.SRATE_48K and nbytes >= 75 and nbytes < 150

	return c1 or c2 or c3 or c4

	def run(self, nbytes, x):

	### 3.3.6.2 Downsampling and filtering input

	mf = int(16 * self.ms)

	r = len(x) // mf
	x_att = np.array([ np.sum(x[ir:(i+1)r]) for i in range(mf) ])

	x_hp = np.empty(mf)
	x_hp[0 ] = 0.375 * x_att[0 ] - 0.5 * self.xn1 + 0.125 * self.xn2
	x_hp[1 ] = 0.375 * x_att[1 ] - 0.5 * x_att[0 ] + 0.125 * self.xn1
	x_hp[2:] = 0.375 * x_att[2:] - 0.5 * x_att[1:-1] + 0.125 * x_att[0:-2]
	self.xn2 = x_att[-2]
	self.xn1 = x_att[-1]

	### 3.3.6.3 Energy calculation

	nb = int(self.ms / 2.5)

	e_att = np.array([ np.sum(np.square(x_hp[40i:40(i+1)]))
	for i in range(nb) ])

	a_att = np.empty(nb)
	a_att[0] = np.maximum(0.25 * self.an1, self.en1)
	for i in range(1,nb):
	a_att[i] = np.maximum(0.25 * a_att[i-1], e_att[i-1])
	self.en1 = e_att[-1]
	self.an1 = a_att[-1]

	### 3.3.6.4 Attack Detection

	p_att = -1
	flags = [ (e_att[i] > 8.5 * a_att[i]) for i in range(nb) ]

	for (i, f) in enumerate(flags):
	if f: p_att = i

	f_att = p_att >= 0 or self.p_att - 1 >= nb // 2
	self.p_att = 1 + p_att

	return self.is_enabled(nbytes) and f_att


	def initial_state():
	return { 'en1': 0.0, 'an1': 0.0, 'p_att': 0 }

	### ------------------------------------------------------------------------ ###

	def check_enabling(rng, dt):

	ok = True

	for sr in range(T.SRATE_16K, T.NUM_SRATE):

	attdet = AttackDetector(dt, sr)

	for nbytes in [ 61, 61-1, 75-1, 75, 80, 80+1, 100-1, 100, 150-1, 150 ]:

	f_att = lc3.attdet_run(dt, sr, nbytes,
	initial_state(), 2 * rng.random(T.NS[dt][sr]+6) - 1)

	ok = ok and f_att == attdet.is_enabled(nbytes)

	return ok

	def check_unit(rng, dt, sr):

	ns = T.NS[dt][sr]
	ok = True

	attdet = AttackDetector(dt, sr)

	state_c = initial_state()
	x_c = np.zeros(ns+6)

	for run in range(100):

	### Generate noise, and an attack at random point

	x = ((2 * rng.random(ns)) - 1) * (2 ** 8 - 1)
	x[(ns * rng.random()).astype(int)] = 2 * 7

	### Check Implementation

	f_att = attdet.run(100, x)

	x_c = np.append(x_c[-6:], x)
	f_att_c = lc3.attdet_run(dt, sr, 100, state_c, x_c)

	ok = ok and f_att_c == f_att
	ok = ok and np.amax(np.abs(1 - state_c['en1']/attdet.en1)) < 2
	ok = ok and np.amax(np.abs(1 - state_c['an1']/attdet.an1)) < 2
	ok = ok and state_c['p_att'] == attdet.p_att

	return ok

	def check_appendix_c(dt):

	sr = T.SRATE_48K

	state = initial_state()

	x = np.append(np.zeros(6), C.X_PCM_ATT[dt][0])
	f_att = lc3.attdet_run(dt, sr, C.NBYTES_ATT[dt], state, x)
	ok = f_att == C.F_ATT[dt][0]

	x = np.append(x[-6:], C.X_PCM_ATT[dt][1])
	f_att = lc3.attdet_run(dt, sr, C.NBYTES_ATT[dt], state, x)
	ok = f_att == C.F_ATT[dt][1]

	return ok

	def check():

	rng = np.random.default_rng(1234)
	ok = True

	for dt in range(T.NUM_DT):
	ok and check_enabling(rng, dt)

	for dt in range(T.NUM_DT):
	for sr in range(T.SRATE_32K, T.NUM_SRATE):
	ok = ok and check_unit(rng, dt, sr)

	for dt in range(T.NUM_DT):
	ok = ok and check_appendix_c(dt)

	return ok

	### ------------------------------------------------------------------------ ###