Upload files to 'Archiv'

Archiv/StartUpTest.py

@@ -7,6 +7,21 @@ from scipy import stats
 
 class StartUPTest:
 
+    @staticmethod
+    def run_all_tests(binary_data: str):
+        # Run monobit_test
+        p_value, result = StartUPTest.monobit_test(binary_data)
+        if not result:
+            return False
+
+        # Run chi_square
+        p_value, result, chi2_statistic = StartUPTest.chi_square(binary_data)
+        if not result:
+            return False
+
+        # All tests passed
+        return True
+
     @staticmethod
     def monobit_test(binary_data: str):
 

Archiv/TotOnline.py

@@ -8,6 +8,38 @@ from scipy.special import gammaincc as gammaincc
 
 
 class TotOnline:
+
+    @staticmethod
+    def run_all_tests(binary_data: str):
+        # Run total_failure_test
+        p_value, result = TotOnline.total_failure_test(binary_data, 10)
+        if not result:
+            return False
+
+        # Run monobit_test
+        p_value, result = TotOnline.monobit_test(binary_data)
+        if not result:
+            return False
+
+        # Run block_frequency_test
+        p_value, result = TotOnline.block_frequency_test(binary_data, 128)
+        if not result:
+            return False
+
+        # Run run_test
+        p_value, result = TotOnline.run_test(binary_data)
+        if not result:
+            return False
+
+        # Run longest_one_block_test
+        if len(binary_data)>127:
+            p_value, result = TotOnline.longest_one_block_test(binary_data)
+            if not result:
+                return False
+
+        # All tests passed
+        return True
+
     @staticmethod
     def total_failure_test(binary_data: str, pattern_length=10):
 
@@ -158,10 +190,7 @@ class TotOnline:
         # print('Length of binary string: ', length_of_binary_data)
 
         # Initialized k, m. n, pi and v_values   
-        if length_of_binary_data < 128:
-            # Not enough data to run this test
-            return 0.00000, 'Error: Not enough data to run this test'
-        elif length_of_binary_data < 6272:
+        if length_of_binary_data < 6272:
             k = 3
             m = 8
             v_values = [1, 2, 3, 4]

Archiv/mainTest.py

@@ -0,0 +1,4 @@
+from pi_numbers_separated_I2C_function import analyze_data
+
+result = analyze_data(8, 10000, startup=False)
+print(result)

Archiv/pi_numbers_separated_I2C.py

@@ -0,0 +1,115 @@
+import os
+import time
+from smbus import SMBus
+from StartUpTest import StartUPTest
+from TotOnline import TotOnline
+import binascii
+
+addr = 0x8
+bus = SMBus(1)
+
+# define the number of numbers and bits per number to generate
+num_numbers = 6
+bits_per_number = 1000000
+
+# calculate the total file size in bits
+filesize = num_numbers * bits_per_number
+
+# define the filename
+filename = f'{num_numbers}numbers_{bits_per_number}bits'
+
+start_time_ges = start_time = time.time()
+start_time = time.time()  # start time of read
+
+with open(filename + '.bin', 'wb') as file:
+    for i in range(num_numbers):
+        # write the separator between numbers except for the last one
+        #if i != num_numbers - 1:
+            #file.write(b'' + b'')
+        for j in range(bits_per_number // 8):
+            # read one byte from the serial port
+            data = bus.read_byte(addr)
+            file.write(bytes([data]))
+            time.sleep(0.0000001)
+
+end_time = time.time()  # end time of read
+elapsed_time = end_time - start_time 
+
+seconds = int(elapsed_time)
+milliseconds = int((elapsed_time % 1) * 1000)
+
+new_filename = f"{filename}_TimeInSeconds_{seconds}_{milliseconds}.bin" # filename in format filename_seconds_milliseconds as txt with needed time to finish read
+
+os.rename(filename + '.bin', new_filename)  # change filename to new filename
+
+'''with open(new_filename, 'rb') as f:
+    # Read the contents of the file as bytes
+    content = f.read()
+    result = StartUPTest.monobit_test(content)
+    print(result[0])
+    print(result[1])
+    result = StartUPTest.chi_square(content)
+    print(result[0])
+    print(result[1])'''
+
+with open(new_filename, 'rb') as f:
+    # Read the contents of the file as bytes
+    content = f.read()
+
+# Convert the bytes to a string of hexadecimal digits with zero padding
+hex_str = ''.join(format(byte, '02x') for byte in content).zfill(num_numbers * (bits_per_number // 4))
+
+# Write the hex string to the file with separators and newlines
+with open(filename + '.txt', 'w') as f:
+    for i in range(num_numbers):
+        hex_number = hex_str[i * (bits_per_number // 4) : (i+1) * (bits_per_number // 4)]
+        # write the separator between numbers except for the last one
+        if i != num_numbers - 1:
+            hex_number += '//'
+        f.write(hex_number + '\n')
+
+print(f"time needed in seconds: {elapsed_time:.2f}. New filename: {new_filename}.")  # console write
+
+# Open the file in binary mode
+with open(new_filename, 'rb') as f:
+    # Read the contents of the file as bytes
+    content = f.read()
+
+# Convert the bytes to a string of binary digits
+binary_str = ''.join(format(byte, '08b') for byte in content)
+
+# Write the binary string back to the file with separators
+with open(filename + '_binary.txt', 'w') as f:
+    for i in range(0, len(binary_str), bits_per_number):
+        binary_number = binary_str[i:i+bits_per_number]
+        f.write(binary_number + '')
+        
+# Open the file in binary mode
+with open(filename + '_binary.txt', 'rb') as f:
+    # Read the contents of the file as bytes
+    content = f.read()
+    #print(content)
+    
+    result = TotOnline.total_failure_test(content)
+    print(result[0])
+    print(result[1])
+    result = TotOnline.block_frequency_test(content)
+    print(result[0])
+    print(result[1])
+    result = TotOnline.longest_one_block_test(content)
+    print(result[0])
+    print(result[1])
+    result = TotOnline.monobit_test(content)
+    print(result[0])
+    print(result[1])
+    result = TotOnline.run_test(content)
+    print(result[0])
+    print(result[1])
+        
+end_time_ges = time.time()
+elapsed_time_ges = end_time_ges - start_time_ges 
+
+
+seconds_ges = int(elapsed_time_ges)
+milliseconds_ges = int((elapsed_time_ges % 1) * 1000)
+print(elapsed_time_ges)

Archiv/pi_numbers_separated_USB.py

@@ -0,0 +1,80 @@
+from math import fabs as fabs
+from math import sqrt as sqrt
+import os
+import serial
+import time
+from StartUpTest import StartUPTest
+from TotOnline import TotOnline
+
+ser = serial.Serial('/dev/ttyACM0', 115200) # change port to input port from arduino
+
+# define the number of numbers and bits per number to generate
+num_numbers = 4
+bits_per_number = 5000
+
+# calculate the total file size in bits
+filesize = num_numbers * bits_per_number
+
+# define the filename
+filename = f'{num_numbers}numbers_{bits_per_number}bits'
+
+start_time = time.time()  # start time of read
+
+with open(filename + '.bin', 'wb') as file:
+    for i in range(num_numbers):
+        # write the separator between numbers except for the last one
+        if i != num_numbers - 1:
+            file.write(b'' + b'')
+        for j in range(bits_per_number // 8):
+            # read one byte from the serial port
+            byte = ser.read(1)
+            file.write(byte)
+
+end_time = time.time()  # end time of read
+elapsed_time = end_time - start_time 
+
+seconds = int(elapsed_time)
+milliseconds = int((elapsed_time % 1) * 1000)
+
+new_filename = f"{filename}_TimeInSeconds_{seconds}_{milliseconds}.bin" # filename in format filename_seconds_milliseconds as txt with needed time to finish read
+
+os.rename(filename + '.bin', new_filename)  # change filename to new filename
+
+# Open the file in binary mode
+with open(new_filename, 'rb') as f:
+    # Read the contents of the file as bytes
+    content = f.read()
+    result = StartUPTest.monobit_test(content)
+    print(result[0])
+    print(result[1])
+    result = StartUPTest.autocorrelation_test(content)
+    print(result[1])
+
+# Convert the bytes to a string of hexadecimal digits with zero padding
+hex_str = ''.join(format(byte, '02x') for byte in content).zfill(num_numbers * (bits_per_number // 4))
+
+# Write the hex string to the file with separators and newlines
+with open(filename + '.txt', 'w') as f:
+    for i in range(num_numbers):
+        hex_number = hex_str[i * (bits_per_number // 4) : (i+1) * (bits_per_number // 4)]
+        # write the separator between numbers except for the last one
+        if i != num_numbers - 1:
+            hex_number += '//'
+        f.write(hex_number + '\n')
+
+print(f"time needed in seconds: {elapsed_time:.2f}. New filename: {new_filename}.")  # console write
+
+# Open the file in binary mode
+with open(new_filename, 'rb') as f:
+    # Read the contents of the file as bytes
+    content = f.read()
+
+# Convert the bytes to a string of binary digits
+binary_str = ''.join(format(byte, '08b') for byte in content)
+
+# Write the binary string back to the file with separators
+with open(filename + '_binary.txt', 'w') as f:
+    for i in range(0, len(binary_str), bits_per_number):
+        binary_number = binary_str[i:i+bits_per_number]
+        f.write(binary_number + '\n')
+