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Python-ELMO is a Python library which offers an encapsulation of the binary tool ELMO, in order to manipulate it easily in Python and SageMath script.
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python-elmo/elmo/engine.py

engine.py 8.7KB
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  1. import numpy as np

  2. import os

  3. from enum import IntEnum, unique

  4. 

  5. from .utils import binary_writing

  6. from .config import ELMO_TOOL_REPOSITORY

  7. 

  8. @unique

  9. class Instruction(IntEnum):

  10.     EOR = 0

  11.     LSL = 1

  12.     STR = 2

  13.     LDR = 3

  14.     MUL = 4

  15.     OTHER = 5

  16.     

  17. # Short name for 'Instruction' class

  18. Instr = Instruction

  19. 

  20. PREVIOUS = 0

  21. CURRENT = 1

  22. SUBSEQUENT = 2

  23. 

  24. class ELMOEngine:

  25.     def __init__(self):

  26.         self.load_coefficients()

  27.         self.reset_points()

  28.     

  29.     def _extract_data(self, nb):

  30.         coeffs = self.coefficients[self.pos:self.pos+nb]

  31.         self.pos += nb

  32.         return coeffs

  33. 

  34.     def load_coefficients(self):

  35.         filename = os.path.join(

  36.             os.path.dirname(os.path.abspath(__file__)),

  37.             ELMO_TOOL_REPOSITORY,

  38.             'coeffs.txt',

  39.         )

  40.         self.coefficients = None

  41.         with open(filename, 'r') as _file:

  42.             self.coefficients = np.array([list(map(float, line.split())) for line in _file.readlines()[:2153]])

  43.         

  44.         if self.coefficients is None:

  45.             raise IOError('Problem to read the coefficients.')

  46.         

  47.         self.pos = 0

  48.         

  49.         self.constant = np.squeeze(self._extract_data(1))

  50.         

  51.         self.PrvInstr = self._extract_data(4)

  52.         self.SubInstr = self._extract_data(4)

  53.         

  54.         self.Operand1 = self._extract_data(32)

  55.         self.Operand2 = self._extract_data(32)

  56.         self.BitFlip1 = self._extract_data(32)

  57.         self.BitFlip2 = self._extract_data(32)

  58.         

  59.         self.HWOp1PrvInstr = self._extract_data(4)

  60.         self.HWOp2PrvInstr = self._extract_data(4)

  61.         self.HDOp1PrvInstr = self._extract_data(4)

  62.         self.HDOp2PrvInstr = self._extract_data(4)

  63.         self.HWOp1SubInstr = self._extract_data(4)

  64.         self.HWOp2SubInstr = self._extract_data(4)

  65.         self.HDOp1SubInstr = self._extract_data(4)

  66.         self.HDOp2SubInstr = self._extract_data(4)

  67.         

  68.         self.Operand1_bitinteractions = self._extract_data(496)

  69.         self.Operand2_bitinteractions = self._extract_data(496)

  70.         self.BitFlip1_bitinteractions = self._extract_data(496)

  71.         self.BitFlip2_bitinteractions = self._extract_data(496)

  72.     

  73.     def reset_points(self):

  74.         self.points = []

  75.         self.power = None

  76.         

  77.     def add_point(self, triplet, previous_ops, current_ops):

  78.         self.points.append((triplet, previous_ops, current_ops))

  79.     

  80.     def _dot(self, a, b):

  81.         return np.sum(a * b, axis=0)

  82.         

  83.     def calculate_point(self, triplet, previous_ops, current_ops, debug=False):

  84.         nb_points = triplet.shape[1]

  85.         instructiontype = triplet[CURRENT]

  86.         instructiontype = instructiontype % 5 # Type 5 = Instruction was not profiled

  87.                 

  88.         # Previous

  89.         previous_instruction_typedec = triplet[PREVIOUS]

  90.         previous_instruction_type = np.zeros((5, nb_points))

  91.         for i in range(nb_points):

  92.             if previous_instruction_typedec[i] < 5:

  93.                 previous_instruction_type[previous_instruction_typedec[i],i] = 1

  94.         

  95.         # Current

  96.         (current_op1_binary, hw_op1) = binary_writing(current_ops[0], with_hamming=True)

  97.         (current_op2_binary, hw_op2) = binary_writing(current_ops[1], with_hamming=True)

  98. 

  99.         (current_op1_bitflip, hd_op1) = binary_writing(previous_ops[0] ^ current_ops[0], with_hamming=True)

  100.         (current_op2_bitflip, hd_op2) = binary_writing(previous_ops[1] ^ current_ops[1], with_hamming=True)

  101.         

  102.         current_instruction_typedec = instructiontype

  103.         current_instruction_type = np.zeros((5, nb_points))

  104.         for i in range(nb_points):

  105.             if triplet[CURRENT,i] < 5:

  106.                 current_instruction_type[current_instruction_typedec[i],i] = 1

  107.         

  108.         # Subsequent

  109.         subsequent_instruction_typedec = triplet[SUBSEQUENT]

  110.         subsequent_instruction_type = np.zeros((5, nb_points))

  111.         for i in range(nb_points):

  112.             if subsequent_instruction_typedec[i] < 5:

  113.                 subsequent_instruction_type[subsequent_instruction_typedec[i],i] = 1

  114. 

  115.         # Component variables

  116.         PrvInstr_data = self._dot( previous_instruction_type[1:], self.PrvInstr[:,instructiontype] )

  117.         SubInstr_data = self._dot( subsequent_instruction_type[1:], self.SubInstr[:,instructiontype] )

  118.         

  119.         Operand1_data = self._dot( current_op1_binary, self.Operand1[:,instructiontype] )

  120.         Operand2_data = self._dot( current_op2_binary, self.Operand2[:,instructiontype] )

  121.         BitFlip1_data = self._dot( current_op1_bitflip, self.BitFlip1[:,instructiontype] )

  122.         BitFlip2_data = self._dot( current_op2_bitflip, self.BitFlip2[:,instructiontype] )

  123.         

  124.         HWOp1PrvInstr_data = hw_op1 * self._dot(previous_instruction_type[1:], self.HWOp1PrvInstr[:,instructiontype])

  125.         HWOp2PrvInstr_data = hw_op2 * self._dot(previous_instruction_type[1:], self.HWOp2PrvInstr[:,instructiontype])

  126.         HDOp1PrvInstr_data = hd_op1 * self._dot(previous_instruction_type[1:], self.HDOp1PrvInstr[:,instructiontype])

  127.         HDOp2PrvInstr_data = hd_op2 * self._dot(previous_instruction_type[1:], self.HDOp2PrvInstr[:,instructiontype])

  128.         HWOp1SubInstr_data = hw_op1 * self._dot(subsequent_instruction_type[1:], self.HWOp1SubInstr[:,instructiontype])

  129.         HWOp2SubInstr_data = hw_op2 * self._dot(subsequent_instruction_type[1:], self.HWOp2SubInstr[:,instructiontype])

  130.         HDOp1SubInstr_data = hd_op1 * self._dot(subsequent_instruction_type[1:], self.HDOp1SubInstr[:,instructiontype])

  131.         HDOp2SubInstr_data = hd_op2 * self._dot(subsequent_instruction_type[1:], self.HDOp2SubInstr[:,instructiontype])

  132.         

  133.         Operand1_bitinteractions_data = np.zeros((nb_points))

  134.         Operand2_bitinteractions_data = np.zeros((nb_points))

  135.         BitFlip1_bitinteractions_data = np.zeros((nb_points))

  136.         BitFlip2_bitinteractions_data = np.zeros((nb_points))

  137.         

  138.         count = 0

  139.         for i in range(32):

  140.             for j in range(i+1,32):

  141.                 Operand1_bitinteractions_data += self.Operand1_bitinteractions[count,instructiontype] * current_op1_binary[i] * current_op1_binary[j]

  142.                 Operand2_bitinteractions_data += self.Operand2_bitinteractions[count,instructiontype] * current_op2_binary[i] * current_op2_binary[j]

  143. 

  144.                 BitFlip1_bitinteractions_data += self.BitFlip1_bitinteractions[count,instructiontype] * current_op1_bitflip[i] * current_op1_bitflip[j]

  145.                 BitFlip2_bitinteractions_data += self.BitFlip2_bitinteractions[count,instructiontype] * current_op2_bitflip[i] * current_op2_bitflip[j]

  146. 

  147.                 count += 1

  148.                 

  149.         power = self.constant[instructiontype] \

  150.                     + PrvInstr_data + SubInstr_data \

  151.                     + Operand1_data + Operand2_data \

  152.                     + BitFlip1_data + BitFlip2_data \

  153.                     + HWOp1PrvInstr_data + HWOp2PrvInstr_data \

  154.                     + HDOp1PrvInstr_data + HDOp2PrvInstr_data \

  155.                     + HWOp1SubInstr_data + HWOp2SubInstr_data \

  156.                     + HDOp1SubInstr_data + HDOp2SubInstr_data \

  157.                     + Operand1_bitinteractions_data + Operand2_bitinteractions_data \

  158.                     + BitFlip1_bitinteractions_data + BitFlip2_bitinteractions_data

  159.         

  160.         for i in range(nb_points):

  161.             if triplet[CURRENT,i] == 5:

  162.                 power[i] = self.constant[triplet[CURRENT,i]]

  163.                 

  164.         if debug:

  165.             print([self.constant[instructiontype], \

  166.                        PrvInstr_data, SubInstr_data, \

  167.                        Operand1_data, Operand2_data, \

  168.                        BitFlip1_data, BitFlip2_data, \

  169.                        HWOp1PrvInstr_data, HWOp2PrvInstr_data, \

  170.                        HDOp1PrvInstr_data, HDOp2PrvInstr_data, \

  171.                        HWOp1SubInstr_data, HWOp2SubInstr_data, \

  172.                        HDOp1SubInstr_data, HDOp2SubInstr_data, \

  173.                        Operand1_bitinteractions_data, Operand2_bitinteractions_data, \

  174.                        BitFlip1_bitinteractions_data, BitFlip2_bitinteractions_data])

  175.         return power

  176.     

  177.     def run(self):

  178.         nb_points = len(self.points)

  179.         triplet = np.array([p[0] for p in self.points]).T # shape = (3, nb_points)

  180.         previous_ops = np.array([p[1] for p in self.points]).T # shape = (2, nb_points)

  181.         current_ops = np.array([p[2] for p in self.points]).T # shape = (2, nb_points)

  182.         

  183.         self.power = self.calculate_point(triplet, previous_ops, current_ops)

  184.     

  185.     def oneshot_point(self, triplet, previous_ops, current_ops):

  186.         self.reset_points()

  187.         self.add_point(triplet, previous_ops, current_ops)

  188.         self.run()

  189.         return self.power