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Shor_version2_5bit_simulation.py
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Shor_version2_5bit_simulation.py
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#--------------------------------------------------------------------------------------------------------------
# Import necessary modules
#--------------------------------------------------------------------------------------------------------------
import sys
from qiskit import QuantumProgram
import Qconfig
import Basic_gates
import math
from random import randint
import control_unitaries
import xlsxwriter
#--------------------------------------------------------------------------------------------------------------
# global variables
#--------------------------------------------------------------------------------------------------------------
Counts = 0
A = 0
Ran_Quantum_period_finding = 0
global m
m = 0
#--------------------------------------------------------------------------------------------------------------
# The function to compute GCD using Euclid's method
# Input : Two number to X and Y for which a GCD is to be computed
# Output : GCD of two given numbers
#--------------------------------------------------------------------------------------------------------------
def gcd(x,y):
while y != 0:
(x, y) = (y, x % y)
return x
#--------------------------------------------------------------------------------------------------------------
# The function to construct the unitary based on a
# Input : Quantum program object, the Circuit name and the quantum register name, and a
# Output : None. The relevant circuit is made.
#--------------------------------------------------------------------------------------------------------------
def cmod(Quantum_program_object,Circuit_name,Quantum_register_name,a):
# Get the circuit and the quantum register by name
qc = Quantum_program_object.get_circuit(Circuit_name)
qr = Quantum_program_object.get_quantum_register(Quantum_register_name)
# Construct unitary based on a
if a == 2:
qc.cswap(qr[4],qr[3],qr[2])
qc.cswap(qr[4],qr[2],qr[1])
qc.cswap(qr[4],qr[1],qr[0])
if a == 4 or a == 11 or a == 14:
qc.cswap(qr[4],qr[2],qr[0])
qc.cswap(qr[4],qr[3],qr[1])
qc.cx(qr[4],qr[3])
qc.cx(qr[4],qr[2])
qc.cx(qr[4],qr[1])
qc.cx(qr[4],qr[0])
if a == 7:
qc.cswap(qr[4],qr[1],qr[0])
qc.cswap(qr[4],qr[2],qr[1])
qc.cswap(qr[4],qr[3],qr[2])
qc.cx(qr[4],qr[3])
qc.cx(qr[4],qr[2])
qc.cx(qr[4],qr[1])
qc.cx(qr[4],qr[0])
if a == 8:
qc.cswap(qr[4],qr[1],qr[0])
qc.cswap(qr[4],qr[2],qr[1])
qc.cswap(qr[4],qr[3],qr[2])
if a == 13:
qc.cswap(qr[4],qr[3],qr[2])
qc.cswap(qr[4],qr[2],qr[1])
qc.cswap(qr[4],qr[1],qr[0])
qc.cx(qr[4],qr[3])
qc.cx(qr[4],qr[2])
qc.cx(qr[4],qr[1])
qc.cx(qr[4],qr[0])
#--------------------------------------------------------------------------------------------------------------
# The function to compute QFT
# Input : Circuit, quantum bits, and number of quantum bits
# Output : None. Circuit is created and saved
#--------------------------------------------------------------------------------------------------------------
def qft(Quantum_program_object,Circuit_name,Quantum_register_name,Smallest_Quantum_register_number,Size_of_QFT):
# Get the circuit and the quantum register by name
qc = Quantum_program_object.get_circuit(Circuit_name)
qr = Quantum_program_object.get_quantum_register(Quantum_register_name)
s = Smallest_Quantum_register_number
for j in range(Size_of_QFT):
for k in range(j):
qc.cu1(math.pi/float(2**(j-k)), qr[s+j], qr[s+k])
qc.h(qr[s+j])
#--------------------------------------------------------------------------------------------------------------
# The function to find period using the Quantum computer
# Input : a and N for which the period is to be computed.
# Output : period r of the function a^x mod N
#--------------------------------------------------------------------------------------------------------------
def period(a,N):
global Ran_Quantum_period_finding
Ran_Quantum_period_finding = 1
# Create the first QuantumProgram object instance.
qp = QuantumProgram()
#qp.set_api(Qconfig.APItoken, Qconfig.config["url"])
# TO DO : generalize the number of qubits and give proper security against rogue input.
# Create the first Quantum Register called "qr" with 12 qubits
qr = qp.create_quantum_register('qr', 5)
# Create your first Classical Register called "cr" with 12 bits
cr = qp.create_classical_register('cr', 3)
# Create the first Quantum Circuit called "qc" involving your Quantum Register "qr"
# and the Classical Register "cr"
qc = qp.create_circuit('Period_Finding', [qr], [cr])
# Get the circuit and the registers by name
Shor1 = qp.get_circuit('Period_Finding')
Q_reg = qp.get_quantum_register('qr')
C_reg = qp.get_classical_register('cr')
# Create the circuit for period finding
# Initialize qr[0] to |1>
Shor1.x(Q_reg[0])
# Step one : apply a**4 mod 15
Shor1.h(Q_reg[4])
# Controlled Identity on the remaining 4 qubits. Which is equivalent to doing nothing
Shor1.h(Q_reg[4])
Shor1.measure(Q_reg[4],C_reg[0])
# Reinitialize to |0>
Shor1.reset(Q_reg[4])
# Step two : apply a**2 mod 15
Shor1.h(Q_reg[4])
# Controlled unitary. Apply a mod 15 twice.
for k in range(2):
cmod(qp,'Period_Finding','qr',a)
if C_reg[0] == 1 :
Shor1.u1(pi/2.0,Q_reg[4])
Shor1.h(Q_reg[4])
Shor1.measure(Q_reg[4],C_reg[1])
# Reinitialize to |0>
Shor1.reset(Q_reg[4])
# Step three : apply 11 mod 15
Shor1.h(Q_reg[4])
# Controlled unitary. Apply a mod 15
cmod(qp,'Period_Finding','qr',a)
# Feed forward and measure
if C_reg[1] == 1 :
Shor1.u1(pi/2.0,Q_reg[4])
if C_reg[0] == 1 :
Shor1.u1(pi/4.0,Q_reg[4])
Shor1.h(Q_reg[4])
Shor1.measure(Q_reg[4],C_reg[2])
# Run the circuit
#qp.set_api(Qconfig.APItoken, Qconfig.config['url']) # set the APIToken and API url
simulate = qp.execute(["Period_Finding"], backend="local_qasm_simulator", shots=1,timeout=500)
simulate.get_counts("Period_Finding")
#print(simulate)
data = simulate.get_counts("Period_Finding")
#print(data)
data = list(data.keys())
#print(data)
r = int(data[0])
#print(r)
l = gcd(2**3,r)
#print(l)
r = int((2**3)/l)
#print(r)
return r
#--------------------------------------------------------------------------------------------------------------
# The main function to compute factors
# Input : The number to be factored, N
# Output : Factors of the number
#--------------------------------------------------------------------------------------------------------------
def Factorize_N(N):
factors = [0,0]
#--------------------------------------------------------------------------------------------------------------
# Step 1 : Determine the number of bits based on N; n = [log2(N)]
#--------------------------------------------------------------------------------------------------------------
n = math.ceil(math.log(N,2))
#--------------------------------------------------------------------------------------------------------------
# Step 2 : Check if N is even. In that case return 2 and the remaining number as factors
#--------------------------------------------------------------------------------------------------------------
if N % 2 == 0:
factors = [2,N/2]
return factors
#--------------------------------------------------------------------------------------------------------------
# Step 3 : Check if N is of the form P^(k), where P is some prime factor. In that case return P and k.
#--------------------------------------------------------------------------------------------------------------
# The step has been eliminated for simulation purposes.
#--------------------------------------------------------------------------------------------------------------
# Step 4 : Choose a random number between 2...(N-1).
#--------------------------------------------------------------------------------------------------------------
while True:
a = randint(2,N-1)
global A
A = a
#--------------------------------------------------------------------------------------------------------------
# Step 5 : Take GCD of a and N. t = GCD(a,N)
#--------------------------------------------------------------------------------------------------------------
t = gcd(N,a)
if t > 1:
factors = [t,N/t]
return factors
#--------------------------------------------------------------------------------------------------------------
# Step 6 : t = 1. Hence, no common period. Find Period using Shor's method
#--------------------------------------------------------------------------------------------------------------
r = period(a,N)
if (r%2 == 0) and (((a**(r/2))+1)%N != 0) and (r != 0) and (r != 8):
break
global Counts
Counts = Counts + 1
factor_1 = gcd((a**(r/2))+1,N)
factor_2 = N/factor_1
factors = [factor_1,factor_2]
return factors
#--------------------------------------------------------------------------------------------------------------
# Running the Shor's algorithm version 1
#--------------------------------------------------------------------------------------------------------------
#--------------------------------------------------------------------------------------------------------------
# Step 0 : Take the input N
#--------------------------------------------------------------------------------------------------------------
factors_list = list()
A_used = list()
Ran_QPF = list()
Total_counts = list()
if __name__ == '__main__':
#global m
for m in range(100):
N = 15
factors_found = Factorize_N(N)
factors_list.append(factors_found)
#ws.write(row,col,A)
#ws.write(row,col+1,Counts)
#ws.write(row,col+2,factors[0])
#ws.write(row,col+3,factors[1])
#ws.write(row,col+4,Ran_Quantum_period_finding)
#row = row + 1
#print("The Number being factorized is 15")
#print("Factors are = ",factors)
#print("Number of times the quantum circuit did not give correct period = ",Counts)
#print ("The parameter a used = ", A)
print("Run ", m)
A_used.append(A)
Ran_QPF.append(Ran_Quantum_period_finding)
Total_counts.append(Counts)
Counts = 0
Ran_Quantum_period_finding = 0
if m == 99:
wb = xlsxwriter.Workbook('log.xlsx')
ws = wb.add_worksheet('Data')
row = 0
col = 0
ws.write(row,col,'a used for factorizing')
ws.write(row,col+1,'Number of times the quantum circuit did not give correct period')
ws.write(row,col+2,'Factor1')
ws.write(row,col+3,'Factor2')
ws.write(row,col+4,'Ran_Quantum_period_finding?')
row = row + 1
for k in range(100):
ws.write(row,col,A_used[k])
ws.write(row,col+1,Total_counts[k])
ws.write(row,col+2,factors_list[k][0])
ws.write(row,col+3,factors_list[k][1])
ws.write(row,col+4,Ran_QPF[k])
row = row + 1
wb.close()