qalg/bench-qiskit/shor_algorithm.py

# https://qiskit.org/documentation/tutorials/circuits/3_summary_of_quantum_operations.html
# https://github.com/olekssy/qiskit-shors/blob/master/shors.py
# https://quantumcomputinguk.org/tutorials/shors-algorithm-with-code

from math import pow,gcd,floor,isinf,ceil,log

from numpy import zeros,pi

from fractions import Fraction
from array import array

from qiskit import QuantumRegister,ClassicalRegister,QuantumCircuit
from qiskit import IBMQ

from quantum_runner import setup_IBM,quantum_simulate

def check_if_power(N):
    b=2
    while (2**b) <= N:
        a = 1
        c = N
        while (c-a) >= 2:
            m = int( (a+c)/2 )

            if (m**b) < (N+1):
                p = int( (m**b) )
            else:
                p = int(N+1)

            if int(p) == int(N):
                print('N is {0}^{1}'.format(int(m),int(b)) )
                return True

            if p<N:
                a = int(m)
            else:
                c = int(m)
        b=b+1

    return False

def create_QFT(circuit,up_reg,n,with_swaps):
    i=n-1
    while i>=0:
        circuit.h(up_reg[i])
        j=i-1
        while j>=0:
            if (pi)/(pow(2,(i-j))) > 0:
                circuit.crz( (pi)/(pow(2,(i-j))) , up_reg[i] , up_reg[j] )
                j=j-1
        i=i-1

    if with_swaps==1:
        i=0
        while i < ((n-1)/2):
            circuit.swap(up_reg[i], up_reg[n-1-i])
            i=i+1

def create_inverse_QFT(circuit,up_reg,n,with_swaps):
    if with_swaps==1:
        i=0
        while i < ((n-1)/2):
            circuit.swap(up_reg[i], up_reg[n-1-i])
            i=i+1

    i=0
    while i<n:
        circuit.h(up_reg[i])
        if i != n-1:
            j=i+1
            y=i
            while y>=0:
                 if (pi)/(pow(2,(j-y))) > 0:
                    circuit.crz( - (pi)/(pow(2,(j-y))) , up_reg[j] , up_reg[y] )


def egcd(a, b):
    if a == 0:
        return (b, 0, 1)
    else:
        g, y, x = egcd(b % a, a)
        return (g, x - (b // a) * y, y)

def modinv(a, m):
    g, x, y = egcd(a, m)
    if g != 1:
        raise Exception('modular inverse does not exist')
    else:
        return x % m

def get_factors(x_value,t_upper,N,a):

    if x_value<=0:
        print('x_value is <= 0, there are no continued fractions\n')
        return False

#    print('Running continued fractions for this case\n')

    T = pow(2,t_upper)

    x_over_T = x_value/T

    i=0
    b = array('i')
    t = array('f')

    b.append(floor(x_over_T))
    t.append(x_over_T - b[i])

    while i>=0:

        if i>0:
            b.append( floor( 1 / (t[i-1]) ) )
            t.append( ( 1 / (t[i-1]) ) - b[i] )


        aux = 0
        j=i
        while j>0:
            aux = 1 / ( b[j] + aux )
            j = j-1

        aux = aux + b[0]

        frac = Fraction(aux).limit_denominator()
        den=frac.denominator

        print('Approximation number {0} of continued fractions:'.format(i+1))
        print("Numerator:{0} \t\t Denominator: {1}\n".format(frac.numerator,frac.denominator))

        """ Increment i for next iteration """
        i=i+1

        if (den%2) == 1:
            if i>=15:
                print('Returning because have already done too much tries')
                return False
            print('Odd denominator, will try next iteration of continued fractions\n')
            continue

        """ If denominator even, try to get factors of N """

        """ Get the exponential a^(r/2) """

        exponential = 0

        if den<1000:
            exponential=pow(a , (den/2))

        """ Check if the value is too big or not """
        if isinf(exponential)==1 or exponential>1000000000:
            print('Denominator of continued fraction is too big!\n')
            aux_out = input('Input number 1 if you want to continue searching, other if you do not: ')
            if aux_out != '1':
                return False
            else:
                continue

        putting_plus = int(exponential + 1)

        putting_minus = int(exponential - 1)

        one_factor = gcd(putting_plus,N)
        other_factor = gcd(putting_minus,N)

        """ Check if the factors found are trivial factors or are the desired
        factors """

        if one_factor==1 or one_factor==N or other_factor==1 or other_factor==N:
            print('Found just trivial factors, not good enough\n')
            if t[i-1]==0:
                print('The continued fractions found exactly x_final/(2^(2n)) , leaving funtion\n')
                return False
            else:
                """ Return if already too much tries and numbers are huge """
                print('Returning because have already done too many tries\n')
                return False
        else:
            print('The factors of {0} are {1} and {2}\n'.format(N,one_factor,other_factor))
            print('Found the desired factors!\n')
            return True

def getAngles(a,N):
    s=bin(int(a))[2:].zfill(N)
    angles=zeros([N])
    for i in range(0, N):
        for j in range(i,N):
            if s[j]=='1':
                angles[N-i-1]+=pow(2, -(j-i))
        angles[N-i-1]*=pi
    return angles

def ccphase(circuit,angle,ctl1,ctl2,tgt):
    circuit.crz(angle/2,ctl1,tgt)
    circuit.cx(ctl2,ctl1)
    circuit.crz(-angle/2,ctl1,tgt)
    circuit.cx(ctl2,ctl1)
    circuit.crz(angle/2,ctl2,tgt)

def phiADD(circuit,q,a,N,inv):
    angle=getAngles(a,N)
    for i in range(0,N):
        if inv==0:
            circuit.p(angle[i],q[i])
        else:
            circuit.p(-angle[i],q[i])

def cphiADD(circuit,q,ctl,a,n,inv):
    angle=getAngles(a,n)
    for i in range(0,n):
        if inv==0:
            circuit.crz(angle[i],ctl,q[i])
        else:
            circuit.crz(-angle[i],ctl,q[i])

def ccphiADD(circuit,q,ctl1,ctl2,a,n,inv):
    angle=getAngles(a,n)
    for i in range(0,n):
        if inv==0:
            ccphase(circuit,angle[i],ctl1,ctl2,q[i])
        else:
            ccphase(circuit,-angle[i],ctl1,ctl2,q[i])

def ccphiADDmodN(circuit, q, ctl1, ctl2, aux, a, N, n):
    ccphiADD(circuit, q, ctl1, ctl2, a, n, 0)
    phiADD(circuit, q, N, n, 1)
    create_inverse_QFT(circuit, q, n, 0)
    circuit.cx(q[n-1],aux)
    create_QFT(circuit,q,n,0)
    cphiADD(circuit, q, aux, N, n, 0)

    ccphiADD(circuit, q, ctl1, ctl2, a, n, 1)
    create_inverse_QFT(circuit, q, n, 0)
    circuit.x(q[n-1])
    circuit.cx(q[n-1], aux)
    circuit.x(q[n-1])
    create_QFT(circuit,q,n,0)
    ccphiADD(circuit, q, ctl1, ctl2, a, n, 0)

def ccphiADDmodN_inv(circuit, q, ctl1, ctl2, aux, a, N, n):
    ccphiADD(circuit, q, ctl1, ctl2, a, n, 1)
    create_inverse_QFT(circuit, q, n, 0)
    circuit.x(q[n-1])
    circuit.cx(q[n-1],aux)
    circuit.x(q[n-1])
    create_QFT(circuit, q, n, 0)
    ccphiADD(circuit, q, ctl1, ctl2, a, n, 0)
    cphiADD(circuit, q, aux, N, n, 1)
    create_inverse_QFT(circuit, q, n, 0)
    circuit.cx(q[n-1], aux)
    create_QFT(circuit, q, n, 0)
    phiADD(circuit, q, N, n, 0)
    ccphiADD(circuit, q, ctl1, ctl2, a, n, 1)

def cMULTmodN(circuit, ctl, q, aux, a, N, n):
    create_QFT(circuit,aux,n+1,0)
    for i in range(0, n):
        ccphiADDmodN(circuit, aux, q[i], ctl, aux[n+1], (2**i)*a % N, N, n+1)
    create_inverse_QFT(circuit, aux, n+1, 0)

    for i in range(0, n):
        circuit.cswap(ctl,q[i],aux[i])

    a_inv = modinv(a, N)
    create_QFT(circuit, aux, n+1, 0)
    i = n-1
    while i >= 0:
        ccphiADDmodN_inv(circuit, aux, q[i], ctl, aux[n+1], pow(2,i)*a_inv % N, N, n+1)
        i -= 1
    create_inverse_QFT(circuit, aux, n+1, 0)

def get_value_a(N):
    a=2
    while gcd(a,N)!=1:
        a=a+1
    return a


def factorize_number(N):
    if N==1 or N==0:
        print('Please put an N different from 0 and from 1')
        exit()

    """ Check if N is even """

    if (N%2)==0:
        print('N is even, so does not make sense!')
        exit()

    """ Check if N can be put in N=p^q, p>1, q>=2 """

    """ Try all numbers for p: from 2 to sqrt(N) """
    if check_if_power(N)==True:
       exit()

#    print('Not an easy case, using the quantum circuit is necessary\n')

    setup_IBM()

    """ Get an integer a that is coprime with N """
    a = get_value_a(N)

#    """ If user wants to force some values, he can do that here, please make sure to update the print and that N and a are coprime"""
#    print('Forcing N=15 and a=4 because its the fastest case, please read top of source file for more info')
#    N=15
#    a=4

    print("help !!!")
    """ Get n value used in Shor's algorithm, to know how many qubits are used """
    n = ceil(log(N,2))

#    print('Total number of qubits used: {0}\n'.format(4*n+2))

    aux = QuantumRegister(n+2)
    up_reg = QuantumRegister(2*n)
    down_reg = QuantumRegister(n)
    up_classic = ClassicalRegister(2*n)
    circuit = QuantumCircuit(down_reg , up_reg , aux, up_classic)

    circuit.h(up_reg)
    circuit.x(down_reg[0])

    """ Apply the multiplication gates as showed in the report in order to create the exponentiation """
    for i in range(0, 2*n):
        cMULTmodN(circuit, up_reg[i], down_reg, aux, int(pow(a, pow(2, i))), N, n)

    """ Apply inverse QFT """
    create_inverse_QFT(circuit, up_reg, 2*n ,1)

    """ Measure the top qubits, to get x value"""
    circuit.measure(up_reg,up_classic)

    """ Simulate the created Quantum Circuit """
#    print(transpile(circuit,BasicAer.get_backend('qasm_simulator')))
    #simulation = execute(circuit, backend=BasicAer.get_backend('qasm_simulator'),shots=number_shots)
    provider = IBMQ.get_provider(hub='ibm-q', group='open', project='main')
    simulation = quantum_simulate(circuit,provider.get_backend('ibmq_lima'),True)

    i=0
    while i < len(simulation):
        print('Result \"{0}\" happened {1} times out of {2}'.format(list(simulation.keys())[i],list(simulation.values())[i]))
        i=i+1

    """ An empty print just to have a good display in terminal """
    print(' ')

    """ Initialize this variable """
    # prob_success=0

    """ For each simulation result, print proper info to user and try to calculate the factors of N"""
  #  i=0
  #  while i < len(counts_result):

        #""" Get the x_value from the final state qubits """
       # output_desired = list(sim_result.get_counts().keys())[i]
       # x_value = int(output_desired, 2)
       # prob_this_result = 100 * ( int( list(sim_result.get_counts().values())[i] ) ) / (number_shots)

        #print("------> Analysing result {0}. This result happened in {1:.4f} % of all cases\n".format(output_desired,prob_this_result))

        #""" Print the final x_value to user """
        # print('In decimal, x_final value for this result is: {0}\n'.format(x_value))

        #""" Get the factors using the x value obtained """
        # success=get_factors(int(x_value),int(2*n),int(N),int(a))

        #if success==True:
         #   prob_success = prob_success + prob_this_result

        #i=i+1

#    print("\nUsing a={0}, found the factors of N={1} in {2:.4f} % of the cases\n".format(a,N,prob_success))

N = 33
factorize_number(N)
init: repository publish 2023-07-24 16:56:29 +05:30			`# https://qiskit.org/documentation/tutorials/circuits/3_summary_of_quantum_operations.html`
			`# https://github.com/olekssy/qiskit-shors/blob/master/shors.py`
			`# https://quantumcomputinguk.org/tutorials/shors-algorithm-with-code`

			`from math import pow,gcd,floor,isinf,ceil,log`

			`from numpy import zeros,pi`

			`from fractions import Fraction`
			`from array import array`

			`from qiskit import QuantumRegister,ClassicalRegister,QuantumCircuit`
			`from qiskit import IBMQ`

			`from quantum_runner import setup_IBM,quantum_simulate`

			`def check_if_power(N):`
			`b=2`
			`while (2**b) <= N:`
			`a = 1`
			`c = N`
			`while (c-a) >= 2:`
			`m = int( (a+c)/2 )`

			`if (m**b) < (N+1):`
			`p = int( (m**b) )`
			`else:`
			`p = int(N+1)`

			`if int(p) == int(N):`
			`print('N is {0}^{1}'.format(int(m),int(b)) )`
			`return True`

			`if p<N:`
			`a = int(m)`
			`else:`
			`c = int(m)`
			`b=b+1`

			`return False`

			`def create_QFT(circuit,up_reg,n,with_swaps):`
			`i=n-1`
			`while i>=0:`
			`circuit.h(up_reg[i])`
			`j=i-1`
			`while j>=0:`
			`if (pi)/(pow(2,(i-j))) > 0:`
			`circuit.crz( (pi)/(pow(2,(i-j))) , up_reg[i] , up_reg[j] )`
			`j=j-1`
			`i=i-1`

			`if with_swaps==1:`
			`i=0`
			`while i < ((n-1)/2):`
			`circuit.swap(up_reg[i], up_reg[n-1-i])`
			`i=i+1`

			`def create_inverse_QFT(circuit,up_reg,n,with_swaps):`
			`if with_swaps==1:`
			`i=0`
			`while i < ((n-1)/2):`
			`circuit.swap(up_reg[i], up_reg[n-1-i])`
			`i=i+1`

			`i=0`
			`while i<n:`
			`circuit.h(up_reg[i])`
			`if i != n-1:`
			`j=i+1`
			`y=i`
			`while y>=0:`
			`if (pi)/(pow(2,(j-y))) > 0:`
			`circuit.crz( - (pi)/(pow(2,(j-y))) , up_reg[j] , up_reg[y] )`


			`def egcd(a, b):`
			`if a == 0:`
			`return (b, 0, 1)`
			`else:`
			`g, y, x = egcd(b % a, a)`
			`return (g, x - (b // a) * y, y)`

			`def modinv(a, m):`
			`g, x, y = egcd(a, m)`
			`if g != 1:`
			`raise Exception('modular inverse does not exist')`
			`else:`
			`return x % m`

			`def get_factors(x_value,t_upper,N,a):`

			`if x_value<=0:`
			`print('x_value is <= 0, there are no continued fractions\n')`
			`return False`

			`# print('Running continued fractions for this case\n')`

			`T = pow(2,t_upper)`

			`x_over_T = x_value/T`

			`i=0`
			`b = array('i')`
			`t = array('f')`

			`b.append(floor(x_over_T))`
			`t.append(x_over_T - b[i])`

			`while i>=0:`

			`if i>0:`
			`b.append( floor( 1 / (t[i-1]) ) )`
			`t.append( ( 1 / (t[i-1]) ) - b[i] )`


			`aux = 0`
			`j=i`
			`while j>0:`
			`aux = 1 / ( b[j] + aux )`
			`j = j-1`

			`aux = aux + b[0]`

			`frac = Fraction(aux).limit_denominator()`
			`den=frac.denominator`

			`print('Approximation number {0} of continued fractions:'.format(i+1))`
			`print("Numerator:{0} \t\t Denominator: {1}\n".format(frac.numerator,frac.denominator))`

			`""" Increment i for next iteration """`
			`i=i+1`

			`if (den%2) == 1:`
			`if i>=15:`
			`print('Returning because have already done too much tries')`
			`return False`
			`print('Odd denominator, will try next iteration of continued fractions\n')`
			`continue`

			`""" If denominator even, try to get factors of N """`

			`""" Get the exponential a^(r/2) """`

			`exponential = 0`

			`if den<1000:`
			`exponential=pow(a , (den/2))`

			`""" Check if the value is too big or not """`
			`if isinf(exponential)==1 or exponential>1000000000:`
			`print('Denominator of continued fraction is too big!\n')`
			`aux_out = input('Input number 1 if you want to continue searching, other if you do not: ')`
			`if aux_out != '1':`
			`return False`
			`else:`
			`continue`

			`putting_plus = int(exponential + 1)`

			`putting_minus = int(exponential - 1)`

			`one_factor = gcd(putting_plus,N)`
			`other_factor = gcd(putting_minus,N)`

			`""" Check if the factors found are trivial factors or are the desired`
			`factors """`

			`if one_factor==1 or one_factor==N or other_factor==1 or other_factor==N:`
			`print('Found just trivial factors, not good enough\n')`
			`if t[i-1]==0:`
			`print('The continued fractions found exactly x_final/(2^(2n)) , leaving funtion\n')`
			`return False`
			`else:`
			`""" Return if already too much tries and numbers are huge """`
			`print('Returning because have already done too many tries\n')`
			`return False`
			`else:`
			`print('The factors of {0} are {1} and {2}\n'.format(N,one_factor,other_factor))`
			`print('Found the desired factors!\n')`
			`return True`

			`def getAngles(a,N):`
			`s=bin(int(a))[2:].zfill(N)`
			`angles=zeros([N])`
			`for i in range(0, N):`
			`for j in range(i,N):`
			`if s[j]=='1':`
			`angles[N-i-1]+=pow(2, -(j-i))`
			`angles[N-i-1]*=pi`
			`return angles`

			`def ccphase(circuit,angle,ctl1,ctl2,tgt):`
			`circuit.crz(angle/2,ctl1,tgt)`
			`circuit.cx(ctl2,ctl1)`
			`circuit.crz(-angle/2,ctl1,tgt)`
			`circuit.cx(ctl2,ctl1)`
			`circuit.crz(angle/2,ctl2,tgt)`

			`def phiADD(circuit,q,a,N,inv):`
			`angle=getAngles(a,N)`
			`for i in range(0,N):`
			`if inv==0:`
			`circuit.p(angle[i],q[i])`
			`else:`
			`circuit.p(-angle[i],q[i])`

			`def cphiADD(circuit,q,ctl,a,n,inv):`
			`angle=getAngles(a,n)`
			`for i in range(0,n):`
			`if inv==0:`
			`circuit.crz(angle[i],ctl,q[i])`
			`else:`
			`circuit.crz(-angle[i],ctl,q[i])`

			`def ccphiADD(circuit,q,ctl1,ctl2,a,n,inv):`
			`angle=getAngles(a,n)`
			`for i in range(0,n):`
			`if inv==0:`
			`ccphase(circuit,angle[i],ctl1,ctl2,q[i])`
			`else:`
			`ccphase(circuit,-angle[i],ctl1,ctl2,q[i])`

			`def ccphiADDmodN(circuit, q, ctl1, ctl2, aux, a, N, n):`
			`ccphiADD(circuit, q, ctl1, ctl2, a, n, 0)`
			`phiADD(circuit, q, N, n, 1)`
			`create_inverse_QFT(circuit, q, n, 0)`
			`circuit.cx(q[n-1],aux)`
			`create_QFT(circuit,q,n,0)`
			`cphiADD(circuit, q, aux, N, n, 0)`

			`ccphiADD(circuit, q, ctl1, ctl2, a, n, 1)`
			`create_inverse_QFT(circuit, q, n, 0)`
			`circuit.x(q[n-1])`
			`circuit.cx(q[n-1], aux)`
			`circuit.x(q[n-1])`
			`create_QFT(circuit,q,n,0)`
			`ccphiADD(circuit, q, ctl1, ctl2, a, n, 0)`

			`def ccphiADDmodN_inv(circuit, q, ctl1, ctl2, aux, a, N, n):`
			`ccphiADD(circuit, q, ctl1, ctl2, a, n, 1)`
			`create_inverse_QFT(circuit, q, n, 0)`
			`circuit.x(q[n-1])`
			`circuit.cx(q[n-1],aux)`
			`circuit.x(q[n-1])`
			`create_QFT(circuit, q, n, 0)`
			`ccphiADD(circuit, q, ctl1, ctl2, a, n, 0)`
			`cphiADD(circuit, q, aux, N, n, 1)`
			`create_inverse_QFT(circuit, q, n, 0)`
			`circuit.cx(q[n-1], aux)`
			`create_QFT(circuit, q, n, 0)`
			`phiADD(circuit, q, N, n, 0)`
			`ccphiADD(circuit, q, ctl1, ctl2, a, n, 1)`

			`def cMULTmodN(circuit, ctl, q, aux, a, N, n):`
			`create_QFT(circuit,aux,n+1,0)`
			`for i in range(0, n):`
			`ccphiADDmodN(circuit, aux, q[i], ctl, aux[n+1], (2*i)a % N, N, n+1)`
			`create_inverse_QFT(circuit, aux, n+1, 0)`

			`for i in range(0, n):`
			`circuit.cswap(ctl,q[i],aux[i])`

			`a_inv = modinv(a, N)`
			`create_QFT(circuit, aux, n+1, 0)`
			`i = n-1`
			`while i >= 0:`
			`ccphiADDmodN_inv(circuit, aux, q[i], ctl, aux[n+1], pow(2,i)*a_inv % N, N, n+1)`
			`i -= 1`
			`create_inverse_QFT(circuit, aux, n+1, 0)`

			`def get_value_a(N):`
			`a=2`
			`while gcd(a,N)!=1:`
			`a=a+1`
			`return a`



			`def factorize_number(N):`
			`if N==1 or N==0:`
			`print('Please put an N different from 0 and from 1')`
			`exit()`

			`""" Check if N is even """`

			`if (N%2)==0:`
			`print('N is even, so does not make sense!')`
			`exit()`

			`""" Check if N can be put in N=p^q, p>1, q>=2 """`

			`""" Try all numbers for p: from 2 to sqrt(N) """`
			`if check_if_power(N)==True:`
			`exit()`

			`# print('Not an easy case, using the quantum circuit is necessary\n')`

			`setup_IBM()`

			`""" Get an integer a that is coprime with N """`
			`a = get_value_a(N)`

			`# """ If user wants to force some values, he can do that here, please make sure to update the print and that N and a are coprime"""`
			`# print('Forcing N=15 and a=4 because its the fastest case, please read top of source file for more info')`
			`# N=15`
			`# a=4`

			`print("help !!!")`
			`""" Get n value used in Shor's algorithm, to know how many qubits are used """`
			`n = ceil(log(N,2))`

			`# print('Total number of qubits used: {0}\n'.format(4*n+2))`

			`aux = QuantumRegister(n+2)`
			`up_reg = QuantumRegister(2*n)`
			`down_reg = QuantumRegister(n)`
			`up_classic = ClassicalRegister(2*n)`
			`circuit = QuantumCircuit(down_reg , up_reg , aux, up_classic)`

			`circuit.h(up_reg)`
			`circuit.x(down_reg[0])`

			`""" Apply the multiplication gates as showed in the report in order to create the exponentiation """`
			`for i in range(0, 2*n):`
			`cMULTmodN(circuit, up_reg[i], down_reg, aux, int(pow(a, pow(2, i))), N, n)`

			`""" Apply inverse QFT """`
			`create_inverse_QFT(circuit, up_reg, 2*n ,1)`

			`""" Measure the top qubits, to get x value"""`
			`circuit.measure(up_reg,up_classic)`

			`""" Simulate the created Quantum Circuit """`
			`# print(transpile(circuit,BasicAer.get_backend('qasm_simulator')))`
			`#simulation = execute(circuit, backend=BasicAer.get_backend('qasm_simulator'),shots=number_shots)`
			`provider = IBMQ.get_provider(hub='ibm-q', group='open', project='main')`
			`simulation = quantum_simulate(circuit,provider.get_backend('ibmq_lima'),True)`

			`i=0`
			`while i < len(simulation):`
			`print('Result \"{0}\" happened {1} times out of {2}'.format(list(simulation.keys())[i],list(simulation.values())[i]))`
			`i=i+1`

			`""" An empty print just to have a good display in terminal """`
			`print(' ')`

			`""" Initialize this variable """`
			`# prob_success=0`

			`""" For each simulation result, print proper info to user and try to calculate the factors of N"""`
			`# i=0`
			`# while i < len(counts_result):`

			`#""" Get the x_value from the final state qubits """`
			`# output_desired = list(sim_result.get_counts().keys())[i]`
			`# x_value = int(output_desired, 2)`
			`# prob_this_result = 100 * ( int( list(sim_result.get_counts().values())[i] ) ) / (number_shots)`

			`#print("------> Analysing result {0}. This result happened in {1:.4f} % of all cases\n".format(output_desired,prob_this_result))`

			`#""" Print the final x_value to user """`
			`# print('In decimal, x_final value for this result is: {0}\n'.format(x_value))`

			`#""" Get the factors using the x value obtained """`
			`# success=get_factors(int(x_value),int(2*n),int(N),int(a))`

			`#if success==True:`
			`# prob_success = prob_success + prob_this_result`

			`#i=i+1`

			`# print("\nUsing a={0}, found the factors of N={1} in {2:.4f} % of the cases\n".format(a,N,prob_success))`

			`N = 33`
			`factorize_number(N)`