Ising_mixerXY.py

# Point 4 of constraint studies for paper, Ising model with XY mixer to implement Hamming's condition, 2 rotamers per residue

# Script to optimise the Hamiltonian, starting directly from the Ising Hamiltonian
# Change file paths, run cells for simulations/hardware
# %%
import numpy as np
import pandas as pd
import time
import os
from copy import deepcopy

num_rot = 2
file_path = "RESULTS/XY-QAOA/5res-2rot.csv"
file_path_depth = "RESULTS/Depths/XY-QAOA/4res-2rot.csv"

########################### Configure the hamiltonian from the values calculated classically with pyrosetta ############################
df1 = pd.read_csv("energy_files/one_body_terms.csv")
q = df1['E_ii'].values
num = len(q)
N = int(num/num_rot)
num_qubits = num

print('Qii values: \n', q)

df2 = pd.read_csv("energy_files/two_body_terms.csv")
value = df2['E_ij'].values
Q = np.zeros((num,num))
n = 0

for i in range(0, num-2):
    if i%2 == 0:
        Q[i][i+2] = deepcopy(value[n])
        Q[i+2][i] = deepcopy(value[n])
        Q[i][i+3] = deepcopy(value[n+1])
        Q[i+3][i] = deepcopy(value[n+1])
        n += 2
    elif i%2 != 0:
        Q[i][i+1] = deepcopy(value[n])
        Q[i+1][i] = deepcopy(value[n])
        Q[i][i+2] = deepcopy(value[n+1])
        Q[i+2][i] = deepcopy(value[n+1])
        n += 2

print('\nQij values: \n', Q)

H = np.zeros((num,num))

for i in range(num):
    for j in range(num):
        if i != j:
            H[i][j] = np.multiply(0.25, Q[i][j])

for i in range(num):
    H[i][i] = -(0.5 * q[i] + sum(0.25 * Q[i][j] for j in range(num) if j != i))

print('\nH: \n', H)

k = 0
for i in range(num_qubits):
    k += 0.5 * q[i]

for i in range(num_qubits):
    for j in range(num_qubits):
        if i != j:
            k += 0.5 * 0.25 * Q[i][j]

# %% ################################################ Classical optimisation ###########################################################
from scipy.sparse.linalg import eigsh

Z_matrix = np.array([[1, 0], [0, -1]])
identity = np.eye(2)

def construct_operator(qubit_indices, num_qubits):
    operator = np.eye(1)
    for qubit in range(num_qubits):
        if qubit in qubit_indices:
            operator = np.kron(operator, Z_matrix)
        else:
            operator = np.kron(operator, identity)
    return operator

C = np.zeros((2**num_qubits, 2**num_qubits))

for i in range(num_qubits):
    operator = construct_operator([i], num_qubits)
    C += H[i][i] * operator

for i in range(num_qubits):
    for j in range(i+1, num_qubits):
        operator = construct_operator([i, j], num_qubits)
        C += H[i][j] * operator

print('C :\n', C)

# Extract the ground state energy and wavefunction
# using sparse representation so as to be able to generalise to larger systems
eigenvalues, eigenvectors = eigsh(C, k=num, which='SA')
print("\n\nClassical optimisation results. \n")
print("Ground energy eigsh: ", eigenvalues[0])
print("ground state wavefuncion eigsh: ", eigenvectors[:,0])
print('\n\n')

# %% ############################################ Quantum optimisation ########################################################################
from qiskit_algorithms.minimum_eigensolvers import QAOA
from qiskit.quantum_info.operators import Pauli, SparsePauliOp
from qiskit_algorithms.optimizers import COBYLA, SPSA
from qiskit.primitives import Sampler
from qiskit import QuantumCircuit

def X_op(i, num_qubits):
    """Return an X Pauli operator on the specified qubit in a num-qubit system."""
    op_list = ['I'] * num_qubits
    op_list[i] = 'X'
    return SparsePauliOp(Pauli(''.join(op_list)))

def generate_pauli_zij(n, i, j):
    if i<0 or i >= n or j<0 or j>=n:
        raise ValueError(f"Indices out of bounds for n={n} qubits. ")
        
    pauli_str = ['I']*n

    if i == j:
        pauli_str[i] = 'Z'
    else:
        pauli_str[i] = 'Z'
        pauli_str[j] = 'Z'

    return Pauli(''.join(pauli_str))

q_hamiltonian = SparsePauliOp(Pauli('I'*num_qubits), coeffs=[0])

for i in range(num_qubits):
    for j in range(i+1, num_qubits):
        if H[i][j] != 0:
            pauli = generate_pauli_zij(num_qubits, i, j)
            op = SparsePauliOp(pauli, coeffs=[H[i][j]])
            q_hamiltonian += op

for i in range(num_qubits):
    pauli = generate_pauli_zij(num_qubits, i, i)
    Z_i = SparsePauliOp(pauli, coeffs=[H[i][i]])
    q_hamiltonian += Z_i

def format_sparsepauliop(op):
    terms = []
    labels = [pauli.to_label() for pauli in op.paulis]
    coeffs = op.coeffs
    for label, coeff in zip(labels, coeffs):
        terms.append(f"{coeff:.10f} * {label}")
    return '\n'.join(terms)

print(f"\nThe hamiltonian constructed using Pauli operators is: \n", format_sparsepauliop(q_hamiltonian))

# XY mixer to implement Hamming condition
def create_xy_hamiltonian(num_qubits):
    hamiltonian = SparsePauliOp(Pauli('I'*num_qubits), coeffs=[0])  
    for i in range(0, num_qubits, 2):
        if i + 1 < num_qubits:
            xx_term = ['I'] * num_qubits
            yy_term = ['I'] * num_qubits
            xx_term[i] = 'X'
            xx_term[i+1] = 'X'
            yy_term[i] = 'Y'
            yy_term[i+1] = 'Y'
            xx_op = SparsePauliOp(Pauli(''.join(xx_term)), coeffs=[1/2])
            yy_op = SparsePauliOp(Pauli(''.join(yy_term)), coeffs=[1/2])
            hamiltonian += xx_op + yy_op
    return -hamiltonian 

XY_mixer = create_xy_hamiltonian(num_qubits)

def format_sparsepauliop(op):
    terms = []
    labels = [pauli.to_label() for pauli in op.paulis]
    coeffs = op.coeffs
    for label, coeff in zip(labels, coeffs):
        terms.append(f"{coeff:.10f} * {label}")
    return '\n'.join(terms)

print('XY mixer: ', XY_mixer)

start_time = time.time()
p = 1
initial_point = np.ones(2 * p)

def generate_initial_bitstring(num_qubits):
    bitstring = [(i%2) for i in range(num_qubits)]
    return ''.join(map(str, bitstring))

initial_bitstring = generate_initial_bitstring(num_qubits)
state_vector = np.zeros(2**num_qubits)
indexx = int(initial_bitstring, 2)
state_vector[indexx] = 1
qc = QuantumCircuit(num_qubits)
qc.initialize(state_vector, range(num_qubits))
# %%
qaoa = QAOA(sampler=Sampler(), optimizer=COBYLA(), reps=p, initial_state=qc, mixer=XY_mixer, initial_point=initial_point)
result = qaoa.compute_minimum_eigenvalue(q_hamiltonian)
end_time = time.time()

print("\n\nThe result of the quantum optimisation using QAOA is: \n")
print('best measurement', result.best_measurement)
elapsed_time = end_time - start_time
print(f"Local Simulation run time: {elapsed_time} seconds")
print('\n\n')

# %% ############################################ Simulators ##########################################################################
from qiskit_aer import Aer
from qiskit_ibm_provider import IBMProvider
from qiskit_aer.noise import NoiseModel
from qiskit.primitives import BackendSampler
from qiskit.transpiler import PassManager

simulator = Aer.get_backend('qasm_simulator')
provider = IBMProvider()
available_backends = provider.backends()
print("Available Backends:", available_backends)
device_backend = provider.get_backend('ibm_sherbrooke')
noise_model = NoiseModel.from_backend(device_backend)

options= {
    "noise_model": noise_model,
    "basis_gates": simulator.configuration().basis_gates,
    "coupling_map": simulator.configuration().coupling_map,
    "seed_simulator": 42,
    "shots": 1000,
    "optimization_level": 3,
    "resilience_level": 3
}

def callback(quasi_dists, parameters, energy):
    intermediate_data.append({
        'quasi_distributions': quasi_dists,
        'parameters': parameters,
        'energy': energy
    })

p = 1
intermediate_data = []
initial_point = np.ones(2 * p)
noisy_sampler = BackendSampler(backend=simulator, options=options, bound_pass_manager=PassManager())

# insert optimiser 

start_time1 = time.time()
qaoa1 = QAOA(sampler=noisy_sampler, optimizer=COBYLA(), reps=p, initial_state=qc, mixer=XY_mixer, initial_point=initial_point,callback=callback)
result1 = qaoa1.compute_minimum_eigenvalue(q_hamiltonian)
end_time1 = time.time()
elapsed_time1 = end_time1 - start_time1

# %%
from qiskit_aer.primitives import Estimator
from qiskit import QuantumCircuit, transpile

def int_to_bitstring(state, total_bits):
    """Converts an integer state to a binary bitstring with padding of leading zeros."""
    return format(state, '0{}b'.format(total_bits))

def check_hamming(bitstring, substring_size):
    """Check if each substring contains exactly one '1'."""
    substrings = [bitstring[i:i+substring_size] for i in range(0, len(bitstring), substring_size)]
    return all(sub.count('1') == 1 for sub in substrings)

def calculate_bitstring_energy(bitstring, hamiltonian, backend=None):
    """
    Calculate the energy of a given bitstring for a specified Hamiltonian.

    Args:
        bitstring (str): The bitstring for which to calculate the energy.
        hamiltonian (SparsePauliOp): The Hamiltonian operator of the system, defined as a SparsePauliOp.
        backend (qiskit.providers.Backend): The quantum backend to execute circuits.

    Returns:
        float: The calculated energy of the bitstring.
    """
    # Prepare the quantum circuit for the bitstring
    num_qubits = len(bitstring)
    qc = QuantumCircuit(num_qubits)
    for i, char in enumerate(bitstring):
        if char == '1':
            qc.x(i)  # Apply X gate if the bit in the bitstring is 1
    
    # Use Aer's statevector simulator if no backend provided
    if backend is None:
        backend = Aer.get_backend('aer_simulator_statevector')

    qc = transpile(qc, backend)
    estimator = Estimator()
    resultt = estimator.run(observables=[hamiltonian], circuits=[qc], backend=backend).result()

    return resultt.values[0].real

eigenstate_distribution = result1.eigenstate
best_measurement = result1.best_measurement
final_bitstrings = {state: probability for state, probability in eigenstate_distribution.items()}

all_bitstrings = {}
max_intermediate_index = -1

for index, data in enumerate(intermediate_data):
    print(f"Quasi Distribution: {data['quasi_distributions']}, Parameters: {data['parameters']}, Energy: {data['energy']}, Index: {index}")
    for distribution in data['quasi_distributions']:
        for int_bitstring, probability in distribution.items():
            intermediate_bitstring = int_to_bitstring(int_bitstring, num_qubits)
            if check_hamming(intermediate_bitstring, num_rot):
                if intermediate_bitstring not in all_bitstrings:
                    all_bitstrings[intermediate_bitstring] = {'probability': 0, 'energy': 0, 'count': 0, 'index': index}
                all_bitstrings[intermediate_bitstring]['probability'] += probability  # Aggregate probabilities
                energy = calculate_bitstring_energy(intermediate_bitstring, q_hamiltonian)
                all_bitstrings[intermediate_bitstring]['energy'] = (all_bitstrings[intermediate_bitstring]['energy'] * all_bitstrings[intermediate_bitstring]['count'] + energy) / (all_bitstrings[intermediate_bitstring]['count'] + 1)
                all_bitstrings[intermediate_bitstring]['count'] += 1
                if all_bitstrings[intermediate_bitstring]['count'] == 1:
                    all_bitstrings[intermediate_bitstring]['index'] = index
                if index > max_intermediate_index:
                    max_intermediate_index = index 

for state, prob in final_bitstrings.items():
    bitstring = int_to_bitstring(state, num_qubits)
    if check_hamming(bitstring, num_rot):
        if bitstring not in all_bitstrings:
            all_bitstrings[bitstring] = {'probability': 0, 'energy': 0, 'count': 0, 'index': max_intermediate_index+1}
        all_bitstrings[bitstring]['probability'] += prob  # Aggregate probabilities
        energy = calculate_bitstring_energy(bitstring, q_hamiltonian)
        all_bitstrings[bitstring]['energy'] = (all_bitstrings[bitstring]['energy'] * all_bitstrings[bitstring]['count'] + energy) / (all_bitstrings[bitstring]['count'] + 1)
        all_bitstrings[bitstring]['count'] += 1

total_bitstrings = sum(
    probability * options['shots']
    for data in intermediate_data
    for distribution in data['quasi_distributions']
    for int_bitstring, probability in distribution.items()
) + sum(probability * options['shots'] for state, probability in final_bitstrings.items()
)

hamming_satisfying_bitstrings = sum(bitstring_data['probability']* options['shots'] for bitstring_data in all_bitstrings.values())
fraction_satisfying_hamming = hamming_satisfying_bitstrings / total_bitstrings
print(f"Fraction of bitstrings that satisfy the Hamming constraint: {fraction_satisfying_hamming}")


sorted_bitstrings = sorted(all_bitstrings.items(), key=lambda x: x[1]['energy'])
# ground_state_repetition = sorted_bitstrings[0][1]['index']

print("Best Measurement:", best_measurement)
print("Sorted Bitstrings: ")
for bitstring, data in sorted_bitstrings:
    print(f"Bitstring: {bitstring}, Probability: {data['probability']}, Energy: {data['energy']}, Count: {data['count']}, Index: {data['index']}")

found = False
for bitstring, data in sorted_bitstrings:
    if bitstring == best_measurement['bitstring']:
        print('Best measurement bitstring respects Hammings conditions.\n')
        print('Ground state energy: ', data['energy']+k)
        data = {
            "Experiment": ["Aer Simulation XY QAOA"],
            "Ground State Energy": [np.real(result1.best_measurement['value'] + k)],
            "Best Measurement": [result1.best_measurement],
            "Execution Time (seconds)": [elapsed_time1],
            "Number of qubits": [num_qubits],
            "shots": [options['shots']],
            "Fraction": [fraction_satisfying_hamming],
            # "Iteration Ground State": [ground_state_repetition],
            "Sorted Bitstrings": [sorted_bitstrings],
            "Total Bitstrings": [total_bitstrings]
        }
        found = True
        break

if not found:
    print('Best measurement bitstring does not respect Hammings conditions, take the sorted bitstring corresponding to the smallest energy.\n')
    post_selected_bitstring, post_selected_energy = sorted_bitstrings[0]
    data = {
        "Experiment": ["Aer Simulation XY QAOA, post-selected"],
        "Ground State Energy": [post_selected_energy['energy'] + k],
        "Best Measurement": [post_selected_bitstring],
        "Execution Time (seconds)": [elapsed_time1],
        "Number of qubits": [num_qubits],
        "shots": [options['shots']],
        "Fraction": [fraction_satisfying_hamming],
        # "Iteration Ground State": [ground_state_repetition],
        "Sorted Bitstrings": [sorted_bitstrings],
        "Total Bitstrings": [total_bitstrings]
    }

df = pd.DataFrame(data)

if not os.path.isfile(file_path):
    # File does not exist, write with header
    df.to_csv(file_path, index=False)
else:
    # File exists, append without writing the header
    df.to_csv(file_path, mode='a', index=False, header=False)

 # %%
print("\n\nThe result of the noisy quantum optimisation using QAOA is: \n")
print('best measurement', result1.best_measurement)
print('Optimal parameters: ', result1.optimal_parameters)
print('The ground state energy with noisy QAOA is: ', np.real(result1.best_measurement['value'] + k))
elapsed_time1 = end_time1 - start_time1
print(f"Aer Simulator run time: {elapsed_time1} seconds")
print('\n\n')

data = {
    "Experiment": ["Aer Simulation XY QAOA"],
    "Ground State Energy": [np.real(result1.best_measurement['value'] + k)],
    "Best Measurement": [result1.best_measurement],
    "Execution Time (seconds)": [elapsed_time1],
    "Number of qubits": [num_qubits]
}

df = pd.DataFrame(data)
df.to_csv(file_path, index=False)

# %% ############################################# Hardware with QAOAAnastz ##################################################################
from qiskit.circuit.library import QAOAAnsatz
from qiskit_algorithms import SamplingVQE
from qiskit_ibm_runtime import QiskitRuntimeService, Session, Sampler
from qiskit import transpile, QuantumCircuit, QuantumRegister
from qiskit.transpiler import CouplingMap, Layout

service = QiskitRuntimeService()
backend = service.backend("ibm_torino")
print('Coupling Map of hardware: ', backend.configuration().coupling_map)

ansatz = QAOAAnsatz(q_hamiltonian, mixer_operator=XY_mixer, reps=p)
print('\n\nQAOAAnsatz: ', ansatz)

target = backend.target

# %%
filtered_coupling_map = [coupling for coupling in backend.configuration().coupling_map if coupling[0] < num_qubits and coupling[1] < num_qubits]

qr = QuantumRegister(num_qubits, 'q')
circuit = QuantumCircuit(qr)
trivial_layout = Layout({qr[i]: i for i in range(num_qubits)})
ansatz_isa = transpile(ansatz, backend=backend, initial_layout=trivial_layout, coupling_map=filtered_coupling_map,
                       optimization_level=3, layout_method='trivial', routing_method='stochastic')
print("\n\nAnsatz layout after explicit transpilation:", ansatz_isa._layout)

hamiltonian_isa = q_hamiltonian.apply_layout(ansatz_isa.layout)
print("\n\nAnsatz layout after transpilation:", hamiltonian_isa)
 
# %%
ansatz_isa.decompose().draw('mpl')

op_counts = ansatz_isa.count_ops()
total_gates = sum(op_counts.values())
depth = ansatz_isa.depth()
print("Operation counts:", op_counts)
print("Total number of gates:", total_gates)
print("Depth of the circuit: ", depth)

data_depth = {
    "Experiment": ["Hardware XY-QAOA"],
    "Total number of gates": [total_gates],
    "Depth of the circuit": [depth]
}

df_depth = pd.DataFrame(data_depth)
df_depth.to_csv(file_path_depth, index=False)

# %%
session = Session(backend=backend)
print('\nhere 1')
sampler = Sampler(backend=backend, session=session)
print('here 2')
qaoa2 = SamplingVQE(sampler=sampler, ansatz=ansatz_isa, optimizer=COBYLA(), initial_point=initial_point)
print('here 3')
result2 = qaoa2.compute_minimum_eigenvalue(hamiltonian_isa)

print("\n\nThe result of the noisy quantum optimisation using QAOAAnsatz is: \n")
print('best measurement', result2.best_measurement)
print('Optimal parameters: ', result2.optimal_parameters)
print('The ground state energy with noisy QAOA is: ', np.real(result2.best_measurement['value']))

# %%
jobs = service.jobs(session_id='crrdap27jqmg008z9m00')

for job in jobs:
    if job.status().name == 'DONE':
        results = job.result()
        print("Job completed successfully")
else:
    print("Job status:", job.status())

# %%
from qiskit.quantum_info import Statevector, Operator

def create_circuit(bitstring):
    """Create a quantum circuit that prepares the quantum state for a given bitstring."""
    qc = QuantumCircuit(len(bitstring))
    for i, bit in enumerate(bitstring):
        if bit == '1':
            qc.x(i)
    return qc

def evaluate_energy(bitstring, operator):
    """Evaluate the energy of a bitstring using the specified operator."""
    circuit = create_circuit(bitstring)
    state = Statevector.from_instruction(circuit)
    if not isinstance(operator, Operator):
        operator = Operator(operator)
    
    expectation_value = state.expectation_value(operator).real
    return expectation_value

def get_best_measurement_from_sampler_result(sampler_result, q_hamiltonian, num_qubits):
    if not hasattr(sampler_result, 'quasi_dists') or not isinstance(sampler_result.quasi_dists, list):
        raise ValueError("SamplerResult does not contain 'quasi_dists' as a list")

    best_bitstring = None
    lowest_energy = float('inf')
    highest_probability = -1

    for quasi_distribution in sampler_result.quasi_dists:
        for int_bitstring, probability in quasi_distribution.items():
            bitstring = format(int_bitstring, '0{}b'.format(num_qubits))  # Ensure bitstring is string
            energy = evaluate_energy(bitstring, q_hamiltonian)
            if energy < lowest_energy:
                lowest_energy = energy
                best_bitstring = bitstring
                highest_probability = probability

    return best_bitstring, highest_probability, lowest_energy


best_bitstring, probability, value = get_best_measurement_from_sampler_result(results, q_hamiltonian, num_qubits)
print(f"Best measurement: {best_bitstring} with ground state energy {value} and probability {probability}")

# %%
total_usage_time = 0
for job in jobs:
    job_result = job.usage_estimation['quantum_seconds']
    total_usage_time += job_result

print(f"Total Usage Time Hardware: {total_usage_time} seconds")
print('\n\n')

# %%
index = ansatz_isa.layout.final_index_layout() # Maps logical qubit index to its position in bitstring

# measured_bitstring = result2.best_measurement['bitstring']
measured_bitstring = best_bitstring
original_bitstring = ['']*num_qubits

for i, logical in enumerate(index):
        original_bitstring[i] = measured_bitstring[logical]

original_bitstring = ''.join(original_bitstring)
print("Original bitstring:", original_bitstring)

data = {
    "Experiment": ["Classical Optimisation", "Quantum Optimisation (QAOA)", "Noisy Quantum Optimisation (Aer Simulator)", "Quantum Optimisation (QAOAAnsatz)"],
    "Ground State Energy": [eigenvalues[0], result.optimal_value + k, np.real(result1.best_measurement['value'] + k), np.real(result2.best_measurement['value'])],
    "Best Measurement": ["N/A", result.optimal_parameters, result1.best_measurement, result2.best_measurement],
    "Optimal Parameters": ["N/A", "N/A", "N/A", result2.optimal_parameters],
    "Execution Time (seconds)": [elapsed_time, elapsed_time, elapsed_time1, total_usage_time],
    "Total Gates": ["N/A", "N/A", total_gates, total_gates],
    "Circuit Depth": ["N/A", "N/A", depth, depth]
}