def circuit_to_dag(circuit): """Build a ``DAGCircuit`` object from a ``QuantumCircuit``. Args: circuit (QuantumCircuit): the input circuit. Return: DAGCircuit: the DAG representing the input circuit. """ dagcircuit = DAGCircuit() dagcircuit.name = circuit.name for register in circuit.qregs: dagcircuit.add_qreg(register) for register in circuit.cregs: dagcircuit.add_creg(register) for main_instruction in circuit.data: # TODO: generate nodes for CompositeGates; # for now simply drop their instructions into the DAG instruction_list = [] is_composite = isinstance(main_instruction, CompositeGate) if is_composite: instruction_list = main_instruction.instruction_list() else: instruction_list.append(main_instruction) for instruction in instruction_list: # Get arguments for classical control (if any) if instruction.control is None: control = None else: control = (instruction.control[0], instruction.control[1]) def duplicate_instruction(inst): """Create a fresh instruction from an input instruction.""" if inst.name == 'barrier': params = [inst.qargs] elif inst.name == 'snapshot': params = inst.params + [inst.qargs] else: params = inst.params + inst.qargs + inst.cargs new_inst = inst.__class__(*params) return new_inst inst = duplicate_instruction(instruction) dagcircuit.apply_operation_back(inst, inst.qargs, inst.cargs, control) return dagcircuit
def circuit_to_dag(circuit): """Build a ``DAGCircuit`` object from a ``QuantumCircuit``. Args: circuit (QuantumCircuit): the input circuit. Return: DAGCircuit: the DAG representing the input circuit. """ dagcircuit = DAGCircuit() dagcircuit.name = circuit.name for register in circuit.qregs: dagcircuit.add_qreg(register) for register in circuit.cregs: dagcircuit.add_creg(register) # Add user gate definitions for name, data in circuit.definitions.items(): dagcircuit.add_basis_element(name, data["n_bits"], 0, data["n_args"]) dagcircuit.add_gate_data(name, data) # Add instructions builtins = { "U": ["U", 1, 0, 3], "CX": ["CX", 2, 0, 0], "measure": ["measure", 1, 1, 0], "reset": ["reset", 1, 0, 0], "barrier": ["barrier", -1, 0, 0] } # Add simulator instructions simulator_instructions = { "snapshot": ["snapshot", -1, 0, 1], "save": ["save", -1, 0, 1], "load": ["load", -1, 0, 1], "noise": ["noise", -1, 0, 1] } for main_instruction in circuit.data: # TODO: generate definitions and nodes for CompositeGates, # for now simply drop their instructions into the DAG instruction_list = [] is_composite = isinstance(main_instruction, CompositeGate) if is_composite: instruction_list = main_instruction.instruction_list() else: instruction_list.append(main_instruction) for instruction in instruction_list: # Add OpenQASM built-in gates on demand if instruction.name in builtins: dagcircuit.add_basis_element(*builtins[instruction.name]) # Add simulator extension instructions if instruction.name in simulator_instructions: dagcircuit.add_basis_element( *simulator_instructions[instruction.name]) # Get arguments for classical control (if any) if instruction.control is None: control = None else: control = (instruction.control[0], instruction.control[1]) def duplicate_instruction(inst): """Create a fresh instruction from an input instruction.""" if inst.name == 'barrier': params = [inst.qargs] elif inst.name in simulator_instructions.keys(): params = inst.params + [inst.qargs] + [inst.circuit] else: params = inst.params + inst.qargs + inst.cargs new_inst = inst.__class__(*params) return new_inst inst = duplicate_instruction(instruction) dagcircuit.apply_operation_back(inst, inst.qargs, inst.cargs, control) return dagcircuit
def circuit_to_dag(circuit, expand_gates=True): """Build a ``DAGCircuit`` object from a ``QuantumCircuit``. Args: circuit (QuantumCircuit): the input circuit. expand_gates (bool): if ``False``, none of the gates are expanded, i.e. the gates that are defined in the circuit are included in the DAG basis. Return: DAGCircuit: the DAG representing the input circuit. """ circuit = copy.deepcopy(circuit) dagcircuit = DAGCircuit() dagcircuit.name = circuit.name for register in circuit.qregs: dagcircuit.add_qreg(register) for register in circuit.cregs: dagcircuit.add_creg(register) # Add user gate definitions for name, data in circuit.definitions.items(): dagcircuit.add_basis_element(name, data["n_bits"], 0, data["n_args"]) dagcircuit.add_gate_data(name, data) # Add instructions builtins = { "U": ["U", 1, 0, 3], "CX": ["CX", 2, 0, 0], "measure": ["measure", 1, 1, 0], "reset": ["reset", 1, 0, 0], "barrier": ["barrier", -1, 0, 0] } # Add simulator instructions simulator_instructions = { "snapshot": ["snapshot", -1, 0, 1], "save": ["save", -1, 0, 1], "load": ["load", -1, 0, 1], "noise": ["noise", -1, 0, 1] } for main_instruction in circuit.data: # TODO: generate definitions and nodes for CompositeGates, # for now simply drop their instructions into the DAG instruction_list = [] is_composite = isinstance(main_instruction, CompositeGate) if is_composite and expand_gates: instruction_list = main_instruction.instruction_list() else: instruction_list.append(main_instruction) for instruction in instruction_list: # Add OpenQASM built-in gates on demand if instruction.name in builtins: dagcircuit.add_basis_element(*builtins[instruction.name]) # Add simulator extension instructions if instruction.name in simulator_instructions: dagcircuit.add_basis_element( *simulator_instructions[instruction.name]) # Get arguments for classical control (if any) if instruction.control is None: control = None else: control = (instruction.control[0], instruction.control[1]) dagcircuit.apply_operation_back(instruction, instruction.qargs, instruction.cargs, control) return dagcircuit