Exemple #1
0
def level_3_pass_manager(pass_manager_config: PassManagerConfig) -> PassManager:
    """Level 3 pass manager: heavy optimization by noise adaptive qubit mapping and
    gate cancellation using commutativity rules and unitary synthesis.

    This pass manager applies the user-given initial layout. If none is given, a search
    for a perfect layout (i.e. one that satisfies all 2-qubit interactions) is conducted.
    If no such layout is found, and device calibration information is available, the
    circuit is mapped to the qubits with best readouts and to CX gates with highest fidelity.

    The pass manager then transforms the circuit to match the coupling constraints.
    It is then unrolled to the basis, and any flipped cx directions are fixed.
    Finally, optimizations in the form of commutative gate cancellation, resynthesis
    of two-qubit unitary blocks, and redundant reset removal are performed.

    Note:
        In simulators where ``coupling_map=None``, only the unrolling and
        optimization stages are done.

    Args:
        pass_manager_config: configuration of the pass manager.

    Returns:
        a level 3 pass manager.

    Raises:
        TranspilerError: if the passmanager config is invalid.
    """
    basis_gates = pass_manager_config.basis_gates
    inst_map = pass_manager_config.inst_map
    coupling_map = pass_manager_config.coupling_map
    initial_layout = pass_manager_config.initial_layout
    layout_method = pass_manager_config.layout_method or "sabre"
    routing_method = pass_manager_config.routing_method or "sabre"
    translation_method = pass_manager_config.translation_method or "translator"
    scheduling_method = pass_manager_config.scheduling_method
    instruction_durations = pass_manager_config.instruction_durations
    seed_transpiler = pass_manager_config.seed_transpiler
    backend_properties = pass_manager_config.backend_properties
    approximation_degree = pass_manager_config.approximation_degree
    unitary_synthesis_method = pass_manager_config.unitary_synthesis_method
    timing_constraints = pass_manager_config.timing_constraints or TimingConstraints()
    unitary_synthesis_plugin_config = pass_manager_config.unitary_synthesis_plugin_config
    target = pass_manager_config.target

    # 1. Unroll to 1q or 2q gates
    _unroll3q = [
        # Use unitary synthesis for basis aware decomposition of UnitaryGates
        UnitarySynthesis(
            basis_gates,
            approximation_degree=approximation_degree,
            method=unitary_synthesis_method,
            plugin_config=unitary_synthesis_plugin_config,
            min_qubits=3,
        ),
        Unroll3qOrMore(),
    ]

    # 2. Layout on good qubits if calibration info available, otherwise on dense links
    _given_layout = SetLayout(initial_layout)

    def _choose_layout_condition(property_set):
        # layout hasn't been set yet
        return not property_set["layout"]

    def _csp_not_found_match(property_set):
        # If a layout hasn't been set by the time we run csp we need to run layout
        if property_set["layout"] is None:
            return True
        # if CSP layout stopped for any reason other than solution found we need
        # to run layout since CSP didn't converge.
        if (
            property_set["CSPLayout_stop_reason"] is not None
            and property_set["CSPLayout_stop_reason"] != "solution found"
        ):
            return True
        return False

    # 2a. If layout method is not set, first try a trivial layout
    _choose_layout_0 = (
        []
        if pass_manager_config.layout_method
        else [
            TrivialLayout(coupling_map),
            Layout2qDistance(coupling_map, property_name="trivial_layout_score"),
        ]
    )
    # 2b. If trivial layout wasn't perfect (ie no swaps are needed) then try
    # using CSP layout to find a perfect layout
    _choose_layout_1 = (
        []
        if pass_manager_config.layout_method
        else CSPLayout(coupling_map, call_limit=10000, time_limit=60, seed=seed_transpiler)
    )

    def _trivial_not_perfect(property_set):
        # Verify that a trivial layout  is perfect. If trivial_layout_score > 0
        # the layout is not perfect. The layout property set is unconditionally
        # set by trivial layout so we clear that before running CSP
        if property_set["trivial_layout_score"] is not None:
            if property_set["trivial_layout_score"] != 0:
                return True
        return False

    # 2c. if CSP didn't converge on a solution use layout_method (dense).
    if layout_method == "trivial":
        _choose_layout_2 = TrivialLayout(coupling_map)
    elif layout_method == "dense":
        _choose_layout_2 = DenseLayout(coupling_map, backend_properties)
    elif layout_method == "noise_adaptive":
        _choose_layout_2 = NoiseAdaptiveLayout(backend_properties)
    elif layout_method == "sabre":
        _choose_layout_2 = SabreLayout(coupling_map, max_iterations=4, seed=seed_transpiler)
    else:
        raise TranspilerError("Invalid layout method %s." % layout_method)

    # 3. Extend dag/layout with ancillas using the full coupling map
    _embed = [FullAncillaAllocation(coupling_map), EnlargeWithAncilla(), ApplyLayout()]

    # 4. Swap to fit the coupling map
    _swap_check = CheckMap(coupling_map)

    def _swap_condition(property_set):
        return not property_set["is_swap_mapped"]

    _swap = [BarrierBeforeFinalMeasurements()]
    if routing_method == "basic":
        _swap += [BasicSwap(coupling_map)]
    elif routing_method == "stochastic":
        _swap += [StochasticSwap(coupling_map, trials=200, seed=seed_transpiler)]
    elif routing_method == "lookahead":
        _swap += [LookaheadSwap(coupling_map, search_depth=5, search_width=6)]
    elif routing_method == "sabre":
        _swap += [SabreSwap(coupling_map, heuristic="decay", seed=seed_transpiler)]
    elif routing_method == "none":
        _swap += [
            Error(
                msg=(
                    "No routing method selected, but circuit is not routed to device. "
                    "CheckMap Error: {check_map_msg}"
                ),
                action="raise",
            )
        ]
    else:
        raise TranspilerError("Invalid routing method %s." % routing_method)

    # 5. Unroll to the basis
    if translation_method == "unroller":
        _unroll = [Unroller(basis_gates)]
    elif translation_method == "translator":
        from qiskit.circuit.equivalence_library import SessionEquivalenceLibrary as sel

        _unroll = [
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                plugin_config=unitary_synthesis_plugin_config,
                method=unitary_synthesis_method,
            ),
            UnrollCustomDefinitions(sel, basis_gates),
            BasisTranslator(sel, basis_gates, target),
        ]
    elif translation_method == "synthesis":
        _unroll = [
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
                plugin_config=unitary_synthesis_plugin_config,
                min_qubits=3,
            ),
            Unroll3qOrMore(),
            Collect2qBlocks(),
            ConsolidateBlocks(basis_gates=basis_gates),
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
                plugin_config=unitary_synthesis_plugin_config,
            ),
        ]
    else:
        raise TranspilerError("Invalid translation method %s." % translation_method)

    # 6. Fix any CX direction mismatch
    _direction_check = [CheckGateDirection(coupling_map, target)]

    def _direction_condition(property_set):
        return not property_set["is_direction_mapped"]

    _direction = [GateDirection(coupling_map, target)]

    # 8. Optimize iteratively until no more change in depth. Removes useless gates
    # after reset and before measure, commutes gates and optimizes contiguous blocks.
    _depth_check = [Depth(), FixedPoint("depth")]

    def _opt_control(property_set):
        return not property_set["depth_fixed_point"]

    _reset = [RemoveResetInZeroState()]

    _meas = [OptimizeSwapBeforeMeasure(), RemoveDiagonalGatesBeforeMeasure()]

    _opt = [
        Collect2qBlocks(),
        ConsolidateBlocks(basis_gates=basis_gates),
        UnitarySynthesis(
            basis_gates,
            approximation_degree=approximation_degree,
            coupling_map=coupling_map,
            backend_props=backend_properties,
            method=unitary_synthesis_method,
            plugin_config=unitary_synthesis_plugin_config,
        ),
        Optimize1qGatesDecomposition(basis_gates),
        CommutativeCancellation(),
    ]

    # 9. Unify all durations (either SI, or convert to dt if known)
    # Schedule the circuit only when scheduling_method is supplied
    _time_unit_setup = [ContainsInstruction("delay")]
    _time_unit_conversion = [TimeUnitConversion(instruction_durations)]

    def _contains_delay(property_set):
        return property_set["contains_delay"]

    _scheduling = []
    if scheduling_method:
        _scheduling += _time_unit_conversion
        if scheduling_method in {"alap", "as_late_as_possible"}:
            _scheduling += [ALAPSchedule(instruction_durations)]
        elif scheduling_method in {"asap", "as_soon_as_possible"}:
            _scheduling += [ASAPSchedule(instruction_durations)]
        else:
            raise TranspilerError("Invalid scheduling method %s." % scheduling_method)

    # 10. Call measure alignment. Should come after scheduling.
    if (
        timing_constraints.granularity != 1
        or timing_constraints.min_length != 1
        or timing_constraints.acquire_alignment != 1
    ):
        _alignments = [
            ValidatePulseGates(
                granularity=timing_constraints.granularity, min_length=timing_constraints.min_length
            ),
            AlignMeasures(alignment=timing_constraints.acquire_alignment),
        ]
    else:
        _alignments = []

    # Build pass manager
    pm3 = PassManager()
    pm3.append(_unroll3q)
    pm3.append(_reset + _meas)
    if coupling_map or initial_layout:
        pm3.append(_given_layout)
        pm3.append(_choose_layout_0, condition=_choose_layout_condition)
        pm3.append(_choose_layout_1, condition=_trivial_not_perfect)
        pm3.append(_choose_layout_2, condition=_csp_not_found_match)
        pm3.append(_embed)
        pm3.append(_swap_check)
        pm3.append(_swap, condition=_swap_condition)
    pm3.append(_unroll)
    if (coupling_map and not coupling_map.is_symmetric) or (
        target is not None and target.get_non_global_operation_names(strict_direction=True)
    ):
        pm3.append(_direction_check)
        pm3.append(_direction, condition=_direction_condition)
        pm3.append(_reset)
        # For transpiling to a target we need to run GateDirection in the
        # optimization loop to correct for incorrect directions that might be
        # inserted by UnitarySynthesis which is direction aware but only via
        # the coupling map which with a target doesn't give a full picture
        if target is not None:
            pm3.append(_depth_check + _opt + _unroll + _direction, do_while=_opt_control)
        else:
            pm3.append(_depth_check + _opt + _unroll, do_while=_opt_control)
    else:
        pm3.append(_reset)
        pm3.append(_depth_check + _opt + _unroll, do_while=_opt_control)
    if inst_map and inst_map.has_custom_gate():
        pm3.append(PulseGates(inst_map=inst_map))
    if scheduling_method:
        pm3.append(_scheduling)
    elif instruction_durations:
        pm3.append(_time_unit_setup)
        pm3.append(_time_unit_conversion, condition=_contains_delay)
    pm3.append(_alignments)

    return pm3
Exemple #2
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def level_1_pass_manager(
        pass_manager_config: PassManagerConfig) -> PassManager:
    """Level 1 pass manager: light optimization by simple adjacent gate collapsing.

    This pass manager applies the user-given initial layout. If none is given,
    and a trivial layout (i-th virtual -> i-th physical) makes the circuit fit
    the coupling map, that is used.
    Otherwise, the circuit is mapped to the most densely connected coupling subgraph,
    and swaps are inserted to map. Any unused physical qubit is allocated as ancilla space.
    The pass manager then unrolls the circuit to the desired basis, and transforms the
    circuit to match the coupling map. Finally, optimizations in the form of adjacent
    gate collapse and redundant reset removal are performed.

    Note:
        In simulators where ``coupling_map=None``, only the unrolling and
        optimization stages are done.

    Args:
        pass_manager_config: configuration of the pass manager.

    Returns:
        a level 1 pass manager.

    Raises:
        TranspilerError: if the passmanager config is invalid.
    """
    basis_gates = pass_manager_config.basis_gates
    inst_map = pass_manager_config.inst_map
    coupling_map = pass_manager_config.coupling_map
    initial_layout = pass_manager_config.initial_layout
    layout_method = pass_manager_config.layout_method or "dense"
    routing_method = pass_manager_config.routing_method or "stochastic"
    translation_method = pass_manager_config.translation_method or "translator"
    scheduling_method = pass_manager_config.scheduling_method
    instruction_durations = pass_manager_config.instruction_durations
    seed_transpiler = pass_manager_config.seed_transpiler
    backend_properties = pass_manager_config.backend_properties
    approximation_degree = pass_manager_config.approximation_degree
    unitary_synthesis_method = pass_manager_config.unitary_synthesis_method
    unitary_synthesis_plugin_config = pass_manager_config.unitary_synthesis_plugin_config
    timing_constraints = pass_manager_config.timing_constraints or TimingConstraints(
    )
    target = pass_manager_config.target

    # 1. Use trivial layout if no layout given
    _given_layout = SetLayout(initial_layout)

    _choose_layout_and_score = [
        TrivialLayout(coupling_map),
        Layout2qDistance(coupling_map, property_name="trivial_layout_score"),
    ]

    def _choose_layout_condition(property_set):
        return not property_set["layout"]

    # 2. Decompose so only 1-qubit and 2-qubit gates remain
    _unroll3q = [
        # Use unitary synthesis for basis aware decomposition of UnitaryGates
        UnitarySynthesis(
            basis_gates,
            approximation_degree=approximation_degree,
            method=unitary_synthesis_method,
            min_qubits=3,
            plugin_config=unitary_synthesis_plugin_config,
        ),
        Unroll3qOrMore(),
    ]

    # 3. Use a better layout on densely connected qubits, if circuit needs swaps
    if layout_method == "trivial":
        _improve_layout = TrivialLayout(coupling_map)
    elif layout_method == "dense":
        _improve_layout = DenseLayout(coupling_map, backend_properties)
    elif layout_method == "noise_adaptive":
        _improve_layout = NoiseAdaptiveLayout(backend_properties)
    elif layout_method == "sabre":
        _improve_layout = SabreLayout(coupling_map,
                                      max_iterations=2,
                                      seed=seed_transpiler)
    else:
        raise TranspilerError("Invalid layout method %s." % layout_method)

    def _not_perfect_yet(property_set):
        return (property_set["trivial_layout_score"] is not None
                and property_set["trivial_layout_score"] != 0)

    # 4. Extend dag/layout with ancillas using the full coupling map
    _embed = [
        FullAncillaAllocation(coupling_map),
        EnlargeWithAncilla(),
        ApplyLayout()
    ]

    # 5. Swap to fit the coupling map
    _swap_check = CheckMap(coupling_map)

    def _swap_condition(property_set):
        return not property_set["is_swap_mapped"]

    _swap = [BarrierBeforeFinalMeasurements()]
    if routing_method == "basic":
        _swap += [BasicSwap(coupling_map)]
    elif routing_method == "stochastic":
        _swap += [
            StochasticSwap(coupling_map, trials=20, seed=seed_transpiler)
        ]
    elif routing_method == "lookahead":
        _swap += [LookaheadSwap(coupling_map, search_depth=4, search_width=4)]
    elif routing_method == "sabre":
        _swap += [
            SabreSwap(coupling_map,
                      heuristic="lookahead",
                      seed=seed_transpiler)
        ]
    elif routing_method == "none":
        _swap += [
            Error(
                msg=
                ("No routing method selected, but circuit is not routed to device. "
                 "CheckMap Error: {check_map_msg}"),
                action="raise",
            )
        ]
    else:
        raise TranspilerError("Invalid routing method %s." % routing_method)

    # 6. Unroll to the basis
    if translation_method == "unroller":
        _unroll = [Unroller(basis_gates)]
    elif translation_method == "translator":
        from qiskit.circuit.equivalence_library import SessionEquivalenceLibrary as sel

        _unroll = [
            # Use unitary synthesis for basis aware decomposition of UnitaryGates before
            # custom unrolling
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                method=unitary_synthesis_method,
                backend_props=backend_properties,
                plugin_config=unitary_synthesis_plugin_config,
            ),
            UnrollCustomDefinitions(sel, basis_gates),
            BasisTranslator(sel, basis_gates, target),
        ]
    elif translation_method == "synthesis":
        _unroll = [
            # Use unitary synthesis for basis aware decomposition of UnitaryGates before
            # collection
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                method=unitary_synthesis_method,
                backend_props=backend_properties,
                min_qubits=3,
            ),
            Unroll3qOrMore(),
            Collect2qBlocks(),
            ConsolidateBlocks(basis_gates=basis_gates),
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                method=unitary_synthesis_method,
                backend_props=backend_properties,
                plugin_config=unitary_synthesis_plugin_config,
            ),
        ]
    else:
        raise TranspilerError("Invalid translation method %s." %
                              translation_method)

    # 7. Fix any bad CX directions
    _direction_check = [CheckGateDirection(coupling_map, target)]

    def _direction_condition(property_set):
        return not property_set["is_direction_mapped"]

    _direction = [GateDirection(coupling_map, target)]

    # 8. Remove zero-state reset
    _reset = RemoveResetInZeroState()

    # 9. Merge 1q rotations and cancel CNOT gates iteratively until no more change in depth
    _depth_check = [Depth(), FixedPoint("depth")]

    def _opt_control(property_set):
        return not property_set["depth_fixed_point"]

    _opt = [Optimize1qGatesDecomposition(basis_gates), CXCancellation()]

    # 10. Unify all durations (either SI, or convert to dt if known)
    # Schedule the circuit only when scheduling_method is supplied
    _time_unit_setup = [ContainsInstruction("delay")]
    _time_unit_conversion = [TimeUnitConversion(instruction_durations)]

    def _contains_delay(property_set):
        return property_set["contains_delay"]

    _scheduling = []
    if scheduling_method:
        _scheduling += _time_unit_conversion
        if scheduling_method in {"alap", "as_late_as_possible"}:
            _scheduling += [ALAPSchedule(instruction_durations)]
        elif scheduling_method in {"asap", "as_soon_as_possible"}:
            _scheduling += [ASAPSchedule(instruction_durations)]
        else:
            raise TranspilerError("Invalid scheduling method %s." %
                                  scheduling_method)

    # 11. Call measure alignment. Should come after scheduling.
    if (timing_constraints.granularity != 1
            or timing_constraints.min_length != 1
            or timing_constraints.acquire_alignment != 1):
        _alignments = [
            ValidatePulseGates(granularity=timing_constraints.granularity,
                               min_length=timing_constraints.min_length),
            AlignMeasures(alignment=timing_constraints.acquire_alignment),
        ]
    else:
        _alignments = []

    # Build pass manager
    pm1 = PassManager()
    if coupling_map or initial_layout:
        pm1.append(_given_layout)
        pm1.append(_unroll3q)
        pm1.append(_choose_layout_and_score,
                   condition=_choose_layout_condition)
        pm1.append(_improve_layout, condition=_not_perfect_yet)
        pm1.append(_embed)
        pm1.append(_swap_check)
        pm1.append(_swap, condition=_swap_condition)
    pm1.append(_unroll)
    if (coupling_map and not coupling_map.is_symmetric) or (
            target is not None
            and target.get_non_global_operation_names(strict_direction=True)):
        pm1.append(_direction_check)
        pm1.append(_direction, condition=_direction_condition)
    pm1.append(_reset)
    pm1.append(_depth_check + _opt + _unroll, do_while=_opt_control)
    if inst_map and inst_map.has_custom_gate():
        pm1.append(PulseGates(inst_map=inst_map))
    if scheduling_method:
        pm1.append(_scheduling)
    elif instruction_durations:
        pm1.append(_time_unit_setup)
        pm1.append(_time_unit_conversion, condition=_contains_delay)
    pm1.append(_alignments)

    return pm1
Exemple #3
0
def level_0_pass_manager(
        pass_manager_config: PassManagerConfig) -> PassManager:
    """Level 0 pass manager: no explicit optimization other than mapping to backend.

    This pass manager applies the user-given initial layout. If none is given, a trivial
    layout consisting of mapping the i-th virtual qubit to the i-th physical qubit is used.
    Any unused physical qubit is allocated as ancilla space.

    The pass manager then unrolls the circuit to the desired basis, and transforms the
    circuit to match the coupling map.

    Note:
        In simulators where ``coupling_map=None``, only the unrolling and
        optimization stages are done.

    Args:
        pass_manager_config: configuration of the pass manager.

    Returns:
        a level 0 pass manager.

    Raises:
        TranspilerError: if the passmanager config is invalid.
    """
    basis_gates = pass_manager_config.basis_gates
    inst_map = pass_manager_config.inst_map
    coupling_map = pass_manager_config.coupling_map
    initial_layout = pass_manager_config.initial_layout
    layout_method = pass_manager_config.layout_method or "trivial"
    routing_method = pass_manager_config.routing_method or "stochastic"
    translation_method = pass_manager_config.translation_method or "translator"
    scheduling_method = pass_manager_config.scheduling_method
    instruction_durations = pass_manager_config.instruction_durations
    seed_transpiler = pass_manager_config.seed_transpiler
    backend_properties = pass_manager_config.backend_properties
    approximation_degree = pass_manager_config.approximation_degree
    timing_constraints = pass_manager_config.timing_constraints or TimingConstraints(
    )
    unitary_synthesis_method = pass_manager_config.unitary_synthesis_method
    unitary_synthesis_plugin_config = pass_manager_config.unitary_synthesis_plugin_config
    target = pass_manager_config.target

    # 1. Decompose so only 1-qubit and 2-qubit gates remain
    _unroll3q = [
        # Use unitary synthesis for basis aware decomposition of UnitaryGates
        UnitarySynthesis(
            basis_gates,
            approximation_degree=approximation_degree,
            method=unitary_synthesis_method,
            min_qubits=3,
            plugin_config=unitary_synthesis_plugin_config,
        ),
        Unroll3qOrMore(),
    ]

    # 2. Choose an initial layout if not set by user (default: trivial layout)
    _given_layout = SetLayout(initial_layout)

    def _choose_layout_condition(property_set):
        return not property_set["layout"]

    if layout_method == "trivial":
        _choose_layout = TrivialLayout(coupling_map)
    elif layout_method == "dense":
        _choose_layout = DenseLayout(coupling_map, backend_properties)
    elif layout_method == "noise_adaptive":
        _choose_layout = NoiseAdaptiveLayout(backend_properties)
    elif layout_method == "sabre":
        _choose_layout = SabreLayout(coupling_map,
                                     max_iterations=1,
                                     seed=seed_transpiler)
    else:
        raise TranspilerError("Invalid layout method %s." % layout_method)

    # 3. Extend dag/layout with ancillas using the full coupling map
    _embed = [
        FullAncillaAllocation(coupling_map),
        EnlargeWithAncilla(),
        ApplyLayout()
    ]

    # 4. Swap to fit the coupling map
    _swap_check = CheckMap(coupling_map)

    def _swap_condition(property_set):
        return not property_set["is_swap_mapped"]

    _swap = [BarrierBeforeFinalMeasurements()]
    if routing_method == "basic":
        _swap += [BasicSwap(coupling_map)]
    elif routing_method == "stochastic":
        _swap += [
            StochasticSwap(coupling_map, trials=20, seed=seed_transpiler)
        ]
    elif routing_method == "lookahead":
        _swap += [LookaheadSwap(coupling_map, search_depth=2, search_width=2)]
    elif routing_method == "sabre":
        _swap += [
            SabreSwap(coupling_map, heuristic="basic", seed=seed_transpiler)
        ]
    elif routing_method == "none":
        _swap += [
            Error(
                msg=
                ("No routing method selected, but circuit is not routed to device. "
                 "CheckMap Error: {check_map_msg}"),
                action="raise",
            )
        ]
    else:
        raise TranspilerError("Invalid routing method %s." % routing_method)

    # 5. Unroll to the basis
    if translation_method == "unroller":
        _unroll = [Unroller(basis_gates)]
    elif translation_method == "translator":
        from qiskit.circuit.equivalence_library import SessionEquivalenceLibrary as sel

        _unroll = [
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
                plugin_config=unitary_synthesis_plugin_config,
            ),
            UnrollCustomDefinitions(sel, basis_gates),
            BasisTranslator(sel, basis_gates, target),
        ]
    elif translation_method == "synthesis":
        _unroll = [
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
                min_qubits=3,
                plugin_config=unitary_synthesis_plugin_config,
            ),
            Unroll3qOrMore(),
            Collect2qBlocks(),
            Collect1qRuns(),
            ConsolidateBlocks(basis_gates=basis_gates),
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
                plugin_config=unitary_synthesis_plugin_config,
            ),
        ]
    else:
        raise TranspilerError("Invalid translation method %s." %
                              translation_method)

    # 6. Fix any bad CX directions
    _direction_check = [CheckGateDirection(coupling_map, target)]

    def _direction_condition(property_set):
        return not property_set["is_direction_mapped"]

    _direction = [GateDirection(coupling_map, target)]

    # 7. Unify all durations (either SI, or convert to dt if known)
    # Schedule the circuit only when scheduling_method is supplied
    _time_unit_setup = [ContainsInstruction("delay")]
    _time_unit_conversion = [TimeUnitConversion(instruction_durations)]

    def _contains_delay(property_set):
        return property_set["contains_delay"]

    _scheduling = []
    if scheduling_method:
        _scheduling += _time_unit_conversion
        if scheduling_method in {"alap", "as_late_as_possible"}:
            _scheduling += [ALAPSchedule(instruction_durations)]
        elif scheduling_method in {"asap", "as_soon_as_possible"}:
            _scheduling += [ASAPSchedule(instruction_durations)]
        else:
            raise TranspilerError("Invalid scheduling method %s." %
                                  scheduling_method)

    # 8. Call measure alignment. Should come after scheduling.
    if (timing_constraints.granularity != 1
            or timing_constraints.min_length != 1
            or timing_constraints.acquire_alignment != 1):
        _alignments = [
            ValidatePulseGates(granularity=timing_constraints.granularity,
                               min_length=timing_constraints.min_length),
            AlignMeasures(alignment=timing_constraints.acquire_alignment),
        ]
    else:
        _alignments = []

    # Build pass manager
    pm0 = PassManager()
    if coupling_map or initial_layout:
        pm0.append(_given_layout)
        pm0.append(_unroll3q)
        pm0.append(_choose_layout, condition=_choose_layout_condition)
        pm0.append(_embed)
        pm0.append(_swap_check)
        pm0.append(_swap, condition=_swap_condition)
    pm0.append(_unroll)
    if (coupling_map and not coupling_map.is_symmetric) or (
            target is not None
            and target.get_non_global_operation_names(strict_direction=True)):
        pm0.append(_direction_check)
        pm0.append(_direction, condition=_direction_condition)
        pm0.append(_unroll)
    if inst_map and inst_map.has_custom_gate():
        pm0.append(PulseGates(inst_map=inst_map))
    if scheduling_method:
        pm0.append(_scheduling)
    elif instruction_durations:
        pm0.append(_time_unit_setup)
        pm0.append(_time_unit_conversion, condition=_contains_delay)
    pm0.append(_alignments)
    return pm0
Exemple #4
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def level_2_pass_manager(
        pass_manager_config: PassManagerConfig) -> PassManager:
    """Level 2 pass manager: medium optimization by initial layout selection and
    gate cancellation using commutativity rules.

    This pass manager applies the user-given initial layout. If none is given, a search
    for a perfect layout (i.e. one that satisfies all 2-qubit interactions) is conducted.
    If no such layout is found, qubits are laid out on the most densely connected subset
    which also exhibits the best gate fidelities.

    The pass manager then transforms the circuit to match the coupling constraints.
    It is then unrolled to the basis, and any flipped cx directions are fixed.
    Finally, optimizations in the form of commutative gate cancellation and redundant
    reset removal are performed.

    Note:
        In simulators where ``coupling_map=None``, only the unrolling and
        optimization stages are done.

    Args:
        pass_manager_config: configuration of the pass manager.

    Returns:
        a level 2 pass manager.

    Raises:
        TranspilerError: if the passmanager config is invalid.
    """
    basis_gates = pass_manager_config.basis_gates
    inst_map = pass_manager_config.inst_map
    coupling_map = pass_manager_config.coupling_map
    initial_layout = pass_manager_config.initial_layout
    layout_method = pass_manager_config.layout_method or "dense"
    routing_method = pass_manager_config.routing_method or "stochastic"
    translation_method = pass_manager_config.translation_method or "translator"
    scheduling_method = pass_manager_config.scheduling_method
    instruction_durations = pass_manager_config.instruction_durations
    seed_transpiler = pass_manager_config.seed_transpiler
    backend_properties = pass_manager_config.backend_properties
    approximation_degree = pass_manager_config.approximation_degree
    unitary_synthesis_method = pass_manager_config.unitary_synthesis_method
    timing_constraints = pass_manager_config.timing_constraints or TimingConstraints(
    )

    # 1. Search for a perfect layout, or choose a dense layout, if no layout given
    _given_layout = SetLayout(initial_layout)

    def _choose_layout_condition(property_set):
        # layout hasn't been set yet
        return not property_set["layout"]

    # 1a. If layout_method is not set, first try a trivial layout
    _choose_layout_0 = ([] if pass_manager_config.layout_method else [
        TrivialLayout(coupling_map),
        Layout2qDistance(coupling_map, property_name="trivial_layout_score"),
    ])
    # 1b. If a trivial layout wasn't perfect (ie no swaps are needed) then try using
    # CSP layout to find a perfect layout
    _choose_layout_1 = ([] if pass_manager_config.layout_method else CSPLayout(
        coupling_map, call_limit=1000, time_limit=10, seed=seed_transpiler))

    def _trivial_not_perfect(property_set):
        # Verify that a trivial layout  is perfect. If trivial_layout_score > 0
        # the layout is not perfect. The layout is unconditionally set by trivial
        # layout so we need to clear it before contuing.
        if property_set["trivial_layout_score"] is not None:
            if property_set["trivial_layout_score"] != 0:
                property_set["layout"]._wrapped = None
                return True
        return False

    def _csp_not_found_match(property_set):
        # If a layout hasn't been set by the time we run csp we need to run layout
        if property_set["layout"] is None:
            return True
        # if CSP layout stopped for any reason other than solution found we need
        # to run layout since CSP didn't converge.
        if (property_set["CSPLayout_stop_reason"] is not None
                and property_set["CSPLayout_stop_reason"] != "solution found"):
            return True
        return False

    # 1c. if CSP layout doesn't converge on a solution use layout_method (dense) to get a layout
    if layout_method == "trivial":
        _choose_layout_2 = TrivialLayout(coupling_map)
    elif layout_method == "dense":
        _choose_layout_2 = DenseLayout(coupling_map, backend_properties)
    elif layout_method == "noise_adaptive":
        _choose_layout_2 = NoiseAdaptiveLayout(backend_properties)
    elif layout_method == "sabre":
        _choose_layout_2 = SabreLayout(coupling_map,
                                       max_iterations=2,
                                       seed=seed_transpiler)
    else:
        raise TranspilerError("Invalid layout method %s." % layout_method)

    # 2. Extend dag/layout with ancillas using the full coupling map
    _embed = [
        FullAncillaAllocation(coupling_map),
        EnlargeWithAncilla(),
        ApplyLayout()
    ]

    # 3. Unroll to 1q or 2q gates
    _unroll3q = [
        # Use unitary synthesis for basis aware decomposition of UnitaryGates
        UnitarySynthesis(
            basis_gates,
            approximation_degree=approximation_degree,
            coupling_map=coupling_map,
            backend_props=backend_properties,
            method=unitary_synthesis_method,
            min_qubits=3,
        ),
        Unroll3qOrMore(),
    ]

    # 4. Swap to fit the coupling map
    _swap_check = CheckMap(coupling_map)

    def _swap_condition(property_set):
        return not property_set["is_swap_mapped"]

    _swap = [BarrierBeforeFinalMeasurements()]
    if routing_method == "basic":
        _swap += [BasicSwap(coupling_map)]
    elif routing_method == "stochastic":
        _swap += [
            StochasticSwap(coupling_map, trials=20, seed=seed_transpiler)
        ]
    elif routing_method == "lookahead":
        _swap += [LookaheadSwap(coupling_map, search_depth=5, search_width=5)]
    elif routing_method == "sabre":
        _swap += [
            SabreSwap(coupling_map, heuristic="decay", seed=seed_transpiler)
        ]
    elif routing_method == "none":
        _swap += [
            Error(
                msg=
                "No routing method selected, but circuit is not routed to device. "
                "CheckMap Error: {check_map_msg}",
                action="raise",
            )
        ]
    else:
        raise TranspilerError("Invalid routing method %s." % routing_method)

    # 5. Unroll to the basis
    if translation_method == "unroller":
        _unroll = [Unroller(basis_gates)]
    elif translation_method == "translator":
        from qiskit.circuit.equivalence_library import SessionEquivalenceLibrary as sel

        _unroll = [
            # Use unitary synthesis for basis aware decomposition of UnitaryGates before
            # custom unrolling
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
            ),
            UnrollCustomDefinitions(sel, basis_gates),
            BasisTranslator(sel, basis_gates),
        ]
    elif translation_method == "synthesis":
        _unroll = [
            # Use unitary synthesis for basis aware decomposition of UnitaryGates before
            # collection
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
                min_qubits=3,
            ),
            Unroll3qOrMore(),
            Collect2qBlocks(),
            ConsolidateBlocks(basis_gates=basis_gates),
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                backend_props=backend_properties,
                method=unitary_synthesis_method,
            ),
        ]
    else:
        raise TranspilerError("Invalid translation method %s." %
                              translation_method)

    # 6. Fix any bad CX directions
    _direction_check = [CheckGateDirection(coupling_map)]

    def _direction_condition(property_set):
        return not property_set["is_direction_mapped"]

    _direction = [GateDirection(coupling_map)]

    # 7. Remove zero-state reset
    _reset = RemoveResetInZeroState()

    # 8. 1q rotation merge and commutative cancellation iteratively until no more change in depth
    _depth_check = [Depth(), FixedPoint("depth")]

    def _opt_control(property_set):
        return not property_set["depth_fixed_point"]

    _opt = [
        Optimize1qGatesDecomposition(basis_gates),
        CommutativeCancellation(basis_gates=basis_gates),
    ]

    # 9. Unify all durations (either SI, or convert to dt if known)
    # Schedule the circuit only when scheduling_method is supplied
    _scheduling = [TimeUnitConversion(instruction_durations)]
    if scheduling_method:
        if scheduling_method in {"alap", "as_late_as_possible"}:
            _scheduling += [ALAPSchedule(instruction_durations)]
        elif scheduling_method in {"asap", "as_soon_as_possible"}:
            _scheduling += [ASAPSchedule(instruction_durations)]
        else:
            raise TranspilerError("Invalid scheduling method %s." %
                                  scheduling_method)

    # 10. Call measure alignment. Should come after scheduling.
    _alignments = [
        ValidatePulseGates(granularity=timing_constraints.granularity,
                           min_length=timing_constraints.min_length),
        AlignMeasures(alignment=timing_constraints.acquire_alignment),
    ]

    # Build pass manager
    pm2 = PassManager()
    if coupling_map or initial_layout:
        pm2.append(_given_layout)
        pm2.append(_choose_layout_0, condition=_choose_layout_condition)
        pm2.append(_choose_layout_1, condition=_trivial_not_perfect)
        pm2.append(_choose_layout_2, condition=_csp_not_found_match)
        pm2.append(_embed)
        pm2.append(_unroll3q)
        pm2.append(_swap_check)
        pm2.append(_swap, condition=_swap_condition)
    pm2.append(_unroll)
    if coupling_map and not coupling_map.is_symmetric:
        pm2.append(_direction_check)
        pm2.append(_direction, condition=_direction_condition)
    pm2.append(_reset)
    pm2.append(_depth_check + _opt + _unroll, do_while=_opt_control)
    if inst_map and inst_map.has_custom_gate():
        pm2.append(PulseGates(inst_map=inst_map))
    pm2.append(_scheduling)
    pm2.append(_alignments)
    return pm2
Exemple #5
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def level_1_pass_manager(
        pass_manager_config: PassManagerConfig) -> PassManager:
    """Level 1 pass manager: light optimization by simple adjacent gate collapsing.

    This pass manager applies the user-given initial layout. If none is given,
    and a trivial layout (i-th virtual -> i-th physical) makes the circuit fit
    the coupling map, that is used.
    Otherwise, the circuit is mapped to the most densely connected coupling subgraph,
    and swaps are inserted to map. Any unused physical qubit is allocated as ancilla space.
    The pass manager then unrolls the circuit to the desired basis, and transforms the
    circuit to match the coupling map. Finally, optimizations in the form of adjacent
    gate collapse and redundant reset removal are performed.

    Note:
        In simulators where ``coupling_map=None``, only the unrolling and
        optimization stages are done.

    Args:
        pass_manager_config: configuration of the pass manager.

    Returns:
        a level 1 pass manager.

    Raises:
        TranspilerError: if the passmanager config is invalid.
    """
    basis_gates = pass_manager_config.basis_gates
    inst_map = pass_manager_config.inst_map
    coupling_map = pass_manager_config.coupling_map
    initial_layout = pass_manager_config.initial_layout
    layout_method = pass_manager_config.layout_method or "dense"
    routing_method = pass_manager_config.routing_method or "stochastic"
    translation_method = pass_manager_config.translation_method or "translator"
    scheduling_method = pass_manager_config.scheduling_method
    instruction_durations = pass_manager_config.instruction_durations
    seed_transpiler = pass_manager_config.seed_transpiler
    backend_properties = pass_manager_config.backend_properties
    approximation_degree = pass_manager_config.approximation_degree
    unitary_synthesis_method = pass_manager_config.unitary_synthesis_method
    unitary_synthesis_plugin_config = pass_manager_config.unitary_synthesis_plugin_config
    timing_constraints = pass_manager_config.timing_constraints or TimingConstraints(
    )
    target = pass_manager_config.target

    # 1. Use trivial layout if no layout given if that isn't perfect use vf2 layout
    _given_layout = SetLayout(initial_layout)

    def _choose_layout_condition(property_set):
        return not property_set["layout"]

    def _trivial_not_perfect(property_set):
        # Verify that a trivial layout is perfect. If trivial_layout_score > 0
        # the layout is not perfect. The layout is unconditionally set by trivial
        # layout so we need to clear it before contuing.
        if (property_set["trivial_layout_score"] is not None
                and property_set["trivial_layout_score"] != 0):
            return True
        return False

    def _vf2_match_not_found(property_set):
        # If a layout hasn't been set by the time we run vf2 layout we need to
        # run layout
        if property_set["layout"] is None:
            return True
        # if VF2 layout stopped for any reason other than solution found we need
        # to run layout since VF2 didn't converge.
        if (property_set["VF2Layout_stop_reason"] is not None
                and property_set["VF2Layout_stop_reason"]
                is not VF2LayoutStopReason.SOLUTION_FOUND):
            return True
        return False

    _choose_layout_0 = ([] if pass_manager_config.layout_method else [
        TrivialLayout(coupling_map),
        Layout2qDistance(coupling_map, property_name="trivial_layout_score"),
    ])

    _choose_layout_1 = ([] if pass_manager_config.layout_method else VF2Layout(
        coupling_map,
        seed=seed_transpiler,
        call_limit=int(5e4),  # Set call limit to ~100ms with retworkx 0.10.2
        time_limit=0.1,
        properties=backend_properties,
        target=target,
    ))

    # 2. Decompose so only 1-qubit and 2-qubit gates remain
    _unroll3q = [
        # Use unitary synthesis for basis aware decomposition of UnitaryGates
        UnitarySynthesis(
            basis_gates,
            approximation_degree=approximation_degree,
            method=unitary_synthesis_method,
            min_qubits=3,
            plugin_config=unitary_synthesis_plugin_config,
            target=target,
        ),
        Unroll3qOrMore(),
    ]

    # 3. Use a better layout on densely connected qubits, if circuit needs swaps
    if layout_method == "trivial":
        _improve_layout = TrivialLayout(coupling_map)
    elif layout_method == "dense":
        _improve_layout = DenseLayout(coupling_map,
                                      backend_properties,
                                      target=target)
    elif layout_method == "noise_adaptive":
        _improve_layout = NoiseAdaptiveLayout(backend_properties)
    elif layout_method == "sabre":
        _improve_layout = SabreLayout(coupling_map,
                                      max_iterations=2,
                                      seed=seed_transpiler)
    else:
        raise TranspilerError("Invalid layout method %s." % layout_method)

    # 4. Extend dag/layout with ancillas using the full coupling map
    _embed = [
        FullAncillaAllocation(coupling_map),
        EnlargeWithAncilla(),
        ApplyLayout()
    ]

    # 5. Swap to fit the coupling map
    _swap_check = CheckMap(coupling_map)

    def _swap_condition(property_set):
        return not property_set["is_swap_mapped"]

    _swap = [BarrierBeforeFinalMeasurements()]
    if routing_method == "basic":
        _swap += [BasicSwap(coupling_map)]
    elif routing_method == "stochastic":
        _swap += [
            StochasticSwap(coupling_map, trials=20, seed=seed_transpiler)
        ]
    elif routing_method == "lookahead":
        _swap += [LookaheadSwap(coupling_map, search_depth=4, search_width=4)]
    elif routing_method == "sabre":
        _swap += [
            SabreSwap(coupling_map,
                      heuristic="lookahead",
                      seed=seed_transpiler)
        ]
    elif routing_method == "none":
        _swap += [
            Error(
                msg=
                ("No routing method selected, but circuit is not routed to device. "
                 "CheckMap Error: {check_map_msg}"),
                action="raise",
            )
        ]
    else:
        raise TranspilerError("Invalid routing method %s." % routing_method)

    # 6. Unroll to the basis
    if translation_method == "unroller":
        _unroll = [Unroller(basis_gates)]
    elif translation_method == "translator":
        from qiskit.circuit.equivalence_library import SessionEquivalenceLibrary as sel

        _unroll = [
            # Use unitary synthesis for basis aware decomposition of UnitaryGates before
            # custom unrolling
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                method=unitary_synthesis_method,
                backend_props=backend_properties,
                plugin_config=unitary_synthesis_plugin_config,
                target=target,
            ),
            UnrollCustomDefinitions(sel, basis_gates),
            BasisTranslator(sel, basis_gates, target),
        ]
    elif translation_method == "synthesis":
        _unroll = [
            # Use unitary synthesis for basis aware decomposition of UnitaryGates before
            # collection
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                method=unitary_synthesis_method,
                backend_props=backend_properties,
                min_qubits=3,
                target=target,
            ),
            Unroll3qOrMore(),
            Collect2qBlocks(),
            ConsolidateBlocks(basis_gates=basis_gates, target=target),
            UnitarySynthesis(
                basis_gates,
                approximation_degree=approximation_degree,
                coupling_map=coupling_map,
                method=unitary_synthesis_method,
                backend_props=backend_properties,
                plugin_config=unitary_synthesis_plugin_config,
                target=target,
            ),
        ]
    else:
        raise TranspilerError("Invalid translation method %s." %
                              translation_method)

    # 7. Fix any bad CX directions
    _direction_check = [CheckGateDirection(coupling_map, target)]

    def _direction_condition(property_set):
        return not property_set["is_direction_mapped"]

    _direction = [GateDirection(coupling_map, target)]

    # 8. Remove zero-state reset
    _reset = RemoveResetInZeroState()

    # 9. Merge 1q rotations and cancel CNOT gates iteratively until no more change in depth
    # or size of circuit
    _depth_check = [Depth(), FixedPoint("depth")]
    _size_check = [Size(), FixedPoint("size")]

    def _opt_control(property_set):
        return (not property_set["depth_fixed_point"]) or (
            not property_set["size_fixed_point"])

    _opt = [Optimize1qGatesDecomposition(basis_gates), CXCancellation()]

    # Build pass manager
    pm1 = PassManager()
    if coupling_map or initial_layout:
        pm1.append(_given_layout)
        pm1.append(_unroll3q)
        pm1.append(_choose_layout_0, condition=_choose_layout_condition)
        pm1.append(_choose_layout_1, condition=_trivial_not_perfect)
        pm1.append(_improve_layout, condition=_vf2_match_not_found)
        pm1.append(_embed)
        pm1.append(_swap_check)
        pm1.append(_swap, condition=_swap_condition)
    pm1.append(_unroll)
    if (coupling_map and not coupling_map.is_symmetric) or (
            target is not None
            and target.get_non_global_operation_names(strict_direction=True)):
        pm1.append(_direction_check)
        pm1.append(_direction, condition=_direction_condition)
    pm1.append(_reset)
    pm1.append(_depth_check + _size_check)
    pm1.append(_opt + _unroll + _depth_check + _size_check,
               do_while=_opt_control)
    if inst_map and inst_map.has_custom_gate():
        pm1.append(PulseGates(inst_map=inst_map))

    # 10. Unify all durations (either SI, or convert to dt if known)
    # Schedule the circuit only when scheduling_method is supplied
    # Apply alignment analysis regardless of scheduling for delay validation.
    if scheduling_method:
        # Do scheduling after unit conversion.
        scheduler = {
            "alap": ALAPScheduleAnalysis,
            "as_late_as_possible": ALAPScheduleAnalysis,
            "asap": ASAPScheduleAnalysis,
            "as_soon_as_possible": ASAPScheduleAnalysis,
        }
        pm1.append(TimeUnitConversion(instruction_durations))
        try:
            pm1.append(scheduler[scheduling_method](instruction_durations))
        except KeyError as ex:
            raise TranspilerError("Invalid scheduling method %s." %
                                  scheduling_method) from ex
    elif instruction_durations:
        # No scheduling. But do unit conversion for delays.
        def _contains_delay(property_set):
            return property_set["contains_delay"]

        pm1.append(ContainsInstruction("delay"))
        pm1.append(TimeUnitConversion(instruction_durations),
                   condition=_contains_delay)
    if (timing_constraints.granularity != 1
            or timing_constraints.min_length != 1
            or timing_constraints.acquire_alignment != 1
            or timing_constraints.pulse_alignment != 1):
        # Run alignment analysis regardless of scheduling.

        def _require_alignment(property_set):
            return property_set["reschedule_required"]

        pm1.append(
            InstructionDurationCheck(
                acquire_alignment=timing_constraints.acquire_alignment,
                pulse_alignment=timing_constraints.pulse_alignment,
            ))
        pm1.append(
            ConstrainedReschedule(
                acquire_alignment=timing_constraints.acquire_alignment,
                pulse_alignment=timing_constraints.pulse_alignment,
            ),
            condition=_require_alignment,
        )
        pm1.append(
            ValidatePulseGates(
                granularity=timing_constraints.granularity,
                min_length=timing_constraints.min_length,
            ))
    if scheduling_method:
        # Call padding pass if circuit is scheduled
        pm1.append(PadDelay())

    return pm1
Exemple #6
0
def generate_scheduling(instruction_durations, scheduling_method,
                        timing_constraints, inst_map):
    """Generate a post optimization scheduling :class:`~qiskit.transpiler.PassManager`

    Args:
        instruction_durations (dict): The dictionary of instruction durations
        scheduling_method (str): The scheduling method to use, can either be
            ``'asap'``/``'as_soon_as_possible'`` or
            ``'alap'``/``'as_late_as_possible'``
        timing_constraints (TimingConstraints): Hardware time alignment restrictions.
        inst_map (InstructionScheduleMap): Mapping object that maps gate to schedule.

    Returns:
        PassManager: The scheduling pass manager

    Raises:
        TranspilerError: If the ``scheduling_method`` kwarg is not a valid value
    """
    scheduling = PassManager()
    if inst_map and inst_map.has_custom_gate():
        scheduling.append(PulseGates(inst_map=inst_map))
    if scheduling_method:
        # Do scheduling after unit conversion.
        scheduler = {
            "alap": ALAPScheduleAnalysis,
            "as_late_as_possible": ALAPScheduleAnalysis,
            "asap": ASAPScheduleAnalysis,
            "as_soon_as_possible": ASAPScheduleAnalysis,
        }
        scheduling.append(TimeUnitConversion(instruction_durations))
        try:
            scheduling.append(
                scheduler[scheduling_method](instruction_durations))
        except KeyError as ex:
            raise TranspilerError("Invalid scheduling method %s." %
                                  scheduling_method) from ex
    elif instruction_durations:
        # No scheduling. But do unit conversion for delays.
        def _contains_delay(property_set):
            return property_set["contains_delay"]

        scheduling.append(ContainsInstruction("delay"))
        scheduling.append(TimeUnitConversion(instruction_durations),
                          condition=_contains_delay)
    if (timing_constraints.granularity != 1
            or timing_constraints.min_length != 1
            or timing_constraints.acquire_alignment != 1
            or timing_constraints.pulse_alignment != 1):
        # Run alignment analysis regardless of scheduling.

        def _require_alignment(property_set):
            return property_set["reschedule_required"]

        scheduling.append(
            InstructionDurationCheck(
                acquire_alignment=timing_constraints.acquire_alignment,
                pulse_alignment=timing_constraints.pulse_alignment,
            ))
        scheduling.append(
            ConstrainedReschedule(
                acquire_alignment=timing_constraints.acquire_alignment,
                pulse_alignment=timing_constraints.pulse_alignment,
            ),
            condition=_require_alignment,
        )
        scheduling.append(
            ValidatePulseGates(
                granularity=timing_constraints.granularity,
                min_length=timing_constraints.min_length,
            ))
    if scheduling_method:
        # Call padding pass if circuit is scheduled
        scheduling.append(PadDelay())

    return scheduling