tensorcircuit.mpscircuit

Quantum circuit: MPS state simulator

class tensorcircuit.mpscircuit.MPSCircuit(nqubits: int, center_position: Optional[int] = None, tensors: Optional[Sequence[Any]] = None, wavefunction: Optional[Union[tensorcircuit.quantum.QuVector, Any]] = None, split: Optional[Dict[str, Any]] = None)

基类：tensorcircuit.abstractcircuit.AbstractCircuit

MPSCircuit class. Simple usage demo below.

mps = tc.MPSCircuit(3)
mps.H(1)
mps.CNOT(0, 1)
mps.rx(2, theta=tc.num_to_tensor(1.))
mps.expectation((tc.gates.z(), 2))

ANY(*index: int, **vars: Any) → None

Apply ANY gate with parameters on the circuit. See tensorcircuit.gates.any_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

CNOT(*index: int, **kws: Any) → None

Apply CNOT gate on the circuit. See tensorcircuit.gates.cnot_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

CPHASE(*index: int, **vars: Any) → None

Apply CPHASE gate with parameters on the circuit. See tensorcircuit.gates.cphase_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

CR(*index: int, **vars: Any) → None

Apply CR gate with parameters on the circuit. See tensorcircuit.gates.cr_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

CRX(*index: int, **vars: Any) → None

Apply CRX gate with parameters on the circuit. See tensorcircuit.gates.crx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

CRY(*index: int, **vars: Any) → None

Apply CRY gate with parameters on the circuit. See tensorcircuit.gates.cry_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

CRZ(*index: int, **vars: Any) → None

Apply CRZ gate with parameters on the circuit. See tensorcircuit.gates.crz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

CU(*index: int, **vars: Any) → None

Apply CU gate with parameters on the circuit. See tensorcircuit.gates.cu_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

CY(*index: int, **kws: Any) → None

Apply CY gate on the circuit. See tensorcircuit.gates.cy_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.-1.j\\ 0.+0.j & 0.+0.j & 0.+1.j & 0.+0.j \end{bmatrix}\end{split}\]

CZ(*index: int, **kws: Any) → None

Apply CZ gate on the circuit. See tensorcircuit.gates.cz_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & -1.+0.j \end{bmatrix}\end{split}\]

EXP(*index: int, **vars: Any) → None

Apply EXP gate with parameters on the circuit. See tensorcircuit.gates.exp_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

EXP1(*index: int, **vars: Any) → None

Apply EXP1 gate with parameters on the circuit. See tensorcircuit.gates.exp1_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

FREDKIN(*index: int, **kws: Any) → None

Apply FREDKIN gate on the circuit. See tensorcircuit.gates.fredkin_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

H(*index: int, **kws: Any) → None

Apply H gate on the circuit. See tensorcircuit.gates.h_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.70710677+0.j & 0.70710677+0.j\\ 0.70710677+0.j & -0.70710677+0.j \end{bmatrix}\end{split}\]

I(*index: int, **kws: Any) → None

Apply I gate on the circuit. See tensorcircuit.gates.i_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

ISWAP(*index: int, **vars: Any) → None

Apply ISWAP gate with parameters on the circuit. See tensorcircuit.gates.iswap_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

MPO(*index: int, **vars: Any) → None

Apply mpo gate in MPO format on the circuit. See tensorcircuit.gates.mpo_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

classmethod MPO_to_gate(tensors: Sequence[Any]) → tensorcircuit.gates.Gate

Convert MPO to gate

MULTICONTROL(*index: int, **vars: Any) → None

Apply multicontrol gate in MPO format on the circuit. See tensorcircuit.gates.multicontrol_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

ORX(*index: int, **vars: Any) → None

Apply ORX gate with parameters on the circuit. See tensorcircuit.gates.orx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

ORY(*index: int, **vars: Any) → None

Apply ORY gate with parameters on the circuit. See tensorcircuit.gates.ory_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

ORZ(*index: int, **vars: Any) → None

Apply ORZ gate with parameters on the circuit. See tensorcircuit.gates.orz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

OX(*index: int, **kws: Any) → None

Apply OX gate on the circuit. See tensorcircuit.gates.ox_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

OY(*index: int, **kws: Any) → None

Apply OY gate on the circuit. See tensorcircuit.gates.oy_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 0.-1.j & 0.+0.j & 0.+0.j\\ 0.+1.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

OZ(*index: int, **kws: Any) → None

Apply OZ gate on the circuit. See tensorcircuit.gates.oz_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & -1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

PHASE(*index: int, **vars: Any) → None

Apply PHASE gate with parameters on the circuit. See tensorcircuit.gates.phase_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

R(*index: int, **vars: Any) → None

Apply R gate with parameters on the circuit. See tensorcircuit.gates.r_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

RX(*index: int, **vars: Any) → None

Apply RX gate with parameters on the circuit. See tensorcircuit.gates.rx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

RXX(*index: int, **vars: Any) → None

Apply RXX gate with parameters on the circuit. See tensorcircuit.gates.rxx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

RY(*index: int, **vars: Any) → None

Apply RY gate with parameters on the circuit. See tensorcircuit.gates.ry_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

RYY(*index: int, **vars: Any) → None

Apply RYY gate with parameters on the circuit. See tensorcircuit.gates.ryy_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

RZ(*index: int, **vars: Any) → None

Apply RZ gate with parameters on the circuit. See tensorcircuit.gates.rz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

RZZ(*index: int, **vars: Any) → None

Apply RZZ gate with parameters on the circuit. See tensorcircuit.gates.rzz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

S(*index: int, **kws: Any) → None

Apply S gate on the circuit. See tensorcircuit.gates.s_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+1.j \end{bmatrix}\end{split}\]

SD(*index: int, **kws: Any) → None

Apply SD gate on the circuit. See tensorcircuit.gates.sd_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & 0.-1.j \end{bmatrix}\end{split}\]

SWAP(*index: int, **kws: Any) → None

Apply SWAP gate on the circuit. See tensorcircuit.gates.swap_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

T(*index: int, **kws: Any) → None

Apply T gate on the circuit. See tensorcircuit.gates.t_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1. & +0.j & 0. & +0.j\\ 0. & +0.j & 0.70710677+0.70710677j \end{bmatrix}\end{split}\]

TD(*index: int, **kws: Any) → None

Apply TD gate on the circuit. See tensorcircuit.gates.td_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1. & +0.j & 0. & +0.j\\ 0. & +0.j & 0.70710677-0.70710677j \end{bmatrix}\end{split}\]

TOFFOLI(*index: int, **kws: Any) → None

Apply TOFFOLI gate on the circuit. See tensorcircuit.gates.toffoli_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

U(*index: int, **vars: Any) → None

Apply U gate with parameters on the circuit. See tensorcircuit.gates.u_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

WROOT(*index: int, **kws: Any) → None

Apply WROOT gate on the circuit. See tensorcircuit.gates.wroot_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.70710677+0.j & -0.5 & -0.5j\\ 0.5 & -0.5j & 0.70710677+0.j \end{bmatrix}\end{split}\]

X(*index: int, **kws: Any) → None

Apply X gate on the circuit. See tensorcircuit.gates.x_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 1.+0.j\\ 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

Y(*index: int, **kws: Any) → None

Apply Y gate on the circuit. See tensorcircuit.gates.y_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 0.-1.j\\ 0.+1.j & 0.+0.j \end{bmatrix}\end{split}\]

Z(*index: int, **kws: Any) → None

Apply Z gate on the circuit. See tensorcircuit.gates.z_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & -1.+0.j \end{bmatrix}\end{split}\]

__init__(nqubits: int, center_position: Optional[int] = None, tensors: Optional[Sequence[Any]] = None, wavefunction: Optional[Union[tensorcircuit.quantum.QuVector, Any]] = None, split: Optional[Dict[str, Any]] = None) → None

MPSCircuit object based on state simulator.

参数

• nqubits (int) -- The number of qubits in the circuit.

• center_position (int, optional) -- The center position of MPS, default to 0

• tensors (Sequence[Tensor], optional) -- If not None, the initial state of the circuit is taken as tensors instead of \(\vert 0\rangle^n\) qubits, defaults to None. When tensors are specified, if center_position is None, then the tensors are canonicalized, otherwise it is assumed the tensors are already canonicalized at the center_position

• wavefunction (Tensor) -- If not None, it is transformed to the MPS form according to the split rules

• split (Any) -- Split rules

amplitude(l: str) → Any

any(*index: int, **vars: Any) → None

Apply ANY gate with parameters on the circuit. See tensorcircuit.gates.any_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

append(c: tensorcircuit.abstractcircuit.AbstractCircuit, indices: Optional[List[int]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

append circuit c before

Example

>>> c1 = tc.Circuit(2)
>>> c1.H(0)
>>> c1.H(1)
>>> c2 = tc.Circuit(2)
>>> c2.cnot(0, 1)
>>> c1.append(c2)
<tensorcircuit.circuit.Circuit object at 0x7f8402968970>
>>> c1.draw()
    ┌───┐
q_0:┤ H ├──■──
    ├───┤┌─┴─┐
q_1:┤ H ├┤ X ├
    └───┘└───┘

参数

• c (BaseCircuit) -- The other circuit to be appended

• indices (Optional[List[int]], optional) -- the qubit indices to which c is appended on. Defaults to None, which means plain concatenation.

返回

The composed circuit

返回类型

BaseCircuit

append_from_qir(qir: List[Dict[str, Any]]) → None

Apply the ciurict in form of quantum intermediate representation after the current cirucit.

Example

>>> c = tc.Circuit(3)
>>> c.H(0)
>>> c.to_qir()
[{'gatef': h, 'gate': Gate(...), 'index': (0,), 'name': 'h', 'split': None, 'mpo': False}]
>>> c2 = tc.Circuit(3)
>>> c2.CNOT(0, 1)
>>> c2.to_qir()
[{'gatef': cnot, 'gate': Gate(...), 'index': (0, 1), 'name': 'cnot', 'split': None, 'mpo': False}]
>>> c.append_from_qir(c2.to_qir())
>>> c.to_qir()
[{'gatef': h, 'gate': Gate(...), 'index': (0,), 'name': 'h', 'split': None, 'mpo': False},
 {'gatef': cnot, 'gate': Gate(...), 'index': (0, 1), 'name': 'cnot', 'split': None, 'mpo': False}]

参数

qir (List[Dict[str, Any]]) -- The quantum intermediate representation.

apply(gate: Union[tensorcircuit.gates.Gate, tensorcircuit.quantum.QuOperator], *index: int, name: Optional[str] = None, split: Optional[Dict[str, Any]] = None, mpo: bool = False, ir_dict: Optional[Dict[str, Any]] = None) → None

Apply a general qubit gate on MPS.

参数

• gate (Gate) -- The Gate to be applied

• index (int) -- Qubit indices of the gate

引发

ValueError -- "MPS does not support application of gate on > 2 qubits."

apply_MPO(tensors: Sequence[Any], index_left: int, center_left: bool = True, split: Optional[Dict[str, Any]] = None) → None

Apply a MPO to the MPS

apply_adjacent_double_gate(gate: tensorcircuit.gates.Gate, index1: int, index2: int, center_position: Optional[int] = None, split: Optional[Dict[str, Any]] = None) → None

Apply a double qubit gate on adjacent qubits of Matrix Product States (MPS).

参数

• gate (Gate) -- The Gate to be applied

• index1 (int) -- The first qubit index of the gate

• index2 (int) -- The second qubit index of the gate

• center_position (Optional[int]) -- Center position of MPS, default is None

apply_double_gate(gate: tensorcircuit.gates.Gate, index1: int, index2: int, split: Optional[Dict[str, Any]] = None) → None

Apply a double qubit gate on MPS.

参数

• gate (Gate) -- The Gate to be applied

• index1 (int) -- The first qubit index of the gate

• index2 (int) -- The second qubit index of the gate

apply_general_gate(gate: Union[tensorcircuit.gates.Gate, tensorcircuit.quantum.QuOperator], *index: int, name: Optional[str] = None, split: Optional[Dict[str, Any]] = None, mpo: bool = False, ir_dict: Optional[Dict[str, Any]] = None) → None

Apply a general qubit gate on MPS.

参数

• gate (Gate) -- The Gate to be applied

• index (int) -- Qubit indices of the gate

引发

ValueError -- "MPS does not support application of gate on > 2 qubits."

static apply_general_gate_delayed(gatef: Callable[[], tensorcircuit.gates.Gate], name: Optional[str] = None, mpo: bool = False) → Callable[[...], None]

static apply_general_variable_gate_delayed(gatef: Callable[[...], tensorcircuit.gates.Gate], name: Optional[str] = None, mpo: bool = False) → Callable[[...], None]

apply_nqubit_gate(gate: tensorcircuit.gates.Gate, *index: int, split: Optional[Dict[str, Any]] = None) → None

Apply a n-qubit gate by transforming the gate to MPO

apply_single_gate(gate: tensorcircuit.gates.Gate, index: int) → None

Apply a single qubit gate on MPS; no truncation is needed.

参数

• gate (Gate) -- gate to be applied

• index (int) -- Qubit index of the gate

barrier_instruction(*index: List[int]) → None

add a barrier instruction flag, no effect on numerical simulation

参数

index (List[int]) -- the corresponding qubits

ccnot(*index: int, **kws: Any) → None

Apply TOFFOLI gate on the circuit. See tensorcircuit.gates.toffoli_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

ccx(*index: int, **kws: Any) → None

Apply TOFFOLI gate on the circuit. See tensorcircuit.gates.toffoli_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

circuit_param: Dict[str, Any]

cnot(*index: int, **kws: Any) → None

Apply CNOT gate on the circuit. See tensorcircuit.gates.cnot_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

cond_measure(index: int) → Any

Measurement on z basis at index qubit based on quantum amplitude (not post-selection). The highlight is that this method can return the measured result as a int Tensor and thus maintained a jittable pipeline.

Example

>>> c = tc.Circuit(2)
>>> c.H(0)
>>> r = c.cond_measurement(0)
>>> c.conditional_gate(r, [tc.gates.i(), tc.gates.x()], 1)
>>> c.expectation([tc.gates.z(), [0]]), c.expectation([tc.gates.z(), [1]])
# two possible outputs: (1, 1) or (-1, -1)

注解

In terms of DMCircuit, this method returns nothing and the density matrix after this method is kept in mixed state without knowing the measuremet resuslts

参数

index (int) -- the qubit for the z-basis measurement

返回

0 or 1 for z measurement on up and down freedom

返回类型

Tensor

cond_measurement(index: int) → Any

Measurement on z basis at index qubit based on quantum amplitude (not post-selection). The highlight is that this method can return the measured result as a int Tensor and thus maintained a jittable pipeline.

Example

>>> c = tc.Circuit(2)
>>> c.H(0)
>>> r = c.cond_measurement(0)
>>> c.conditional_gate(r, [tc.gates.i(), tc.gates.x()], 1)
>>> c.expectation([tc.gates.z(), [0]]), c.expectation([tc.gates.z(), [1]])
# two possible outputs: (1, 1) or (-1, -1)

注解

In terms of DMCircuit, this method returns nothing and the density matrix after this method is kept in mixed state without knowing the measuremet resuslts

参数

index (int) -- the qubit for the z-basis measurement

返回

0 or 1 for z measurement on up and down freedom

返回类型

Tensor

conditional_gate(which: Any, kraus: Sequence[tensorcircuit.gates.Gate], *index: int) → None

Apply which-th gate from kraus list, i.e. apply kraus[which]

参数

• which (Tensor) -- Tensor of shape [] and dtype int

• kraus (Sequence[Gate]) -- A list of gate in the form of tc.gate or Tensor

• index (int) -- the qubit lines the gate applied on

conj() → tensorcircuit.mpscircuit.MPSCircuit

Compute the conjugate of the current MPS.

返回

The constructed MPS

返回类型

MPSCircuit

consecutive_swap(index_from: int, index_to: int, split: Optional[Dict[str, Any]] = None) → None

copy() → tensorcircuit.mpscircuit.MPSCircuit

Copy the current MPS.

返回

The constructed MPS

返回类型

MPSCircuit

copy_without_tensor() → tensorcircuit.mpscircuit.MPSCircuit

Copy the current MPS without the tensors.

返回

The constructed MPS

返回类型

MPSCircuit

cphase(*index: int, **vars: Any) → None

Apply CPHASE gate with parameters on the circuit. See tensorcircuit.gates.cphase_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

cr(*index: int, **vars: Any) → None

Apply CR gate with parameters on the circuit. See tensorcircuit.gates.cr_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

crx(*index: int, **vars: Any) → None

Apply CRX gate with parameters on the circuit. See tensorcircuit.gates.crx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

cry(*index: int, **vars: Any) → None

Apply CRY gate with parameters on the circuit. See tensorcircuit.gates.cry_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

crz(*index: int, **vars: Any) → None

Apply CRZ gate with parameters on the circuit. See tensorcircuit.gates.crz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

cswap(*index: int, **kws: Any) → None

Apply FREDKIN gate on the circuit. See tensorcircuit.gates.fredkin_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

cu(*index: int, **vars: Any) → None

Apply CU gate with parameters on the circuit. See tensorcircuit.gates.cu_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

cx(*index: int, **kws: Any) → None

Apply CNOT gate on the circuit. See tensorcircuit.gates.cnot_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

cy(*index: int, **kws: Any) → None

Apply CY gate on the circuit. See tensorcircuit.gates.cy_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.-1.j\\ 0.+0.j & 0.+0.j & 0.+1.j & 0.+0.j \end{bmatrix}\end{split}\]

cz(*index: int, **kws: Any) → None

Apply CZ gate on the circuit. See tensorcircuit.gates.cz_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & -1.+0.j \end{bmatrix}\end{split}\]

draw(**kws: Any) → Any

Visualise the circuit. This method recevies the keywords as same as qiskit.circuit.QuantumCircuit.draw. More details can be found here: https://qiskit.org/documentation/stubs/qiskit.circuit.QuantumCircuit.draw.html. Interesting kws options include: ``idle_wires``(bool)

Example

>>> c = tc.Circuit(3)
>>> c.H(1)
>>> c.X(2)
>>> c.CNOT(0, 1)
>>> c.draw(output='text')
q_0: ───────■──
     ┌───┐┌─┴─┐
q_1: ┤ H ├┤ X ├
     ├───┤└───┘
q_2: ┤ X ├─────
     └───┘

exp(*index: int, **vars: Any) → None

Apply EXP gate with parameters on the circuit. See tensorcircuit.gates.exp_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

exp1(*index: int, **vars: Any) → None

Apply EXP1 gate with parameters on the circuit. See tensorcircuit.gates.exp1_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

expectation(*ops: Tuple[tensorcircuit.gates.Gate, List[int]], reuse: bool = True, other: Optional[tensorcircuit.mpscircuit.MPSCircuit] = None, conj: bool = True, normalize: bool = False, split: Optional[Dict[str, Any]] = None, **kws: Any) → Any

Compute the expectation of corresponding operators in the form of tensor.

参数

• ops (Tuple[tn.Node, List[int]]) -- Operator and its position on the circuit, eg. (gates.Z(), [1]), (gates.X(), [2]) is for operator \(Z_1X_2\)

• reuse (bool, optional) -- If True, then the wavefunction tensor is cached for further expectation evaluation, defaults to be true.

• other (MPSCircuit, optional) -- If not None, will be used as bra

• conj (bool, defaults to be True) -- Whether to conjugate the bra state

• normalize (bool, defaults to be True) -- Whether to normalize the MPS

• split (Any) -- Truncation split

返回

The expectation of corresponding operators

返回类型

Tensor

expectation_ps(x: Optional[Sequence[int]] = None, y: Optional[Sequence[int]] = None, z: Optional[Sequence[int]] = None, ps: Optional[Sequence[int]] = None, reuse: bool = True, noise_conf: Optional[Any] = None, nmc: int = 1000, status: Optional[Any] = None, **kws: Any) → Any

Shortcut for Pauli string expectation. x, y, z list are for X, Y, Z positions

Example

>>> c = tc.Circuit(2)
>>> c.X(0)
>>> c.H(1)
>>> c.expectation_ps(x=[1], z=[0])
array(-0.99999994+0.j, dtype=complex64)

>>> c = tc.Circuit(2)
>>> c.cnot(0, 1)
>>> c.rx(0, theta=0.4)
>>> c.rx(1, theta=0.8)
>>> c.h(0)
>>> c.h(1)
>>> error1 = tc.channels.generaldepolarizingchannel(0.1, 1)
>>> error2 = tc.channels.generaldepolarizingchannel(0.06, 2)
>>> noise_conf = NoiseConf()
>>> noise_conf.add_noise("rx", error1)
>>> noise_conf.add_noise("cnot", [error2], [[0, 1]])
>>> c.expectation_ps(x=[0], noise_conf=noise_conf, nmc=10000)
(0.46274087-3.764033e-09j)

参数

• x (Optional[Sequence[int]], optional) -- sites to apply X gate, defaults to None

• y (Optional[Sequence[int]], optional) -- sites to apply Y gate, defaults to None

• z (Optional[Sequence[int]], optional) -- sites to apply Z gate, defaults to None

• ps (Optional[Sequence[int]], optional) -- or one can apply a ps structures instead of x, y, z, e.g. [0, 1, 3, 0, 2, 2] for X_1Z_2Y_4Y_5 defaults to None, ps can overwrite x, y and z

• reuse (bool, optional) -- whether to cache and reuse the wavefunction, defaults to True

• noise_conf (Optional[NoiseConf], optional) -- Noise Configuration, defaults to None

• nmc (int, optional) -- repetition time for Monte Carlo sampling for noisfy calculation, defaults to 1000

• status (Optional[Tensor], optional) -- external randomness given by tensor uniformly from [0, 1], defaults to None, used for noisfy circuit sampling

返回

Expectation value

返回类型

Tensor

fredkin(*index: int, **kws: Any) → None

Apply FREDKIN gate on the circuit. See tensorcircuit.gates.fredkin_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

classmethod from_json(jsonstr: str, circuit_params: Optional[Dict[str, Any]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

load json str as a Circuit

参数

• jsonstr (str) -- _description_

• circuit_params (Optional[Dict[str, Any]], optional) -- Extra circuit parameters in the format of __init__, defaults to None

返回

_description_

返回类型

AbstractCircuit

classmethod from_json_file(file: str, circuit_params: Optional[Dict[str, Any]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

load json file and convert it to a circuit

参数

• file (str) -- filename

• circuit_params (Optional[Dict[str, Any]], optional) -- _description_, defaults to None

返回

_description_

返回类型

AbstractCircuit

classmethod from_openqasm(qasmstr: str, circuit_params: Optional[Dict[str, Any]] = None, keep_measure_order: bool = False) → tensorcircuit.abstractcircuit.AbstractCircuit

classmethod from_openqasm_file(file: str, circuit_params: Optional[Dict[str, Any]] = None, keep_measure_order: bool = False) → tensorcircuit.abstractcircuit.AbstractCircuit

classmethod from_qir(qir: List[Dict[str, Any]], circuit_params: Optional[Dict[str, Any]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

Restore the circuit from the quantum intermediate representation.

Example

>>> c = tc.Circuit(3)
>>> c.H(0)
>>> c.rx(1, theta=tc.array_to_tensor(0.7))
>>> c.exp1(0, 1, unitary=tc.gates._zz_matrix, theta=tc.array_to_tensor(-0.2), split=split)
>>> len(c)
7
>>> c.expectation((tc.gates.z(), [1]))
array(0.764842+0.j, dtype=complex64)
>>> qirs = c.to_qir()
>>>
>>> c = tc.Circuit.from_qir(qirs, circuit_params={"nqubits": 3})
>>> len(c._nodes)
7
>>> c.expectation((tc.gates.z(), [1]))
array(0.764842+0.j, dtype=complex64)

参数

• qir (List[Dict[str, Any]]) -- The quantum intermediate representation of a circuit.

• circuit_params (Optional[Dict[str, Any]]) -- Extra circuit parameters.

返回

The circuit have same gates in the qir.

返回类型

Circuit

classmethod from_qiskit(qc: Any, n: Optional[int] = None, inputs: Optional[List[float]] = None, circuit_params: Optional[Dict[str, Any]] = None, binding_params: Optional[Union[Sequence[float], Dict[Any, float]]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

Import Qiskit QuantumCircuit object as a tc.Circuit object.

Example

>>> from qiskit import QuantumCircuit
>>> qisc = QuantumCircuit(3)
>>> qisc.h(2)
>>> qisc.cswap(1, 2, 0)
>>> qisc.swap(0, 1)
>>> c = tc.Circuit.from_qiskit(qisc)

参数

• qc (QuantumCircuit in Qiskit) -- Qiskit Circuit object

• n (int) -- The number of qubits for the circuit

• inputs (Optional[List[float]], optional) -- possible input wavefunction for tc.Circuit, defaults to None

• circuit_params (Optional[Dict[str, Any]]) -- kwargs given in Circuit.__init__ construction function, default to None.

• binding_params (Optional[Union[Sequence[float], Dict[Any, float]]]) -- (variational) parameters for the circuit. Could be either a sequence or dictionary depending on the type of parameters in the Qiskit circuit. For ParameterVectorElement use sequence. For Parameter use dictionary

返回

The same circuit but as tensorcircuit object

返回类型

Circuit

classmethod from_qsim_file(file: str, circuit_params: Optional[Dict[str, Any]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

gate_aliases = [['cnot', 'cx'], ['fredkin', 'cswap'], ['toffoli', 'ccnot'], ['toffoli', 'ccx'], ['any', 'unitary'], ['sd', 'sdg'], ['td', 'tdg']]

gate_count(gate_list: Optional[Union[str, Sequence[str]]] = None) → int

count the gate number of the circuit

Example

>>> c = tc.Circuit(3)
>>> c.h(0)
>>> c.multicontrol(0, 1, 2, ctrl=[0, 1], unitary=tc.gates._x_matrix)
>>> c.toffolli(1, 2, 0)
>>> c.gate_count()
3
>>> c.gate_count(["multicontrol", "toffoli"])
2

参数

gate_list (Optional[Sequence[str]], optional) -- gate name or gate name list to be counted, defaults to None (counting all gates)

返回

the total number of all gates or gates in the gate_list

返回类型

int

gate_count_by_condition(cond_func: Callable[[Dict[str, Any]], bool]) → int

count the number of gates that satisfy certain condition

Example

>>> c = tc.Circuit(3)
>>> c.x(0)
>>> c.h(0)
>>> c.multicontrol(0, 1, 2, ctrl=[0, 1], unitary=tc.gates._x_matrix)
>>> c.gate_count_by_condition(lambda qir: qir["index"] == (0, ))
2
>>> c.gate_count_by_condition(lambda qir: qir["mpo"])
1

参数

cond_func (Callable[[Dict[str, Any]], bool]) -- the condition for counting the gate

返回

the total number of all gates which satisfy the condition

返回类型

int

gate_summary() → Dict[str, int]

return the summary dictionary on gate type - gate count pair

返回

the gate count dict by gate type

返回类型

Dict[str, int]

classmethod gate_to_MPO(gate: Union[tensorcircuit.gates.Gate, Any], *index: int) → Tuple[Sequence[Any], int]

Convert gate to MPO form with identities at empty sites

get_bond_dimensions() → Any

Get the MPS bond dimensions

返回

MPS tensors

返回类型

Tensor

get_center_position() → Optional[int]

Get the center position of the MPS

返回

center position

返回类型

Optional[int]

get_norm() → Any

Get the normalized Center Position.

返回

Normalized Center Position.

返回类型

Tensor

get_positional_logical_mapping() → Dict[int, int]

Get positional logical mapping dict based on measure instruction. This function is useful when we only measure part of the qubits in the circuit, to process the count result from partial measurement, we must be aware of the mapping, i.e. for each position in the count bitstring, what is the corresponding qubits (logical) defined on the circuit

返回

positional_logical_mapping

返回类型

Dict[int, int]

get_quvector() → tensorcircuit.quantum.QuVector

Get the representation of the output state in the form of QuVector

has to be full contracted in MPS

返回

QuVector representation of the output state from the circuit

返回类型

QuVector

get_tensors() → List[Any]

Get the MPS tensors

返回

MPS tensors

返回类型

List[Tensor]

h(*index: int, **kws: Any) → None

Apply H gate on the circuit. See tensorcircuit.gates.h_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.70710677+0.j & 0.70710677+0.j\\ 0.70710677+0.j & -0.70710677+0.j \end{bmatrix}\end{split}\]

i(*index: int, **kws: Any) → None

Apply I gate on the circuit. See tensorcircuit.gates.i_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

initial_mapping(logical_physical_mapping: Dict[int, int], n: Optional[int] = None, circuit_params: Optional[Dict[str, Any]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

generate a new circuit with the qubit mapping given by logical_physical_mapping

参数

• logical_physical_mapping (Dict[int, int]) -- how to map logical qubits to the physical qubits on the new circuit

• n (Optional[int], optional) -- number of qubit of the new circuit, can be different from the original one, defaults to None

• circuit_params (Optional[Dict[str, Any]], optional) -- _description_, defaults to None

返回

_description_

返回类型

AbstractCircuit

inputs: Any

inverse(circuit_params: Optional[Dict[str, Any]] = None) → tensorcircuit.abstractcircuit.AbstractCircuit

inverse the circuit, return a new inversed circuit

EXAMPLE

>>> c = tc.Circuit(2)
>>> c.H(0)
>>> c.rzz(1, 2, theta=0.8)
>>> c1 = c.inverse()

参数

circuit_params (Optional[Dict[str, Any]], optional) -- keywords dict for initialization the new circuit, defaults to None

返回

the inversed circuit

返回类型

Circuit

is_mps: bool = True

is_valid() → bool

Check whether the circuit is legal.

返回

Whether the circuit is legal.

返回类型

bool

iswap(*index: int, **vars: Any) → None

Apply ISWAP gate with parameters on the circuit. See tensorcircuit.gates.iswap_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

measure(*index: int, with_prob: bool = False, status: Optional[Any] = None) → Tuple[Any, Any]

Take measurement to the given quantum lines.

参数

• index (int) -- Measure on which quantum line.

• with_prob (bool, optional) -- If true, theoretical probability is also returned.

• status (Optional[Tensor]) -- external randomness, with shape [index], defaults to None

返回

The sample output and probability (optional) of the quantum line.

返回类型

Tuple[Tensor, Tensor]

measure_instruction(*index: int) → None

add a measurement instruction flag, no effect on numerical simulation

参数

index (int) -- the corresponding qubits

mid_measurement(index: int, keep: int = 0) → None

Middle measurement in the z-basis on the circuit, note the wavefunction output is not normalized with mid_measurement involved, one should normalized the state manually if needed.

参数

• index (int) -- The index of qubit that the Z direction postselection applied on

• keep (int, optional) -- 0 for spin up, 1 for spin down, defaults to 0

mpo(*index: int, **vars: Any) → None

Apply mpo gate in MPO format on the circuit. See tensorcircuit.gates.mpo_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

mpogates = ['multicontrol', 'mpo']

multicontrol(*index: int, **vars: Any) → None

Apply multicontrol gate in MPO format on the circuit. See tensorcircuit.gates.multicontrol_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

normalize() → None

Normalize MPS Circuit according to the center position.

orx(*index: int, **vars: Any) → None

Apply ORX gate with parameters on the circuit. See tensorcircuit.gates.orx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

ory(*index: int, **vars: Any) → None

Apply ORY gate with parameters on the circuit. See tensorcircuit.gates.ory_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

orz(*index: int, **vars: Any) → None

Apply ORZ gate with parameters on the circuit. See tensorcircuit.gates.orz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

ox(*index: int, **kws: Any) → None

Apply OX gate on the circuit. See tensorcircuit.gates.ox_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

oy(*index: int, **kws: Any) → None

Apply OY gate on the circuit. See tensorcircuit.gates.oy_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 0.-1.j & 0.+0.j & 0.+0.j\\ 0.+1.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

oz(*index: int, **kws: Any) → None

Apply OZ gate on the circuit. See tensorcircuit.gates.oz_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & -1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

phase(*index: int, **vars: Any) → None

Apply PHASE gate with parameters on the circuit. See tensorcircuit.gates.phase_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

position(site: int) → None

Wrapper of tn.FiniteMPS.position. Set orthogonality center.

参数

site (int) -- The orthogonality center

prepend(c: tensorcircuit.abstractcircuit.AbstractCircuit) → tensorcircuit.abstractcircuit.AbstractCircuit

prepend circuit c before

参数

c (BaseCircuit) -- The other circuit to be prepended

返回

The composed circuit

返回类型

BaseCircuit

proj_with_mps(other: tensorcircuit.mpscircuit.MPSCircuit, conj: bool = True) → Any

Compute the projection between other as bra and self as ket.

参数

other (MPSCircuit) -- ket of the other MPS, which will be converted to bra automatically

返回

The projection in form of tensor

返回类型

Tensor

r(*index: int, **vars: Any) → None

Apply R gate with parameters on the circuit. See tensorcircuit.gates.r_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

reduce_dimension(index_left: int, center_left: bool = True, split: Optional[Dict[str, Any]] = None) → None

Reduce the bond dimension between two adjacent sites by SVD

classmethod reduce_tensor_dimension(tensor_left: Any, tensor_right: Any, center_left: bool = True, split: Optional[Dict[str, Any]] = None) → Tuple[Any, Any]

Reduce the bond dimension between two general tensors by SVD

reset_instruction(*index: int) → None

add a reset instruction flag, no effect on numerical simulation

参数

index (int) -- the corresponding qubits

rx(*index: int, **vars: Any) → None

Apply RX gate with parameters on the circuit. See tensorcircuit.gates.rx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

rxx(*index: int, **vars: Any) → None

Apply RXX gate with parameters on the circuit. See tensorcircuit.gates.rxx_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

ry(*index: int, **vars: Any) → None

Apply RY gate with parameters on the circuit. See tensorcircuit.gates.ry_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

ryy(*index: int, **vars: Any) → None

Apply RYY gate with parameters on the circuit. See tensorcircuit.gates.ryy_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

rz(*index: int, **vars: Any) → None

Apply RZ gate with parameters on the circuit. See tensorcircuit.gates.rz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

rzz(*index: int, **vars: Any) → None

Apply RZZ gate with parameters on the circuit. See tensorcircuit.gates.rzz_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

s(*index: int, **kws: Any) → None

Apply S gate on the circuit. See tensorcircuit.gates.s_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & 0.+1.j \end{bmatrix}\end{split}\]

sd(*index: int, **kws: Any) → None

Apply SD gate on the circuit. See tensorcircuit.gates.sd_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & 0.-1.j \end{bmatrix}\end{split}\]

sdg(*index: int, **kws: Any) → None

Apply SD gate on the circuit. See tensorcircuit.gates.sd_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & 0.-1.j \end{bmatrix}\end{split}\]

select_gate(which: Any, kraus: Sequence[tensorcircuit.gates.Gate], *index: int) → None

Apply which-th gate from kraus list, i.e. apply kraus[which]

参数

• which (Tensor) -- Tensor of shape [] and dtype int

• kraus (Sequence[Gate]) -- A list of gate in the form of tc.gate or Tensor

• index (int) -- the qubit lines the gate applied on

set_split_rules(split: Dict[str, Any]) → None

Set truncation split when double qubit gates are applied. If nothing is specified, no truncation will take place and the bond dimension will keep growing. For more details, refer to split_tensor.

参数

split (Any) -- Truncation split

sgates = ['i', 'x', 'y', 'z', 'h', 't', 's', 'td', 'sd', 'wroot', 'cnot', 'cz', 'swap', 'cy', 'ox', 'oy', 'oz', 'toffoli', 'fredkin']

slice(begin: int, end: int) → tensorcircuit.mpscircuit.MPSCircuit

Get a slice of the MPS (only for internal use)

static standardize_gate(name: str) → str

standardize the gate name to tc common gate sets

参数

name (str) -- non-standard gate name

返回

the standard gate name

返回类型

str

state(form: str = 'default') → Any

Compute the output wavefunction from the circuit.

参数

form (str, optional) -- the str indicating the form of the output wavefunction

返回

Tensor with shape [1, -1]

返回类型

Tensor a b ab | | ||

i--A--B--j -> i--XX--j

swap(*index: int, **kws: Any) → None

Apply SWAP gate on the circuit. See tensorcircuit.gates.swap_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j \end{bmatrix}\end{split}\]

t(*index: int, **kws: Any) → None

Apply T gate on the circuit. See tensorcircuit.gates.t_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1. & +0.j & 0. & +0.j\\ 0. & +0.j & 0.70710677+0.70710677j \end{bmatrix}\end{split}\]

td(*index: int, **kws: Any) → None

Apply TD gate on the circuit. See tensorcircuit.gates.td_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1. & +0.j & 0. & +0.j\\ 0. & +0.j & 0.70710677-0.70710677j \end{bmatrix}\end{split}\]

tdg(*index: int, **kws: Any) → None

Apply TD gate on the circuit. See tensorcircuit.gates.td_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1. & +0.j & 0. & +0.j\\ 0. & +0.j & 0.70710677-0.70710677j \end{bmatrix}\end{split}\]

tex(**kws: Any) → str

Generate latex string based on quantikz latex package

返回

Latex string that can be directly compiled via, e.g. latexit

返回类型

str

to_cirq(enable_instruction: bool = False) → Any

Translate tc.Circuit to a cirq circuit object.

参数

enable_instruction (bool, defaults to False) -- whether also export measurement and reset instructions

返回

A cirq circuit of this circuit.

to_json(file: Optional[str] = None, simplified: bool = False) → Any

circuit dumps to json

参数

• file (Optional[str], optional) -- file str to dump the json to, defaults to None, return the json str

• simplified (bool) -- If False, keep all info for each gate, defaults to be False. If True, suitable for IO since less information is required

返回

None if dumps to file otherwise the json str

返回类型

Any

to_openqasm(**kws: Any) → str

transform circuit to openqasm via qiskit circuit, see https://qiskit.org/documentation/stubs/qiskit.circuit.QuantumCircuit.qasm.html for usage on possible options for kws

返回

circuit representation in openqasm format

返回类型

str

to_qir() → List[Dict[str, Any]]

Return the quantum intermediate representation of the circuit.

Example

>>> c = tc.Circuit(2)
>>> c.CNOT(0, 1)
>>> c.to_qir()
[{'gatef': cnot, 'gate': Gate(
    name: 'cnot',
    tensor:
        array([[[[1.+0.j, 0.+0.j],
                [0.+0.j, 0.+0.j]],

                [[0.+0.j, 1.+0.j],
                [0.+0.j, 0.+0.j]]],


            [[[0.+0.j, 0.+0.j],
                [0.+0.j, 1.+0.j]],

                [[0.+0.j, 0.+0.j],
                [1.+0.j, 0.+0.j]]]], dtype=complex64),
    edges: [
        Edge(Dangling Edge)[0],
        Edge(Dangling Edge)[1],
        Edge('cnot'[2] -> 'qb-1'[0] ),
        Edge('cnot'[3] -> 'qb-2'[0] )
    ]), 'index': (0, 1), 'name': 'cnot', 'split': None, 'mpo': False}]

返回

The quantum intermediate representation of the circuit.

返回类型

List[Dict[str, Any]]

to_qiskit(enable_instruction: bool = False, enable_inputs: bool = False) → Any

Translate tc.Circuit to a qiskit QuantumCircuit object.

参数

• enable_instruction (bool, defaults to False) -- whether also export measurement and reset instructions

• enable_inputs (bool, defaults to False) -- whether also export the inputs

返回

A qiskit object of this circuit.

toffoli(*index: int, **kws: Any) → None

Apply TOFFOLI gate on the circuit. See tensorcircuit.gates.toffoli_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j & 0.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j\\ 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 0.+0.j & 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

u(*index: int, **vars: Any) → None

Apply U gate with parameters on the circuit. See tensorcircuit.gates.u_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

unitary(*index: int, **vars: Any) → None

Apply ANY gate with parameters on the circuit. See tensorcircuit.gates.any_gate().

参数

• index (int.) -- Qubit number that the gate applies on.

• vars (float.) -- Parameters for the gate.

vgates = ['r', 'cr', 'u', 'cu', 'rx', 'ry', 'rz', 'phase', 'rxx', 'ryy', 'rzz', 'cphase', 'crx', 'cry', 'crz', 'orx', 'ory', 'orz', 'iswap', 'any', 'exp', 'exp1']

vis_tex(**kws: Any) → str

Generate latex string based on quantikz latex package

返回

Latex string that can be directly compiled via, e.g. latexit

返回类型

str

wavefunction(form: str = 'default') → Any

Compute the output wavefunction from the circuit.

参数

form (str, optional) -- the str indicating the form of the output wavefunction

返回

Tensor with shape [1, -1]

返回类型

Tensor a b ab | | ||

i--A--B--j -> i--XX--j

classmethod wavefunction_to_tensors(wavefunction: Any, dim_phys: int = 2, norm: bool = True, split: Optional[Dict[str, Any]] = None) → List[Any]

Construct the MPS tensors from a given wavefunction.

参数

• wavefunction (Tensor) -- The given wavefunction (any shape is OK)

• split (Dict) -- Truncation split

• dim_phys (int) -- Physical dimension, 2 for MPS and 4 for MPO

• norm (bool) -- Whether to normalize the wavefunction

返回

The tensors

返回类型

List[Tensor]

wroot(*index: int, **kws: Any) → None

Apply WROOT gate on the circuit. See tensorcircuit.gates.wroot_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.70710677+0.j & -0.5 & -0.5j\\ 0.5 & -0.5j & 0.70710677+0.j \end{bmatrix}\end{split}\]

x(*index: int, **kws: Any) → None

Apply X gate on the circuit. See tensorcircuit.gates.x_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 1.+0.j\\ 1.+0.j & 0.+0.j \end{bmatrix}\end{split}\]

y(*index: int, **kws: Any) → None

Apply Y gate on the circuit. See tensorcircuit.gates.y_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 0.+0.j & 0.-1.j\\ 0.+1.j & 0.+0.j \end{bmatrix}\end{split}\]

z(*index: int, **kws: Any) → None

Apply Z gate on the circuit. See tensorcircuit.gates.z_gate().

参数

index (int.) --

Qubit number that the gate applies on. The matrix for the gate is

\[\begin{split}\begin{bmatrix} 1.+0.j & 0.+0.j\\ 0.+0.j & -1.+0.j \end{bmatrix}\end{split}\]

tensorcircuit.mpscircuit.split_tensor(tensor: Any, center_left: bool = True, split: Optional[Dict[str, Any]] = None) → Tuple[Any, Any]

Split the tensor by SVD or QR depends on whether a truncation is required.

参数

• tensor (Tensor) -- The input tensor to split.

• center_left (bool, optional) -- Determine the orthogonal center is on the left tensor or the right tensor.

返回

Two tensors after splitting

返回类型

Tuple[Tensor, Tensor]