Coverage for qml_essentials/model.py: 93%

1from typing import Any, Dict, Optional, Tuple, Callable, Union, List 

2import pennylane as qml 

3import warnings 

4from copy import deepcopy 

5import jax 

6import jax.numpy as jnp 

7import numpy as np 

8from jax import random 

9 

10from qml_essentials.ansaetze import Ansaetze, Circuit, Encoding 

11from qml_essentials.gates import Gates 

12from qml_essentials.gates import PulseInformation as pinfo 

13from qml_essentials.utils import QuanTikz, safe_random_split 

14 

15import logging 

16 

17log = logging.getLogger(__name__) 

18 

19 

20class Model: 

21 """ 

22 A quantum circuit model. 

23 """ 

24 

25 lightning_threshold = 12 

26 cpu_scaler = 0.9 # default cpu scaler, =1 means full CPU for MP 

27 

28 def __init__( 

29 self, 

30 n_qubits: int, 

31 n_layers: int, 

32 circuit_type: Union[str, Circuit] = "No_Ansatz", 

33 data_reupload: Union[bool, List[List[bool]], List[List[List[bool]]]] = True, 

34 state_preparation: Union[ 

35 str, Callable, List[Union[str, Callable]], None 

36 ] = None, 

37 encoding: Union[Encoding, str, Callable, List[Union[str, Callable]]] = Gates.RX, 

38 trainable_frequencies: bool = False, 

39 initialization: str = "random", 

40 initialization_domain: List[float] = [0, 2 * jnp.pi], 

41 output_qubit: Union[List[int], int] = -1, 

42 shots: Optional[int] = None, 

43 random_seed: int = 1000, 

44 remove_zero_encoding: bool = True, 

45 use_multithreading: bool = False, 

46 repeat_batch_axis: List[bool] = [True, True, True], 

47 ) -> None: 

48 """ 

49 Initialize the quantum circuit model. 

50 Parameters will have the shape [impl_n_layers, parameters_per_layer] 

51 where impl_n_layers is the number of layers provided and added by one 

52 depending if data_reupload is True and parameters_per_layer is given by 

53 the chosen ansatz. 

54 

55 The model is initialized with the following parameters as defaults: 

56 - noise_params: None 

57 - execution_type: "expval" 

58 - shots: None 

59 

60 Args: 

61 n_qubits (int): The number of qubits in the circuit. 

62 n_layers (int): The number of layers in the circuit. 

63 circuit_type (str, Circuit): The type of quantum circuit to use. 

64 If None, defaults to "no_ansatz". 

65 data_reupload (Union[bool, List[bool], List[List[bool]]], optional): 

66 Whether to reupload data to the quantum device on each 

67 layer and qubit. Detailed re-uploading instructions can be given 

68 as a list/array of 0/False and 1/True with shape (n_qubits, 

69 n_layers) to specify where to upload the data. Defaults to True 

70 for applying data re-uploading to the full circuit. 

71 encoding (Union[str, Callable, List[str], List[Callable]], optional): 

72 The unitary to use for encoding the input data. Can be a string 

73 (e.g. "RX") or a callable (e.g. qml.RX). Defaults to qml.RX. 

74 If input is multidimensional it is assumed to be a list of 

75 unitaries or a list of strings. 

76 trainable_frequencies (bool, optional): 

77 Sets trainable encoding parameters for trainable frequencies. 

78 Defaults to False. 

79 initialization (str, optional): The strategy to initialize the parameters. 

80 Can be "random", "zeros", "zero-controlled", "pi", or "pi-controlled". 

81 Defaults to "random". 

82 output_qubit (List[int], int, optional): The index of the output 

83 qubit (or qubits). When set to -1 all qubits are measured, or a 

84 global measurement is conducted, depending on the execution 

85 type. 

86 shots (Optional[int], optional): The number of shots to use for 

87 the quantum device. Defaults to None. 

88 random_seed (int, optional): seed for the random number generator 

89 in initialization is "random" and for random noise parameters. 

90 Defaults to 1000. 

91 remove_zero_encoding (bool, optional): whether to 

92 remove the zero encoding from the circuit. Defaults to True. 

93 use_multithreading (bool, optional): whether to use JAX 

94 multithreading to parallelise over batch dimension. 

95 

96 Returns: 

97 None 

98 """ 

99 # Initialize default parameters needed for circuit evaluation 

100 self.n_qubits: int = n_qubits 

101 self.output_qubit: Union[List[int], int] = output_qubit 

102 self.n_layers: int = n_layers 

103 self.noise_params: Optional[Dict[str, Union[float, Dict[str, float]]]] = None 

104 self.shots = shots 

105 self.remove_zero_encoding = remove_zero_encoding 

106 self.use_multithreading = use_multithreading 

107 self.trainable_frequencies: bool = trainable_frequencies 

108 self.execution_type: str = "expval" 

109 self.repeat_batch_axis: List[bool] = repeat_batch_axis 

110 

111 # --- State Preparation --- 

112 try: 

113 self._sp = Gates.parse_gates(state_preparation, Gates) 

114 except ValueError as e: 

115 raise ValueError(f"Error parsing encodings: {e}") 

116 

117 # prepare corresponding pulse parameters (always optimized pulses) 

118 self.sp_pulse_params = [] 

119 for sp in self._sp: 

120 sp_name = sp.__name__ if hasattr(sp, "__name__") else str(sp) 

121 

122 if pinfo.gate_by_name(sp_name) is not None: 

123 self.sp_pulse_params.append(pinfo.gate_by_name(sp_name).params) 

124 else: 

125 # gate has no pulse parametrization 

126 self.sp_pulse_params.append(None) 

127 

128 # --- Encoding --- 

129 if isinstance(encoding, Encoding): 

130 # user wants custom strategy? do it! 

131 self._enc = encoding 

132 else: 

133 # use hammming encoding by default 

134 self._enc = Encoding("hamming", encoding) 

135 

136 # Number of possible inputs 

137 self.n_input_feat = len(self._enc) 

138 log.debug(f"Number of input features: {self.n_input_feat}") 

139 

140 # Trainable frequencies, default initialization as in arXiv:2309.03279v2 

141 self.enc_params = jnp.ones((self.n_qubits, self.n_input_feat)) 

142 

143 self._zero_inputs = False 

144 

145 # --- Data-Reuploading --- 

146 # Process data reuploading strategy and set degree 

147 if not isinstance(data_reupload, bool): 

148 if not isinstance(data_reupload, np.ndarray): 

149 data_reupload = np.array(data_reupload) 

150 

151 if len(data_reupload.shape) == 2: 

152 assert data_reupload.shape == ( 

153 n_layers, 

154 n_qubits, 

155 ), f"Data reuploading array has wrong shape. \ 

156 Expected {(n_layers, n_qubits)} or\ 

157 {(n_layers, n_qubits, self.n_input_feat)},\ 

158 got {data_reupload.shape}." 

159 data_reupload = data_reupload.reshape(*data_reupload.shape, 1) 

160 data_reupload = np.repeat(data_reupload, self.n_input_feat, axis=2) 

161 

162 assert data_reupload.shape == ( 

163 n_layers, 

164 n_qubits, 

165 self.n_input_feat, 

166 ), f"Data reuploading array has wrong shape. \ 

167 Expected {(n_layers, n_qubits, self.n_input_feat)},\ 

168 got {data_reupload.shape}." 

169 

170 log.debug(f"Data reuploading array:\n{data_reupload}") 

171 else: 

172 if data_reupload: 

173 impl_n_layers: int = ( 

174 n_layers + 1 

175 ) # we need L+1 according to Schuld et al. 

176 data_reupload = np.ones((n_layers, n_qubits, self.n_input_feat)) 

177 log.debug("Full data reuploading.") 

178 else: 

179 impl_n_layers: int = n_layers 

180 data_reupload = np.zeros((n_layers, n_qubits, self.n_input_feat)) 

181 data_reupload[0][0] = 1 

182 log.debug("No data reuploading.") 

183 

184 # convert to boolean values 

185 data_reupload = data_reupload.astype(bool) 

186 self.data_reupload = jnp.array(data_reupload) 

187 

188 self.degree: Tuple = tuple( 

189 self._enc.get_n_freqs(jnp.count_nonzero(self.data_reupload[..., i])) 

190 for i in range(self.n_input_feat) 

191 ) 

192 

193 self.frequencies: Tuple = tuple( 

194 self._enc.get_spectrum(jnp.count_nonzero(self.data_reupload[..., i])) 

195 for i in range(self.n_input_feat) 

196 ) 

197 

198 self.has_dru = jnp.max(jnp.array([jnp.max(f) for f in self.frequencies])) > 1 

199 

200 # check for the highest degree among all input dimensions 

201 if self.has_dru: 

202 impl_n_layers: int = n_layers + 1 # we need L+1 according to Schuld et al. 

203 else: 

204 impl_n_layers = n_layers 

205 log.info(f"Number of implicit layers: {impl_n_layers}.") 

206 

207 # --- Ansatz --- 

208 # only weak check for str. We trust the user to provide sth useful 

209 if isinstance(circuit_type, str): 

210 self.pqc: Callable[[Optional[jnp.ndarray], int], int] = getattr( 

211 Ansaetze, circuit_type or "No_Ansatz" 

212 )() 

213 else: 

214 self.pqc = circuit_type() 

215 log.info(f"Using Ansatz {circuit_type}.") 

216 

217 # calculate the shape of the parameter vector here, we will re-use this in init. 

218 params_per_layer = self.pqc.n_params_per_layer(self.n_qubits) 

219 self._params_shape: Tuple[int, int] = (impl_n_layers, params_per_layer) 

220 log.info(f"Parameters per layer: {params_per_layer}") 

221 

222 pulse_params_per_layer = self.pqc.n_pulse_params_per_layer(self.n_qubits) 

223 self._pulse_params_shape: Tuple[int, int] = ( 

224 impl_n_layers, 

225 pulse_params_per_layer, 

226 ) 

227 

228 # intialize to None as we can't know this yet 

229 self._batch_shape = None 

230 

231 # this will also be re-used in the init method, 

232 # however, only if nothing is provided 

233 self._inialization_strategy = initialization 

234 self._initialization_domain = initialization_domain 

235 

236 # ..here! where we only require a JAX random key 

237 self.random_key = self.initialize_params(random.key(random_seed)) 

238 

239 # Initializing pulse params 

240 self.pulse_params: jnp.ndarray = jnp.ones((*self._pulse_params_shape, 1)) 

241 

242 log.info(f"Initialized pulse parameters with shape {self.pulse_params.shape}.") 

243 

244 # Initialize two circuits, one with the default device and 

245 # one with the mixed device 

246 # which allows us to later route depending on the state_vector flag 

247 if self.n_qubits < self.lightning_threshold: 

248 device = "default.qubit" 

249 else: 

250 device = "lightning.qubit" 

251 self.use_multithreading = False 

252 self.circuit: qml.QNode = qml.QNode( 

253 self._circuit, 

254 qml.device( 

255 device, 

256 shots=self.shots, 

257 wires=self.n_qubits, 

258 ), 

259 interface="jax-jit", 

260 diff_method="parameter-shift" if self.shots is not None else "best", 

261 ) 

262 

263 self.circuit_mixed: qml.QNode = qml.QNode( 

264 self._circuit, 

265 qml.device("default.mixed", shots=self.shots, wires=self.n_qubits), 

266 interface="jax-jit", 

267 diff_method="parameter-shift" if self.shots is not None else "best", 

268 ) 

269 

270 @property 

271 def noise_params(self) -> Optional[Dict[str, Union[float, Dict[str, float]]]]: 

272 """ 

273 Gets the noise parameters of the model. 

274 

275 Returns: 

276 Optional[Dict[str, float]]: A dictionary of 

277 noise parameters or None if not set. 

278 """ 

279 return self._noise_params 

280 

281 @noise_params.setter 

282 def noise_params( 

283 self, kvs: Optional[Dict[str, Union[float, Dict[str, float]]]] 

284 ) -> None: 

285 """ 

286 Sets the noise parameters of the model. 

287 

288 Typically a "noise parameter" refers to the error probability. 

289 ThermalRelaxation is a special case, and supports a dict as value with 

290 structure: 

291 "ThermalRelaxation": 

292 { 

293 "t1": 2000, # relative t1 time. 

294 "t2": 1000, # relative t2 time 

295 "t_factor" 1: # relative gate time factor 

296 }, 

297 

298 Args: 

299 kvs (Optional[Dict[str, Union[float, Dict[str, float]]]]): A 

300 dictionary of noise parameters. If all values are 0.0, the noise 

301 parameters are set to None. 

302 

303 Returns: 

304 None 

305 """ 

306 # set to None if only zero values provided 

307 if kvs is not None and all(v == 0.0 for v in kvs.values()): 

308 kvs = None 

309 

310 # set default values 

311 if kvs is not None: 

312 defaults = { 

313 "BitFlip": 0.0, 

314 "PhaseFlip": 0.0, 

315 "Depolarizing": 0.0, 

316 "MultiQubitDepolarizing": 0.0, 

317 "AmplitudeDamping": 0.0, 

318 "PhaseDamping": 0.0, 

319 "GateError": 0.0, 

320 "ThermalRelaxation": None, 

321 "StatePreparation": 0.0, 

322 "Measurement": 0.0, 

323 } 

324 for key, default_val in defaults.items(): 

325 kvs.setdefault(key, default_val) 

326 

327 # check if there are any keys not supported 

328 for key in kvs.keys(): 

329 if key not in defaults: 

330 warnings.warn( 

331 f"Noise type {key} is not supported by this package", 

332 UserWarning, 

333 ) 

334 

335 # check valid params for thermal relaxation noise channel 

336 tr_params = kvs["ThermalRelaxation"] 

337 if isinstance(tr_params, dict): 

338 tr_params.setdefault("t1", 0.0) 

339 tr_params.setdefault("t2", 0.0) 

340 tr_params.setdefault("t_factor", 0.0) 

341 valid_tr_keys = {"t1", "t2", "t_factor"} 

342 for k in tr_params.keys(): 

343 if k not in valid_tr_keys: 

344 warnings.warn( 

345 f"Thermal Relaxation parameter {k} is not supported " 

346 f"by this package", 

347 UserWarning, 

348 ) 

349 if not all(tr_params.values()) or tr_params["t2"] > 2 * tr_params["t1"]: 

350 warnings.warn( 

351 "Received invalid values for Thermal Relaxation noise " 

352 "parameter. Thermal relaxation is not applied!", 

353 UserWarning, 

354 ) 

355 kvs["ThermalRelaxation"] = 0.0 

356 

357 self._noise_params = kvs 

358 

359 @property 

360 def output_qubit(self) -> List[int]: 

361 """Get the output qubit indices for measurement.""" 

362 return self._output_qubit 

363 

364 @output_qubit.setter 

365 def output_qubit(self, value: Union[int, List[int]]) -> None: 

366 """ 

367 Set the output qubit(s) for measurement. 

368 

369 Args: 

370 value: Qubit index or list of indices. Use -1 for all qubits. 

371 """ 

372 if isinstance(value, list): 

373 assert ( 

374 len(value) <= self.n_qubits 

375 ), f"Size of output_qubit {len(value)} cannot be\ 

376 larger than number of qubits {self.n_qubits}." 

377 elif isinstance(value, int): 

378 if value == -1: 

379 value = list(range(self.n_qubits)) 

380 else: 

381 assert ( 

382 value < self.n_qubits 

383 ), f"Output qubit {value} cannot be larger than {self.n_qubits}." 

384 value = [value] 

385 

386 self._output_qubit = value 

387 

388 @property 

389 def execution_type(self) -> str: 

390 """ 

391 Gets the execution type of the model. 

392 

393 Returns: 

394 str: The execution type, one of 'density', 'expval', or 'probs'. 

395 """ 

396 return self._execution_type 

397 

398 @execution_type.setter 

399 def execution_type(self, value: str) -> None: 

400 if value == "density": 

401 self._result_shape = ( 

402 2 ** len(self.output_qubit), 

403 2 ** len(self.output_qubit), 

404 ) 

405 elif value == "expval": 

406 # check if all qubits are used 

407 if len(self.output_qubit) == self.n_qubits: 

408 self._result_shape = (len(self.output_qubit),) 

409 # if not -> parity measurement with only 1D output per pair 

410 # or n_local measurement 

411 else: 

412 self._result_shape = (len(self.output_qubit),) 

413 elif value == "probs": 

414 # in case this is a list of parities, 

415 # each pair has 2^len(qubits) probabilities 

416 n_parity = ( 

417 2 ** len(self.output_qubit[0]) 

418 if isinstance(self.output_qubit[0], Tuple) 

419 else 2 

420 ) 

421 self._result_shape = (len(self.output_qubit), n_parity) 

422 elif value == "state": 

423 self._result_shape = (2 ** len(self.output_qubit),) 

424 else: 

425 raise ValueError(f"Invalid execution type: {value}.") 

426 

427 if value == "state" and not self.all_qubit_measurement: 

428 warnings.warn( 

429 f"{value} measurement does ignore output_qubit, which is " 

430 f"{self.output_qubit}.", 

431 UserWarning, 

432 ) 

433 

434 if value == "probs" and self.shots is None: 

435 warnings.warn( 

436 "Setting execution_type to probs without specifying shots.", 

437 UserWarning, 

438 ) 

439 

440 if value == "density" and self.shots is not None: 

441 warnings.warn( 

442 "Setting execution_type to density with specified shots.", 

443 UserWarning, 

444 ) 

445 

446 self._execution_type = value 

447 

448 @property 

449 def shots(self) -> Optional[int]: 

450 """ 

451 Gets the number of shots to use for the quantum device. 

452 

453 Returns: 

454 Optional[int]: The number of shots. 

455 """ 

456 return self._shots 

457 

458 @shots.setter 

459 def shots(self, value: Optional[int]) -> None: 

460 """ 

461 Sets the number of shots to use for the quantum device. 

462 

463 Args: 

464 value (Optional[int]): The number of shots. 

465 If an integer less than or equal to 0 is provided, it is set to None. 

466 

467 Returns: 

468 None 

469 """ 

470 if type(value) is int and value <= 0: 

471 value = None 

472 self._shots = value 

473 

474 @property 

475 def params(self) -> jnp.ndarray: 

476 """Get the variational parameters of the model.""" 

477 return self._params 

478 

479 @params.setter 

480 def params(self, value: jnp.ndarray) -> None: 

481 """Set the variational parameters, ensuring batch dimension exists.""" 

482 if len(value.shape) == 2: 

483 value = value.reshape(*value.shape, 1) 

484 

485 self._params = value 

486 

487 @property 

488 def enc_params(self) -> jnp.ndarray: 

489 """Get the encoding parameters used for input transformation.""" 

490 return self._enc_params 

491 

492 @enc_params.setter 

493 def enc_params(self, value: jnp.ndarray) -> None: 

494 """Set the encoding parameters.""" 

495 self._enc_params = value 

496 

497 @property 

498 def pulse_params(self) -> jnp.ndarray: 

499 """Get the pulse parameters for pulse-mode gate execution.""" 

500 return self._pulse_params 

501 

502 @pulse_params.setter 

503 def pulse_params(self, value: jnp.ndarray) -> None: 

504 """Set the pulse parameters.""" 

505 self._pulse_params = value 

506 

507 @property 

508 def all_qubit_measurement(self) -> bool: 

509 """Check if measurement is performed on all qubits.""" 

510 return self.output_qubit == list(range(self.n_qubits)) 

511 

512 @property 

513 def batch_shape(self) -> Tuple[int, ...]: 

514 """ 

515 Get the batch shape (B_I, B_P, B_R). 

516 If the model was not called before, 

517 it returns (1, 1, 1). 

518 

519 Returns: 

520 Tuple[int, ...]: Tuple of (input_batch, param_batch, pulse_batch). 

521 Returns (1, 1, 1) if model has not been called yet. 

522 """ 

523 if self._batch_shape is None: 

524 log.debug("Model was not called yet. Returning (1,1,1) as batch shape.") 

525 return (1, 1, 1) 

526 return self._batch_shape 

527 

528 @property 

529 def eff_batch_shape(self) -> Tuple[int, ...]: 

530 """ 

531 Get the effective batch shape after applying repeat_batch_axis mask. 

532 

533 Returns: 

534 Tuple[int, ...]: Effective batch dimensions, excluding zeros. 

535 """ 

536 batch_shape = np.array(self.batch_shape) * self.repeat_batch_axis 

537 batch_shape = batch_shape[batch_shape != 0] 

538 return batch_shape 

539 

540 def initialize_params( 

541 self, 

542 random_key: Optional[random.PRNGKey] = None, 

543 repeat: int = 1, 

544 initialization: Optional[str] = None, 

545 initialization_domain: Optional[List[float]] = None, 

546 ) -> random.PRNGKey: 

547 """ 

548 Initialize the variational parameters of the model. 

549 

550 Args: 

551 random_key (Optional[random.PRNGKey]): JAX random key for initialization. 

552 If None, uses the model's internal random key. 

553 repeat (int): Number of parameter sets to create (batch dimension). 

554 Defaults to 1. 

555 initialization (Optional[str]): Strategy for parameter initialization. 

556 Options: "random", "zeros", "pi", "zero-controlled", "pi-controlled". 

557 If None, uses the strategy specified in the constructor. 

558 initialization_domain (Optional[List[float]]): Domain [min, max] for 

559 random initialization. If None, uses the domain from constructor. 

560 

561 Returns: 

562 random.PRNGKey: Updated random key after initialization. 

563 

564 Raises: 

565 Exception: If an invalid initialization method is specified. 

566 """ 

567 # Initializing params 

568 params_shape = (*self._params_shape, repeat) 

569 

570 # use existing strategy if not specified 

571 initialization = initialization or self._inialization_strategy 

572 initialization_domain = initialization_domain or self._initialization_domain 

573 

574 random_key, sub_key = safe_random_split( 

575 random_key if random_key is not None else self.random_key 

576 ) 

577 

578 def set_control_params(params: jnp.ndarray, value: float) -> jnp.ndarray: 

579 indices = self.pqc.get_control_indices(self.n_qubits) 

580 if indices is None: 

581 warnings.warn( 

582 f"Specified {initialization} but circuit\ 

583 does not contain controlled rotation gates.\ 

584 Parameters are intialized randomly.", 

585 UserWarning, 

586 ) 

587 else: 

588 np_params = np.array(params) 

589 np_params[:, indices[0] : indices[1] : indices[2]] = ( 

590 np.ones_like(params[:, indices[0] : indices[1] : indices[2]]) 

591 * value 

592 ) 

593 params = jnp.array(np_params) 

594 return params 

595 

596 if initialization == "random": 

597 self.params: jnp.ndarray = random.uniform( 

598 sub_key, 

599 params_shape, 

600 minval=initialization_domain[0], 

601 maxval=initialization_domain[1], 

602 ) 

603 elif initialization == "zeros": 

604 self.params: jnp.ndarray = jnp.zeros(params_shape) 

605 elif initialization == "pi": 

606 self.params: jnp.ndarray = jnp.ones(params_shape) * jnp.pi 

607 elif initialization == "zero-controlled": 

608 self.params: jnp.ndarray = random.uniform( 

609 sub_key, 

610 params_shape, 

611 minval=initialization_domain[0], 

612 maxval=initialization_domain[1], 

613 ) 

614 self.params = set_control_params(self.params, 0) 

615 elif initialization == "pi-controlled": 

616 self.params: jnp.ndarray = random.uniform( 

617 sub_key, 

618 params_shape, 

619 minval=initialization_domain[0], 

620 maxval=initialization_domain[1], 

621 ) 

622 self.params = set_control_params(self.params, jnp.pi) 

623 else: 

624 raise Exception("Invalid initialization method") 

625 

626 log.info( 

627 f"Initialized parameters with shape {self.params.shape}\ 

628 using strategy {initialization}." 

629 ) 

630 

631 return random_key 

632 

633 def transform_input( 

634 self, inputs: jnp.ndarray, enc_params: jnp.ndarray 

635 ) -> jnp.ndarray: 

636 """ 

637 Transform input data by scaling with encoding parameters. 

638 

639 Implements the input transformation as described in arXiv:2309.03279v2, 

640 where inputs are linearly scaled by encoding parameters before being 

641 used in the quantum circuit. 

642 

643 Args: 

644 inputs (jnp.ndarray): Input data point of shape (n_input_feat,) or 

645 (batch_size, n_input_feat). 

646 enc_params (jnp.ndarray): Encoding weight scalar or vector used to 

647 scale the input. 

648 

649 Returns: 

650 jnp.ndarray: Transformed input, element-wise product of inputs 

651 and enc_params. 

652 """ 

653 return inputs * enc_params 

654 

655 def _iec( 

656 self, 

657 inputs: jnp.ndarray, 

658 data_reupload: jnp.ndarray, 

659 enc: Encoding, 

660 enc_params: jnp.ndarray, 

661 noise_params: Optional[Dict[str, Union[float, Dict[str, float]]]] = None, 

662 random_key: Optional[random.PRNGKey] = None, 

663 ) -> None: 

664 """ 

665 Apply Input Encoding Circuit (IEC) with angle encoding. 

666 

667 Encodes classical input data into the quantum circuit using rotation 

668 gates (e.g., RX, RY, RZ). Supports data re-uploading at specified 

669 positions in the circuit. 

670 

671 Args: 

672 inputs (jnp.ndarray): Input data of shape (n_input_feat,) or 

673 (batch_size, n_input_feat). 

674 data_reupload (jnp.ndarray): Boolean array of shape (n_qubits, n_input_feat) 

675 indicating where to apply encoding gates. 

676 enc (Encoding): Encoding strategy containing the encoding gate functions. 

677 enc_params (jnp.ndarray): Encoding parameters of shape 

678 (n_qubits, n_input_feat) used to scale inputs. 

679 noise_params (Optional[Dict[str, Union[float, Dict[str, float]]]]): 

680 Noise parameters for gate-level noise simulation. Defaults to None. 

681 random_key (Optional[random.PRNGKey]): JAX random key for stochastic 

682 noise. Defaults to None. 

683 

684 Returns: 

685 None: Gates are applied in-place to the quantum circuit. 

686 """ 

687 # check for zero, because due to input validation, input cannot be none 

688 if self.remove_zero_encoding and self._zero_inputs and self.batch_shape[0] == 1: 

689 return 

690 

691 for q in range(self.n_qubits): 

692 # use the last dimension of the inputs (feature dimension) 

693 for idx in range(inputs.shape[-1]): 

694 if data_reupload[q, idx]: 

695 # use elipsis to indiex only the last dimension 

696 # as inputs are generally *not* qubit dependent 

697 random_key, sub_key = safe_random_split(random_key) 

698 enc[idx]( 

699 self.transform_input(inputs[..., idx], enc_params[q, idx]), 

700 wires=q, 

701 noise_params=noise_params, 

702 random_key=sub_key, 

703 ) 

704 

705 def _circuit( 

706 self, 

707 params: jnp.ndarray, 

708 inputs: jnp.ndarray, 

709 pulse_params: Optional[jnp.ndarray] = None, 

710 enc_params: Optional[jnp.ndarray] = None, 

711 gate_mode: str = "unitary", 

712 noise_params: Optional[Dict[str, Union[float, Dict[str, float]]]] = None, 

713 random_key: Optional[random.PRNGKey] = None, 

714 ) -> Union[float, jnp.ndarray]: 

715 """ 

716 Build and execute the quantum circuit. 

717 

718 Constructs the full quantum circuit including variational layers and 

719 encoding, then returns the measurement result based on the configured 

720 execution type. 

721 

722 Args: 

723 params (jnp.ndarray): Variational parameters of shape 

724 (n_layers, n_params_per_layer). 

725 inputs (jnp.ndarray): Input data of shape (n_input_feat,). 

726 pulse_params (Optional[jnp.ndarray]): Pulse parameter scalers of shape 

727 (n_layers, n_pulse_params_per_layer) for pulse-mode execution. 

728 Defaults to None. 

729 enc_params (Optional[jnp.ndarray]): Encoding parameters of shape 

730 (n_qubits, n_input_feat). Defaults to None (uses model's enc_params). 

731 gate_mode (str): Gate execution mode, either "unitary" or "pulse". 

732 Defaults to "unitary". 

733 noise_params (Optional[Dict[str, Union[float, Dict[str, float]]]]): 

734 Noise parameters for simulation. Defaults to None. 

735 random_key (Optional[random.PRNGKey]): JAX random key for stochastic 

736 operations. Defaults to None. 

737 

738 Returns: 

739 Union[float, jnp.ndarray]: Circuit output depending on execution_type: 

740 - "expval": Expectation value(s) of the observable(s) 

741 - "density": Density matrix of output qubits 

742 - "probs": Measurement probabilities 

743 - "state": Full quantum state vector 

744 """ 

745 self._variational( 

746 params=params, 

747 inputs=inputs, 

748 pulse_params=pulse_params, 

749 enc_params=enc_params, 

750 gate_mode=gate_mode, 

751 noise_params=noise_params, 

752 random_key=random_key, 

753 ) 

754 return self._observable() 

755 

756 def _variational( 

757 self, 

758 params: jnp.ndarray, 

759 inputs: jnp.ndarray, 

760 pulse_params: Optional[jnp.ndarray] = None, 

761 enc_params: Optional[jnp.ndarray] = None, 

762 gate_mode: str = "unitary", 

763 noise_params: Optional[Dict[str, Union[float, Dict[str, float]]]] = None, 

764 random_key: Optional[random.PRNGKey] = None, 

765 ) -> None: 

766 """ 

767 Build the variational quantum circuit structure. 

768 

769 Constructs the circuit by applying state preparation, alternating 

770 variational ansatz layers with input encoding layers, and optional 

771 noise channels. 

772 

773 Args: 

774 params (jnp.ndarray): Variational parameters of shape 

775 (n_layers, n_params_per_layer). 

776 inputs (jnp.ndarray): Input data of shape (n_input_feat,). 

777 pulse_params (Optional[jnp.ndarray]): Pulse parameter scalers of shape 

778 (n_layers, n_pulse_params_per_layer) for pulse-mode execution. 

779 Defaults to None (uses model's pulse_params). 

780 enc_params (Optional[jnp.ndarray]): Encoding parameters of shape 

781 (n_qubits, n_input_feat). Defaults to None (uses model's enc_params). 

782 gate_mode (str): Gate execution mode, either "unitary" or "pulse". 

783 Defaults to "unitary". 

784 noise_params (Optional[Dict[str, Union[float, Dict[str, float]]]]): 

785 Noise parameters for simulation. Defaults to None. 

786 random_key (Optional[random.PRNGKey]): JAX random key for stochastic 

787 operations. Defaults to None. 

788 

789 Returns: 

790 None: Gates are applied in-place to the quantum circuit. 

791 

792 Note: 

793 Issues RuntimeWarning if called directly without providing parameters 

794 that would normally be passed through the forward method. 

795 """ 

796 # TODO: rework and double check params shape 

797 if len(params.shape) > 2 and params.shape[2] == 1: 

798 params = params[:, :, 0] 

799 

800 if len(inputs.shape) > 1 and inputs.shape[0] == 1: 

801 inputs = inputs[0] 

802 

803 if enc_params is None: 

804 # TODO: Raise warning if trainable frequencies is True, or similar. I.e., no 

805 # warning if user does not care for frequencies or enc_params 

806 if self.trainable_frequencies: 

807 warnings.warn( 

808 "Explicit call to `_circuit` or `_variational` detected: " 

809 "`enc_params` is None, using `self.enc_params` instead.", 

810 RuntimeWarning, 

811 ) 

812 enc_params = self.enc_params 

813 

814 if pulse_params is None: 

815 if gate_mode == "pulse": 

816 warnings.warn( 

817 "Explicit call to `_circuit` or `_variational` detected: " 

818 "`pulse_params` is None, using `self.pulse_params` instead.", 

819 RuntimeWarning, 

820 ) 

821 pulse_params = self.pulse_params 

822 

823 if noise_params is None: 

824 if self.noise_params is not None: 

825 warnings.warn( 

826 "Explicit call to `_circuit` or `_variational` detected: " 

827 "`noise_params` is None, using `self.noise_params` instead.", 

828 RuntimeWarning, 

829 ) 

830 noise_params = self.noise_params 

831 

832 if noise_params is not None: 

833 if random_key is None: 

834 warnings.warn( 

835 "Explicit call to `_circuit` or `_variational` detected: " 

836 "`random_key` is None, using `random.PRNGKey(0)` instead.", 

837 RuntimeWarning, 

838 ) 

839 random_key = self.random_key 

840 self._apply_state_prep_noise(noise_params=noise_params) 

841 

842 # state preparation 

843 for q in range(self.n_qubits): 

844 for _sp, sp_pulse_params in zip(self._sp, self.sp_pulse_params): 

845 random_key, sub_key = safe_random_split(random_key) 

846 _sp( 

847 wires=q, 

848 pulse_params=sp_pulse_params, 

849 noise_params=noise_params, 

850 random_key=sub_key, 

851 gate_mode=gate_mode, 

852 ) 

853 

854 # circuit building 

855 for layer in range(0, self.n_layers): 

856 self.random_key, sub_key = safe_random_split(self.random_key) 

857 # ansatz layers 

858 self.pqc( 

859 params[layer], 

860 self.n_qubits, 

861 pulse_params=pulse_params[layer], 

862 noise_params=noise_params, 

863 random_key=sub_key, 

864 gate_mode=gate_mode, 

865 ) 

866 

867 self.random_key, sub_key = safe_random_split(self.random_key) 

868 # encoding layers 

869 self._iec( 

870 inputs,