Coverage for qml_essentials / model.py: 91%

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

2 

3import warnings 

4import jax.numpy as jnp 

5import numpy as np 

6from jax import random 

7 

8from qml_essentials import jaqsi as js 

9from qml_essentials import operations as op 

10from qml_essentials.tape import recording 

11from qml_essentials.operations import KrausChannel 

12from qml_essentials.ansaetze import Ansaetze, Circuit, Encoding 

13from qml_essentials.gates import Gates, PulseInformation as pinfo 

14from qml_essentials.utils import safe_random_split 

15 

16import logging 

17 

18log = logging.getLogger(__name__) 

19 

20 

21class Model: 

22 """ 

23 A quantum circuit model. 

24 """ 

25 

26 def __init__( 

27 self, 

28 n_qubits: int, 

29 n_layers: int, 

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

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

32 state_preparation: Union[ 

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

34 ] = None, 

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

36 trainable_frequencies: bool = False, 

37 initialization: str = "random", 

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

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

40 shots: Optional[int] = None, 

41 random_seed: int = 1000, 

42 remove_zero_encoding: bool = True, 

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

44 pulse_shape: str = "gaussian", 

45 ) -> None: 

46 """ 

47 Initialize the quantum circuit model. 

48 Parameters will have the shape [impl_n_layers, parameters_per_layer] 

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

50 depending if data_reupload is True and parameters_per_layer is given by 

51 the chosen ansatz. 

52 

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

54 - noise_params: None 

55 - execution_type: "expval" 

56 - shots: None 

57 

58 Args: 

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

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

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

62 If None, defaults to "no_ansatz". 

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

64 Whether to reupload data to the quantum device on each 

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

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

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

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

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

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

71 (e.g. "RX") or a callable (e.g. op.RX). Defaults to op.RX. 

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

73 unitaries or a list of strings. 

74 trainable_frequencies (bool, optional): 

75 Sets trainable encoding parameters for trainable frequencies. 

76 Defaults to False. 

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

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

79 Defaults to "random". 

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

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

82 global measurement is conducted, depending on the execution 

83 type. 

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

85 the quantum device. Defaults to None. 

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

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

88 Defaults to 1000. 

89 remove_zero_encoding (bool, optional): whether to 

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

91 repeat_batch_axis (List[bool], optional): Each boolean in the array 

92 determines over which axes to parallelise computation. The axes 

93 correspond to [inputs, params, pulse_params]. Defaults to 

94 [True, True, True], meaning that batching is enabled over all 

95 axes. 

96 pulse_shape (str, optional): Pulse envelope shape for pulse-level 

97 simulation. One of ``PulseEnvelope.available()``. 

98 Defaults to ``"gaussian"``. 

99 

100 Returns: 

101 None 

102 """ 

103 # Initialize default parameters needed for circuit evaluation 

104 self.n_qubits: int = n_qubits 

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

106 self.n_layers: int = n_layers 

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

108 self.shots = shots 

109 self.remove_zero_encoding = remove_zero_encoding 

110 self.trainable_frequencies: bool = trainable_frequencies 

111 self.execution_type: str = "expval" 

112 self.repeat_batch_axis: List[bool] = repeat_batch_axis 

113 

114 # --- Pulse envelope --- 

115 pinfo.set_envelope(pulse_shape) 

116 

117 # --- State Preparation --- 

118 try: 

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

120 except ValueError as e: 

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

122 

123 # prepare corresponding pulse parameters (always optimized pulses) 

124 self.sp_pulse_params = [] 

125 for sp in self._sp: 

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

127 

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

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

130 else: 

131 # gate has no pulse parametrization 

132 self.sp_pulse_params.append(None) 

133 

134 # --- Encoding --- 

135 if isinstance(encoding, Encoding): 

136 # user wants custom strategy? do it! 

137 self._enc = encoding 

138 else: 

139 # use hammming encoding by default 

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

141 

142 if self._enc.is_golomb: 

143 self._enc._n_qubits = n_qubits 

144 

145 # Number of possible inputs 

146 self.n_input_feat = len(self._enc) 

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

148 

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

150 self.enc_params = jnp.ones((self.n_layers, self.n_qubits, self.n_input_feat)) 

151 

152 self._zero_inputs = False 

153 

154 # --- Data-Reuploading --- 

155 

156 # Keep as NumPy array (not JAX) so that ``if data_reupload[q, idx]`` 

157 # in _iec remains a concrete Python bool even under jax.jit tracing. 

158 # note that setting this will also update self.degree and self.frequencies 

159 # and in consequence also self.has_dru 

160 self.data_reupload = data_reupload 

161 

162 # check for the highest degree among all input dimensions 

163 if self.has_dru: 

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

165 else: 

166 impl_n_layers = n_layers 

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

168 

169 # --- Ansatz --- 

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

171 if isinstance(circuit_type, str): 

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

173 Ansaetze, circuit_type or "No_Ansatz" 

174 )() 

175 else: 

176 self.pqc = circuit_type() 

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

178 

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

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

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

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

183 

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

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

186 impl_n_layers, 

187 pulse_params_per_layer, 

188 ) 

189 

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

191 self._batch_shape = None 

192 

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

194 # however, only if nothing is provided 

195 self._inialization_strategy = initialization 

196 self._initialization_domain = initialization_domain 

197 

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

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

200 

201 # Initializing pulse params 

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

203 

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

205 

206 # Initialise the jaqsi Script that wraps _variational. 

207 # No device selection needed - jaqsi auto-routes between statevector 

208 # and density-matrix simulation based on whether noise channels are 

209 # present on the tape. 

210 self.script = js.Script(f=self._variational, n_qubits=self.n_qubits) 

211 

212 @property 

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

214 """ 

215 Gets the noise parameters of the model. 

216 

217 Returns: 

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

219 noise parameters or None if not set. 

220 """ 

221 return self._noise_params 

222 

223 @noise_params.setter 

224 def noise_params( 

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

226 ) -> None: 

227 """ 

228 Sets the noise parameters of the model. 

229 

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

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

232 structure: 

233 "ThermalRelaxation": 

234 { 

235 "t1": 2000, # relative t1 time. 

236 "t2": 1000, # relative t2 time 

237 "t_factor" 1: # relative gate time factor 

238 }, 

239 

240 Args: 

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

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

243 parameters are set to None. 

244 

245 Returns: 

246 None 

247 """ 

248 # set to None if only zero values provided 

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

250 kvs = None 

251 

252 # set default values 

253 if kvs is not None: 

254 defaults = { 

255 "BitFlip": 0.0, 

256 "PhaseFlip": 0.0, 

257 "Depolarizing": 0.0, 

258 "MultiQubitDepolarizing": 0.0, 

259 "AmplitudeDamping": 0.0, 

260 "PhaseDamping": 0.0, 

261 "GateError": 0.0, 

262 "ThermalRelaxation": None, 

263 "StatePreparation": 0.0, 

264 "Measurement": 0.0, 

265 } 

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

267 kvs.setdefault(key, default_val) 

268 

269 # check if there are any keys not supported 

270 for key in kvs.keys(): 

271 if key not in defaults: 

272 warnings.warn( 

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

274 UserWarning, 

275 ) 

276 

277 # check valid params for thermal relaxation noise channel 

278 tr_params = kvs["ThermalRelaxation"] 

279 if isinstance(tr_params, dict): 

280 tr_params.setdefault("t1", 0.0) 

281 tr_params.setdefault("t2", 0.0) 

282 tr_params.setdefault("t_factor", 0.0) 

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

284 for k in tr_params.keys(): 

285 if k not in valid_tr_keys: 

286 warnings.warn( 

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

288 f"by this package", 

289 UserWarning, 

290 ) 

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

292 warnings.warn( 

293 "Received invalid values for Thermal Relaxation noise " 

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

295 UserWarning, 

296 ) 

297 kvs["ThermalRelaxation"] = 0.0 

298 

299 self._noise_params = kvs 

300 

301 @property 

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

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

304 return self._output_qubit 

305 

306 @output_qubit.setter 

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

308 """ 

309 Set the output qubit(s) for measurement. 

310 

311 Args: 

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

313 """ 

314 if isinstance(value, list): 

315 assert len(value) <= self.n_qubits, ( 

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

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

318 ) 

319 elif isinstance(value, int): 

320 if value == -1: 

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

322 else: 

323 assert value < self.n_qubits, ( 

324 f"Output qubit {value} cannot be larger than {self.n_qubits}." 

325 ) 

326 value = [value] 

327 

328 self._output_qubit = value 

329 

330 @property 

331 def execution_type(self) -> str: 

332 """ 

333 Gets the execution type of the model. 

334 

335 Returns: 

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

337 """ 

338 return self._execution_type 

339 

340 @execution_type.setter 

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

342 if value == "density": 

343 self._result_shape = ( 

344 2 ** len(self.output_qubit), 

345 2 ** len(self.output_qubit), 

346 ) 

347 elif value == "expval": 

348 # check if all qubits are used 

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

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

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

352 # or n_local measurement 

353 else: 

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

355 elif value == "probs": 

356 # in case this is a list of parities, 

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

358 n_parity = ( 

359 (2,) * len(self.output_qubit) 

360 if isinstance(self.output_qubit, (Tuple, List)) 

361 else (2,) 

362 ) 

363 self._result_shape = n_parity 

364 elif value == "state": 

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

366 else: 

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

368 

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

370 warnings.warn( 

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

372 f"{self.output_qubit}.", 

373 UserWarning, 

374 ) 

375 

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

377 warnings.warn( 

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

379 UserWarning, 

380 ) 

381 

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

383 raise ValueError("Setting execution_type to density with shots not None.") 

384 

385 self._execution_type = value 

386 

387 @property 

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

389 """ 

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

391 

392 Returns: 

393 Optional[int]: The number of shots. 

394 """ 

395 return self._shots 

396 

397 @shots.setter 

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

399 """ 

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

401 

402 Args: 

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

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

405 

406 Returns: 

407 None 

408 """ 

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

410 value = None 

411 self._shots = value 

412 

413 @property 

414 def params(self) -> jnp.ndarray: 

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

416 return self._params 

417 

418 @params.setter 

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

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

421 if len(value.shape) == 2: 

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

423 

424 self._params = value 

425 

426 @property 

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

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

429 return self._enc_params 

430 

431 @enc_params.setter 

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

433 """Set the encoding parameters.""" 

434 self._enc_params = value 

435 

436 @property 

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

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

439 return self._pulse_params 

440 

441 @pulse_params.setter 

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

443 """Set the pulse parameters.""" 

444 self._pulse_params = value 

445 

446 @property 

447 def data_reupload(self) -> jnp.ndarray: 

448 """Get the data reupload mask.""" 

449 return self._data_reupload 

450 

451 @data_reupload.setter 

452 def data_reupload(self, value: jnp.ndarray) -> None: 

453 """Set the data reupload mask. 

454 

455 Always converts to a concrete NumPy boolean array so that 

456 ``if data_reupload[q, idx]`` in :meth:`_iec` remains a plain 

457 Python ``bool`` even inside JAX-traced functions (jit / grad / vmap). 

458 """ 

459 # Process data reuploading strategy and set degree 

460 if not isinstance(value, bool): 

461 if not isinstance(value, np.ndarray): 

462 value = np.array(value) 

463 

464 if len(value.shape) == 2: 

465 assert value.shape == ( 

466 self.n_layers, 

467 self.n_qubits, 

468 ), ( 

469 f"Data reuploading array has wrong shape. \ 

470 Expected {(self.n_layers, self.n_qubits)} or\ 

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

472 got {value.shape}." 

473 ) 

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

475 value = np.repeat(value, self.n_input_feat, axis=2) 

476 

477 assert value.shape == ( 

478 self.n_layers, 

479 self.n_qubits, 

480 self.n_input_feat, 

481 ), ( 

482 f"Data reuploading array has wrong shape. \ 

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

484 got {value.shape}." 

485 ) 

486 

487 log.debug(f"Data reuploading array:\n{value}") 

488 else: 

489 if value: 

490 value = np.ones((self.n_layers, self.n_qubits, self.n_input_feat)) 

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

492 else: 

493 value = np.zeros((self.n_layers, self.n_qubits, self.n_input_feat)) 

494 value[0][0] = 1 

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

496 

497 # convert to boolean values 

498 self._data_reupload = np.asarray(value).astype(bool) 

499 

500 self.degree: Tuple = tuple( 

501 self._enc.get_n_freqs(np.count_nonzero(self.data_reupload[..., i])) 

502 for i in range(self.n_input_feat) 

503 ) 

504 

505 self.frequencies: Tuple = tuple( 

506 self._enc.get_spectrum(np.count_nonzero(self.data_reupload[..., i])) 

507 for i in range(self.n_input_feat) 

508 ) 

509 

510 # Cache has_dru as a plain Python bool so that it can be used in 

511 # Python ``if`` statements even inside JAX-traced functions. 

512 self._has_dru: bool = bool(max(int(np.max(f)) for f in self._frequencies) > 1) 

513 

514 @property 

515 def degree(self) -> Tuple: 

516 """Get the degree of the model.""" 

517 return self._degree 

518 

519 @degree.setter 

520 def degree(self, value: Tuple): 

521 self._degree = value 

522 

523 @property 

524 def frequencies(self) -> Tuple: 

525 """Get the frequencies of the model.""" 

526 return self._frequencies 

527 

528 @frequencies.setter 

529 def frequencies(self, value: Tuple): 

530 self._frequencies = value 

531 

532 def exact_spectrum(self, method: str = "tree") -> Tuple[np.ndarray, ...]: 

533 """Compute the exact per-feature Fourier spectrum via the FourierTree. 

534 

535 Unlike :attr:`frequencies` -- a naive per-feature estimate derived purely 

536 from the encoding, which can *overestimate* the spectrum (some 

537 coefficients are constrained to zero for all parameters) -- this builds 

538 the analytical Fourier tree (Nemkov et al.) and returns, for each input 

539 feature, the integer frequencies whose Fourier coefficient is not 

540 identically zero. The result is always a subset of :attr:`frequencies`. 

541 

542 The support is derived purely symbolically (no parameter sampling): see 

543 :meth:`~qml_essentials.coefficients.FourierTree.get_exact_support`. 

544 With ``method="tree"`` (default), frequencies whose contributions cancel 

545 identically across tree paths (e.g. two consecutive encodings combining 

546 into a single rotation) are excluded exactly; this enumerates the 

547 explicit tree, which can be infeasible for deep entangling circuits. 

548 With ``method="dp"``, a merged-state dynamic program derives the support 

549 without enumerating paths, which scales to deep circuits (single input 

550 feature only) at the cost of not detecting identical cross-path 

551 cancellations. 

552 

553 Requires a Clifford + Pauli-rotation ansatz (see 

554 :class:`~qml_essentials.pauli.PauliCircuit`); other gate sets raise 

555 ``NotImplementedError`` during tree construction. 

556 

557 Args: 

558 method (str): ``"tree"`` (fully exact) or ``"dp"`` (scalable). 

559 

560 Returns: 

561 Tuple[np.ndarray, ...]: One sorted integer frequency array per input 

562 feature (same layout as :attr:`frequencies`). 

563 """ 

564 from qml_essentials.coefficients import FourierTree # avoid circular imp. 

565 

566 tree = FourierTree(self) 

567 

568 # Position of each model feature within the tree's frequency vectors. 

569 feature_pos = {feat: i for i, feat in enumerate(tree.features)} 

570 

571 # Union of the symbolic supports over all observables (roots). 

572 support = set() 

573 for freqs in tree.get_exact_support(method=method): 

574 farr = np.asarray(freqs) 

575 for k in range(farr.shape[0]): 

576 key = ( 

577 (int(farr[k]),) 

578 if farr.ndim == 1 

579 else tuple(int(v) for v in farr[k]) 

580 ) 

581 support.add(key) 

582 

583 spectrum = [] 

584 for feat in range(self.n_input_feat): 

585 if support and feat in feature_pos: 

586 pos = feature_pos[feat] 

587 vals = sorted({k[pos] for k in support}) 

588 else: 

589 vals = [0] 

590 spectrum.append(np.array(vals, dtype=int)) 

591 return tuple(spectrum) 

592 

593 @property 

594 def has_dru(self) -> bool: 

595 """Check if the model has data reupload.""" 

596 return self._has_dru 

597 

598 @property 

599 def all_qubit_measurement(self) -> bool: 

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

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

602 

603 @property 

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

605 """ 

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

607 If the model was not called before, 

608 it returns (1, 1, 1). 

609 

610 Returns: 

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

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

613 """ 

614 if self._batch_shape is None: 

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

616 return (1, 1, 1) 

617 return self._batch_shape 

618 

619 @property 

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

621 """ 

622 Get the effective batch shape after applying repeat_batch_axis mask. 

623 

624 Returns: 

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

626 """ 

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

628 batch_shape = batch_shape[batch_shape != 0] 

629 return batch_shape 

630 

631 def initialize_params( 

632 self, 

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

634 repeat: int = 1, 

635 initialization: Optional[str] = None, 

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

637 ) -> random.PRNGKey: 

638 """ 

639 Initialize the variational parameters of the model. 

640 

641 Args: 

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

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

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

645 Defaults to 1. 

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

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

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

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

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

651 

652 Returns: 

653 random.PRNGKey: Updated random key after initialization. 

654 

655 Raises: 

656 Exception: If an invalid initialization method is specified. 

657 """ 

658 # Initializing params 

659 params_shape = (repeat, *self._params_shape) 

660 

661 # use existing strategy if not specified 

662 initialization = initialization or self._inialization_strategy 

663 initialization_domain = initialization_domain or self._initialization_domain 

664 

665 random_key, sub_key = safe_random_split( 

666 random_key if random_key is not None else self.random_key 

667 ) 

668 

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

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

671 if indices is None: 

672 warnings.warn( 

673 f"Specified {initialization} but circuit\ 

674 does not contain controlled rotation gates.\ 

675 Parameters are intialized randomly.", 

676 UserWarning, 

677 ) 

678 else: 

679 np_params = np.array(params) 

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

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

682 * value 

683 ) 

684 params = jnp.array(np_params) 

685 return params 

686 

687 if initialization == "random": 

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

689 sub_key, 

690 params_shape, 

691 minval=initialization_domain[0], 

692 maxval=initialization_domain[1], 

693 ) 

694 elif initialization == "zeros": 

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

696 elif initialization == "pi": 

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

698 elif initialization == "zero-controlled": 

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

700 sub_key, 

701 params_shape, 

702 minval=initialization_domain[0], 

703 maxval=initialization_domain[1], 

704 ) 

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

706 elif initialization == "pi-controlled": 

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

708 sub_key, 

709 params_shape, 

710 minval=initialization_domain[0], 

711 maxval=initialization_domain[1], 

712 ) 

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

714 else: 

715 raise Exception("Invalid initialization method") 

716 

717 log.info( 

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

719 using strategy {initialization}." 

720 ) 

721 

722 return random_key 

723 

724 def transform_input( 

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

726 ) -> jnp.ndarray: 

727 """ 

728 Transform input data by scaling with encoding parameters. 

729 

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

731 where inputs are linearly scaled by encoding parameters before being 

732 used in the quantum circuit. 

733 

734 Args: 

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

736 (batch_size, n_input_feat). 

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

738 scale the input. 

739 

740 Returns: 

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

742 and enc_params. 

743 """ 

744 return inputs * enc_params 

745 

746 def _iec( 

747 self, 

748 inputs: jnp.ndarray, 

749 data_reupload: jnp.ndarray, 

750 enc: Encoding, 

751 enc_params: jnp.ndarray, 

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

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

754 ) -> None: 

755 """ 

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

757 

758 Encodes classical input data into the quantum circuit using rotation 

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

760 positions in the circuit. 

761 

762 For Golomb encoding, a single multi-qubit diagonal unitary is applied 

763 to all qubits simultaneously instead of per-qubit rotation gates. 

764 

765 Args: 

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

767 (batch_size, n_input_feat). 

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

769 indicating where to apply encoding gates. 

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

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

772 (n_qubits, n_input_feat) used to scale inputs. 

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

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

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

776 noise. Defaults to None. 

777 

778 Returns: 

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

780 """ 

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

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

783 return 

784 

785 # --- Golomb encoding: single multi-qubit gate on all qubits -------- 

786 if enc.is_golomb: 

787 idx = 0 # Golomb encoding supports a single input feature 

788 # Check if any qubit has re-uploading enabled for this layer 

789 if data_reupload[:, idx].any(): 

790 random_key, sub_key = safe_random_split(random_key) 

791 # Use the mean of enc_params across qubits as scalar scaling 

792 # (Golomb acts on all qubits jointly) 

793 mean_enc_param = jnp.mean(enc_params[:, idx]) 

794 all_wires = list(range(self.n_qubits)) 

795 enc[idx]( 

796 self.transform_input(inputs[..., idx], mean_enc_param), 

797 wires=all_wires, 

798 noise_params=noise_params, 

799 random_key=sub_key, 

800 ) 

801 return 

802 

803 # --- Standard per-qubit encoding ----------------------------------- 

804 for q in range(self.n_qubits): 

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

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

807 if data_reupload[q, idx]: 

808 # use elipsis to indiex only the last dimension 

809 # as inputs are generally *not* qubit dependent 

810 random_key, sub_key = safe_random_split(random_key) 

811 enc[idx]( 

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

813 wires=q, 

814 noise_params=noise_params, 

815 random_key=sub_key, 

816 ) 

817 

818 def _variational( 

819 self, 

820 params: jnp.ndarray, 

821 inputs: jnp.ndarray, 

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

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

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

825 gate_mode: str = "unitary", 

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

827 ) -> None: 

828 """ 

829 Build the variational quantum circuit structure. 

830 

831 Constructs the circuit by applying state preparation, alternating 

832 variational ansatz layers with input encoding layers, and optional 

833 noise channels. 

834 

835 The first five parameters (after ``self``) - ``params``, ``inputs``, 

836 ``pulse_params``, ``random_key``, ``enc_params`` - are the batchable 

837 positional arguments. 

838 The remaining keyword arguments are broadcast across the batch. 

839 

840 Args: 

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

842 (n_layers, n_params_per_layer). 

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

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

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

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

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

848 operations. Defaults to None. 

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

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

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

852 Defaults to "unitary". 

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

854 Noise parameters for simulation. Defaults to None. 

855 

856 Returns: 

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

858 

859 Note: 

860 Issues RuntimeWarning if called directly without providing parameters 

861 that would normally be passed through the forward method. 

862 """ 

863 # TODO: rework and double check params shape 

864 if len(params.shape) > 2 and params.shape[0] == 1: 

865 params = params[0] 

866 

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

868 inputs = inputs[0] 

869 

870 if enc_params is None: 

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

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

873 if self.trainable_frequencies: