Coverage for pySDC/helpers/spectral_helper.py: 93%

1import numpy as np 

2import scipy 

3from pySDC.implementations.datatype_classes.mesh import mesh 

4from scipy.special import factorial 

5from functools import wraps 

6 

7 

8def cache(func): 

9 """ 

10 Decorator for caching return values of functions. 

11 This is very similar to `functools.cache`, but without the memory leaks (see 

12 https://docs.astral.sh/ruff/rules/cached-instance-method/). 

13 

14 Example: 

15 

16 .. code-block:: python 

17 

18 num_calls = 0 

19 

20 @cache 

21 def increment(x): 

22 num_calls += 1 

23 return x + 1 

24 

25 increment(0) # returns 1, num_calls = 1 

26 increment(1) # returns 2, num_calls = 2 

27 increment(0) # returns 1, num_calls = 2 

28 

29 

30 Args: 

31 func (function): The function you want to cache the return value of 

32 

33 Returns: 

34 return value of func 

35 """ 

36 attr_cache = f"_{func.__name__}_cache" 

37 

38 @wraps(func) 

39 def wrapper(self, *args, **kwargs): 

40 if not hasattr(self, attr_cache): 

41 setattr(self, attr_cache, {}) 

42 

43 cache = getattr(self, attr_cache) 

44 

45 key = (args, frozenset(kwargs.items())) 

46 if key in cache: 

47 return cache[key] 

48 result = func(self, *args, **kwargs) 

49 cache[key] = result 

50 return result 

51 

52 return wrapper 

53 

54 

55class SpectralHelper1D: 

56 """ 

57 Abstract base class for 1D spectral discretizations. Defines a common interface with parameters and functions that 

58 all bases need to have. 

59 

60 When implementing new bases, please take care to use the modules that are supplied as class attributes to enable 

61 the code for GPUs. 

62 

63 Attributes: 

64 N (int): Resolution 

65 x0 (float): Coordinate of left boundary 

66 x1 (float): Coordinate of right boundary 

67 L (float): Length of the domain 

68 useGPU (bool): Whether to use GPUs 

69 

70 """ 

71 

72 fft_lib = scipy.fft 

73 sparse_lib = scipy.sparse 

74 linalg = scipy.sparse.linalg 

75 xp = np 

76 

77 def __init__(self, N, x0=None, x1=None, useGPU=False): 

78 """ 

79 Constructor 

80 

81 Args: 

82 N (int): Resolution 

83 x0 (float): Coordinate of left boundary 

84 x1 (float): Coordinate of right boundary 

85 useGPU (bool): Whether to use GPUs 

86 """ 

87 self.N = N 

88 self.x0 = x0 

89 self.x1 = x1 

90 self.L = x1 - x0 

91 self.useGPU = useGPU 

92 

93 if useGPU: 

94 self.setup_GPU() 

95 

96 @classmethod 

97 def setup_GPU(cls): 

98 """switch to GPU modules""" 

99 import cupy as cp 

100 import cupyx.scipy.sparse as sparse_lib 

101 import cupyx.scipy.sparse.linalg as linalg 

102 import cupyx.scipy.fft as fft_lib 

103 from pySDC.implementations.datatype_classes.cupy_mesh import cupy_mesh 

104 

105 cls.xp = cp 

106 cls.sparse_lib = sparse_lib 

107 cls.linalg = linalg 

108 cls.fft_lib = fft_lib 

109 

110 def get_Id(self): 

111 """ 

112 Get identity matrix 

113 

114 Returns: 

115 sparse diagonal identity matrix 

116 """ 

117 return self.sparse_lib.eye(self.N) 

118 

119 def get_zero(self): 

120 """ 

121 Get a matrix with all zeros of the correct size. 

122 

123 Returns: 

124 sparse matrix with zeros everywhere 

125 """ 

126 return 0 * self.get_Id() 

127 

128 def get_differentiation_matrix(self): 

129 raise NotImplementedError() 

130 

131 def get_integration_matrix(self): 

132 raise NotImplementedError() 

133 

134 def get_wavenumbers(self): 

135 """ 

136 Get the grid in spectral space 

137 """ 

138 raise NotImplementedError 

139 

140 def get_empty_operator_matrix(self, S, O): 

141 """ 

142 Return a matrix of operators to be filled with the connections between the solution components. 

143 

144 Args: 

145 S (int): Number of components in the solution 

146 O (sparse matrix): Zero matrix used for initialization 

147 

148 Returns: 

149 list of lists containing sparse zeros 

150 """ 

151 return [[O for _ in range(S)] for _ in range(S)] 

152 

153 def get_basis_change_matrix(self, *args, **kwargs): 

154 """ 

155 Some spectral discretization change the basis during differentiation. This method can be used to transfer 

156 between the various bases. 

157 

158 This method accepts arbitrary arguments that may not be used in order to provide an easy interface for multi- 

159 dimensional bases. For instance, you may combine an FFT discretization with an ultraspherical discretization. 

160 The FFT discretization will always be in the same base, but the ultraspherical discretization uses a different 

161 base for every derivative. You can then ask all bases for transfer matrices from one ultraspherical derivative 

162 base to the next. The FFT discretization will ignore this and return an identity while the ultraspherical 

163 discretization will return the desired matrix. After a Kronecker product, you get the 2D version of the matrix 

164 you want. This is what the `SpectralHelper` does when you call the method of the same name on it. 

165 

166 Returns: 

167 sparse bases change matrix 

168 """ 

169 return self.sparse_lib.eye(self.N) 

170 

171 def get_BC(self, kind): 

172 """ 

173 To facilitate boundary conditions (BCs) we use either a basis where all functions satisfy the BCs automatically, 

174 as is the case in FFT basis for periodic BCs, or boundary bordering. In boundary bordering, specific lines in 

175 the matrix are replaced by the boundary conditions as obtained by this method. 

176 

177 Args: 

178 kind (str): The type of BC you want to implement please refer to the implementations of this method in the 

179 individual 1D bases for what is implemented 

180 

181 Returns: 

182 self.xp.array: Boundary condition 

183 """ 

184 raise NotImplementedError(f'No boundary conditions of {kind=!r} implemented!') 

185 

186 def get_filter_matrix(self, kmin=0, kmax=None): 

187 """ 

188 Get a bandpass filter. 

189 

190 Args: 

191 kmin (int): Lower limit of the bandpass filter 

192 kmax (int): Upper limit of the bandpass filter 

193 

194 Returns: 

195 sparse matrix 

196 """ 

197 

198 k = abs(self.get_wavenumbers()) 

199 

200 kmax = max(k) if kmax is None else kmax 

201 

202 mask = self.xp.logical_or(k >= kmax, k < kmin) 

203 

204 if self.useGPU: 

205 Id = self.get_Id().get() 

206 else: 

207 Id = self.get_Id() 

208 F = Id.tolil() 

209 F[:, mask] = 0 

210 return F.tocsc() 

211 

212 def get_1dgrid(self): 

213 """ 

214 Get the grid in physical space 

215 

216 Returns: 

217 self.xp.array: Grid 

218 """ 

219 raise NotImplementedError 

220 

221 

222class ChebychevHelper(SpectralHelper1D): 

223 """ 

224 The Chebychev base consists of special kinds of polynomials, with the main advantage that you can easily transform 

225 between physical and spectral space by discrete cosine transform. 

226 The differentiation in the Chebychev T base is dense, but can be preconditioned to yield a differentiation operator 

227 that moves to Chebychev U basis during differentiation, which is sparse. When using this technique, problems need to 

228 be formulated in first order formulation. 

229 

230 This implementation is largely based on the Dedalus paper (arXiv:1905.10388). 

231 """ 

232 

233 def __init__(self, *args, transform_type='fft', x0=-1, x1=1, **kwargs): 

234 """ 

235 Constructor. 

236 Please refer to the parent class for additional arguments. Notably, you have to supply a resolution `N` and you 

237 may choose to run on GPUs via the `useGPU` argument. 

238 

239 Args: 

240 transform_type ('fft' or 'dct'): Either use DCT functions directly implemented in the transform library or 

241 use the FFT from the library to compute the DCT 

242 x0 (float): Coordinate of left boundary. Note that only -1 is currently implented 

243 x1 (float): Coordinate of right boundary. Note that only +1 is currently implented 

244 """ 

245 # need linear transformation y = ax + b with a = (x1-x0)/2 and b = (x1+x0)/2 

246 self.lin_trf_fac = (x1 - x0) / 2 

247 self.lin_trf_off = (x1 + x0) / 2 

248 super().__init__(*args, x0=x0, x1=x1, **kwargs) 

249 self.transform_type = transform_type 

250 

251 if self.transform_type == 'fft': 

252 self.get_fft_utils() 

253 

254 self.norm = self.get_norm() 

255 

256 def get_1dgrid(self): 

257 ''' 

258 Generates a 1D grid with Chebychev points. These are clustered at the boundary. You need this kind of grid to 

259 use discrete cosine transformation (DCT) to get the Chebychev representation. If you want a different grid, you 

260 need to do an affine transformation before any Chebychev business. 

261 

262 Returns: 

263 numpy.ndarray: 1D grid 

264 ''' 

265 return self.lin_trf_fac * self.xp.cos(np.pi / self.N * (self.xp.arange(self.N) + 0.5)) + self.lin_trf_off 

266 

267 def get_wavenumbers(self): 

268 """Get the domain in spectral space""" 

269 return self.xp.arange(self.N) 

270 

271 @cache 

272 def get_conv(self, name, N=None): 

273 ''' 

274 Get conversion matrix between different kinds of polynomials. The supported kinds are 

275 - T: Chebychev polynomials of first kind 

276 - U: Chebychev polynomials of second kind 

277 - D: Dirichlet recombination. 

278 

279 You get the desired matrix by choosing a name as ``A2B``. I.e. ``T2U`` for the conversion matrix from T to U. 

280 Once generates matrices are cached. So feel free to call the method as often as you like. 

281 

282 Args: 

283 name (str): Conversion code, e.g. 'T2U' 

284 N (int): Size of the matrix (optional) 

285 

286 Returns: 

287 scipy.sparse: Sparse conversion matrix 

288 ''' 

289 N = N if N else self.N 

290 sp = self.sparse_lib 

291 xp = self.xp 

292 

293 def get_forward_conv(name): 

294 if name == 'T2U': 

295 mat = (sp.eye(N) - sp.diags(xp.ones(N - 2), offsets=+2)) / 2.0 

296 mat[:, 0] *= 2 

297 elif name == 'D2T': 

298 mat = sp.eye(N) - sp.diags(xp.ones(N - 2), offsets=+2) 

299 elif name[0] == name[-1]: 

300 mat = self.sparse_lib.eye(self.N) 

301 else: 

302 raise NotImplementedError(f'Don\'t have conversion matrix {name!r}') 

303 return mat 

304 

305 try: 

306 mat = get_forward_conv(name) 

307 except NotImplementedError as E: 

308 try: 

309 fwd = get_forward_conv(name[::-1]) 

310 import scipy.sparse as sp 

311 

312 if self.sparse_lib == sp: 

313 mat = self.sparse_lib.linalg.inv(fwd.tocsc()) 

314 else: 

315 mat = self.sparse_lib.csc_matrix(sp.linalg.inv(fwd.tocsc().get())) 

316 except NotImplementedError: 

317 raise NotImplementedError from E 

318 

319 return mat 

320 

321 def get_basis_change_matrix(self, conv='T2T', **kwargs): 

322 """ 

323 As the differentiation matrix in Chebychev-T base is dense but is sparse when simultaneously changing base to 

324 Chebychev-U, you may need a basis change matrix to transfer the other matrices as well. This function returns a 

325 conversion matrix from `ChebychevHelper.get_conv`. Not that `**kwargs` are used to absorb arguments for other 

326 bases, see documentation of `SpectralHelper1D.get_basis_change_matrix`. 

327 

328 Args: 

329 conv (str): Conversion code, i.e. T2U 

330 

331 Returns: 

332 Sparse conversion matrix 

333 """ 

334 return self.get_conv(conv) 

335 

336 def get_integration_matrix(self, lbnd=0): 

337 """ 

338 Get matrix for integration 

339 

340 Args: 

341 lbnd (float): Lower bound for integration, only 0 is currently implemented 

342 

343 Returns: 

344 Sparse integration matrix 

345 """ 

346 S = self.sparse_lib.diags(1 / (self.xp.arange(self.N - 1) + 1), offsets=-1) @ self.get_conv('T2U') 

347 n = self.xp.arange(self.N) 

348 if lbnd == 0: 

349 S = S.tocsc() 

350 S[0, 1::2] = ( 

351 (n / (2 * (self.xp.arange(self.N) + 1)))[1::2] 

352 * (-1) ** (self.xp.arange(self.N // 2)) 

353 / (np.append([1], self.xp.arange(self.N // 2 - 1) + 1)) 

354 ) * self.lin_trf_fac 

355 else: 

356 raise NotImplementedError(f'This function allows to integrate only from x=0, you attempted from x={lbnd}.') 

357 return S 

358 

359 def get_differentiation_matrix(self, p=1): 

360 ''' 

361 Keep in mind that the T2T differentiation matrix is dense. 

362 

363 Args: 

364 p (int): Derivative you want to compute 

365 

366 Returns: 

367 numpy.ndarray: Differentiation matrix 

368 ''' 

369 D = self.xp.zeros((self.N, self.N)) 

370 for j in range(self.N): 

371 for k in range(j): 

372 D[k, j] = 2 * j * ((j - k) % 2) 

373 

374 D[0, :] /= 2 

375 return self.sparse_lib.csc_matrix(self.xp.linalg.matrix_power(D, p)) / self.lin_trf_fac**p 

376 

377 def get_norm(self, N=None): 

378 ''' 

379 Get normalization for converting Chebychev coefficients and DCT 

380 

381 Args: 

382 N (int, optional): Resolution 

383 

384 Returns: 

385 self.xp.array: Normalization 

386 ''' 

387 N = self.N if N is None else N 

388 norm = self.xp.ones(N) / N 

389 norm[0] /= 2 

390 return norm 

391 

392 def get_fft_shuffle(self, forward, N): 

393 """ 

394 In order to more easily parallelize using distributed FFT libraries, we express the DCT via an FFT following 

395 doi.org/10.1109/TASSP.1980.1163351. The idea is based on reshuffling the data to be periodic and rotating it 

396 in the complex plane. This function returns a mask to do the shuffling. 

397 

398 Args: 

399 forward (bool): Whether you want the shuffle for forward transform or backward transform 

400 N (int): size of the grid 

401 

402 Returns: 

403 self.xp.array: Use as mask 

404 """ 

405 xp = self.xp 

406 if forward: 

407 return xp.append(xp.arange((N + 1) // 2) * 2, -xp.arange(N // 2) * 2 - 1 - N % 2) 

408 else: 

409 mask = xp.zeros(N, dtype=int) 

410 mask[: N - N % 2 : 2] = xp.arange(N // 2) 

411 mask[1::2] = N - xp.arange(N // 2) - 1 

412 mask[-1] = N // 2 

413 return mask 

414 

415 def get_fft_shift(self, forward, N): 

416 """ 

417 As described in the docstring for `get_fft_shuffle`, we need to rotate in the complex plane in order to use FFT for DCT. 

418 

419 Args: 

420 forward (bool): Whether you want the rotation for forward transform or backward transform 

421 N (int): size of the grid 

422 

423 Returns: 

424 self.xp.array: Rotation 

425 """ 

426 k = self.get_wavenumbers() 

427 norm = self.get_norm() 

428 xp = self.xp 

429 if forward: 

430 return 2 * xp.exp(-1j * np.pi * k / (2 * N) + 0j * np.pi / 4) * norm 

431 else: 

432 shift = xp.exp(1j * np.pi * k / (2 * N)) 

433 shift[0] = 0.5 

434 return shift / norm 

435 

436 def get_fft_utils(self): 

437 """ 

438 Get the required utilities for using FFT to do DCT as described in the docstring for `get_fft_shuffle` and keep 

439 them cached. 

440 """ 

441 self.fft_utils = { 

442 'fwd': {}, 

443 'bck': {}, 

444 } 

445 

446 # forwards transform 

447 self.fft_utils['fwd']['shuffle'] = self.get_fft_shuffle(True, self.N) 

448 self.fft_utils['fwd']['shift'] = self.get_fft_shift(True, self.N) 

449 

450 # backwards transform 

451 self.fft_utils['bck']['shuffle'] = self.get_fft_shuffle(False, self.N) 

452 self.fft_utils['bck']['shift'] = self.get_fft_shift(False, self.N) 

453 

454 return self.fft_utils 

455 

456 def transform(self, u, axis=-1, **kwargs): 

457 """ 

458 1D DCT along axis. `kwargs` will be passed on to the FFT library. 

459 

460 Args: 

461 u: Data you want to transform 

462 axis (int): Axis you want to transform along 

463 

464 Returns: 

465 Data in spectral space 

466 """ 

467 if self.transform_type.lower() == 'dct': 

468 return self.fft_lib.dct(u, axis=axis, **kwargs) * self.norm 

469 elif self.transform_type.lower() == 'fft': 

470 result = u.copy() 

471 

472 shuffle = [slice(0, s, 1) for s in u.shape] 

473 shuffle[axis] = self.fft_utils['fwd']['shuffle'] 

474 

475 v = u[(*shuffle,)] 

476 

477 V = self.fft_lib.fft(v, axis=axis, **kwargs) 

478 

479 expansion = [np.newaxis for _ in u.shape] 

480 expansion[axis] = slice(0, u.shape[axis], 1) 

481 

482 V *= self.fft_utils['fwd']['shift'][(*expansion,)] 

483 

484 result.real[...] = V.real[...] 

485 return result 

486 else: 

487 raise NotImplementedError(f'Please choose a transform type from fft and dct, not {self.transform_type=}') 

488 

489 def itransform(self, u, axis=-1): 

490 """ 

491 1D inverse DCT along axis. 

492 

493 Args: 

494 u: Data you want to transform 

495 axis (int): Axis you want to transform along 

496 

497 Returns: 

498 Data in physical space 

499 """ 

500 assert self.norm.shape[0] == u.shape[axis] 

501 

502 if self.transform_type == 'dct': 

503 return self.fft_lib.idct(u / self.norm, axis=axis) 

504 elif self.transform_type == 'fft': 

505 result = u.copy() 

506 

507 expansion = [np.newaxis for _ in u.shape] 

508 expansion[axis] = slice(0, u.shape[axis], 1) 

509 

510 v = self.fft_lib.ifft(u * self.fft_utils['bck']['shift'][(*expansion,)], axis=axis) 

511 

512 shuffle = [slice(0, s, 1) for s in u.shape] 

513 shuffle[axis] = self.fft_utils['bck']['shuffle'] 

514 V = v[(*shuffle,)] 

515 

516 result.real[...] = V.real[...] 

517 return result 

518 else: 

519 raise NotImplementedError 

520 

521 def get_BC(self, kind, **kwargs): 

522 """ 

523 Get boundary condition row for boundary bordering. `kwargs` will be passed on to implementations of the BC of 

524 the kind you choose. Specifically, `x` for `'dirichlet'` boundary condition, which is the coordinate at which to 

525 set the BC. 

526 

527 Args: 

528 kind ('integral' or 'dirichlet'): Kind of boundary condition you want 

529 """ 

530 if kind.lower() == 'integral': 

531 return self.get_integ_BC_row(**kwargs) 

532 elif kind.lower() == 'dirichlet': 

533 return self.get_Dirichlet_BC_row(**kwargs) 

534 else: 

535 return super().get_BC(kind) 

536 

537 def get_integ_BC_row(self): 

538 """ 

539 Get a row for generating integral BCs with T polynomials. 

540 It returns the values of the integrals of T polynomials over the entire interval. 

541 

542 Returns: 

543 self.xp.ndarray: Row to put into a matrix 

544 """ 

545 n = self.xp.arange(self.N) + 1 

546 me = self.xp.zeros_like(n).astype(float) 

547 me[2:] = ((-1) ** n[1:-1] + 1) / (1 - n[1:-1] ** 2) 

548 me[0] = 2.0 

549 return me 

550 

551 def get_Dirichlet_BC_row(self, x): 

552 """ 

553 Get a row for generating Dirichlet BCs at x with T polynomials. 

554 It returns the values of the T polynomials at x. 

555 

556 Args: 

557 x (float): Position of the boundary condition 

558 

559 Returns: 

560 self.xp.ndarray: Row to put into a matrix 

561 """ 

562 if x == -1: 

563 return (-1) ** self.xp.arange(self.N) 

564 elif x == 1: 

565 return self.xp.ones(self.N) 

566 elif x == 0: 

567 n = (1 + (-1) ** self.xp.arange(self.N)) / 2 

568 n[2::4] *= -1 

569 return n 

570 else: 

571 raise NotImplementedError(f'Don\'t know how to generate Dirichlet BC\'s at {x=}!') 

572 

573 def get_Dirichlet_recombination_matrix(self): 

574 ''' 

575 Get matrix for Dirichlet recombination, which changes the basis to have sparse boundary conditions. 

576 This makes for a good right preconditioner. 

577 

578 Returns: 

579 scipy.sparse: Sparse conversion matrix 

580 ''' 

581 N = self.N 

582 sp = self.sparse_lib 

583 xp = self.xp 

584 

585 return sp.eye(N) - sp.diags(xp.ones(N - 2), offsets=+2) 

586 

587 

588class UltrasphericalHelper(ChebychevHelper): 

589 """ 

590 This implementation follows https://doi.org/10.1137/120865458. 

591 The ultraspherical method works in Chebychev polynomials as well, but also uses various Gegenbauer polynomials. 

592 The idea is that for every derivative of Chebychev T polynomials, there is a basis of Gegenbauer polynomials where the differentiation matrix is a single off-diagonal. 

593 There are also conversion operators from one derivative basis to the next that are sparse. 

594 

595 This basis is used like this: For every equation that you have, look for the highest derivative and bump all matrices to the correct basis. If your highest derivative is 2 and you have an identity, it needs to get bumped from 0 to 1 and from 1 to 2. If you have a first derivative as well, it needs to be bumped from 1 to 2. 

596 You don't need the same resulting basis in all equations. You just need to take care that you translate the right hand side to the correct basis as well. 

597 """ 

598 

599 def get_differentiation_matrix(self, p=1): 

600 """ 

601 Notice that while sparse, this matrix is not diagonal, which means the inversion cannot be parallelized easily. 

602 

603 Args: 

604 p (int): Order of the derivative 

605 

606 Returns: 

607 sparse differentiation matrix 

608 """ 

609 sp = self.sparse_lib 

610 xp = self.xp 

611 N = self.N 

612 l = p 

613 return 2 ** (l - 1) * factorial(l - 1) * sp.diags(xp.arange(N - l) + l, offsets=l) / self.lin_trf_fac**p 

614 

615 def get_S(self, lmbda): 

616 """ 

617 Get matrix for bumping the derivative base by one from lmbda to lmbda + 1. This is the same language as in 

618 https://doi.org/10.1137/120865458. 

619 

620 Args: 

621 lmbda (int): Ingoing derivative base 

622 

623 Returns: 

624 sparse matrix: Conversion from derivative base lmbda to lmbda + 1 

625 """ 

626 N = self.N 

627 

628 if lmbda == 0: 

629 sp = scipy.sparse 

630 mat = ((sp.eye(N) - sp.diags(np.ones(N - 2), offsets=+2)) / 2.0).tolil() 

631 mat[:, 0] *= 2 

632 else: 

633 sp = self.sparse_lib 

634 xp = self.xp 

635 mat = sp.diags(lmbda / (lmbda + xp.arange(N))) - sp.diags( 

636 lmbda / (lmbda + 2 + xp.arange(N - 2)), offsets=+2 

637 ) 

638 

639 return self.sparse_lib.csc_matrix(mat) 

640 

641 def get_basis_change_matrix(self, p_in=0, p_out=0, **kwargs): 

642 """ 

643 Get a conversion matrix from derivative base `p_in` to `p_out`. 

644 

645 Args: 

646 p_out (int): Resulting derivative base 

647 p_in (int): Ingoing derivative base 

648 """ 

649 mat_fwd = self.sparse_lib.eye(self.N) 

650 for i in range(min([p_in, p_out]), max([p_in, p_out])): 

651 mat_fwd = self.get_S(i) @ mat_fwd 

652 

653 if p_out > p_in: 

654 return mat_fwd 

655 

656 else: 

657 # We have to invert the matrix on CPU because the GPU equivalent is not implemented in CuPy at the time of writing. 

658 import scipy.sparse as sp 

659 

660 if self.useGPU: 

661 mat_fwd = mat_fwd.get() 

662 

663 mat_bck = sp.linalg.inv(mat_fwd.tocsc()) 

664 

665 return self.sparse_lib.csc_matrix(mat_bck) 

666 

667 def get_integration_matrix(self): 

668 """ 

669 Get an integration matrix. Please use `UltrasphericalHelper.get_integration_constant` afterwards to compute the 

670 integration constant such that integration starts from x=-1. 

671 

672 Example: 

673 

674 .. code-block:: python 

675 

676 import numpy as np 

677 from pySDC.helpers.spectral_helper import UltrasphericalHelper 

678 

679 N = 4 

680 helper = UltrasphericalHelper(N) 

681 coeffs = np.random.random(N) 

682 coeffs[-1] = 0 

683 

684 poly = np.polynomial.Chebyshev(coeffs) 

685 

686 S = helper.get_integration_matrix() 

687 U_hat = S @ coeffs 

688 U_hat[0] = helper.get_integration_constant(U_hat, axis=-1) 

689 

690 assert np.allclose(poly.integ(lbnd=-1).coef[:-1], U_hat) 

691 

692 Returns: 

693 sparse integration matrix 

694 """ 

695 return ( 

696 self.sparse_lib.diags(1 / (self.xp.arange(self.N - 1) + 1), offsets=-1) 

697 @ self.get_basis_change_matrix(p_out=1, p_in=0) 

698 * self.lin_trf_fac 

699 ) 

700 

701 def get_integration_constant(self, u_hat, axis): 

702 """ 

703 Get integration constant for lower bound of -1. See documentation of `UltrasphericalHelper.get_integration_matrix` for details. 

704 

705 Args: 

706 u_hat: Solution in spectral space 

707 axis: Axis you want to integrate over 

708 

709 Returns: 

710 Integration constant, has one less dimension than `u_hat` 

711 """ 

712 slices = [ 

713 None, 

714 ] * u_hat.ndim 

715 slices[axis] = slice(1, u_hat.shape[axis]) 

716 return self.xp.sum(u_hat[(*slices,)] * (-1) ** (self.xp.arange(u_hat.shape[axis] - 1)), axis=axis) 

717 

718 

719class FFTHelper(SpectralHelper1D): 

720 def __init__(self, *args, x0=0, x1=2 * np.pi, **kwargs): 

721 """ 

722 Constructor. 

723 Please refer to the parent class for additional arguments. Notably, you have to supply a resolution `N` and you 

724 may choose to run on GPUs via the `useGPU` argument. 

725 

726 Args: 

727 transform_type ('fft' or 'dct'): Either use DCT functions directly implemented in the transform library or 

728 use the FFT from the library to compute the DCT 

729 x0 (float, optional): Coordinate of left boundary 

730 x1 (float, optional): Coordinate of right boundary 

731 """ 

732 super().__init__(*args, x0=x0, x1=x1, **kwargs) 

733 

734 def get_1dgrid(self): 

735 """ 

736 We use equally spaced points including the left boundary and not including the right one, which is the left boundary. 

737 """ 

738 dx = self.L / self.N 

739 return self.xp.arange(self.N) * dx + self.x0 

740 

741 def get_wavenumbers(self): 

742 """ 

743 Be careful that this ordering is very unintuitive. 

744 """ 

745 return self.xp.fft.fftfreq(self.N, 1.0 / self.N) * 2 * np.pi / self.L 

746 

747 def get_differentiation_matrix(self, p=1): 

748 """ 

749 This matrix is diagonal, allowing to invert concurrently. 

750 

751 Args: 

752 p (int): Order of the derivative 

753 

754 Returns: 

755 sparse differentiation matrix 

756 """ 

757 k = self.get_wavenumbers() 

758 

759 if self.useGPU: 

760 # Have to raise the matrix to power p on CPU because the GPU equivalent is not implemented in CuPy at the time of writing. 

761 import scipy.sparse as sp 

762 

763 D = self.sparse_lib.diags(1j * k).get() 

764 return self.sparse_lib.csc_matrix(sp.linalg.matrix_power(D, p)) 

765 else: 

766 return self.linalg.matrix_power(self.sparse_lib.diags(1j * k), p) 

767 

768 def get_integration_matrix(self, p=1): 

769 """ 

770 Get integration matrix to compute `p`-th integral over the entire domain. 

771 

772 Args: 

773 p (int): Order of integral you want to compute 

774 

775 Returns: 

776 sparse integration matrix 

777 """ 

778 k = self.xp.array(self.get_wavenumbers(), dtype='complex128') 

779 k[0] = 1j * self.L 

780 return self.linalg.matrix_power(self.sparse_lib.diags(1 / (1j * k)), p) 

781 

782 def transform(self, u, axis=-1, **kwargs): 

783 """ 

784 1D FFT along axis. `kwargs` are passed on to the FFT library. 

785 

786 Args: 

787 u: Data you want to transform 

788 axis (int): Axis you want to transform along 

789 

790 Returns: 

791 transformed data 

792 """ 

793 return self.fft_lib.fft(u, axis=axis, **kwargs) 

794 

795 def itransform(self, u, axis=-1): 

796 """ 

797 Inverse 1D FFT. 

798 

799 Args: 

800 u: Data you want to transform 

801 axis (int): Axis you want to transform along 

802 

803 Returns: 

804 transformed data 

805 """ 

806 return self.fft_lib.ifft(u, axis=axis) 

807 

808 def get_BC(self, kind): 

809 """ 

810 Get a sort of boundary condition. You can use `kind=integral`, to fix the integral, or you can use `kind=Nyquist`. 

811 The latter is not really a boundary condition, but is used to set the Nyquist mode to some value, preferably zero. 

812 You should set the Nyquist mode zero when the solution in physical space is real and the resolution is even. 

813 

814 Args: 

815 kind ('integral' or 'nyquist'): Kind of BC 

816 

817 Returns: 

818 self.xp.ndarray: Boundary condition row 

819 """ 

820 if kind.lower() == 'integral': 

821 return self.get_integ_BC_row() 

822 elif kind.lower() == 'nyquist': 

823 assert ( 

824 self.N % 2 == 0 

825 ), f'Do not eliminate the Nyquist mode with odd resolution as it is fully resolved. You chose {self.N} in this axis' 

826 BC = self.xp.zeros(self.N) 

827 BC[self.get_Nyquist_mode_index()] = 1 

828 return BC 

829 else: 

830 return super().get_BC(kind) 

831 

832 def get_Nyquist_mode_index(self): 

833 """ 

834 Compute the index of the Nyquist mode, i.e. the mode with the lowest wavenumber, which doesn't have a positive 

835 counterpart for even resolution. This means real waves of this wave number cannot be properly resolved and you 

836 are best advised to set this mode zero if representing real functions on even-resolution grids is what you're 

837 after. 

838 

839 Returns: 

840 int: Index of the Nyquist mode 

841 """ 

842 k = self.get_wavenumbers() 

843 Nyquist_mode = min(k) 

844 return self.xp.where(k == Nyquist_mode)[0][0] 

845 

846 def get_integ_BC_row(self): 

847 """ 

848 Only the 0-mode has non-zero integral with FFT basis in periodic BCs 

849 """ 

850 me = self.xp.zeros(self.N) 

851 me[0] = self.L / self.N 

852 return me 

853 

854 

855class SpectralHelper: 

856 """ 

857 This class has three functions: 

858 - Easily assemble matrices containing multiple equations 

859 - Direct product of 1D bases to solve problems in more dimensions 

860 - Distribute the FFTs to facilitate concurrency. 

861 

862 Attributes: 

863 comm (mpi4py.Intracomm): MPI communicator 

864 debug (bool): Perform additional checks at extra computational cost 

865 useGPU (bool): Whether to use GPUs 

866 axes (list): List of 1D bases 

867 components (list): List of strings of the names of components in the equations 

868 full_BCs (list): List of Dictionaries containing all information about the boundary conditions 

869 BC_mat (list): List of lists of sparse matrices to put BCs into and eventually assemble the BC matrix from 

870 BCs (sparse matrix): Matrix containing only the BCs 

871 fft_cache (dict): Cache FFTs of various shapes here to facilitate padding and so on 

872 BC_rhs_mask (self.xp.ndarray): Mask values that contain boundary conditions in the right hand side 

873 BC_zero_index (self.xp.ndarray): Indeces of rows in the matrix that are replaced by BCs 

874 BC_line_zero_matrix (sparse matrix): Matrix that zeros rows where we can then add the BCs in using `BCs` 

875 rhs_BCs_hat (self.xp.ndarray): Boundary conditions in spectral space 

876 global_shape (tuple): Global shape of the solution as in `mpi4py-fft` 

877 local_slice (slice): Local slice of the solution as in `mpi4py-fft` 

878 fft_obj: When using distributed FFTs, this will be a parallel transform object from `mpi4py-fft` 

879 init (tuple): This is the same `init` that is used throughout the problem classes 

880 init_forward (tuple): This is the equivalent of `init` in spectral space 

881 """ 

882 

883 xp = np