Coverage for pySDC/helpers/spectral_helper.py: 90%

1import numpy as np 

2import scipy 

3from pySDC.implementations.datatype_classes.mesh import mesh 

4from scipy.special import factorial 

5from functools import partial, wraps 

6import logging 

7 

8 

9def cache(func): 

10 """ 

11 Decorator for caching return values of functions. 

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

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

14 

15 Example: 

16 

17 .. code-block:: python 

18 

19 num_calls = 0 

20 

21 @cache 

22 def increment(x): 

23 num_calls += 1 

24 return x + 1 

25 

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

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

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

29 

30 

31 Args: 

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

33 

34 Returns: 

35 return value of func 

36 """ 

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

38 

39 @wraps(func) 

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

41 if not hasattr(self, attr_cache): 

42 setattr(self, attr_cache, {}) 

43 

44 cache = getattr(self, attr_cache) 

45 

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

47 if key in cache: 

48 return cache[key] 

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

50 cache[key] = result 

51 return result 

52 

53 return wrapper 

54 

55 

56class SpectralHelper1D: 

57 """ 

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

59 all bases need to have. 

60 

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

62 the code for GPUs. 

63 

64 Attributes: 

65 N (int): Resolution 

66 x0 (float): Coordinate of left boundary 

67 x1 (float): Coordinate of right boundary 

68 L (float): Length of the domain 

69 useGPU (bool): Whether to use GPUs 

70 

71 """ 

72 

73 fft_lib = scipy.fft 

74 sparse_lib = scipy.sparse 

75 linalg = scipy.sparse.linalg 

76 xp = np 

77 distributable = False 

78 

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

80 """ 

81 Constructor 

82 

83 Args: 

84 N (int): Resolution 

85 x0 (float): Coordinate of left boundary 

86 x1 (float): Coordinate of right boundary 

87 useGPU (bool): Whether to use GPUs 

88 useFFTW (bool): Whether to use FFTW for the transforms 

89 """ 

90 self.N = N 

91 self.x0 = x0 

92 self.x1 = x1 

93 self.L = x1 - x0 

94 self.useGPU = useGPU 

95 self.plans = {} 

96 self.logger = logging.getLogger(name=type(self).__name__) 

97 

98 if useGPU: 

99 self.setup_GPU() 

100 else: 

101 self.setup_CPU(useFFTW=useFFTW) 

102 

103 if useGPU and useFFTW: 

104 raise ValueError('Please run either on GPUs or with FFTW, not both!') 

105 

106 @classmethod 

107 def setup_GPU(cls): 

108 """switch to GPU modules""" 

109 import cupy as cp 

110 import cupyx.scipy.sparse as sparse_lib 

111 import cupyx.scipy.sparse.linalg as linalg 

112 import cupyx.scipy.fft as fft_lib 

113 from pySDC.implementations.datatype_classes.cupy_mesh import cupy_mesh 

114 

115 cls.xp = cp 

116 cls.sparse_lib = sparse_lib 

117 cls.linalg = linalg 

118 cls.fft_lib = fft_lib 

119 

120 @classmethod 

121 def setup_CPU(cls, useFFTW=False): 

122 """switch to CPU modules""" 

123 

124 cls.xp = np 

125 cls.sparse_lib = scipy.sparse 

126 cls.linalg = scipy.sparse.linalg 

127 

128 if useFFTW: 

129 from mpi4py_fft import fftw 

130 

131 cls.fft_backend = 'fftw' 

132 cls.fft_lib = fftw 

133 else: 

134 cls.fft_backend = 'scipy' 

135 cls.fft_lib = scipy.fft 

136 

137 cls.fft_comm_backend = 'MPI' 

138 cls.dtype = mesh 

139 

140 def get_Id(self): 

141 """ 

142 Get identity matrix 

143 

144 Returns: 

145 sparse diagonal identity matrix 

146 """ 

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

148 

149 def get_zero(self): 

150 """ 

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

152 

153 Returns: 

154 sparse matrix with zeros everywhere 

155 """ 

156 return 0 * self.get_Id() 

157 

158 def get_differentiation_matrix(self): 

159 raise NotImplementedError() 

160 

161 def get_integration_matrix(self): 

162 raise NotImplementedError() 

163 

164 def get_wavenumbers(self): 

165 """ 

166 Get the grid in spectral space 

167 """ 

168 raise NotImplementedError 

169 

170 def get_empty_operator_matrix(self, S, O): 

171 """ 

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

173 

174 Args: 

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

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

177 

178 Returns: 

179 list of lists containing sparse zeros 

180 """ 

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

182 

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

184 """ 

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

186 between the various bases. 

187 

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

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

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

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

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

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

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

195 

196 Returns: 

197 sparse bases change matrix 

198 """ 

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

200 

201 def get_BC(self, kind): 

202 """ 

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

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

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

206 

207 Args: 

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

209 individual 1D bases for what is implemented 

210 

211 Returns: 

212 self.xp.array: Boundary condition 

213 """ 

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

215 

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

217 """ 

218 Get a bandpass filter. 

219 

220 Args: 

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

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

223 

224 Returns: 

225 sparse matrix 

226 """ 

227 

228 k = abs(self.get_wavenumbers()) 

229 

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

231 

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

233 

234 if self.useGPU: 

235 Id = self.get_Id().get() 

236 else: 

237 Id = self.get_Id() 

238 F = Id.tolil() 

239 F[:, mask] = 0 

240 return F.tocsc() 

241 

242 def get_1dgrid(self): 

243 """ 

244 Get the grid in physical space 

245 

246 Returns: 

247 self.xp.array: Grid 

248 """ 

249 raise NotImplementedError 

250 

251 

252class ChebychevHelper(SpectralHelper1D): 

253 """ 

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

255 between physical and spectral space by discrete cosine transform. 

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

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

258 be formulated in first order formulation. 

259 

260 This implementation is largely based on the Dedalus paper (https://doi.org/10.1103/PhysRevResearch.2.023068). 

261 """ 

262 

263 def __init__(self, *args, x0=-1, x1=1, **kwargs): 

264 """ 

265 Constructor. 

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

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

268 

269 Args: 

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

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

272 """ 

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

274 self.lin_trf_fac = (x1 - x0) / 2 

275 self.lin_trf_off = (x1 + x0) / 2 

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

277 

278 self.norm = self.get_norm() 

279 

280 def get_1dgrid(self): 

281 ''' 

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

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

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

285 

286 Returns: 

287 numpy.ndarray: 1D grid 

288 ''' 

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

290 

291 def get_wavenumbers(self): 

292 """Get the domain in spectral space""" 

293 return self.xp.arange(self.N) 

294 

295 @cache 

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

297 ''' 

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

299 - T: Chebychev polynomials of first kind 

300 - U: Chebychev polynomials of second kind 

301 - D: Dirichlet recombination. 

302 

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

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

305 

306 Args: 

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

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

309 

310 Returns: 

311 scipy.sparse: Sparse conversion matrix 

312 ''' 

313 N = N if N else self.N 

314 sp = self.sparse_lib 

315 xp = self.xp 

316 

317 def get_forward_conv(name): 

318 if name == 'T2U': 

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

320 mat[:, 0] *= 2 

321 elif name == 'D2T': 

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

323 elif name[0] == name[-1]: 

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

325 else: 

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

327 return mat 

328 

329 try: 

330 mat = get_forward_conv(name) 

331 except NotImplementedError as E: 

332 try: 

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

334 import scipy.sparse as sp 

335 

336 if self.sparse_lib == sp: 

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

338 else: 

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

340 except NotImplementedError: 

341 raise NotImplementedError from E 

342 

343 return mat 

344 

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

346 """ 

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

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

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

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

351 

352 Args: 

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

354 

355 Returns: 

356 Sparse conversion matrix 

357 """ 

358 return self.get_conv(conv) 

359 

360 def get_integration_matrix(self, lbnd=0): 

361 """ 

362 Get matrix for integration 

363 

364 Args: 

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

366 

367 Returns: 

368 Sparse integration matrix 

369 """ 

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

371 n = self.xp.arange(self.N) 

372 if lbnd == 0: 

373 S = S.tocsc() 

374 S[0, 1::2] = ( 

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

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

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

378 ) * self.lin_trf_fac 

379 else: 

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

381 return S 

382 

383 def get_differentiation_matrix(self, p=1): 

384 ''' 

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

386 

387 Args: 

388 p (int): Derivative you want to compute 

389 

390 Returns: 

391 numpy.ndarray: Differentiation matrix 

392 ''' 

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

394 for j in range(self.N): 

395 for k in range(j): 

396 D[k, j] = 2 * j * ((j - k) % 2) 

397 

398 D[0, :] /= 2 

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

400 

401 @cache 

402 def get_norm(self, N=None): 

403 ''' 

404 Get normalization for converting Chebychev coefficients and DCT 

405 

406 Args: 

407 N (int, optional): Resolution 

408 

409 Returns: 

410 self.xp.array: Normalization 

411 ''' 

412 N = self.N if N is None else N 

413 norm = self.xp.ones(N) / N 

414 norm[0] /= 2 

415 return norm 

416 

417 def transform(self, u, *args, axes=None, shape=None, **kwargs): 

418 """ 

419 DCT along axes. `kwargs` will be passed on to the FFT library. 

420 

421 Args: 

422 u: Data you want to transform 

423 axes (tuple): Axes you want to transform along 

424 

425 Returns: 

426 Data in spectral space 

427 """ 

428 axes = axes if axes else tuple(i for i in range(u.ndim)) 

429 kwargs['s'] = shape 

430 kwargs['norm'] = kwargs.get('norm', 'backward') 

431 

432 trf = self.fft_lib.dctn(u, *args, axes=axes, type=2, **kwargs) 

433 for axis in axes: 

434 

435 if self.N < trf.shape[axis]: 

436 # mpi4py-fft implements padding only for FFT, where the frequencies are sorted such that the zeros are 

437 # removed in the middle rather than the end. We need to resort this here and put the highest frequencies 

438 # in the middle. 

439 _trf = self.xp.zeros_like(trf) 

440 N = self.N 

441 N_pad = _trf.shape[axis] - N 

442 end_first_half = N // 2 + 1 

443 

444 # copy first "half" 

445 su = [slice(None)] * trf.ndim 

446 su[axis] = slice(0, end_first_half) 

447 _trf[tuple(su)] = trf[tuple(su)] 

448 

449 # copy second "half" 

450 su = [slice(None)] * u.ndim 

451 su[axis] = slice(end_first_half + N_pad, None) 

452 s_u = [slice(None)] * u.ndim 

453 s_u[axis] = slice(end_first_half, N) 

454 _trf[tuple(su)] = trf[tuple(s_u)] 

455 

456 # # copy values to be cut 

457 # su = [slice(None)] * u.ndim 

458 # su[axis] = slice(end_first_half, end_first_half + N_pad) 

459 # s_u = [slice(None)] * u.ndim 

460 # s_u[axis] = slice(-N_pad, None) 

461 # _trf[tuple(su)] = trf[tuple(s_u)] 

462 

463 trf = _trf 

464 

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

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

467 norm = self.xp.ones(trf.shape[axis]) * self.norm[-1] 

468 norm[: self.N] = self.norm 

469 trf *= norm[(*expansion,)] 

470 return trf 

471 

472 def itransform(self, u, *args, axes=None, shape=None, **kwargs): 

473 """ 

474 Inverse DCT along axis. 

475 

476 Args: 

477 u: Data you want to transform 

478 axes (tuple): Axes you want to transform along 

479 

480 Returns: 

481 Data in physical space 

482 """ 

483 axes = axes if axes else tuple(i for i in range(u.ndim)) 

484 kwargs['s'] = shape 

485 kwargs['norm'] = kwargs.get('norm', 'backward') 

486 kwargs['overwrite_x'] = kwargs.get('overwrite_x', False) 

487 

488 for axis in axes: 

489 

490 if self.N == u.shape[axis]: 

491 _u = u.copy() 

492 else: 

493 # mpi4py-fft implements padding only for FFT, where the frequencies are sorted such that the zeros are 

494 # added in the middle rather than the end. We need to resort this here and put the padding in the end. 

495 N = self.N 

496 _u = self.xp.zeros_like(u) 

497 

498 # copy first half 

499 su = [slice(None)] * u.ndim 

500 su[axis] = slice(0, N // 2 + 1) 

501 _u[tuple(su)] = u[tuple(su)] 

502 

503 # copy second half 

504 su = [slice(None)] * u.ndim 

505 su[axis] = slice(-(N // 2), None) 

506 s_u = [slice(None)] * u.ndim 

507 s_u[axis] = slice(N // 2, N // 2 + (N // 2)) 

508 _u[tuple(s_u)] = u[tuple(su)] 

509 

510 if N % 2 == 0: 

511 su = [slice(None)] * u.ndim 

512 su[axis] = N // 2 

513 _u[tuple(su)] *= 2 

514 

515 # generate norm 

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

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

518 norm = self.xp.ones(_u.shape[axis]) 

519 norm[: self.N] = self.norm 

520 norm = self.get_norm(u.shape[axis]) * _u.shape[axis] / self.N 

521 

522 _u /= norm[(*expansion,)] 

523 

524 return self.fft_lib.idctn(_u, *args, axes=axes, type=2, **kwargs) 

525 

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

527 """ 

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

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

530 set the BC. 

531 

532 Args: 

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

534 """ 

535 if kind.lower() == 'integral': 

536 return self.get_integ_BC_row(**kwargs) 

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

538 return self.get_Dirichlet_BC_row(**kwargs) 

539 else: 

540 return super().get_BC(kind) 

541 

542 def get_integ_BC_row(self): 

543 """ 

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

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

546 

547 Returns: 

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

549 """ 

550 n = self.xp.arange(self.N) + 1 

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

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

553 me[0] = 2.0 

554 return me 

555 

556 def get_Dirichlet_BC_row(self, x): 

557 """ 

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

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

560 

561 Args: 

562 x (float): Position of the boundary condition 

563 

564 Returns: 

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

566 """ 

567 if x == -1: 

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

569 elif x == 1: 

570 return self.xp.ones(self.N) 

571 elif x == 0: 

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

573 n[2::4] *= -1 

574 return n 

575 else: 

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

577 

578 def get_Dirichlet_recombination_matrix(self): 

579 ''' 

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

581 This makes for a good right preconditioner. 

582 

583 Returns: 

584 scipy.sparse: Sparse conversion matrix 

585 ''' 

586 N = self.N 

587 sp = self.sparse_lib 

588 xp = self.xp 

589 

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

591 

592 

593class UltrasphericalHelper(ChebychevHelper): 

594 """ 

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

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

597 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. 

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

599 

600 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. 

601 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. 

602 """ 

603 

604 def get_differentiation_matrix(self, p=1): 

605 """ 

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

607 

608 Args: 

609 p (int): Order of the derivative 

610 

611 Returns: 

612 sparse differentiation matrix 

613 """ 

614 sp = self.sparse_lib 

615 xp = self.xp 

616 N = self.N 

617 l = p 

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

619 

620 def get_S(self, lmbda): 

621 """ 

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

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

624 

625 Args: 

626 lmbda (int): Ingoing derivative base 

627 

628 Returns: 

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

630 """ 

631 N = self.N 

632 

633 if lmbda == 0: 

634 sp = scipy.sparse 

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

636 mat[:, 0] *= 2 

637 else: 

638 sp = self.sparse_lib 

639 xp = self.xp 

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

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

642 ) 

643 

644 return self.sparse_lib.csc_matrix(mat) 

645 

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

647 """ 

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

649 

650 Args: 

651 p_out (int): Resulting derivative base 

652 p_in (int): Ingoing derivative base 

653 """ 

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

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

656 mat_fwd = self.get_S(i) @ mat_fwd 

657 

658 if p_out > p_in: 

659 return mat_fwd 

660 

661 else: 

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

663 import scipy.sparse as sp 

664 

665 if self.useGPU: 

666 mat_fwd = mat_fwd.get() 

667 

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

669 

670 return self.sparse_lib.csc_matrix(mat_bck) 

671 

672 def get_integration_matrix(self): 

673 """ 

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

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

676 

677 Example: 

678 

679 .. code-block:: python 

680 

681 import numpy as np 

682 from pySDC.helpers.spectral_helper import UltrasphericalHelper 

683 

684 N = 4 

685 helper = UltrasphericalHelper(N) 

686 coeffs = np.random.random(N) 

687 coeffs[-1] = 0 

688 

689 poly = np.polynomial.Chebyshev(coeffs) 

690 

691 S = helper.get_integration_matrix() 

692 U_hat = S @ coeffs 

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

694 

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

696 

697 Returns: 

698 sparse integration matrix 

699 """ 

700 return ( 

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

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

703 * self.lin_trf_fac 

704 ) 

705 

706 def get_integration_constant(self, u_hat, axis): 

707 """ 

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

709 

710 Args: 

711 u_hat: Solution in spectral space 

712 axis: Axis you want to integrate over 

713 

714 Returns: 

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

716 """ 

717 slices = [ 

718 None, 

719 ] * u_hat.ndim 

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

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

722 

723 

724class FFTHelper(SpectralHelper1D): 

725 distributable = True 

726 

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

728 """ 

729 Constructor. 

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

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

732 

733 Args: 

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

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

736 """ 

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

738 

739 def get_1dgrid(self): 

740 """ 

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

742 """ 

743 dx = self.L / self.N 

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

745 

746 def get_wavenumbers(self): 

747 """ 

748 Be careful that this ordering is very unintuitive. 

749 """ 

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

751 

752 def get_differentiation_matrix(self, p=1): 

753 """ 

754 This matrix is diagonal, allowing to invert concurrently. 

755 

756 Args: 

757 p (int): Order of the derivative 

758 

759 Returns: 

760 sparse differentiation matrix 

761 """ 

762 k = self.get_wavenumbers() 

763 

764 if self.useGPU: 

765 if p > 1: 

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

767 from scipy.sparse.linalg import matrix_power 

768 

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

770 return self.sparse_lib.csc_matrix(matrix_power(D, p)) 

771 else: 

772 return self.sparse_lib.diags(1j * k) 

773 else: 

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

775 

776 def get_integration_matrix(self, p=1): 

777 """ 

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

779 

780 Args: 

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

782 

783 Returns: 

784 sparse integration matrix 

785 """ 

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

787 k[0] = 1j * self.L 

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

789 

790 def get_plan(self, u, forward, *args, **kwargs): 

791 if self.fft_lib.__name__ == 'mpi4py_fft.fftw': 

792 if 'axes' in kwargs.keys(): 

793 kwargs['axes'] = tuple(kwargs['axes']) 

794 key = (forward, u.shape, args, *(me for me in kwargs.values())) 

795 if key in self.plans.keys(): 

796 return self.plans[key] 

797 else: 

798 self.logger.debug(f'Generating FFT plan for {key=}') 

799 transform = self.fft_lib.fftn(u, *args, **kwargs) if forward else self.fft_lib.ifftn(u, *args, **kwargs) 

800 self.plans[key] = transform 

801 

802 return self.plans[key] 

803 else: 

804 if forward: 

805 return partial(self.fft_lib.fftn, norm=kwargs.get('norm', 'backward')) 

806 else: 

807 return partial(self.fft_lib.ifftn, norm=kwargs.get('norm', 'forward')) 

808 

809 def transform(self, u, *args, axes=None, shape=None, **kwargs): 

810 """ 

811 FFT along axes. `kwargs` are passed on to the FFT library. 

812 

813 Args: 

814 u: Data you want to transform 

815 axes (tuple): Axes you want to transform over 

816 

817 Returns: 

818 transformed data 

819 """ 

820 axes = axes if axes else tuple(i for i in range(u.ndim)) 

821 kwargs['s'] = shape 

822 plan = self.get_plan(u, *args, forward=True, axes=axes, **kwargs) 

823 return plan(u, *args, axes=axes, **kwargs) 

824 

825 def itransform(self, u, *args, axes=None, shape=None, **kwargs): 

826 """ 

827 Inverse FFT. 

828 

829 Args: 

830 u: Data you want to transform 

831 axes (tuple): Axes over which to transform 

832 

833 Returns: 

834 transformed data 

835 """ 

836 axes = axes if axes else tuple(i for i in range(u.ndim)) 

837 kwargs['s'] = shape 

838 plan = self.get_plan(u, *args, forward=False, axes=axes, **kwargs) 

839 return plan(u, *args, axes=axes, **kwargs) / np.prod([u.shape[axis] for axis in axes])