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graphengine/third_party/fwkacllib/inc/ops/linalg_ops.h

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  1. /**

  2.  * Copyright 2019-2020 Huawei Technologies Co., Ltd

  3.  *

  4.  * Licensed under the Apache License, Version 2.0 (the "License");

  5.  * you may not use this file except in compliance with the License.

  6.  * You may obtain a copy of the License at

  7.  *

  8.  * http://www.apache.org/licenses/LICENSE-2.0

  9.  *

  10.  * Unless required by applicable law or agreed to in writing, software

  11.  * distributed under the License is distributed on an "AS IS" BASIS,

  12.  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.

  13.  * See the License for the specific language governing permissions and

  14.  * limitations under the License.

  15.  */

  16. 

  17. /*!

  18.  * \file linalg_ops.h

  19.  * \brief

  20.  */

  21. #ifndef OPS_BUILT_IN_OP_PROTO_INC_LINALG_OPS_H_

  22. #define OPS_BUILT_IN_OP_PROTO_INC_LINALG_OPS_H_

  23. 

  24. #include "graph/operator_reg.h"

  25. #include "graph/operator.h"

  26. 

  27. namespace ge {

  28. 

  29. /**

  30. *@brief Computes the reverse mode backpropagated gradient of the Cholesky

  31. algorithm . \n

  32. 

  33. *@par Inputs:

  34. *The input x has to be symmetric and positive definite. Inputs include:

  35. *@li x:A Tensor. Must be one of the following types: double, float32. Output

  36. of batch Cholesky algorithm x = cholesky(A). Shape is [..., M, M]. Algorithm

  37. depends only on lower triangular part of the innermost matrices of this tensor.

  38. *@li grad:A Tensor. Must have the same type as l. df/dx where f is some

  39. scalar function. Shape is [..., M, M]. Algorithm depends only on lower

  40. triangular part of the innermost matrices of this tensor . \n

  41. 

  42. *@par Outputs:

  43. *y:A Tensor. Has the same type as x . \n

  44. 

  45. *@attention Constraints:

  46. *The input x is a tensor of shape [..., M, M] whose inner-most 2 dimensions

  47. form square matrices.

  48. 

  49. *@par Third-party framework compatibility

  50. *Compatible with tensorflow CholeskyGrad operator.

  51. */

  52. 

  53. REG_OP(CholeskyGrad)

  54.     .INPUT(x, TensorType({DT_FLOAT, DT_DOUBLE}))

  55.     .INPUT(grad, TensorType({DT_FLOAT, DT_DOUBLE}))

  56.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  57.     .OP_END_FACTORY_REG(CholeskyGrad)

  58. 

  59. /**

  60. *@brief Computes the Cholesky decomposition of one or more square matrices . \n

  61. 

  62. *@par Inputs:

  63. *The input x has to be symmetric and positive definite.Inputs include:

  64. *x:A Tensor. Must be one of the following types: double, float32. Shape

  65. is [..., M, M] . \n

  66. 

  67. *@par Outputs:

  68. *y:A Tensor. Has the same type as x . \n

  69. 

  70. *@attention Constraints:

  71. *The input x is a tensor of shape [..., M, M] whose inner-most 2 dimensions

  72. form square matrices.

  73. 

  74. *@par Third-party framework compatibility

  75. *Compatible with tensorflow Cholesky operator.

  76. */

  77. 

  78. REG_OP(Cholesky)

  79.     .INPUT(x, TensorType({DT_FLOAT, DT_DOUBLE}))

  80.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  81.     .OP_END_FACTORY_REG(Cholesky)

  82. 

  83. /**

  84. *@brief Computes the sign and the log of the absolute value of the determinant

  85. of one or more square matrices . \n

  86. 

  87. *@par Inputs:

  88. *The input x is a tensor of shape [N, M, M] whose inner-most 2 dimensions

  89. form square matrices. Inputs include:

  90. *x:A Tensor. Must be one of the following types: double, float32. Shape is

  91. [..., M, M] . \n

  92. 

  93. *@par Outputs:

  94. *@li y:A Tensor. Has the same type as x.

  95. *@li sign:A Tensor. Has the same type as x . \n

  96. 

  97. *@attention Constraints:

  98. *The input x is a tensor of shape [N, M, M] whose inner-most 2 dimensions

  99. form square matrices. \n

  100. 

  101. *@par Third-party framework compatibility

  102. *Compatible with tensorflow LogMatrixDeterminant operator.

  103. */

  104. 

  105. REG_OP(LogMatrixDeterminant)

  106.     .INPUT(x, TensorType({DT_FLOAT, DT_DOUBLE}))

  107.     .OUTPUT(sign, TensorType({DT_FLOAT, DT_DOUBLE}))

  108.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  109.     .OP_END_FACTORY_REG(LogMatrixDeterminant)

  110. 

  111. /**

  112. *@brief Computes the determinant of one or more square matrices . \n

  113. 

  114. *@par Inputs:

  115. *The input x is a tensor of shape [N, M, M] whose inner-most 2 dimensions

  116. form square matrices. Inputs include:

  117. *x:A Tensor. Must be one of the following types: double, float32. Shape is

  118. [..., M, M] . \n

  119. 

  120. *@par Outputs:

  121. *y:A Tensor. Has the same type as x . \n

  122. 

  123. *@attention Constraints:

  124. *The input x is a tensor of shape [..., M, M] whose inner-most 2 dimensions

  125. form square matrices.

  126. 

  127. *@par Third-party framework compatibility

  128. *Compatible with tensorflow MatrixDeterminant operator.

  129. */

  130. 

  131. REG_OP(MatrixDeterminant)

  132.     .INPUT(x, TensorType({DT_FLOAT, DT_DOUBLE}))

  133.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  134.     .OP_END_FACTORY_REG(MatrixDeterminant)

  135. 

  136. /**

  137. *@brief Computes the inverse of one or more square invertible matrices or

  138. their adjoints (conjugate transposes) . \n

  139. 

  140. *@par Inputs:

  141. *The input x is a tensor of shape [..., M, M] whose inner-most 2 dimensions

  142. form square matrices. Inputs include:

  143. *x:A Tensor. Must be one of the following types: double, float. Shape is

  144. [..., M, M] . \n

  145. 

  146. *@par Attributes:

  147. *adjoint:An optional bool. Defaults to False.Boolean indicating whether to

  148. deal with matrix or its (block-wise) adjoint . \n

  149. 

  150. *@par Outputs:

  151. *y:A Tensor. Has the same type as x . \n

  152. 

  153. *@attention Constraints:

  154. *The input x is a tensor of shape [..., M, M] whose inner-most 2 dimensions

  155. form square matrices.  \n

  156. 

  157. *@par Third-party framework compatibility

  158. *Compatible with tensorflow MatrixInverse operator.

  159. */

  160. 

  161. REG_OP(MatrixInverse)

  162.     .INPUT(x, TensorType({DT_FLOAT, DT_DOUBLE}))

  163.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  164.     .ATTR(adjoint, Bool, false)

  165.     .OP_END_FACTORY_REG(MatrixInverse)

  166. 

  167. /**

  168. *@brief Solves systems of linear equations . \n

  169. 

  170. *@par Inputs:

  171. *The input rhs must have the same type as matrix. Inputs include:

  172. *@li matrix:A Tensor. Must be one of the following types: double, float.

  173. Shape is [..., M, M].

  174. *@li rhs:A Tensor. Must have the same type as matrix. Shape is [..., M, K] . \n

  175. 

  176. *@par Attributes:

  177. *adjoint:An optional bool. Defaults to False.Boolean indicating whether to

  178. solve with matrix or its (block-wise) adjoint . \n

  179. 

  180. *@par Outputs:

  181. *y:A Tensor. Has the same type as matrix . \n

  182. 

  183. *@attention Constraints:

  184. *The input matrix is a tensor of shape [..., M, M] whose inner-most 2

  185. dimensions form square matrices.  \n

  186. 

  187. *@par Third-party framework compatibility

  188. *Compatible with tensorflow MatrixSolve operator.

  189. */

  190. 

  191. REG_OP(MatrixSolve)

  192.     .INPUT(matrix, TensorType({DT_FLOAT, DT_DOUBLE}))

  193.     .INPUT(rhs, TensorType({DT_FLOAT, DT_DOUBLE}))

  194.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  195.     .ATTR(adjoint, Bool, false)

  196.     .OP_END_FACTORY_REG(MatrixSolve)

  197. 

  198. /**

  199. *@brief Solves systems of linear equations . \n

  200. 

  201. *@par Inputs:

  202. *The input rhs must have the same type as matrix. Inputs include:

  203. *@li matrix:A Tensor. Shape is [..., M, M].

  204. *@li rhs:A Tensor. Must have the same type as matrix. Shape is [..., M, K].

  205. *@li l2:0-D double Tensor. Ignored if fast=False . \n

  206. 

  207. *@par Attributes:

  208. *fast:bool. Defaults to True . \n

  209. 

  210. *@par Outputs:

  211. *y:Tensor of shape [..., N, K] whose inner-most 2 dimensions form M-by-K

  212. matrices that solve the equations matrix[..., :, :] * output[..., :, :] =

  213. rhs[..., :, :] in the least squares sense . \n

  214. 

  215. *@attention Constraints:

  216. *The input matrix matrix is a tensor of shape [..., M, M] whose inner-most 2

  217. dimensions form square matrices.  \n

  218. 

  219. *@par Third-party framework compatibility

  220. *Compatible with tensorflow MatrixSolveLs operator.

  221. */

  222. 

  223. REG_OP(MatrixSolveLs)

  224.     .INPUT(matrix, TensorType({DT_FLOAT, DT_DOUBLE}))

  225.     .INPUT(rhs, TensorType({DT_FLOAT, DT_DOUBLE}))

  226.     .INPUT(l2, TensorType({DT_DOUBLE}))

  227.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  228.     .ATTR(fast, Bool, true)

  229.     .OP_END_FACTORY_REG(MatrixSolveLs)

  230. 

  231. /**

  232. *@brief Solves systems of linear equations with upper or lower triangular

  233. matrices by backsubstitution . \n

  234. 

  235. *@par Inputs:

  236. *The input rhs must have the same type as matrix. Inputs include:

  237. *@li matrix: A Tensor. Must be one of the following types: double, float.

  238. Shape is [..., M, M].

  239. *@li rhs:A Tensor. Must have the same type as matrix. Shape is [..., M, K] . \n

  240. 

  241. *@par Attributes:

  242. *@li lower: An optional bool. Defaults to True. Boolean indicating whether

  243. the innermost matrices in matrix are lower or upper triangular.

  244. *@li An optional bool. Defaults to False. Boolean indicating whether to solve

  245. with matrix or its (block-wise) adjoint . \n

  246. 

  247. *@par Outputs:

  248. *y:A Tensor. Has the same type as matrix . \n

  249. 

  250. *@attention Constraints:

  251. *The input matrix is a tensor of shape [..., M, M] whose inner-most 2

  252. dimensions form square matrices.  \n

  253. 

  254. *@par Third-party framework compatibility

  255. *Compatible with tensorflow MatrixTriangularSolve operator.

  256. */

  257. 

  258. REG_OP(MatrixTriangularSolve)

  259.     .INPUT(matrix, TensorType({DT_FLOAT, DT_DOUBLE}))

  260.     .INPUT(rhs, TensorType({DT_FLOAT, DT_DOUBLE}))

  261.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  262.     .ATTR(lower, Bool, true)

  263.     .ATTR(adjoint, Bool, false)

  264.     .OP_END_FACTORY_REG(MatrixTriangularSolve)

  265. 

  266. /**

  267. *@brief Computes the QR decompositions of one or more matrices . \n

  268. 

  269. *@par Inputs:

  270. *The input shape of x must be [..., M, N]. Inputs include:

  271. *x:A Tensor whose shape is [..., M, N]. Must be one of the following types:

  272. double, float . \n

  273. 

  274. *@par Attributes:

  275. *full_matrices: An optional bool. Defaults to False. If true, compute

  276. full-sized q and r. If false (the default), compute only the leading P

  277. columns of q . \n

  278. 

  279. *@par Outputs:

  280. *@li q: A Tensor. Has the same type as x.

  281. *@li r: A Tensor. Has the same type as x . \n

  282. 

  283. *@attention Constraints:

  284. *The input matrix x is a tensor of shape [..., M, N] whose inner-most 2

  285. dimensions form matrices of size [M, N].  \n

  286. 

  287. *@par Third-party framework compatibility

  288. *Compatible with tensorflow Qr operator.

  289. */

  290. 

  291. REG_OP(Qr)

  292.     .INPUT(x, TensorType({ DT_FLOAT16, DT_FLOAT, DT_DOUBLE }))

  293.     .OUTPUT(q, TensorType({ DT_FLOAT16, DT_FLOAT, DT_DOUBLE }))

  294.     .OUTPUT(r, TensorType({ DT_FLOAT16, DT_FLOAT, DT_DOUBLE }))

  295.     .ATTR(full_matrices, Bool, false)

  296.     .OP_END_FACTORY_REG(Qr)

  297. 

  298. /**

  299. *@brief Computes the eigen decomposition of a batch of self-adjoint matrices . \n

  300. 

  301. *@par Inputs:

  302. *The input shape of x must be [..., N, N]. Inputs include:

  303. *x:Tensor of shape [..., N, N]. Only the lower triangular part of each inner

  304. inner matrix is referenced . \n

  305. 

  306. *@par Attributes:

  307. *compute_v:bool. Defaults to True . \n

  308. 

  309. *@par Outputs:

  310. *@li eigen_value:Eigenvalues. Shape is [..., N]. Sorted in non-decreasing order.

  311. *@li eigen_vector:Shape is [..., N, N]. The columns of the inner most matrices

  312. contain eigenvectors of the corresponding matrices in tensor

  313. 

  314. *@attention Constraints:

  315. *The input x is a tensor of shape [..., N, N] whose inner-most 2 dimensions

  316. form square matrices.   \n

  317. 

  318. *@par Third-party framework compatibility

  319. *Compatible with tensorflow SelfAdjointEig operator.

  320. */

  321. 

  322. REG_OP(SelfAdjointEig)

  323.     .INPUT(x, TensorType({ DT_DOUBLE, DT_FLOAT }))

  324.     .OUTPUT(eigen_value, TensorType({ DT_DOUBLE, DT_FLOAT }))

  325.     .OUTPUT(eigen_vector, TensorType({ DT_DOUBLE, DT_FLOAT }))

  326.     .ATTR(compute_v, Bool, true)

  327.     .OP_END_FACTORY_REG(SelfAdjointEig)

  328. 

  329. /**

  330. *@brief Computes the singular value decompositions of one or more matrices . \n

  331. 

  332. *@par Inputs:

  333. *The input shape of x must be [..., N, N]. Inputs include:

  334. *x:Tensor of shape [..., M, N]. Let P be the minimum of M and N . \n

  335. 

  336. *@par Attributes:

  337. *compute_uv:If True then left and right singular vectors will be computed and

  338. returned in u and v, respectively. Otherwise, only the singular values will

  339. be computed, which can be significantly faster . \n

  340. 

  341. *@par Outputs:

  342. *@li sigma:Singular values. Shape is [..., P]. The values are sorted in

  343. reverse order of magnitude, so s[..., 0] is the largest value, s[..., 1]

  344. is the second largest, etc.

  345. *@li u:Left singular vectors. If full_matrices is False (default) then shape

  346. is [..., M, P]; if full_matrices is True then shape is [..., M, M]. Not

  347. returned if compute_uv is False.

  348. *@li v:Right singular vectors. If full_matrices is False (default) then shape

  349. is [..., N, P]. If full_matrices is True then shape is [..., N, N]. Not

  350. returned if compute_uv is False . \n

  351. 

  352. *@attention Constraints:

  353. *The input x is a tensor of shape [..., N, N] whose inner-most 2 dimensions

  354. form square matrices.  \n

  355. 

  356. *@par Third-party framework compatibility

  357. *Compatible with tensorflow Svd operator

  358. */

  359. 

  360. REG_OP(Svd)

  361.     .INPUT(x, TensorType({ DT_DOUBLE, DT_FLOAT }))

  362.     .OUTPUT(sigma, TensorType({ DT_DOUBLE, DT_FLOAT }))

  363.     .OUTPUT(u, TensorType({ DT_DOUBLE, DT_FLOAT }))

  364.     .OUTPUT(v, TensorType({ DT_DOUBLE, DT_FLOAT }))

  365.     .ATTR(compute_uv, Bool, true)

  366.     .ATTR(full_matrices, Bool, false)

  367.     .OP_END_FACTORY_REG(Svd)

  368. 

  369. /**

  370. *@brief Computes the LU decomposition of one or more square matrices . \n

  371. 

  372. *@par Inputs:

  373. *input: A tensor of shape `[..., M, M]` whose inner-most 2 dimensions form

  374. matrices of size `[M, M]` . \n

  375. 

  376. *@par Outputs:

  377. *@li lu: A tensor of shape `[..., M, M]` whose strictly lower triangular part

  378. denotes the lower triangular factor `L` with unit diagonal.

  379. *@li p: upper triangular part denotes the upper triangular factor `U`.Permutation

  380. of the rows encoded as a list of indices in `0..M-1`. Shape is `[..., M]` . \n

  381. 

  382. *@par Third-party framework compatibility

  383. * Compatible with TensorFlow Lu operator.

  384. */

  385. 

  386. REG_OP(Lu)

  387.     .INPUT(input, TensorType({DT_FLOAT, DT_DOUBLE}))

  388.     .OUTPUT(lu, TensorType({DT_FLOAT, DT_DOUBLE}))

  389.     .OUTPUT(p, TensorType({DT_INT32, DT_INT64}))

  390.     .REQUIRED_ATTR(output_idx_type, Type)

  391.     .OP_END_FACTORY_REG(Lu)

  392. 

  393. /**

  394. *@brief Computes the matrix square root of one or more square matrices . \n

  395. 

  396. *@par Inputs:

  397. *input: Shape is `[..., M, M]` . \n

  398. 

  399. *@par Outputs:

  400. y: Shape is `[..., M, M]` . \n

  401. 

  402. *@par Third-party framework compatibility

  403. * Compatible with TensorFlow MatrixSquareRoot operator.

  404. */

  405. 

  406. REG_OP(MatrixSquareRoot)

  407.     .INPUT(input, TensorType({DT_FLOAT, DT_DOUBLE}))

  408.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  409.     .OP_END_FACTORY_REG(MatrixSquareRoot)

  410. 

  411. /**

  412. *@brief Solves tridiagonal systems of equations . \n

  413. 

  414. *@par Inputs:

  415. *@li diagonals: Tensor of shape `[..., 3, M]` whose innermost 2 dimensions represent the tridiagonal matrices with three rows being the superdiagonal, diagonals, and subdiagonals, in order. The last element of the superdiagonal and the first element of the subdiagonal is ignored.

  416. *@li rhs: Tensor of shape `[..., M, K]`, representing K right-hand sides per each

  417. left-hand side . \n

  418. 

  419. *@par Outputs:

  420. y: Tensor of shape `[..., M, K]` containing the solutions \n

  421. 

  422. *@par Third-party framework compatibility

  423. * Compatible with TensorFlow TridiagonalSolve operator.

  424. */

  425. 

  426. REG_OP(TridiagonalSolve)

  427.     .INPUT(diagonals, TensorType({DT_FLOAT, DT_DOUBLE}))

  428.     .INPUT(rhs, TensorType({DT_FLOAT, DT_DOUBLE}))

  429.     .OUTPUT(y, TensorType({DT_FLOAT, DT_DOUBLE}))

  430.     .ATTR(partial_pivoting, Bool, true)

  431.     .OP_END_FACTORY_REG(TridiagonalSolve)

  432. 

  433. }  // namespace ge

  434. 

  435. #endif  // OPS_BUILT_IN_OP_PROTO_INC_LINALG_OPS_H_