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update the documentation of MatrixSetDiag, MatrixDiag, MatrixDiagPart, Unfold and Pad operators.
tags/v1.2.0-rc1
wangshuide2020
5 years ago
1 changed files with 8 additions and 23 deletions
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+8 -23mindspore/nn/layer/basic.py
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mindspore/nn/layer/basic.py
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| @@ -579,11 +579,7 @@ class Pad(Cell): | |||
| paddings are int type. For `D` th dimension of input, paddings[D, 0] indicates how many sizes to be | |||
| extended ahead of the `D` th dimension of the input tensor, and paddings[D, 1] indicates how many sizes to | |||
| be extended behind of the `D` th dimension of the input tensor. The padded size of each dimension D of the | |||
| output is: | |||
| .. code-block:: | |||
| paddings[D, 0] + input_x.dim_size(D) + paddings[D, 1] | |||
| output is: :math:`paddings[D, 0] + input_x.dim_size(D) + paddings[D, 1]` | |||
| mode (str): Specifies padding mode. The optional values are "CONSTANT", "REFLECT", "SYMMETRIC". | |||
| Default: "CONSTANT". | |||
| @@ -759,13 +755,11 @@ class Unfold(Cell): | |||
| Tensor, a 4-D tensor whose data type is same as `input_x`, | |||
| and the shape is [out_batch, out_depth, out_row, out_col] where `out_batch` is the same as the `in_batch`. | |||
| .. code-block:: | |||
| out_depth = ksize_row * ksize_col * in_depth | |||
| :math:`out_depth = ksize_row * ksize_col * in_depth` | |||
| out_row = (in_row - (ksize_row + (ksize_row - 1) * (rate_row - 1))) // stride_row + 1 | |||
| :math:`out_row = (in_row - (ksize_row + (ksize_row - 1) * (rate_row - 1))) // stride_row + 1` | |||
| out_col = (in_col - (ksize_col + (ksize_col - 1) * (rate_col - 1))) // stride_col + 1 | |||
| :math:`out_col = (in_col - (ksize_col + (ksize_col - 1) * (rate_col - 1))) // stride_col + 1` | |||
| Raises: | |||
| TypeError: If `ksizes`, `strides` or `rates` is neither a tuple nor list. | |||
| @@ -925,10 +919,7 @@ class MatrixDiag(Cell): | |||
| Assume `x` has :math:`k` dimensions :math:`[I, J, K, ..., N]`, then the output is a tensor of rank | |||
| :math:`k+1` with dimensions :math:`[I, J, K, ..., N, N]` where: | |||
| .. code-block:: | |||
| output[i, j, k, ..., m, n] = 1{m=n} * x[i, j, k, ..., n] | |||
| :math:`output[i, j, k, ..., m, n] = 1{m=n} * x[i, j, k, ..., n]` | |||
| Inputs: | |||
| - **x** (Tensor) - The diagonal values. It can be one of the following data types: | |||
| @@ -971,10 +962,7 @@ class MatrixDiagPart(Cell): | |||
| Assume `x` has :math:`k` dimensions :math:`[I, J, K, ..., M, N]`, then the output is a tensor of rank | |||
| :math:`k-1` with dimensions :math:`[I, J, K, ..., min(M, N)]` where: | |||
| .. code-block:: | |||
| output[i, j, k, ..., n] = x[i, j, k, ..., n, n] | |||
| :math:`output[i, j, k, ..., n] = x[i, j, k, ..., n, n]` | |||
| Inputs: | |||
| - **x** (Tensor) - The batched tensor. It can be one of the following data types: | |||
| @@ -1019,12 +1007,9 @@ class MatrixSetDiag(Cell): | |||
| Assume `x` has :math:`k+1` dimensions :math:`[I, J, K, ..., M, N]` and `diagonal` has :math:`k` | |||
| dimensions :math:`[I, J, K, ..., min(M, N)]`. Then the output is a tensor of rank :math:`k+1` with dimensions | |||
| :math:`[I, J, K, ..., M, N]` where: | |||
| :math:`output[i, j, k, ..., m, n] = diagnoal[i, j, k, ..., n] for m == n` | |||
| .. code-block:: | |||
| output[i, j, k, ..., m, n] = diagnoal[i, j, k, ..., n] for m == n | |||
| output[i, j, k, ..., m, n] = x[i, j, k, ..., m, n] for m != n | |||
| :math:`output[i, j, k, ..., m, n] = x[i, j, k, ..., m, n] for m != n` | |||
| Inputs: | |||
| - **x** (Tensor) - The batched tensor. Rank k+1, where k >= 1. It can be one of the following data types: | |||