mindspore.set_dump
- mindspore.set_dump(target, enabled=True)[source]
Enable or disable dump for the target and its contents.
target should be an instance of
mindspore.nn.Cell
ormindspore.ops.Primitive
. Please note that this API takes effect only when Asynchronous Dump is enabled and the dump_mode field in dump config file is"2"
. See the dump document for details. The default enabled status for amindspore.nn.Cell
ormindspore.ops.Primitive
is False.Warning
This is an experimental API that is subject to change or deletion. It is not supported for 2.3 version.
Note
This API is only effective for GRAPH_MODE with Ascend backend.
This API only supports being called before training starts. If you call this API during training, it may not be effective.
After using set_dump(Cell, True) , operators in forward and backward computation (computation generated by the grad operations) of the cell will be dumped.
For
mindspore.nn.SoftmaxCrossEntropyWithLogits
layer, the forward computation and backward computation use the same set of operators. So you can only see dump data from backward computation. Please note thatmindspore.nn.SoftmaxCrossEntropyWithLogits
layer will also use the above operators internally when initialized with sparse=True and reduction=”mean” .
- Parameters
- Supported Platforms:
Ascend
Examples
Note
Please set environment variable MINDSPORE_DUMP_CONFIG to the dump config file and set dump_mode field in dump config file to 2 before running this example. See dump document for details.
>>> import numpy as np >>> import mindspore as ms >>> import mindspore.nn as nn >>> from mindspore import Tensor, set_dump >>> >>> ms.set_context(device_target="Ascend", mode=ms.GRAPH_MODE) >>> >>> class MyNet(nn.Cell): ... def __init__(self): ... super().__init__() ... self.conv1 = nn.Conv2d(5, 6, 5, pad_mode='valid') ... self.relu1 = nn.ReLU() ... ... def construct(self, x): ... x = self.conv1(x) ... x = self.relu1(x) ... return x >>> >>> if __name__ == "__main__": ... net = MyNet() ... set_dump(net.conv1) ... input_tensor = Tensor(np.ones([1, 5, 10, 10], dtype=np.float32)) ... output = net(input_tensor)