mindspore.train.Model
- class mindspore.train.Model(network, loss_fn=None, optimizer=None, metrics=None, eval_network=None, eval_indexes=None, amp_level='O0', boost_level='O0', **kwargs)[source]
High-Level API for training or inference.
Model groups layers into an object with training and inference features based on the arguments.
Note
If use mixed precision functions, need to set parameter optimizer at the same time, otherwise mixed precision functions do not take effect. When uses mixed precision functions, global_step in optimizer may be different from cur_step_num in Model.
- Parameters
network (Cell) – A training or testing network.
loss_fn (Cell) – Objective function. If loss_fn is None, the network should contain the calculation of loss and parallel if needed. Default: None.
optimizer (Cell) – Optimizer for updating the weights. If optimizer is None, the network needs to do backpropagation and update weights. Default value: None.
metrics (Union[dict, set]) – A Dictionary or a set of metrics for model evaluation. eg: {‘accuracy’, ‘recall’}. Default: None.
eval_network (Cell) – Network for evaluation. If not defined, network and loss_fn would be wrapped as eval_network . Default: None.
eval_indexes (list) – It is used when eval_network is defined. If eval_indexes is None by default, all outputs of the eval_network would be passed to metrics. If eval_indexes is set, it must contain three elements: the positions of loss value, predicted value and label in outputs of the eval_network. In this case, the loss value will be passed to the Loss metric, the predicted value and label will be passed to other metrics.
mindspore.train.Metric.set_indexes()
is recommended instead of eval_indexes. Default: None.amp_level (str) –
Option for argument level in
mindspore.amp.build_train_network()
, level for mixed precision training. Supports [“O0”, “O1”, “O2”, “O3”, “auto”]. Default: “O0”.”O0”: Do not change.
”O1”: Cast the operators in white_list to float16, the remaining operators are kept in float32.
”O2”: Cast network to float16, keep BatchNorm run in float32, using dynamic loss scale.
”O3”: Cast network to float16, the BatchNorm is also cast to float16, loss scale will not be used.
auto: Set level to recommended level in different devices. Set level to “O2” on GPU, set level to “O3” on Ascend. The recommended level is chosen by the expert experience, not applicable to all scenarios. User should specify the level for special network.
”O2” is recommended on GPU, “O3” is recommended on Ascend. The BatchNorm strategy can be changed by keep_batchnorm_fp32 settings in kwargs. keep_batchnorm_fp32 must be a bool. The loss scale strategy can be changed by loss_scale_manager setting in kwargs. loss_scale_manager should be a subclass of
mindspore.amp.LossScaleManager
. The more detailed explanation of amp_level setting can be found at mindspore.amp.build_train_network.boost_level (str) –
Option for argument level in mindspore.boost, level for boost mode training. Supports [“O0”, “O1”, “O2”]. Default: “O0”.
”O0”: Do not change.
”O1”: Enable the boost mode, the performance is improved by about 20%, and the accuracy is the same as the original accuracy.
”O2”: Enable the boost mode, the performance is improved by about 30%, and the accuracy is reduced by less than 3%.
If you want to config boost mode by yourself, you can set boost_config_dict as boost.py. In order for this function to work, you need to set the optimizer, eval_network or metric parameters at the same time.
Notice: The current optimization enabled by default only applies to some networks, and not all networks can obtain the same benefits. It is recommended to enable this function on the Graph mode + Ascend platform, and for better acceleration, refer to the documentation to configure boost_config_dict.
Examples
>>> from mindspore import nn >>> from mindspore.train import Model >>> >>> class Net(nn.Cell): ... def __init__(self, num_class=10, num_channel=1): ... super(Net, self).__init__() ... self.conv1 = nn.Conv2d(num_channel, 6, 5, pad_mode='valid') ... self.conv2 = nn.Conv2d(6, 16, 5, pad_mode='valid') ... self.fc1 = nn.Dense(16*5*5, 120, weight_init='ones') ... self.fc2 = nn.Dense(120, 84, weight_init='ones') ... self.fc3 = nn.Dense(84, num_class, weight_init='ones') ... self.relu = nn.ReLU() ... self.max_pool2d = nn.MaxPool2d(kernel_size=2, stride=2) ... self.flatten = nn.Flatten() ... ... def construct(self, x): ... x = self.max_pool2d(self.relu(self.conv1(x))) ... x = self.max_pool2d(self.relu(self.conv2(x))) ... x = self.flatten(x) ... x = self.relu(self.fc1(x)) ... x = self.relu(self.fc2(x)) ... x = self.fc3(x) ... return x >>> >>> net = Net() >>> loss = nn.SoftmaxCrossEntropyWithLogits() >>> optim = nn.Momentum(params=net.trainable_params(), learning_rate=0.1, momentum=0.9) >>> model = Model(net, loss_fn=loss, optimizer=optim, metrics=None) >>> # For details about how to build the dataset, please refer to the variable `dataset_train` in tutorial >>> # document on the official website: >>> # https://www.mindspore.cn/tutorials/zh-CN/r2.0.0-alpha/beginner/quick_start.html >>> dataset = create_custom_dataset() >>> model.train(2, dataset)
- build(train_dataset=None, valid_dataset=None, sink_size=- 1, epoch=1)[source]
Build computational graphs and data graphs with the sink mode.
Warning
This is an experimental prototype that is subject to change or deletion.
Note
The interface builds the computational graphs, when the interface is executed first, ‘Model.train’ only performs the graphs execution. Pre-build process only supports GRAPH_MODE and Ascend target currently. It only supports dataset sink mode.
- Parameters
train_dataset (Dataset) – A training dataset iterator. If train_dataset is defined, training graphs will be built. Default: None.
valid_dataset (Dataset) – An evaluating dataset iterator. If valid_dataset is defined, evaluation graphs will be built, and metrics in Model can not be None. Default: None.
sink_size (int) – Control the amount of data in each sink. Default: -1.
epoch (int) – Control the training epochs. Default: 1.
Examples
>>> from mindspore import nn >>> from mindspore.train import Model >>> from mindspore.amp import FixedLossScaleManager >>> >>> # For details about how to build the dataset, please refer to the tutorial >>> # document on the official website. >>> dataset = create_custom_dataset() >>> net = Net() >>> loss = nn.SoftmaxCrossEntropyWithLogits() >>> loss_scale_manager = FixedLossScaleManager() >>> optim = nn.Momentum(params=net.trainable_params(), learning_rate=0.1, momentum=0.9) >>> model = Model(net, loss_fn=loss, optimizer=optim, metrics=None, ... loss_scale_manager=loss_scale_manager) >>> model.build(dataset, epoch=2) >>> model.train(2, dataset)
- eval(valid_dataset, callbacks=None, dataset_sink_mode=False)[source]
Evaluation API.
Configure to pynative mode or CPU, the evaluating process will be performed with dataset non-sink mode.
Note
If dataset_sink_mode is True, data will be sent to device. At this point, the dataset will be bound to this model, so the dataset cannot be used by other models. If the device is Ascend, features of data will be transferred one by one. The limitation of data transmission per time is 256M.
The interface builds the computational graphs and then executes the computational graphs. However, when the Model.build is executed first, it only performs the graphs execution.
- Parameters
valid_dataset (Dataset) – Dataset to evaluate the model.
callbacks (Optional[list(Callback), Callback]) – List of callback objects or callback object, which should be executed while evaluation. Default: None.
dataset_sink_mode (bool) – Determines whether to pass the data through dataset channel. Default: False.
- Returns
Dict, the key is the metric name defined by users and the value is the metrics value for the model in the test mode.
Examples
>>> from mindspore import nn >>> from mindspore.train import Model >>> >>> # For details about how to build the dataset, please refer to the tutorial >>> # document on the official website. >>> dataset = create_custom_dataset() >>> net = Net() >>> loss = nn.SoftmaxCrossEntropyWithLogits() >>> model = Model(net, loss_fn=loss, optimizer=None, metrics={'acc'}) >>> acc = model.eval(dataset, dataset_sink_mode=False)
- property eval_network
Get the model’s eval network.
- Returns
Object, the instance of evaluate network.
- fit(epoch, train_dataset, valid_dataset=None, valid_frequency=1, callbacks=None, dataset_sink_mode=False, valid_dataset_sink_mode=False, sink_size=- 1, initial_epoch=0)[source]
Fit API.
Evaluation process will be performed during training process if valid_dataset is provided.
More details please refer to mindspore.train.Model.train and mindspore.train.Model.eval.
- Parameters
epoch (int) – Total training epochs. Generally, train network will be trained on complete dataset per epoch. If dataset_sink_mode is set to True and sink_size is greater than 0, each epoch will train sink_size steps instead of total steps of dataset. If epoch used with initial_epoch, it is to be understood as “final epoch”.
train_dataset (Dataset) – A training dataset iterator. If loss_fn is defined, the data and label will be passed to the network and the loss_fn respectively, so a tuple (data, label) should be returned from dataset. If there is multiple data or labels, set loss_fn to None and implement calculation of loss in network, then a tuple (data1, data2, data3, …) with all data returned from dataset will be passed to the network.
valid_dataset (Dataset) – Dataset to evaluate the model. If valid_dataset is provided, evaluation process will be performed on the end of training process. Default: None.
valid_frequency (int, list) – Only relevant if valid_dataset is provided. If an integer, specifies how many training epochs to run before a new validation run is performed, e.g. valid_frequency=2 runs validation every 2 epochs. If a list, specifies the epochs on which to run validation, e.g. valid_frequency=[1, 5] runs validation at the end of the 1st, 5th epochs. Default: 1
callbacks (Optional[list[Callback], Callback]) – List of callback objects or callback object, which should be executed while training. Default: None.
dataset_sink_mode (bool) – Determines whether to pass the train data through dataset channel. Configure pynative mode or CPU, the training process will be performed with dataset not sink. Default: False.
valid_dataset_sink_mode (bool) – Determines whether to pass the validation data through dataset channel. Default: False.
sink_size (int) – Control the amount of data in each sink. sink_size is invalid if dataset_sink_mode is False. If sink_size = -1, sink the complete dataset for each epoch. If sink_size > 0, sink sink_size data for each epoch. Default: -1.
initial_epoch (int) – Epoch at which to start train, it useful for resuming a previous training run. Default: 0.
Examples
>>> from mindspore import nn >>> from mindspore.train import Model >>> >>> # For details about how to build the dataset, please refer to the tutorial >>> # document on the official website. >>> train_dataset = create_custom_dataset() >>> valid_dataset = create_custom_dataset() >>> net = Net() >>> loss = nn.SoftmaxCrossEntropyWithLogits() >>> optim = nn.Momentum(params=net.trainable_params(), learning_rate=0.1, momentum=0.9) >>> model = Model(net, loss_fn=loss, optimizer=optim, metrics={"accuracy"}) >>> model.fit(2, train_dataset, valid_dataset)
- infer_predict_layout(*predict_data)[source]
Generate parameter layout for the predict network in ‘AUTO_PARALLEL’ or ‘SEMI_AUTO_PARALLEL’ mode.
Data could be a single tensor or multiple tensors.
Note
Batch data should be put together in one tensor.
- Parameters
predict_data (Union[Tensor, list[Tensor], tuple[Tensor]], optional) – The predict data, can be a single tensor, a list of tensor, or a tuple of tensor.
- Returns
Dict, Parameter layout dictionary used for load distributed checkpoint. Using as one of input parameters of load_distributed_checkpoint, always.
- Raises
RuntimeError – If not in GRAPH_MODE.
Examples
>>> # This example should be run with multiple devices. Refer to the tutorial > Distributed Training on >>> # mindspore.cn. >>> import numpy as np >>> import mindspore as ms >>> from mindspore import Tensor >>> from mindspore.train import Model >>> from mindspore.communication import init >>> >>> ms.set_context(mode=ms.GRAPH_MODE) >>> init() >>> ms.set_auto_parallel_context(full_batch=True, parallel_mode=ms.ParallelMode.SEMI_AUTO_PARALLEL) >>> input_data = Tensor(np.random.randint(0, 255, [1, 1, 32, 32]), ms.float32) >>> model = Model(Net()) >>> predict_map = model.infer_predict_layout(input_data)
- infer_train_layout(train_dataset, dataset_sink_mode=True, sink_size=- 1)[source]
Generate parameter layout for the train network in ‘AUTO_PARALLEL’ or ‘SEMI_AUTO_PARALLEL’ mode. Only dataset sink mode is supported for now.
Warning
This is an experimental prototype that is subject to change and/or deletion.
Note
This is a pre-compile function. The arguments should be the same as model.train() function.
- Parameters
train_dataset (Dataset) – A training dataset iterator. If there is no loss_fn, a tuple with multiple data (data1, data2, data3, …) should be returned and passed to the network. Otherwise, a tuple (data, label) should be returned. The data and label would be passed to the network and loss function respectively.
dataset_sink_mode (bool) – Determines whether to pass the data through dataset channel. Configure pynative mode or CPU, the training process will be performed with dataset not sink. Default: True.
sink_size (int) – Control the amount of data in each sink. If sink_size = -1, sink the complete dataset for each epoch. If sink_size > 0, sink sink_size data for each epoch. If dataset_sink_mode is False, set sink_size as invalid. Default: -1.
- Returns
Dict, Parameter layout dictionary used for load distributed checkpoint
Examples
>>> # This example should be run with multiple devices. Refer to the tutorial > Distributed Training on >>> # mindspore.cn. >>> import numpy as np >>> import mindspore as ms >>> from mindspore import Tensor, nn >>> from mindspore.train import Model >>> from mindspore.communication import init >>> >>> ms.set_context(mode=ms.GRAPH_MODE) >>> init() >>> ms.set_auto_parallel_context(parallel_mode=ms.ParallelMode.SEMI_AUTO_PARALLEL) >>> >>> # For details about how to build the dataset, please refer to the tutorial >>> # document on the official website. >>> dataset = create_custom_dataset() >>> net = Net() >>> loss = nn.SoftmaxCrossEntropyWithLogits() >>> loss_scale_manager = ms.FixedLossScaleManager() >>> optim = nn.Momentum(params=net.trainable_params(), learning_rate=0.1, momentum=0.9) >>> model = Model(net, loss_fn=loss, optimizer=optim, metrics=None, ... loss_scale_manager=loss_scale_manager) >>> layout_dict = model.infer_train_layout(dataset)
- predict(*predict_data)[source]
Generate output predictions for the input samples.
- Parameters
predict_data (Union[Tensor, list[Tensor], tuple[Tensor]], optional) – The predict data, can be a single tensor, a list of tensor, or a tuple of tensor.
- Returns
Tensor, array(s) of predictions.
Examples
>>> import numpy as np >>> import mindspore >>> from mindspore import Tensor >>> from mindspore.train import Model >>> >>> input_data = Tensor(np.random.randint(0, 255, [1, 1, 32, 32]), mindspore.float32) >>> model = Model(Net()) >>> result = model.predict(input_data)
- property predict_network
Get the model’s predict network.
- Returns
Object, the instance of predict network.
- train(epoch, train_dataset, callbacks=None, dataset_sink_mode=False, sink_size=- 1, initial_epoch=0)[source]
Training API.
When setting pynative mode or CPU, the training process will be performed with dataset not sink.
Note
If dataset_sink_mode is True, data will be sent to device. If the device is Ascend, features of data will be transferred one by one. The limitation of data transmission per time is 256M.
When dataset_sink_mode is True, the step_end method of the instance of Callback will be called at the end of epoch.
If dataset_sink_mode is True, dataset will be bound to this model and cannot be used by other models.
If sink_size > 0, each epoch of the dataset can be traversed unlimited times until you get sink_size elements of the dataset. The next epoch continues to traverse from the end position of the previous traversal.
The interface builds the computational graphs and then executes the computational graphs. However, when the Model.build is executed first, it only performs the graphs execution.
- Parameters
epoch (int) – Total training epochs. Generally, train network will be trained on complete dataset per epoch. If dataset_sink_mode is set to True and sink_size is greater than 0, each epoch will train sink_size steps instead of total steps of dataset. If epoch used with initial_epoch, it is to be understood as “final epoch”.
train_dataset (Dataset) – A training dataset iterator. If loss_fn is defined, the data and label will be passed to the network and the loss_fn respectively, so a tuple (data, label) should be returned from dataset. If there is multiple data or labels, set loss_fn to None and implement calculation of loss in network, then a tuple (data1, data2, data3, …) with all data returned from dataset will be passed to the network.
callbacks (Optional[list[Callback], Callback]) – List of callback objects or callback object, which should be executed while training. Default: None.
dataset_sink_mode (bool) – Determines whether to pass the data through dataset channel. Configure pynative mode or CPU, the training process will be performed with dataset not sink. Default: False.
sink_size (int) – Control the amount of data in each sink. sink_size is invalid if dataset_sink_mode is False. If sink_size = -1, sink the complete dataset for each epoch. If sink_size > 0, sink sink_size data for each epoch. Default: -1.
initial_epoch (int) – Epoch at which to start train, it used for resuming a previous training run. Default: 0.
Examples
>>> from mindspore import nn >>> from mindspore.train import Model >>> >>> # For details about how to build the dataset, please refer to the tutorial >>> # document on the official website. >>> dataset = create_custom_dataset() >>> net = Net() >>> loss = nn.SoftmaxCrossEntropyWithLogits() >>> loss_scale_manager = ms.FixedLossScaleManager() >>> optim = nn.Momentum(params=net.trainable_params(), learning_rate=0.1, momentum=0.9) >>> model = Model(net, loss_fn=loss, optimizer=optim, metrics=None, ... loss_scale_manager=loss_scale_manager) >>> model.train(2, dataset)
- property train_network
Get the model’s train network.
- Returns
Object, the instance of train network.