mindspore.ops.SparseApplyAdagradV2
- class mindspore.ops.SparseApplyAdagradV2(lr, epsilon, use_locking=False, update_slots=True)[source]
Updates relevant entries according to the adagrad scheme, one more epsilon attribute than SparseApplyAdagrad.
\[\begin{split}\begin{array}{ll} \\ accum += grad * grad \\ var -= lr * grad * \frac{1}{\sqrt{accum} + \epsilon} \end{array}\end{split}\]where \(\epsilon\) represents epsilon.
Inputs of var, accum and grad comply with the implicit type conversion rules to make the data types consistent. If they have different data types, lower priority data type will be converted to relatively highest priority data type. RuntimeError exception will be thrown when the data type conversion of Parameter is required.
- Parameters
- Inputs:
var (Parameter) - Variable to be updated. The data type must be float16 or float32. The shape is \((N, *)\) where \(*\) means, any number of additional dimensions.
accum (Parameter) - Accumulation to be updated. The shape and data type must be the same as var.
grad (Tensor) - Gradients has the same data type as var and grad.shape[1:] = var.shape[1:] if var.shape > 1.
indices (Tensor) - A vector of indices into the first dimension of var and accum. The type must be int32 and indices.shape[0] = grad.shape[0].
- Outputs:
Tuple of 2 tensors, the updated parameters.
var (Tensor) - The same shape and data type as var.
accum (Tensor) - The same shape and data type as accum.
- Raises
- Supported Platforms:
Ascend
Examples
>>> class Net(nn.Cell): ... def __init__(self): ... super(Net, self).__init__() ... self.sparse_apply_adagrad_v2 = ops.SparseApplyAdagradV2(lr=1e-8, epsilon=1e-6) ... self.var = Parameter(Tensor(np.array([[0.2]]).astype(np.float32)), name="var") ... self.accum = Parameter(Tensor(np.array([[0.1]]).astype(np.float32)), name="accum") ... ... def construct(self, grad, indices): ... out = self.sparse_apply_adagrad_v2(self.var, self.accum, grad, indices) ... return out ... >>> net = Net() >>> grad = Tensor(np.array([[0.7]]).astype(np.float32)) >>> indices = Tensor(np.ones([1]), mindspore.int32) >>> output = net(grad, indices) >>> print(output) (Tensor(shape=[1, 1], dtype=Float32, value= [[ 2.00000003e-01]]), Tensor(shape=[1, 1], dtype=Float32, value= [[ 1.00000001e-01]]))