Source code for mindspore.nn.optim.lamb

# Copyright 2020 Huawei Technologies Co., Ltd
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# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
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# http://www.apache.org/licenses/LICENSE-2.0
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# ============================================================================
"""lamb"""
import numpy as np
from mindspore.common import dtype as mstype
from mindspore.common.initializer import initializer
from mindspore.ops import operations as P
from mindspore.ops import composite as C
from mindspore.ops import functional as F
from mindspore.common.parameter import Parameter
from mindspore.common.tensor import Tensor
from mindspore._checkparam import Validator as validator
from mindspore._checkparam import Rel
from .optimizer import Optimizer
from .. import layer

num_one = Tensor(np.ones([1]), mstype.float32)

lamb_opt = C.MultitypeFuncGraph("lamb_opt")

@lamb_opt.register("Tensor", "Tensor", "Tensor", "Tensor", "Tensor", "Tensor", "Tensor", "Tensor", "Tensor",
                   "Tensor", "Bool")
def _update_run_op(beta1, beta2, eps, lr, weight_decay_tensor, global_step, param, m, v,
                   gradient, decay_flag):
    """
    Update parameters.

    Args:
        beta1 (Tensor): The exponential decay rate for the 1st moment estimates. Should be in range (0.0, 1.0).
        beta2 (Tensor): The exponential decay rate for the 2nd moment estimates. Should be in range (0.0, 1.0).
        eps (Tensor): Term added to the denominator to improve numerical stability. Should be greater than 0.
        lr (Tensor): Learning rate.
        weight_decay_tensor (Tensor): Weight decay. Should be equal to or greater than 0.
        global_step (Tensor): Global step.
        param (Tensor): Parameters.
        m (Tensor): m value of parameters.
        v (Tensor): v value of parameters.
        gradient (Tensor): Gradient of parameters.
        decay_flag (bool): Specifies whether param update with weight decay.

    Returns:
        Tensor, the new value of v after updating.
    """
    op_mul = P.Mul()
    op_sqrt = P.Sqrt()
    op_rsqrt = P.Rsqrt()
    op_square = P.Square()
    op_cast = P.Cast()
    op_reshape = P.Reshape()
    op_shape = P.Shape()
    op_pow = P.Pow()
    op_norm = layer.Norm()
    op_select = P.Select()
    op_greater = P.Greater()
    op_fill = P.Fill()
    op_dtype = P.DType()

    param_fp32 = op_cast(param, mstype.float32)
    m_fp32 = op_cast(m, mstype.float32)
    v_fp32 = op_cast(v, mstype.float32)
    gradient_fp32 = op_cast(gradient, mstype.float32)

    next_m = op_mul(beta1, m_fp32) + op_mul(op_cast(num_one, mstype.float32) - beta1, gradient_fp32)

    next_v = op_mul(beta2, v_fp32) + op_mul(op_cast(num_one, mstype.float32) - beta2, op_square(gradient_fp32))

    next_mm = next_m / (op_cast(num_one, mstype.float32)
                        - op_pow(beta1, op_cast(global_step + num_one, mstype.float32)))
    next_vv = next_v / (op_cast(num_one, mstype.float32) -
                        op_pow(beta2, op_cast(global_step + num_one, mstype.float32)))
    w_norm = op_norm(param_fp32)
    g_norm = op_norm(gradient_fp32)

    g_norm_hat = op_norm(op_mul(next_mm, op_rsqrt(next_vv + eps)) + weight_decay_tensor * param_fp32)
    zeros = F.zeros_like_tensor(w_norm)
    ones = op_fill(op_dtype(w_norm), op_shape(w_norm), 1.0)
    trust_ratio = op_select(
        op_greater(w_norm, zeros),
        op_select(op_greater(g_norm, zeros), w_norm / g_norm_hat, ones),
        ones)
    tens = op_fill(op_dtype(trust_ratio), op_shape(trust_ratio), 10.0)
    trust_ratio = C.clip_by_value(trust_ratio, zeros, tens)
    update = next_mm / (op_sqrt(next_vv) + eps)

    if decay_flag:
        update = update + op_mul(weight_decay_tensor, param_fp32)

    update_with_lr = op_mul(op_mul(trust_ratio, lr), update)

    next_param = param_fp32 - op_reshape(update_with_lr, op_shape(param_fp32))

    next_v = F.depend(next_v, F.assign(param, next_param))
    next_v = F.depend(next_v, F.assign(m, next_m))
    next_v = F.depend(next_v, F.assign(v, next_v))

    return next_v


def _check_param_value(decay_steps, warmup_steps, start_learning_rate,
                       end_learning_rate, power, beta1, beta2, eps, weight_decay, prim_name):
    """Check the type of inputs."""
    _ = warmup_steps
    validator.check_float_positive('start_learning_rate', start_learning_rate, prim_name)
    validator.check_float_legal_value('start_learning_rate', start_learning_rate, prim_name)
    validator.check_value_type("end_learning_rate", end_learning_rate, [float], prim_name)
    validator.check_float_legal_value('end_learning_rate', end_learning_rate, prim_name)
    validator.check_float_positive('power', power, prim_name)
    validator.check_float_legal_value('power', power, prim_name)
    validator.check_integer('decay_steps', decay_steps, 0, Rel.GT, prim_name)
    validator.check_integer('warmup_steps', decay_steps, 0, Rel.GT, prim_name)
    validator.check_value_type("beta1", beta1, [float], prim_name)
    validator.check_value_type("beta2", beta2, [float], prim_name)
    validator.check_value_type("eps", eps, [float], prim_name)
    validator.check_value_type("weight_dacay", weight_decay, [float], prim_name)
    validator.check_number_range("beta1", beta1, 0.0, 1.0, Rel.INC_NEITHER, prim_name)
    validator.check_number_range("beta2", beta2, 0.0, 1.0, Rel.INC_NEITHER, prim_name)
    validator.check_number_range("eps", eps, 0.0, float("inf"), Rel.INC_NEITHER, prim_name)
    validator.check_number_range("weight_decay", weight_decay, 0.0, float("inf"), Rel.INC_LEFT, prim_name)


[docs]class Lamb(Optimizer): """ Lamb Dynamic LR. LAMB is an optimization algorithm employing a layerwise adaptive large batch optimization technique. Refer to the paper `LARGE BATCH OPTIMIZATION FOR DEEP LEARNING: TRAINING BERT IN 76 MINUTES <https://arxiv.org/abs/1904.00962>`_. Args: params (list[Parameter]): A list of parameter, which will be updated. The element in `params` should be class mindspore.Parameter. decay_steps (int): The steps of the lr decay. Should be equal to or greater than 1. warmup_steps (int): The steps of lr warm up. Default: 0. start_learning_rate (float): A floating point value for the learning rate. Default: 0.1. end_learning_rate (float): A floating point value for the end learning rate. Default: 0.0001. power (float): The power of the polynomial. Default: 1.0. beta1 (float): The exponential decay rate for the 1st moment estimates. Default: 0.9. Should be in range (0.0, 1.0). beta2 (float): The exponential decay rate for the 2nd moment estimates. Default: 0.999. Should be in range (0.0, 1.0). eps (float): Term added to the denominator to improve numerical stability. Default: 1e-6. Should be greater than 0. weight_decay (float): Weight decay (L2 penalty). Default: 0.0. Should be equal to or greater than 0. decay_filter (Function): A function to determine whether to apply weight decay on parameters. Default: lambda x: 'LayerNorm' not in x.name and 'bias' not in x.name. Inputs: - **gradients** (tuple[Tensor]) - The gradients of `params`, the shape is the same as `params`. Outputs: tuple[Parameter], the updated velocity value, the shape is the same as `params`. Examples: >>> net = Net() >>> loss = nn.SoftmaxCrossEntropyWithLogits() >>> optim = nn.Lamb(params=net.trainable_params(), decay_steps=10) >>> model = Model(net, loss_fn=loss, optimizer=optim, metrics=None) """ def __init__(self, params, decay_steps, warmup_steps=0, start_learning_rate=0.1, end_learning_rate=0.0001, power=1.0, beta1=0.9, beta2=0.999, eps=1e-6, weight_decay=0.0, decay_filter=lambda x: 'layernorm' not in x.name.lower() and 'bias' not in x.name.lower()): super(Lamb, self).__init__(start_learning_rate, params) if self.is_group: raise RuntimeError(f"The {self.cls_name} optimizer cannot support group setting.") _check_param_value(decay_steps, warmup_steps, start_learning_rate, end_learning_rate, power, beta1, beta2, eps, weight_decay, self.cls_name) # turn them to scalar when me support scalar/tensor mix operations self.global_step = Parameter(initializer(0, [1]), name="global_step") self.warmup_steps = Tensor(np.array([warmup_steps]).astype(np.float32)) self.warmup_flag = False if warmup_steps > 0: self.warmup_flag = True self.decay_steps = Tensor(np.array([decay_steps]).astype(np.float32)) self.start_learning_rate = Tensor(np.array([start_learning_rate]).astype(np.float32)) self.end_learning_rate = Tensor(np.array([end_learning_rate]).astype(np.float32)) self.diff_learning_rate = Tensor(np.array([start_learning_rate - end_learning_rate]).astype(np.float32)) self.power = power self.beta1 = Tensor(np.array([beta1]).astype(np.float32)) self.beta2 = Tensor(np.array([beta2]).astype(np.float32)) self.eps = Tensor(np.array([eps]).astype(np.float32)) self.weight_decay_tensor = Tensor(np.array([weight_decay]).astype(np.float32)) self.params = self.parameters self.moments1 = self.params.clone(prefix="lamb_m", init='zeros') self.moments2 = self.params.clone(prefix="lamb_v", init='zeros') self.decay_flag = tuple(decay_filter(x) for x in self.params) self.hyper_map = C.HyperMap() self.min = P.Minimum() self.pow = P.Pow() self.greater = P.Greater() self.one = Tensor(np.array([1.0]).astype(np.float32)) self.cast = P.Cast() def construct(self, gradients): step = self.min(self.global_step, self.decay_steps) p = step / self.decay_steps lr = self.diff_learning_rate * self.pow(self.one - p, self.power) + self.end_learning_rate if self.warmup_flag: warmup_percent = self.global_step / self.warmup_steps warmup_lr = self.start_learning_rate * warmup_percent is_warmup = self.cast(self.greater(self.warmup_steps, self.global_step), mstype.float32) lr = (self.one - is_warmup) * lr + is_warmup * warmup_lr updated_velocity = self.hyper_map(F.partial(lamb_opt, self.beta1, self.beta2, self.eps, lr, self.weight_decay_tensor, self.global_step), self.params, self.moments1, self.moments2, gradients, self.decay_flag) added_global_step = self.global_step + self.one F.control_depend(lr, added_global_step) self.global_step = added_global_step return updated_velocity