We have released adabelief-pytorch==0.2.0
and adabelief-tf==0.2.0
. Please use the latest version from pip. Source code is available under folder pypi_packages/adabelief_pytorch0.2.0
and pypi_packages/adabelief_tf0.2.0
.
- External Links
- Link to extra experiments
- Table of hyper-parameters
- Quick Guide Important infomation on hyper-params.
- Installation and usage
- A quick look at the algorithm
- Detailed Discussions
- Reproduce results in the paper
- Update Plan
- Citation
- Slides
Project Page, arXiv , Reddit , Twitter, BiliBili (中文), BiliBili (Engligh), Youtube
- SN-GAN https://github.com/juntang-zhuang/SNGAN-AdaBelief
- Transformer (PyTorch 1.1) https://github.com/juntang-zhuang/transformer-adabelief
- Transformer (PyTorch 1.6) https://github.com/juntang-zhuang/fairseq-adabelief
- Reinforcement Learning (Toy) https://github.com/juntang-zhuang/rainbow-adabelief
- Reinforcement Learning (HalfCheetah-v2 Walker2d-v2) https://github.com/juntang-zhuang/SAC-Adabelief
- Object detection (by yuanwei2019) https://github.com/yuanwei2019/EAdam-optimizer (Note that this version uses
adabelief-pytorch==0.0.5
, and the default hyper-parameters is different fromadabelief-pytorch==0.1.0
. Please check your version of adabelief, and whether you specify all hyper-parameters, or does the default is what you want.) - Text classification and word embedding in Tensorflow
In the next release of adabelief-pytorch
, we will modify the default of several arguments, in order to fit the needs of for general tasks such as GAN and Transformer. Please check if you specify these arguments or use the default when upgrade from version 0.0.5 to higher.
Version | epsilon | weight_decouple | rectify |
---|---|---|---|
adabelief-pytorch=0.0.5 | 1e-8 | False | False |
latest version 0.2.0>0.0.5 | 1e-16 | True | True |
In adabelief-tf==0.1.0
, we modify adabelief-tf
to have the same feature as adabelief-pytorch
, inlcuding decoupled weight decay and learning rate rectification. Furthermore, we will add support for TensorFlow>=2.0 and Keras. The source code is in pypi_packages/adabelief_tf0.1.0
. We tested with a text classification task and a word embedding task.
The default value is updated, please check if you specify these arguments or use the default when upgrade from version 0.0.1 to higher.:
Version | epsilon | weight_decouple | rectify |
---|---|---|---|
adabelief-tf=0.0.1 | 1e-8 | Not supported | Not supported |
latest version 0.2.0>0.0.1 | 1e-14 | Supported (Not an option in arguments) | default: True |
-
Check if the code is from the latest official implementation (adabelief-pytorch==0.1.0, adabelief-tf==0.1.0) Default hyper-parameters are different from the old version.
-
check all hyper-parameters, DO NOT simply use the default,
Epsilon in AdaBelief is different from Adam (typically eps_adabelief = eps_adam*eps_adam)
( eps of Adam in Tensorflow is 1e-7, in PyTorch is 1e-8, need to consider this when use AdaBelief in Tensorflow)If SGD is better than Adam -> Set a large eps (1e-8) in AdaBelief-pytorch (1e-7 in Tensorflow )
If SGD is worse than Adam -> Set a small eps (1e-16) in AdaBelief-pytorch (1e-14 in Tensorflow, rectify=True often helps)If AdamW is better than Adam -> Turn on “weight_decouple” in AdaBelief-pytorch (this is on in adabelief-tf==0.1.0 and cannot shut down).
Note that default weight decay is very different for Adam and AdamW, you might need to consider this when using AdaBelief with and without decoupled weight decay. -
Check ALL hyper-parameters. Refer to our github page for a list of recommended hyper-parameters
Please check if you have specify all arguments and check your version is latest, the default might not be suitable for different tasks, see tables below
- Note weight decay varies with tasks, for different tasks the weight decay is untuned from the original repository (only changed the optimizer and other hyper-parameters).
Task | lr | beta1 | beta2 | epsilon | weight_decay | weight_decouple | rectify | fixed_decay | amsgrad |
---|---|---|---|---|---|---|---|---|---|
Cifar | 1e-3 | 0.9 | 0.999 | 1e-8 | 5e-4 | False | False | False | False |
ImageNet | 1e-3 | 0.9 | 0.999 | 1e-8 | 1e-2 | True | False | False | False |
Object detection (PASCAL) | 1e-4 | 0.9 | 0.999 | 1e-8 | 1e-4 | False | False | False | False |
LSTM-1layer | 1e-3 | 0.9 | 0.999 | 1e-16 | 1.2e-6 | False | False | False | False |
LSTM 2,3 layer | 1e-2 | 0.9 | 0.999 | 1e-12 | 1.2e-6. | False | False | False | False |
GAN (small) | 2e-4 | 0.5 | 0.999 | 1e-12 | 0 | True=False (decay=0) | False | False | False |
SN-GAN (large) | 2e-4 | 0.5 | 0.999 | 1e-16 | 0 | True=False (decay=0) | True | False | False |
Transformer | 5e-4 | 0.9 | 0.999 | 1e-16 | 1e-4 | True | True | False | False |
Reinforcement (Rainbow) | 1e-4 | 0.9 | 0.999 | 1e-10 | 0.0 | True=False (decay=0) | True | False | False |
Reinforcement (HalfCheetah-v2) | 1e-3 | 0.9 | 0.999 | 1e-12 | 0.0 | True=False (decay=0) | True | False | False |
epsilon
is used in a different way in Tensorflow (default 1e-7) compared to PyTorch (default 1e-8), so eps in Tensorflow might needs to be larger than in PyTorch (perhaps 100 times larger in Tensorflow, e.g. eps=1e-16 in PyTorch v.s eps=1e-14 in Tensorflow). But personally I don't have much experience with Tensorflow, it's likely that you need to slightly tune eps.
( Results in the paper are all generated using the PyTorch implementation in adabelief-pytorch
package, which is the ONLY package that I have extensively tested for now.)
Please install latest version (0.2.0), previous version (0.0.5) uses different default arguments.
pip install adabelief-pytorch==0.2.0
from adabelief_pytorch import AdaBelief
optimizer = AdaBelief(model.parameters(), lr=1e-3, eps=1e-16, betas=(0.9,0.999), weight_decouple = True, rectify = False)
pip install ranger-adabelief==0.1.0
from ranger_adabelief import RangerAdaBelief
optimizer = RangerAdaBelief(model.parameters(), lr=1e-3, eps=1e-12, betas=(0.9,0.999))
2. Tensorflow implementation (eps of AdaBelief in Tensorflow is larger than in PyTorch, same for Adam)
pip install adabelief-tf==0.2.0
from adabelief_tf import AdaBeliefOptimizer
optimizer = AdaBeliefOptimizer(learning_rate=1e-3, epsilon=1e-14, rectify=False)
See folder PyTorch_Experiments
, for each subfolder, execute sh run.sh
. See readme.txt
in each subfolder for visualization, or
refer to jupyter notebook for visualization.
Please install the latest version from pip, old versions might suffer from bugs. Source code for up-to-date package is available in folder pypi_packages
.
AdaBelief uses a different denominator from Adam, and is orthogonal to other techniques such as recification, decoupled weight decay, weight averaging et.al. This implies when you use some techniques with Adam, to get a good result with AdaBelief you might still need those techniques.
-
epsilon
in AdaBelief plays a different role as in Adam, typically when you useepslison=x
in Adam, usingepsilon=x*x
will give similar results in AdaBelief. The default valueepsilon=1e-8
is not a good option in many cases, in version >0.1.0 the default eps is set as 1e-16. -
If you task needs a "non-adaptive" optimizer, which means SGD performs much better than Adam(W), such as on image recognition, you need to set a large
epsilon
(e.g. 1e-8) for AdaBelief to make it morenon-adaptive
; if your task needs a reallyadaptive
optimizer, which means Adam is much better than SGD, such as GAN and Transformer, then the recommendedepsilon
for AdaBelief is small (1e-12, 1e-16 ...). -
If decoupled weight decay is very important for your task, which means AdamW is much better than Adam, then you need to set
weight_decouple
as True to turn on decoupled decay in AdaBelief. Note that many optimizers uses decoupled weight decay without specifying it as an options, e.g. RAdam, but we provide it as an option so users are aware of what technique is actually used. -
Don't use "gradient threshold" (clamp each element independently) in AdaBelief, it could result in division by 0 and explosion in update; but "gradient clip" (shrink amplitude of the gradient vector but keeps its direction) is fine, though from my limited experience sometimes the clip range needs to be the same or larger than Adam.
-
Decoupling (argument
weight_decouple
appears inAdaBelief
andRangerAdaBelief
):
Currently there are two ways to perform weight decay for adaptive optimizers, directly apply it to the gradient (Adam), ordecouple
weight decay from gradient descent (AdamW). This is passed to the optimizer by argumentweight_decouple (default: False)
. -
Fixed ratio (argument
fixed_decay (default: False)
appears inAdaBelief
):
(1) Ifweight_decouple == False
, then this argument does not affect optimization.
(2) Ifweight_decouple == True
:
- If
fixed_decay == False
, the weight is multiplied by1 -lr x weight_decay
- If
fixed_decay == True
, the weight is multiplied by1 - weight_decay
. This is implemented as an option but not used to produce results in the paper. -
What is the acutal weight-decay we are using?
This is seldom discussed in the literature, but personally I think it's very important. When we setweight_decay=1e-4
for SGD, the weight is scaled by1 - lr x weight_decay
. Two points need to be emphasized: (1)lr
in SGD is typically larger than Adam (0.1 vs 0.001), so the weight decay in Adam needs to be set as a larger number to compensate. (2)lr
decays, this means typically we use a larger weight decay in early phases, and use a small weight decay in late phases.
AdaBelief seems to require a different epsilon
from Adam. In CV tasks in this paper, epsilon
is set as 1e-8
. For GAN training it's set as 1e-16
. We recommend try different epsilon
values in practice, and sweep through a large region. We recommend use eps=1e-8
when SGD outperforms Adam, such as many CV tasks; recommend eps=1e-16
when Adam outperforms SGD, such as GAN and Transformer. Sometimes you might need to try eps=1e-12
, such as in some reinforcement learning tasks.
Whether to turn on the rectification as in RAdam. The recitification basically uses SGD in early phases for warmup, then switch to Adam. Rectification is implemented as an option, but is never used to produce results in the paper.
Whether to take the max (over history) of denominator, same as AMSGrad. It's set as False for all experiments.
- Results in the paper are generated using the PyTorch implementation in
adabelief-pytorch
package. This is the ONLY package that I have extensively tested for now. - We also provide a modification of
ranger
optimizer inranger-adabelief
which combinesRAdam + LookAhead + Gradient Centralization + AdaBelief
, but this is not used in the paper and is not extensively tested. Theadabelief-tf
is a naive implementation in Tensorflow. It lacks many features such asdecoupled weight decay
, and is not extensively tested. Currently I don't have plans to improve it since I seldom use Tensorflow, please contact me if you want to collaborate and improve it.- The
adabelief-tf==0.1.0
supports the same feature asadabelief-pytorch==0.1.0
, includingdecoupled weight decay
and rectification. But personally I don't have the chance to perform extensive tests as with the PyTorch version.
The experiments on Cifar is the same as demo in AdaBound, with the only difference is the optimizer. The ImageNet experiment uses a different learning rate schedule, typically is decayed by 1/10 at epoch 30, 60, and ends at 90. For some reasons I have not extensively experimented, AdaBelief performs good when decayed at epoch 70, 80 and ends at 90, using the default lr schedule produces a slightly worse result. If you have any ideas on this please open an issue here or email me.
I got some feedbacks on RNN on reddit discussion, here are a few tips:
- The epsilon is suggested to set as a smaller value for RNN (e.g. 1e-12, 1e-16). Please try different epsilon values, it varies from task to task.
- I might confuse "gradient threshold" with "gradient clip" in previous readme, clarify below:
(1) By "gradient threshold" I refer to element-wise operation, which only takes values between a certain region [a,b]. Values outside this region will be set as a and b respectively.
(2) By "gradient clip" I refer to the operation on a vector or tensor. Suppose X is a tensor, if ||X|| > thres, then X <- X/||X|| * thres. Take X as a vector, "gradient clip" shrinks the amplitude but keeps the direction.
(3) "Gradient threshold" is incompatible with AdaBelief, because if gt is thresholded for a long time, then |gt-mt|~=0, and the division will explode; however, "gradient clip" is fine for Adabelief, yet the clip range still needs tuning (perhaps AdaBelief needs a larger range than Adam).
Please contact me at j.zhuang@yale.edu
or open an issue here if you would like to help improve it, especially the tensorflow version, or explore combination with other methods, some discussion on the theory part, or combination with other methods to create a better optimizer. Any thoughts are welcome!
Someone (under the wechat group Jiqizhixin) points out that the results on GAN is bad, this might be due to the choice of GAN model (We pick the simplest code example from PyTorch docs without adding more tricks), and we did not perform cherry-picking or worsen the baseline perfomance intentionally. We will update results on new GANs (e.g. SN-GAN) and release code later.Upload code for LSTM experiments.(10/23/2020) Transformer trains fine locally with PyTorch 1.1 CUDA9.0 (BLEU score 35.74 (highest is 35.85) on IWSLT14 DE-En with small transformer), but works much worse on a server with PyTorch 1.4 CUDA 10.0 (BLEU score < 26) using the same code. The code is to reproduce the error is at: https://github.com/juntang-zhuang/transformer-adabeliefTest AdaBelief on more examples, such as Transformer, Reinforcement Learning.Merge Tensorflow improvementsCompare the rectified update, currently the implementation is slightly different fromRAdam
implementation.Correct the coding error in RangerAdaBeliefThe AMSGrad implmentation might be problematic, see discusssion #32 (comment)Coupled weight decay in adabelief-pytorch=0.1.0 is not working, though does not affect decoupled weight decay. #33 (comment)Solve the problem in mixed-precision with AdaBelief, see discussion #31 (comment)- Implement fused version (as in apex) for faster speed.
- Updated results on an SN-GAN is in https://github.com/juntang-zhuang/SNGAN-AdaBelief, AdaBelief achieves 12.36 FID (lower is better) on Cifar10, while Adam achieves 13.25 (number taken from the log of official repository
PyTorch-studioGAN
). - LSTM experiments uploaded to
PyTorch_Experiments/LSTM
- Identify the problem of Transformer with PyTorch 1.4, to be an old version
fairseq
is incompatible with new version PyTorch, works fine with latestfairseq
.
Code on Transformer to work with PyTorch 1.6 is at: https://github.com/juntang-zhuang/fairseq-adabelief
Code for transformer to work with PyTorch 1.1 and CUDA9.0 is at: https://github.com/juntang-zhuang/transformer-adabelief - Tested on a toy example of reinforcement learning.
- Released
adabelief-pytorch==0.1.0
andadabelief-tf==0.1.0
. The Tensorflow version now supports TF>=2.0 and Keras, with the same features as in the PyTorch version, including decoupled weight decay and rectification. - Released
adabelief-pytorch==0.2.0
. Fix the error with coupled weight decay inadabelief-pytorch==0.1.0
, fix theamsgrad
update inadabelief-pytorch==0.1.0
. Add options to disable the message printing, by specifyprint_change_log=False
when initiating the optimizer. - Released
adabelief-tf==0.2.0
. Add options to disable the message printing, by specifyprint_change_log=False
when initiating the optimizer. Delte redundant computations, so0.2.0
should be faster than0.1.0
. Removed dependencies ontensorflow-addons
. adabelief-pytorch==0.2.1
is compatible with mixed-precision training.
@article{zhuang2020adabelief,
title={AdaBelief Optimizer: Adapting Stepsizes by the Belief in Observed Gradients},
author={Zhuang, Juntang and Tang, Tommy and Ding, Yifan and Tatikonda, Sekhar and Dvornek, Nicha and Papademetris, Xenophon and Duncan, James},
journal={Conference on Neural Information Processing Systems},
year={2020}
}
@article{zhuang2021acprop,
title={Momentum Centering and Asynchronous Update for Adaptive Gradient Methods},
author={Zhuang, Juntang and Ding, Yifan and Tang, Tommy and Dvornek, Nicha and Tatikonda, Sekhar and Duncan, James},
journal={Conference on Neural Information Processing Systems},
year={2021}
}