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base: aljaz:0.0.107
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aljaz:main aljaz:fix_resizing_in_test
aljaz:1.15.6 aljaz:1.15.5 aljaz:1.15.4 aljaz:1.15.3 aljaz:1.15.2 aljaz:1.15.1 aljaz:1.14.3 aljaz:1.14.2 aljaz:1.14.1 aljaz:1.14.0 aljaz:1.12.4 aljaz:1.12.3 aljaz:1.12.2 aljaz:1.12.1 aljaz:1.12.0 aljaz:1.11.4 aljaz:1.11.2 aljaz:1.11.1 aljaz:1.11.0 aljaz:1.10.9 aljaz:0.10.8 aljaz:1.10.7 aljaz:1.10.6 aljaz:1.10.5 aljaz:1.10.4 aljaz:1.10.3 aljaz:1.10.2 aljaz:1.10.1 aljaz:1.10.0 aljaz:1.9.0 aljaz:1.8.4 aljaz:1.8.3 aljaz:1.8.2 aljaz:1.8.1 aljaz:1.8.0 aljaz:1.7.0 aljaz:1.6.5 aljaz:1.6.4 aljaz:1.6.3 aljaz:1.6.2 aljaz:1.6.1 aljaz:1.6.0 aljaz:1.5.0 aljaz:1.4.6 aljaz:1.4.5 aljaz:1.4.4 aljaz:1.4.3 aljaz:1.4.2 aljaz:1.4.1 aljaz:1.4.0 aljaz:1.2.2 aljaz:1.2.1 aljaz:1.2.0 aljaz:1.1.0 aljaz:1.0.6 aljaz:1.0.5 aljaz:1.0.4 aljaz:1.0.3 aljaz:1.0.1 aljaz:1.0.0 aljaz:0.26.2 aljaz:v0.26.1 aljaz:v0.26.0 aljaz:v0.25.2 aljaz:v0.25.1 aljaz:v0.25.0 aljaz:v0.24.3 aljaz:v0.24.2 aljaz:v0.24.1 aljaz:v0.24.0 aljaz:v0.23.10 aljaz:v0.23.9 aljaz:v0.23.8 aljaz:v0.23.7 aljaz:v0.23.6 aljaz:v0.23.5 aljaz:v0.23.4 aljaz:v0.23.3 aljaz:v0.23.2 aljaz:v0.23.1 aljaz:v0.23.0 aljaz:v0.22.3 aljaz:v0.22.1 aljaz:v0.22.2 aljaz:v0.21.3 aljaz:v0.21.2 aljaz:v0.21.1 aljaz:v0.21.0 aljaz:v0.20.1 aljaz:v0.20.0 aljaz:v0.19.6 aljaz:v0.19.5 aljaz:v0.19.4 aljaz:v0.19.3 aljaz:v0.19.2 aljaz:v0.19.1 aljaz:v0.19.0 aljaz:v0.18.0 aljaz:v0.17.1 aljaz:v0.17.0 aljaz:v0.16.19 aljaz:v0.16.18 aljaz:v0.16.17 aljaz:v0.16.16 aljaz:v0.16.15 aljaz:v0.16.14 aljaz:v0.16.13 aljaz:v0.16.12 aljaz:v0.16.11 aljaz:v0.16.10 aljaz:v0.16.9 aljaz:v0.16.8 aljaz:v0.16.7 aljaz:v0.16.6 aljaz:v0.16.5 aljaz:v0.16.3 aljaz:v0.16.2 aljaz:v0.16.1 aljaz:v0.16.0 aljaz:v0.15.4 aljaz:v0.15.3 aljaz:v0.15.2 aljaz:v0.15.1 aljaz:v0.15.0 aljaz:v0.14.1 aljaz:v0.14.0 aljaz:v0.12.4 aljaz:v0.12.3 aljaz:v0.12.2 aljaz:v0.12.1 aljaz:v0.12.0 aljaz:v0.11.5 aljaz:0.11.4 aljaz:v0.11.3 aljaz:v0.11.2 aljaz:v0.11.1 aljaz:v0.11.0 aljaz:v0.10.1 aljaz:v0.10.0 aljaz:v0.9.2 aljaz:v0.9.1 aljaz:v0.9.0 aljaz:v0.8.1 aljaz:v0.8.0 aljaz:v0.7.1 aljaz:v0.7.0 aljaz:v0.6.16 aljaz:v0.6.15 aljaz:v0.6.14 aljaz:0.6.13 aljaz:v0.6.12 aljaz:v0.6.11 aljaz:v0.6.10 aljaz:v0.6.9 aljaz:v0.6.8 aljaz:v0.6.7 aljaz:v0.6.6 aljaz:v0.6.5 aljaz:v0.6.4 aljaz:v0.6.3 aljaz:v0.6.2 aljaz:v0.6.1 aljaz:v0.6.0 aljaz:v0.5.7 aljaz:v0.5.6 aljaz:v0.5.5 aljaz:v0.5.4 aljaz:v0.5.3 aljaz:v0.5.2 aljaz:v0.5.1 aljaz:0.5.0a aljaz:v0.5.0 aljaz:v0.4.14 aljaz:0.4.12 aljaz:0.4.11 aljaz:0.4.10 aljaz:v0.4.9 aljaz:0.4.8 aljaz:0.4.7 aljaz:0.4.6 aljaz:0.4.5 aljaz:0.4.3 aljaz:0.4.2 aljaz:0.4.1 aljaz:0.4.0 aljaz:0.3.9 aljaz:0.3.8 aljaz:0.3.7 aljaz:0.3.6 aljaz:0.3.5 aljaz:0.3.4 aljaz:0.3.3 aljaz:0.3.2 aljaz:0.3.1 aljaz:0.3.0 aljaz:0.2.46 aljaz:0.2.44 aljaz:0.2.43 aljaz:0.2.42 aljaz:0.2.41 aljaz:0.2.40 aljaz:0.2.39 aljaz:0.2.38 aljaz:0.2.37 aljaz:02.36 aljaz:0.2.35 aljaz:0.2.34 aljaz:0.2.33 aljaz:0.2.32 aljaz:0.2.31 aljaz:0.2.30 aljaz:0.2.29 aljaz:0.2.28 aljaz:0.2.27 aljaz:0.2.26 aljaz:0.2.25 aljaz:0.2.24 aljaz:0.2.23 aljaz:0.2.22 aljaz:0.2.21 aljaz:0.2.20 aljaz:0.2.19 aljaz:0.2.18 aljaz:0.2.17 aljaz:0.2.16 aljaz:0.2.15 aljaz:0.2.14 aljaz:0.2.12 aljaz:0.2.11 aljaz:0.2.10 aljaz:0.2.9 aljaz:0.2.8 aljaz:0.2.7 aljaz:0.2.6a aljaz:0.2.6 aljaz:0.2.5 aljaz:0.2.4 aljaz:0.2.3 aljaz:0.2.2a aljaz:0.2.2 aljaz:0.2.1 aljaz:0.2.0 aljaz:0.1.10 aljaz:0.1.9 aljaz:0.1.8 aljaz:0.1.7a aljaz:0.1.7 aljaz:0.1.6 aljaz:0.1.5 aljaz:0.1.4 aljaz:0.1.2 aljaz:0.1.1 aljaz:0.1.0 aljaz:0.0.109 aljaz:0.0.108 aljaz:0.0.107 aljaz:0.0.106 aljaz:0.0.105 aljaz:0.0.104 aljaz:0.0.102 aljaz:0.0.101 aljaz:0.0.100 aljaz:0.0.99 aljaz:0.0.98 aljaz:0.0.97 aljaz:0.0.96 aljaz:0.0.95 aljaz:0.0.94 aljaz:0.0.93 aljaz:0.0.92 aljaz:0.0.91 aljaz:0.0.90 aljaz:0.0.89 aljaz:0.0.88 aljaz:0.0.87 aljaz:0.0.86 aljaz:0.0.85 aljaz:0.0.84 aljaz:0.0.82 aljaz:0.0.81 aljaz:0.0.80 aljaz:0.0.79 aljaz:0.0.78 aljaz:0.0.77 aljaz:0.0.76 aljaz:0.0.75 aljaz:0.0.74 aljaz:0.0.73 aljaz:0.0.72 aljaz:0.0.71 aljaz:0.0.70 aljaz:0.0.67 aljaz:0.0.65 aljaz:0.0.64 aljaz:0.0.63 aljaz:0.0.62 aljaz:0.0.61 aljaz:0.0.60 aljaz:0.0.59 aljaz:0.0.58 aljaz:0.0.57 aljaz:0.0.56 aljaz:0.0.55 aljaz:0.0.54 aljaz:0.0.53 aljaz:0.0.52 aljaz:0.0.51 aljaz:0.0.50 aljaz:0.0.49 aljaz:0.0.48 aljaz:0.0.47 aljaz:0.0.46 aljaz:0.0.45 aljaz:0.0.44 aljaz:0.0.43 aljaz:0.0.42 aljaz:0.0.41 aljaz:0.0.40 aljaz:0.0.39 aljaz:0.0.38 aljaz:0.0.37 aljaz:0.0.36 aljaz:0.0.35 aljaz:0.0.34 aljaz:0.0.33 aljaz:0.0.32 aljaz:0.0.31 aljaz:0.0.28 aljaz:0.0.27 aljaz:0.0.26 aljaz:0.0.25 aljaz:0.0.24 aljaz:0.0.23 aljaz:0.0.22 aljaz:0.0.21 aljaz:0.0.20 aljaz:0.0.18 aljaz:0.0.17 aljaz:0.0.16 aljaz:0.0.15 aljaz:0.0.14 aljaz:0.0.12 aljaz:0.0.11 aljaz:0.0.10 aljaz:0.0.9 aljaz:0.0.8 aljaz:0.0.7 aljaz:0.0.6a aljaz:0.0.6 aljaz:0.0.5 aljaz:0.0.4 aljaz:0.0.2 aljaz:0.0.1
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compare: aljaz:0.3.0
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aljaz:main aljaz:fix_resizing_in_test
aljaz:1.15.6 aljaz:1.15.5 aljaz:1.15.4 aljaz:1.15.3 aljaz:1.15.2 aljaz:1.15.1 aljaz:1.14.3 aljaz:1.14.2 aljaz:1.14.1 aljaz:1.14.0 aljaz:1.12.4 aljaz:1.12.3 aljaz:1.12.2 aljaz:1.12.1 aljaz:1.12.0 aljaz:1.11.4 aljaz:1.11.2 aljaz:1.11.1 aljaz:1.11.0 aljaz:1.10.9 aljaz:0.10.8 aljaz:1.10.7 aljaz:1.10.6 aljaz:1.10.5 aljaz:1.10.4 aljaz:1.10.3 aljaz:1.10.2 aljaz:1.10.1 aljaz:1.10.0 aljaz:1.9.0 aljaz:1.8.4 aljaz:1.8.3 aljaz:1.8.2 aljaz:1.8.1 aljaz:1.8.0 aljaz:1.7.0 aljaz:1.6.5 aljaz:1.6.4 aljaz:1.6.3 aljaz:1.6.2 aljaz:1.6.1 aljaz:1.6.0 aljaz:1.5.0 aljaz:1.4.6 aljaz:1.4.5 aljaz:1.4.4 aljaz:1.4.3 aljaz:1.4.2 aljaz:1.4.1 aljaz:1.4.0 aljaz:1.2.2 aljaz:1.2.1 aljaz:1.2.0 aljaz:1.1.0 aljaz:1.0.6 aljaz:1.0.5 aljaz:1.0.4 aljaz:1.0.3 aljaz:1.0.1 aljaz:1.0.0 aljaz:0.26.2 aljaz:v0.26.1 aljaz:v0.26.0 aljaz:v0.25.2 aljaz:v0.25.1 aljaz:v0.25.0 aljaz:v0.24.3 aljaz:v0.24.2 aljaz:v0.24.1 aljaz:v0.24.0 aljaz:v0.23.10 aljaz:v0.23.9 aljaz:v0.23.8 aljaz:v0.23.7 aljaz:v0.23.6 aljaz:v0.23.5 aljaz:v0.23.4 aljaz:v0.23.3 aljaz:v0.23.2 aljaz:v0.23.1 aljaz:v0.23.0 aljaz:v0.22.3 aljaz:v0.22.1 aljaz:v0.22.2 aljaz:v0.21.3 aljaz:v0.21.2 aljaz:v0.21.1 aljaz:v0.21.0 aljaz:v0.20.1 aljaz:v0.20.0 aljaz:v0.19.6 aljaz:v0.19.5 aljaz:v0.19.4 aljaz:v0.19.3 aljaz:v0.19.2 aljaz:v0.19.1 aljaz:v0.19.0 aljaz:v0.18.0 aljaz:v0.17.1 aljaz:v0.17.0 aljaz:v0.16.19 aljaz:v0.16.18 aljaz:v0.16.17 aljaz:v0.16.16 aljaz:v0.16.15 aljaz:v0.16.14 aljaz:v0.16.13 aljaz:v0.16.12 aljaz:v0.16.11 aljaz:v0.16.10 aljaz:v0.16.9 aljaz:v0.16.8 aljaz:v0.16.7 aljaz:v0.16.6 aljaz:v0.16.5 aljaz:v0.16.3 aljaz:v0.16.2 aljaz:v0.16.1 aljaz:v0.16.0 aljaz:v0.15.4 aljaz:v0.15.3 aljaz:v0.15.2 aljaz:v0.15.1 aljaz:v0.15.0 aljaz:v0.14.1 aljaz:v0.14.0 aljaz:v0.12.4 aljaz:v0.12.3 aljaz:v0.12.2 aljaz:v0.12.1 aljaz:v0.12.0 aljaz:v0.11.5 aljaz:0.11.4 aljaz:v0.11.3 aljaz:v0.11.2 aljaz:v0.11.1 aljaz:v0.11.0 aljaz:v0.10.1 aljaz:v0.10.0 aljaz:v0.9.2 aljaz:v0.9.1 aljaz:v0.9.0 aljaz:v0.8.1 aljaz:v0.8.0 aljaz:v0.7.1 aljaz:v0.7.0 aljaz:v0.6.16 aljaz:v0.6.15 aljaz:v0.6.14 aljaz:0.6.13 aljaz:v0.6.12 aljaz:v0.6.11 aljaz:v0.6.10 aljaz:v0.6.9 aljaz:v0.6.8 aljaz:v0.6.7 aljaz:v0.6.6 aljaz:v0.6.5 aljaz:v0.6.4 aljaz:v0.6.3 aljaz:v0.6.2 aljaz:v0.6.1 aljaz:v0.6.0 aljaz:v0.5.7 aljaz:v0.5.6 aljaz:v0.5.5 aljaz:v0.5.4 aljaz:v0.5.3 aljaz:v0.5.2 aljaz:v0.5.1 aljaz:0.5.0a aljaz:v0.5.0 aljaz:v0.4.14 aljaz:0.4.12 aljaz:0.4.11 aljaz:0.4.10 aljaz:v0.4.9 aljaz:0.4.8 aljaz:0.4.7 aljaz:0.4.6 aljaz:0.4.5 aljaz:0.4.3 aljaz:0.4.2 aljaz:0.4.1 aljaz:0.4.0 aljaz:0.3.9 aljaz:0.3.8 aljaz:0.3.7 aljaz:0.3.6 aljaz:0.3.5 aljaz:0.3.4 aljaz:0.3.3 aljaz:0.3.2 aljaz:0.3.1 aljaz:0.3.0 aljaz:0.2.46 aljaz:0.2.44 aljaz:0.2.43 aljaz:0.2.42 aljaz:0.2.41 aljaz:0.2.40 aljaz:0.2.39 aljaz:0.2.38 aljaz:0.2.37 aljaz:02.36 aljaz:0.2.35 aljaz:0.2.34 aljaz:0.2.33 aljaz:0.2.32 aljaz:0.2.31 aljaz:0.2.30 aljaz:0.2.29 aljaz:0.2.28 aljaz:0.2.27 aljaz:0.2.26 aljaz:0.2.25 aljaz:0.2.24 aljaz:0.2.23 aljaz:0.2.22 aljaz:0.2.21 aljaz:0.2.20 aljaz:0.2.19 aljaz:0.2.18 aljaz:0.2.17 aljaz:0.2.16 aljaz:0.2.15 aljaz:0.2.14 aljaz:0.2.12 aljaz:0.2.11 aljaz:0.2.10 aljaz:0.2.9 aljaz:0.2.8 aljaz:0.2.7 aljaz:0.2.6a aljaz:0.2.6 aljaz:0.2.5 aljaz:0.2.4 aljaz:0.2.3 aljaz:0.2.2a aljaz:0.2.2 aljaz:0.2.1 aljaz:0.2.0 aljaz:0.1.10 aljaz:0.1.9 aljaz:0.1.8 aljaz:0.1.7a aljaz:0.1.7 aljaz:0.1.6 aljaz:0.1.5 aljaz:0.1.4 aljaz:0.1.2 aljaz:0.1.1 aljaz:0.1.0 aljaz:0.0.109 aljaz:0.0.108 aljaz:0.0.107 aljaz:0.0.106 aljaz:0.0.105 aljaz:0.0.104 aljaz:0.0.102 aljaz:0.0.101 aljaz:0.0.100 aljaz:0.0.99 aljaz:0.0.98 aljaz:0.0.97 aljaz:0.0.96 aljaz:0.0.95 aljaz:0.0.94 aljaz:0.0.93 aljaz:0.0.92 aljaz:0.0.91 aljaz:0.0.90 aljaz:0.0.89 aljaz:0.0.88 aljaz:0.0.87 aljaz:0.0.86 aljaz:0.0.85 aljaz:0.0.84 aljaz:0.0.82 aljaz:0.0.81 aljaz:0.0.80 aljaz:0.0.79 aljaz:0.0.78 aljaz:0.0.77 aljaz:0.0.76 aljaz:0.0.75 aljaz:0.0.74 aljaz:0.0.73 aljaz:0.0.72 aljaz:0.0.71 aljaz:0.0.70 aljaz:0.0.67 aljaz:0.0.65 aljaz:0.0.64 aljaz:0.0.63 aljaz:0.0.62 aljaz:0.0.61 aljaz:0.0.60 aljaz:0.0.59 aljaz:0.0.58 aljaz:0.0.57 aljaz:0.0.56 aljaz:0.0.55 aljaz:0.0.54 aljaz:0.0.53 aljaz:0.0.52 aljaz:0.0.51 aljaz:0.0.50 aljaz:0.0.49 aljaz:0.0.48 aljaz:0.0.47 aljaz:0.0.46 aljaz:0.0.45 aljaz:0.0.44 aljaz:0.0.43 aljaz:0.0.42 aljaz:0.0.41 aljaz:0.0.40 aljaz:0.0.39 aljaz:0.0.38 aljaz:0.0.37 aljaz:0.0.36 aljaz:0.0.35 aljaz:0.0.34 aljaz:0.0.33 aljaz:0.0.32 aljaz:0.0.31 aljaz:0.0.28 aljaz:0.0.27 aljaz:0.0.26 aljaz:0.0.25 aljaz:0.0.24 aljaz:0.0.23 aljaz:0.0.22 aljaz:0.0.21 aljaz:0.0.20 aljaz:0.0.18 aljaz:0.0.17 aljaz:0.0.16 aljaz:0.0.15 aljaz:0.0.14 aljaz:0.0.12 aljaz:0.0.11 aljaz:0.0.10 aljaz:0.0.9 aljaz:0.0.8 aljaz:0.0.7 aljaz:0.0.6a aljaz:0.0.6 aljaz:0.0.5 aljaz:0.0.4 aljaz:0.0.2 aljaz:0.0.1

87 Commits
0.0.107 ... 0.3.0

Author SHA1 Message Date
Phil Wang
13382885d9 final update to dalle2 repository for a while - sampling from prior in chunks automatically with max_batch_size keyword given 2022-05-16 12:57:31 -07:00
Phil Wang
c3d4a7ffe4 update working unconditional decoder example 2022-05-16 12:50:07 -07:00
Phil Wang
164d9be444 use a decorator and take care of sampling in chunks (max_batch_size keyword), in case one is sampling a huge grid of images 2022-05-16 12:34:28 -07:00
Phil Wang
5562ec6be2 status updates 2022-05-16 12:01:54 -07:00
Phil Wang
89ff04cfe2 final tweak to EMA class 2022-05-16 11:54:34 -07:00
Phil Wang
f4016f6302 allow for overriding use of EMA during sampling in decoder trainer with use_non_ema keyword, also fix some issues with automatic normalization of images and low res conditioning image if latent diffusion is in play 2022-05-16 11:18:30 -07:00
Phil Wang
1212f7058d allow text encodings and text mask to be passed in on forward and sampling for Decoder class 2022-05-16 10:40:32 -07:00
Phil Wang
dab106d4e5 back to no_grad for now, also keep track and restore unet devices in one_unet_in_gpu contextmanager 2022-05-16 09:36:14 -07:00
Phil Wang
bb151ca6b1 unet_number on decoder trainer only needs to be passed in if there is greater than 1 unet, so that unconditional training of a single ddpm is seamless (experiment in progress locally) 2022-05-16 09:17:17 -07:00
zion
4a59dea4cf Migrate to text-conditioned prior training (#95) 
* migrate to conditioned prior

* unify reader logic with a wrapper (#1)

* separate out reader logic

* support both training methods

* Update train prior to use embedding wrapper (#3)

* Support Both Methods

* bug fixes

* small bug fixes

* embedding only wrapper bug

* use smaller val perc

* final bug fix for embedding-only

Co-authored-by: nousr <>
 2022-05-15 20:16:38 -07:00
Phil Wang
ecf9e8027d make sure classifier free guidance is used only if conditional dropout is present on the DiffusionPrior and Decoder classes. also make sure prior can have a different conditional scale than decoder 2022-05-15 19:09:38 -07:00
Phil Wang
36c5079bd7 LazyLinear is not mature, make users pass in text_embed_dim if text conditioning is turned on 2022-05-15 18:56:52 -07:00
Phil Wang
4a4c7ac9e6 cond drop prob for diffusion prior network should default to 0 2022-05-15 18:47:45 -07:00
Phil Wang
fad7481479 todo 2022-05-15 17:00:25 -07:00
Phil Wang
123658d082 cite Ho et al, since cascading ddpm is now trainable 2022-05-15 16:56:53 -07:00
Phil Wang
11d4e11f10 allow for training unconditional ddpm or cascading ddpms 2022-05-15 16:54:56 -07:00
Phil Wang
99778e12de trainer classes now takes care of auto-casting numpy to torch tensors, and setting correct device based on model parameter devices 2022-05-15 15:25:45 -07:00
Phil Wang
0f0011caf0 todo 2022-05-15 14:28:35 -07:00
Phil Wang
7b7a62044a use eval vs training mode to determine whether to call backprop on trainer forward 2022-05-15 14:20:59 -07:00
Phil Wang
156fe5ed9f final cleanup for the day 2022-05-15 12:38:41 -07:00
Phil Wang
5ec34bebe1 cleanup readme 2022-05-15 12:29:26 -07:00
Phil Wang
8eaacf1ac1 remove indirection 2022-05-15 12:05:45 -07:00
Phil Wang
e66c7b0249 incorrect naming 2022-05-15 11:23:52 -07:00
Phil Wang
f7cd4a0992 product management 2022-05-15 11:21:12 -07:00
Phil Wang
68e7d2f241 make sure gradient accumulation feature works even if all arguments passed in are keyword arguments 2022-05-15 11:16:16 -07:00
Phil Wang
74f222596a remove todo 2022-05-15 11:01:35 -07:00
Phil Wang
aa6772dcff make sure optimizer and scaler is reloaded on resume for training diffusion prior script, move argparse to click 2022-05-15 10:48:10 -07:00
Phil Wang
71d0c4edae cleanup to use diffusion prior trainer 2022-05-15 10:16:05 -07:00
Phil Wang
f7eee09d8b 0.2.30 2022-05-15 09:56:59 -07:00
Phil Wang
89de5af63e experiment tracker agnostic 2022-05-15 09:56:40 -07:00
Phil Wang
4ec6d0ba81 backwards pass is not recommended under the autocast context, per pytorch docs 2022-05-14 18:26:19 -07:00
Phil Wang
aee92dba4a simplify more 2022-05-14 17:16:46 -07:00
Phil Wang
b0cd5f24b6 take care of gradient accumulation automatically for researchers, by passing in a max_batch_size on the decoder or diffusion prior trainer forward 2022-05-14 17:04:09 -07:00
Phil Wang
b494ed81d4 take care of backwards within trainer classes for diffusion prior and decoder, readying to take care of gradient accumulation as well (plus, unsure if loss should be backwards within autocast block) 2022-05-14 15:49:24 -07:00
Phil Wang
ff3474f05c normalize conditioning tokens outside of cross attention blocks 2022-05-14 14:23:52 -07:00
Phil Wang
d5293f19f1 lineup with paper 2022-05-14 13:57:00 -07:00
Phil Wang
e697183849 be able to customize adam eps 2022-05-14 13:55:04 -07:00
Phil Wang
591d37e266 lower default initial learning rate to what Jonathan Ho had in his original repo 2022-05-14 13:22:43 -07:00
Phil Wang
d1f02e8f49 always use sandwich norm for attention layer 2022-05-14 12:13:41 -07:00
Phil Wang
9faab59b23 use post-attn-branch layernorm in attempt to stabilize cross attention conditioning in decoder 2022-05-14 11:58:09 -07:00
Phil Wang
5d27029e98 make sure lowres conditioning image is properly normalized to -1 to 1 for cascading ddpm 2022-05-14 01:23:54 -07:00
Phil Wang
3115fa17b3 fix everything around normalizing images to -1 to 1 for ddpm training automatically 2022-05-14 01:17:11 -07:00
Phil Wang
124d8577c8 move the inverse normalization function called before image embeddings are derived from clip to within the diffusion prior and decoder classes 2022-05-14 00:37:52 -07:00
Phil Wang
2db0c9794c comments 2022-05-12 14:25:20 -07:00
Phil Wang
2277b47ffd make sure learned variance can work for any number of unets in the decoder, defaults to first unet, as suggested was used in the paper 2022-05-12 14:18:15 -07:00
Phil Wang
28b58e568c cleanup in preparation of option for learned variance 2022-05-12 12:04:52 -07:00
Phil Wang
924455d97d align the ema model device back after sampling from the cascading ddpm in the decoder 2022-05-11 19:56:54 -07:00
Phil Wang
6021945fc8 default to l2 loss 2022-05-11 19:24:51 -07:00
Light-V
6f76652d11 fix typo in README.md (#85) 
The default config for clip from openai should be ViT-B/32
 2022-05-11 13:38:16 -07:00
Phil Wang
3dda2570ed fix amp issue for https://github.com/lucidrains/DALLE2-pytorch/issues/82 2022-05-11 08:21:39 -07:00
Phil Wang
2f3c02dba8 numerical accuracy for noise schedule parameters 2022-05-10 15:28:46 -07:00
Phil Wang
908088cfea wrap up cross embed layer feature 2022-05-10 12:19:34 -07:00
Phil Wang
8dc8a3de0d product management 2022-05-10 11:51:38 -07:00
Phil Wang
35f89556ba bring in the cross embed layer from Crossformer paper for initial convolution in unet 2022-05-10 11:50:38 -07:00
Phil Wang
2b55f753b9 fix new issue with github actions and auto pypi package uploading 2022-05-10 10:51:15 -07:00
Phil Wang
fc8fce38fb make sure cascading DDPM can be trained unconditionally, to ready for CLI one command training for the public 2022-05-10 10:48:10 -07:00
Phil Wang
a1bfb03ba4 project management 2022-05-10 10:13:51 -07:00
Phil Wang
b1e7b5f6bb make sure resnet groups in unet is finely customizable 2022-05-10 10:12:50 -07:00
z
10b905b445 smol typo (#81) 2022-05-10 09:52:50 -07:00
Phil Wang
9b322ea634 patch 2022-05-09 19:46:19 -07:00
Phil Wang
ba64ea45cc 0.2.3 2022-05-09 16:50:31 -07:00
Phil Wang
64f7be1926 some cleanup 2022-05-09 16:50:21 -07:00
Phil Wang
db805e73e1 fix a bug with numerical stability in attention, sorry! 🐛 2022-05-09 16:23:37 -07:00
z
cb07b37970 Ensure Eval Mode In Metric Functions (#79) 
* add eval/train toggles

* train/eval flags

* shift train toggle

Co-authored-by: nousr <z@localhost.com>
 2022-05-09 16:05:40 -07:00
Phil Wang
a774bfefe2 add attention and feedforward dropouts to train_diffusion_prior script 2022-05-09 13:57:15 -07:00
Phil Wang
2ae57f0cf5 cleanup 2022-05-09 13:51:26 -07:00
Phil Wang
e46eaec817 deal the diffusion prior problem yet another blow 2022-05-09 11:08:52 -07:00
Kumar R
8647cb5e76 Val loss changes, with quite a few other changes. This is in place of the earlier PR(https://github.com/lucidrains/DALLE2-pytorch/pull/67) (#77) 
* Val_loss changes - no rebased with lucidrains' master.

* Val Loss changes - now rebased with lucidrains' master

* train_diffusion_prior.py updates

* dalle2_pytorch.py updates

* __init__.py changes

* Update train_diffusion_prior.py

* Update dalle2_pytorch.py

* Update train_diffusion_prior.py

* Update train_diffusion_prior.py

* Update dalle2_pytorch.py

* Update train_diffusion_prior.py

* Update train_diffusion_prior.py

* Update train_diffusion_prior.py

* Update train_diffusion_prior.py

* Update README.md

* Update README.md

* Update README.md

* Update README.md

* Update README.md

* Update README.md

* Update README.md

* Update README.md

* Update README.md
 2022-05-09 08:53:29 -07:00
Phil Wang
53c189e46a give more surface area for attention in diffusion prior 2022-05-09 08:08:11 -07:00
Phil Wang
dde51fd362 revert restriction for classifier free guidance for diffusion prior, given @crowsonkb advice 2022-05-07 20:55:41 -07:00
Nasir Khalid
2eac7996fa Additional image_embed metric (#75) 
Added metric to track image_embed vs predicted_image_embed
 2022-05-07 14:32:33 -07:00
Phil Wang
4010aec033 turn off classifier free guidance if predicting x_start for diffusion prior 2022-05-07 09:38:17 -07:00
Phil Wang
c87b84a259 todo 2022-05-07 09:21:08 -07:00
Phil Wang
8b05468653 todo 2022-05-07 08:33:45 -07:00
Phil Wang
830afd3c15 sinusoidal embed time embeddings for diffusion prior as well, for continuous version 2022-05-07 08:32:43 -07:00
Phil Wang
8f93729d19 when in doubt, make it a hyperparameter 2022-05-07 07:52:17 -07:00
z
cd5f2c1de4 simulate unrelated captions as a training metric (#66) 
* add unrelated embedding metric

* change to torch.roll

Co-authored-by: nousr <z@localhost.com>
Co-authored-by: nousr <>
 2022-05-07 05:34:59 -07:00
Phil Wang
85ed77d512 fix a potentially huge bug thanks to @CiaoHe https://github.com/lucidrains/DALLE2-pytorch/issues/71 2022-05-07 05:05:54 -07:00
Piero Rolando
fd53fa17db Fix a typo in README (#70) 
Change "pyhon" for "python" (correct)
 2022-05-06 16:53:36 -07:00
Phil Wang
3676ef4d49 make sure vqgan-vae trainer supports mixed precision 2022-05-06 10:44:16 -07:00
Phil Wang
28e944f328 make sure openai clip adapter outputs l2normed embeddings 2022-05-06 10:12:03 -07:00
Phil Wang
14e63a3f67 also offer l2norm clamping in diffusion prior during training, if one were using predict x0 objective 2022-05-06 10:05:14 -07:00
Phil Wang
09e9eaa5a6 project management 2022-05-06 09:00:22 -07:00
Phil Wang
e6d752cf4a reprioritize 2022-05-06 08:55:26 -07:00
Phil Wang
ad20a14a4d bring in rotary embeddings for diffusion prior causal transformer (the most powerful relative positional encoding, used in PaLM) - 0.1.0 because of breaking change 2022-05-06 08:45:30 -07:00
Phil Wang
0be1e0d64c support CoCa, which seems to be better than CLIP (has an autoregressive text encoder) https://arxiv.org/abs/2205.01917 2022-05-06 08:27:12 -07:00
Phil Wang
98df1ba51e add diffusion prior trainer, which automatically takes care of the exponential moving average (training and sampling), as well as mixed precision, gradient clipping 2022-05-06 08:11:09 -07:00
13 changed files with 1793 additions and 600 deletions
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240
README.md
View File

@@ -14,6 +14,12 @@ Please join <a href="https://discord.gg/xBPBXfcFHd"><img alt="Join us on Discord
There was enough interest for a <a href="https://github.com/lucidrains/dalle2-jax">Jax version</a>. I will also eventually extend this to <a href="https://github.com/lucidrains/dalle2-video">text to video</a>, once the repository is in a good place.
## Status
- A research group has used the code in this repository to train a functional diffusion prior for their CLIP generations. Will share their work once they release their preprint. This, and <a href="https://github.com/crowsonkb">Katherine's</a> own experiments, validate OpenAI's finding that the extra prior increases variety of generations.
- Decoder is now verified working for unconditional generation on my experimental setup for Oxford flowers
## Install
```bash
@@ -508,7 +514,7 @@ To use a pretrained OpenAI CLIP, simply import `OpenAIClipAdapter` and pass it i
import torch
from dalle2_pytorch import DALLE2, DiffusionPriorNetwork, DiffusionPrior, Unet, Decoder, OpenAIClipAdapter
# openai pretrained clip - defaults to ViT/B-32
# openai pretrained clip - defaults to ViT-B/32
clip = OpenAIClipAdapter()
@@ -706,7 +712,7 @@ mock_image_embed = torch.randn(1, 512).cuda()
images = decoder.sample(mock_image_embed) # (1, 3, 1024, 1024)
```
## Training wrapper (wip)
## Training wrapper
### Decoder Training
@@ -732,8 +738,8 @@ clip = CLIP(
# mock data
text = torch.randint(0, 49408, (4, 256)).cuda()
images = torch.randn(4, 3, 256, 256).cuda()
text = torch.randint(0, 49408, (32, 256)).cuda()
images = torch.randn(32, 3, 256, 256).cuda()
# decoder (with unet)
@@ -774,8 +780,12 @@ decoder_trainer = DecoderTrainer(
)
for unet_number in (1, 2):
loss = decoder_trainer(images, text = text, unet_number = unet_number) # use the decoder_trainer forward
loss.backward()
loss = decoder_trainer(
images,
text = text,
unet_number = unet_number, # which unet to train on
max_batch_size = 4 # gradient accumulation - this sets the maximum batch size in which to do forward and backwards pass - for this example 32 / 4 == 8 times
)
decoder_trainer.update(unet_number) # update the specific unet as well as its exponential moving average
@@ -786,6 +796,122 @@ mock_image_embed = torch.randn(4, 512).cuda()
images = decoder_trainer.sample(mock_image_embed, text = text) # (4, 3, 256, 256)
```
### Diffusion Prior Training
Similarly, one can use the `DiffusionPriorTrainer` to automatically instantiate and keep track of an exponential moving averaged prior.
```python
import torch
from dalle2_pytorch import DALLE2, DiffusionPriorNetwork, DiffusionPrior, DiffusionPriorTrainer, Unet, Decoder, CLIP
clip = CLIP(
dim_text = 512,
dim_image = 512,
dim_latent = 512,
num_text_tokens = 49408,
text_enc_depth = 6,
text_seq_len = 256,
text_heads = 8,
visual_enc_depth = 6,
visual_image_size = 256,
visual_patch_size = 32,
visual_heads = 8
).cuda()
# mock data
text = torch.randint(0, 49408, (512, 256)).cuda()
images = torch.randn(512, 3, 256, 256).cuda()
# prior networks (with transformer)
prior_network = DiffusionPriorNetwork(
dim = 512,
depth = 6,
dim_head = 64,
heads = 8
).cuda()
diffusion_prior = DiffusionPrior(
net = prior_network,
clip = clip,
timesteps = 100,
cond_drop_prob = 0.2
).cuda()
diffusion_prior_trainer = DiffusionPriorTrainer(
diffusion_prior,
lr = 3e-4,
wd = 1e-2,
ema_beta = 0.99,
ema_update_after_step = 1000,
ema_update_every = 10,
)
loss = diffusion_prior_trainer(text, images, max_batch_size = 4)
diffusion_prior_trainer.update() # this will update the optimizer as well as the exponential moving averaged diffusion prior
# after much of the above three lines in a loop
# you can sample from the exponential moving average of the diffusion prior identically to how you do so for DiffusionPrior
image_embeds = diffusion_prior_trainer.sample(text, max_batch_size = 4) # (512, 512) - exponential moving averaged image embeddings
```
## Bonus
### Unconditional Training
The repository also contains the means to train unconditional DDPM model, or even cascading DDPMs. You simply have to set `unconditional = True` in the `Decoder`
ex.
```python
import torch
from dalle2_pytorch import Unet, Decoder, DecoderTrainer
# unet for the cascading ddpm
unet1 = Unet(
dim = 128,
dim_mults=(1, 2, 4, 8)
).cuda()
unet2 = Unet(
dim = 32,
dim_mults = (1, 2, 4, 8, 16)
).cuda()
# decoder, which contains the unets
decoder = Decoder(
unet = (unet1, unet2),
image_sizes = (256, 512), # first unet up to 256px, then second to 512px
timesteps = 1000,
unconditional = True
).cuda()
# decoder trainer
decoder_trainer = DecoderTrainer(decoder)
# images (get a lot of this)
images = torch.randn(1, 3, 512, 512).cuda()
# feed images into decoder
for i in (1, 2):
loss = decoder_trainer(images, unet_number = i)
decoder_trainer.update(unet_number = i)
# do the above for many many many many images
# then it will learn to generate images
images = decoder_trainer.sample(batch_size = 36, max_batch_size = 4) # (36, 3, 512, 512)
```
## Dataloaders
### Decoder Dataloaders
In order to make loading data simple and efficient, we include some general dataloaders that can be used to train portions of the network.
@@ -830,42 +956,65 @@ dataset = ImageEmbeddingDataset(
)
```
## Scripts
### Scripts (wip)
### Using the `train_diffusion_prior.py` script
#### `train_diffusion_prior.py`
This script allows training the DiffusionPrior on pre-computed text and image embeddings. The working example below elucidates this process.
Please note that the script internally passes text_embed and image_embed to the DiffusionPrior, unlike the example below.
### Usage
#### Usage
```bash
$ pyhon train_diffusion_prior.py
$ python train_diffusion_prior.py
```
The most significant parameters for the script are as follows:
--image-embed-url, default = "https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/img_emb/")
- `image-embed-url`, default = `"https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/img_emb/"`
--text-embed-url, default = "https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/text_emb/")
- `text-embed-url`, default = `"https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/text_emb/"`
--image-embed-dim, default=768 - 768 corresponds to the ViT iL/14 embedding size,change it to what your chosen ViT generates
- `image-embed-dim`, default = `768` - 768 corresponds to the ViT iL/14 embedding size,change it to what your chosen ViT generates
--learning-rate, default=1.1e-4
- `learning-rate`, default = `1.1e-4`
--weight-decay, default=6.02e-2
- `weight-decay`, default = `6.02e-2`
--max-grad-norm, default=0.5
- `max-grad-norm`, default = `0.5`
--batch-size, default=10 ** 4
- `batch-size`, default = `10 ** 4`
--num-epochs, default=5
- `num-epochs`, default = `5`
--clip, default=None # Signals the prior to use pre-computed embeddings
- `clip`, default = `None` # Signals the prior to use pre-computed embeddings
### Sample wandb run log
#### Loading and Saving the DiffusionPrior model
Please find a sample wandb run log at : https://wandb.ai/laion/diffusion-prior/runs/aul0rhv5?workspace=
Two methods are provided, load_diffusion_model and save_diffusion_model, the names being self-explanatory.
```python
from dalle2_pytorch.train import load_diffusion_model, save_diffusion_model
```
##### Loading
load_diffusion_model(dprior_path, device)
dprior_path : path to saved model(.pth)
device : the cuda device you're running on
##### Saving
save_diffusion_model(save_path, model, optimizer, scaler, config, image_embed_dim)
save_path : path to save at
model : object of Diffusion_Prior
optimizer : optimizer object - see train_diffusion_prior.py for how to create one.
e.g: optimizer = get_optimizer(diffusion_prior.net.parameters(), wd=weight_decay, lr=learning_rate)
scaler : a GradScaler object.
e.g: scaler = GradScaler(enabled=amp)
config : config object created in train_diffusion_prior.py - see file for example.
image_embed_dim - the dimension of the image_embedding
e.g: 768
## CLI (wip)
@@ -904,20 +1053,29 @@ Once built, images will be saved to the same directory the command is invoked
- [x] add convnext backbone for vqgan-vae (in addition to vit [vit-vqgan] + resnet)
- [x] make sure DDPMs can be run with traditional resnet blocks (but leave convnext as an option for experimentation)
- [x] make sure for the latter unets in the cascade, one can train on crops for learning super resolution (constrain the unet to be only convolutions in that case, or allow conv-like attention with rel pos bias)
- [x] offer setting in diffusion prior to split time and image embeddings into multiple tokens, configurable, for more surface area during attention
- [x] make sure resnet hyperparameters can be configurable across unet depth (groups and expansion factor)
- [x] pull logic for training diffusion prior into a class DiffusionPriorTrainer, for eventual script based + CLI based training
- [x] make sure the cascading ddpm in the repository can be trained unconditionally, offer a one-line CLI tool for training on a folder of images
- [x] bring in cross-scale embedding from iclr paper https://github.com/lucidrains/vit-pytorch/blob/main/vit_pytorch/crossformer.py#L14
- [x] cross embed layers for downsampling, as an option
- [x] use an experimental tracker agnostic setup, as done <a href="https://github.com/lucidrains/tf-bind-transformer#simple-trainer-class-for-fine-tuning">here</a>
- [ ] become an expert with unets, cleanup unet code, make it fully configurable, port all learnings over to https://github.com/lucidrains/x-unet (test out unet² in ddpm repo) - consider https://github.com/lucidrains/uformer-pytorch attention-based unet
- [ ] copy the cascading ddpm code to a separate repo (perhaps https://github.com/lucidrains/denoising-diffusion-pytorch) as the main contribution of dalle2 really is just the prior network
- [ ] transcribe code to Jax, which lowers the activation energy for distributed training, given access to TPUs
- [ ] pull logic for training diffusion prior into a class DiffusionPriorTrainer, for eventual script based + CLI based training
- [ ] train on a toy task, offer in colab
- [ ] think about how best to design a declarative training config that handles preencoding for prior and training of multiple networks in decoder
- [ ] extend diffusion head to use diffusion-gan (potentially using lightweight-gan) to speed up inference
- [ ] bring in cross-scale embedding from iclr paper https://github.com/lucidrains/vit-pytorch/blob/main/vit_pytorch/crossformer.py#L14
- [ ] figure out if possible to augment with external memory, as described in https://arxiv.org/abs/2204.11824
- [ ] test out grid attention in cascading ddpm locally, decide whether to keep or remove
- [ ] use an experimental tracker agnostic setup, as done <a href="https://github.com/lucidrains/tf-bind-transformer#simple-trainer-class-for-fine-tuning">here</a>
- [ ] interface out the vqgan-vae so a pretrained one can be pulled off the shelf to validate latent diffusion + DALL-E2
- [ ] make sure FILIP works with DALL-E2 from x-clip https://arxiv.org/abs/2111.07783
- [ ] make sure resnet hyperparameters can be configurable across unet depth (groups and expansion factor)
- [ ] offer save / load methods on the trainer classes to automatically take care of state dicts for scalers / optimizers / saving versions and checking for breaking changes
- [ ] bring in skip-layer excitatons (from lightweight gan paper) to see if it helps for either decoder of unet or vqgan-vae training
- [ ] decoder needs one day worth of refactor for tech debt
- [ ] allow for unet to be able to condition non-cross attention style as well
- [ ] for all model classes with hyperparameters that changes the network architecture, make it requirement that they must expose a config property, and write a simple function that asserts that it restores the object correctly
- [ ] for both diffusion prior and decoder, all exponential moving averaged models needs to be saved and restored as well (as well as the step number)
- [ ] read the paper, figure it out, and build it https://github.com/lucidrains/DALLE2-pytorch/issues/89
## Citations
@@ -985,4 +1143,34 @@ Once built, images will be saved to the same directory the command is invoked
}
```
```bibtex
@article{Yu2022CoCaCC,
title = {CoCa: Contrastive Captioners are Image-Text Foundation Models},
author = {Jiahui Yu and Zirui Wang and Vijay Vasudevan and Legg Yeung and Mojtaba Seyedhosseini and Yonghui Wu},
journal = {ArXiv},
year = {2022},
volume = {abs/2205.01917}
}
```
```bibtex
@misc{wang2021crossformer,
title = {CrossFormer: A Versatile Vision Transformer Hinging on Cross-scale Attention},
author = {Wenxiao Wang and Lu Yao and Long Chen and Binbin Lin and Deng Cai and Xiaofei He and Wei Liu},
year = {2021},
eprint = {2108.00154},
archivePrefix = {arXiv},
primaryClass = {cs.CV}
}
```
```bibtex
@article{ho2021cascaded,
title = {Cascaded Diffusion Models for High Fidelity Image Generation},
author = {Ho, Jonathan and Saharia, Chitwan and Chan, William and Fleet, David J and Norouzi, Mohammad and Salimans, Tim},
journal = {arXiv preprint arXiv:2106.15282},
year = {2021}
}
```
*Creating noise from data is easy; creating data from noise is generative modeling.* - <a href="https://arxiv.org/abs/2011.13456">Yang Song's paper</a>

2
dalle2_pytorch/__init__.py
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@@ -1,6 +1,6 @@
from dalle2_pytorch.dalle2_pytorch import DALLE2, DiffusionPriorNetwork, DiffusionPrior, Unet, Decoder
from dalle2_pytorch.dalle2_pytorch import OpenAIClipAdapter
from dalle2_pytorch.train import DecoderTrainer
from dalle2_pytorch.trainer import DecoderTrainer, DiffusionPriorTrainer
from dalle2_pytorch.vqgan_vae import VQGanVAE
from x_clip import CLIP

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3
dalle2_pytorch/dataloaders/__init__.py
View File

@@ -1 +1,2 @@
from dalle2_pytorch.dataloaders.decoder_loader import ImageEmbeddingDataset, create_image_embedding_dataloader
from dalle2_pytorch.dataloaders.decoder_loader import ImageEmbeddingDataset, create_image_embedding_dataloader
from dalle2_pytorch.dataloaders.embedding_wrapper import make_splits

180
dalle2_pytorch/dataloaders/embedding_wrapper.py Normal file
View File

@@ -0,0 +1,180 @@
from torch.utils.data import IterableDataset
from torch import from_numpy
from clip import tokenize
from embedding_reader import EmbeddingReader
class PriorEmbeddingLoader(IterableDataset):
def __init__(
self,
text_conditioned: bool,
batch_size: int,
start: int,
stop: int,
image_reader,
text_reader: EmbeddingReader = None,
device: str = "cpu",
) -> None:
super(PriorEmbeddingLoader).__init__()
self.text_conditioned = text_conditioned
if not self.text_conditioned:
self.text_reader = text_reader
self.image_reader = image_reader
self.batch_size = batch_size
self.start = start
self.stop = stop
self.device = device
def __iter__(self):
self.n = 0
loader_args = dict(
batch_size=self.batch_size,
start=self.start,
end=self.stop,
show_progress=False,
)
if self.text_conditioned:
self.loader = self.image_reader(**loader_args)
else:
self.loader = zip(
self.image_reader(**loader_args), self.text_reader(**loader_args)
)
return self
def __next__(self):
try:
return self.get_sample()
except StopIteration:
raise StopIteration
def get_sample(self):
"""
pre-proocess data from either reader into a common format
"""
self.n += 1
if self.text_conditioned:
image_embedding, caption = next(self.loader)
image_embedding = from_numpy(image_embedding).to(self.device)
tokenized_caption = tokenize(
caption["caption"].to_list(), truncate=True
).to(self.device)
return image_embedding, tokenized_caption
else:
(image_embedding, _), (text_embedding, _) = next(self.loader)
image_embedding = from_numpy(image_embedding).to(self.device)
text_embedding = from_numpy(text_embedding).to(self.device)
return image_embedding, text_embedding
def make_splits(
text_conditioned: bool,
batch_size: int,
num_data_points: int,
train_split: float,
eval_split: float,
device: str,
img_url: str,
meta_url: str = None,
txt_url: str = None,
):
assert img_url is not None, "Must supply some image embeddings"
if text_conditioned:
assert meta_url is not None, "Must supply metadata url if text-conditioning"
image_reader = EmbeddingReader(
embeddings_folder=img_url,
file_format="parquet_npy",
meta_columns=["caption"],
metadata_folder=meta_url,
)
# compute split points
if num_data_points > image_reader.count:
print("Specified point count is larger than the number of points available...defaulting to max length of reader.")
num_data_points = image_reader.count
train_set_size = int(train_split * num_data_points)
eval_set_size = int(eval_split * num_data_points)
eval_stop = int(train_set_size + eval_set_size)
train_loader = PriorEmbeddingLoader(
text_conditioned=text_conditioned,
image_reader=image_reader,
batch_size=batch_size,
start=0,
stop=train_set_size,
device=device,
)
eval_loader = PriorEmbeddingLoader(
text_conditioned=text_conditioned,
image_reader=image_reader,
batch_size=batch_size,
start=train_set_size,
stop=eval_stop,
device=device,
)
test_loader = PriorEmbeddingLoader(
text_conditioned=text_conditioned,
image_reader=image_reader,
batch_size=batch_size,
start=eval_stop,
stop=int(num_data_points),
device=device,
)
else:
assert (
txt_url is not None
), "Must supply text embedding url if not text-conditioning"
image_reader = EmbeddingReader(img_url, file_format="npy")
text_reader = EmbeddingReader(txt_url, file_format="npy")
# compute split points
if num_data_points > image_reader.count:
print("Specified point count is larger than the number of points available...defaulting to max length of reader.")
num_data_points = image_reader.count
train_set_size = int(train_split * num_data_points)
eval_set_size = int(eval_split * num_data_points)
eval_stop = int(train_set_size + eval_set_size)
train_loader = PriorEmbeddingLoader(
text_conditioned=text_conditioned,
image_reader=image_reader,
text_reader=text_reader,
batch_size=batch_size,
start=0,
stop=train_set_size,
device=device,
)
eval_loader = PriorEmbeddingLoader(
text_conditioned=text_conditioned,
image_reader=image_reader,
text_reader=text_reader,
batch_size=batch_size,
start=train_set_size,
stop=eval_stop,
device=device,
)
test_loader = PriorEmbeddingLoader(
text_conditioned=text_conditioned,
image_reader=image_reader,
text_reader=text_reader,
batch_size=batch_size,
start=eval_stop,
stop=int(num_data_points),
device=device,
)
return train_loader, eval_loader, test_loader

59
dalle2_pytorch/dataloaders/simple_image_only_dataloader.py Normal file
View File

@@ -0,0 +1,59 @@
from pathlib import Path
import torch
from torch.utils import data
from torchvision import transforms, utils
from PIL import Image
# helpers functions
def cycle(dl):
while True:
for data in dl:
yield data
# dataset and dataloader
class Dataset(data.Dataset):
def __init__(
self,
folder,
image_size,
exts = ['jpg', 'jpeg', 'png']
):
super().__init__()
self.folder = folder
self.image_size = image_size
self.paths = [p for ext in exts for p in Path(f'{folder}').glob(f'**/*.{ext}')]
self.transform = transforms.Compose([
transforms.Resize(image_size),
transforms.RandomHorizontalFlip(),
transforms.CenterCrop(image_size),
transforms.ToTensor()
])
def __len__(self):
return len(self.paths)
def __getitem__(self, index):
path = self.paths[index]
img = Image.open(path)
return self.transform(img)
def get_images_dataloader(
folder,
*,
batch_size,
image_size,
shuffle = True,
cycle_dl = True,
pin_memory = True
):
ds = Dataset(folder, image_size)
dl = data.DataLoader(ds, batch_size = batch_size, shuffle = shuffle, pin_memory = pin_memory)
if cycle_dl:
dl = cycle(dl)
return dl

7
dalle2_pytorch/optimizer.py
View File

@@ -7,16 +7,17 @@ def separate_weight_decayable_params(params):
def get_optimizer(
params,
lr = 3e-4,
lr = 2e-5,
wd = 1e-2,
betas = (0.9, 0.999),
eps = 1e-8,
filter_by_requires_grad = False
):
if filter_by_requires_grad:
params = list(filter(lambda t: t.requires_grad, params))
if wd == 0:
return Adam(params, lr = lr, betas = betas)
return Adam(params, lr = lr, betas = betas, eps = eps)
params = set(params)
wd_params, no_wd_params = separate_weight_decayable_params(params)
@@ -26,4 +27,4 @@ def get_optimizer(
{'params': list(no_wd_params), 'weight_decay': 0},
]
return AdamW(param_groups, lr = lr, weight_decay = wd, betas = betas)
return AdamW(param_groups, lr = lr, weight_decay = wd, betas = betas, eps = eps)

49
dalle2_pytorch/trackers.py Normal file
View File

@@ -0,0 +1,49 @@
import os
import torch
from torch import nn
# helper functions
def exists(val):
return val is not None
# base class
class BaseTracker(nn.Module):
def __init__(self):
super().__init__()
def init(self, config, **kwargs):
raise NotImplementedError
def log(self, log, **kwargs):
raise NotImplementedError
# basic stdout class
class ConsoleTracker(BaseTracker):
def init(self, **config):
print(config)
def log(self, log, **kwargs):
print(log)
# basic wandb class
class WandbTracker(BaseTracker):
def __init__(self):
super().__init__()
try:
import wandb
except ImportError as e:
print('`pip install wandb` to use the wandb experiment tracker')
raise e
os.environ["WANDB_SILENT"] = "true"
self.wandb = wandb
def init(self, **config):
self.wandb.init(**config)
def log(self, log, **kwargs):
self.wandb.log(log, **kwargs)

199
dalle2_pytorch/train.py
View File

@@ -1,199 +0,0 @@
import copy
from functools import partial
import torch
from torch import nn
from torch.cuda.amp import autocast, GradScaler
from dalle2_pytorch.dalle2_pytorch import Decoder
from dalle2_pytorch.optimizer import get_optimizer
# helper functions
def exists(val):
return val is not None
def cast_tuple(val, length = 1):
return val if isinstance(val, tuple) else ((val,) * length)
def pick_and_pop(keys, d):
values = list(map(lambda key: d.pop(key), keys))
return dict(zip(keys, values))
def group_dict_by_key(cond, d):
return_val = [dict(),dict()]
for key in d.keys():
match = bool(cond(key))
ind = int(not match)
return_val[ind][key] = d[key]
return (*return_val,)
def string_begins_with(prefix, str):
return str.startswith(prefix)
def group_by_key_prefix(prefix, d):
return group_dict_by_key(partial(string_begins_with, prefix), d)
def groupby_prefix_and_trim(prefix, d):
kwargs_with_prefix, kwargs = group_dict_by_key(partial(string_begins_with, prefix), d)
kwargs_without_prefix = dict(map(lambda x: (x[0][len(prefix):], x[1]), tuple(kwargs_with_prefix.items())))
return kwargs_without_prefix, kwargs
# exponential moving average wrapper
class EMA(nn.Module):
def __init__(
self,
model,
beta = 0.99,
update_after_step = 1000,
update_every = 10,
):
super().__init__()
self.beta = beta
self.online_model = model
self.ema_model = copy.deepcopy(model)
self.update_after_step = update_after_step # only start EMA after this step number, starting at 0
self.update_every = update_every
self.register_buffer('initted', torch.Tensor([False]))
self.register_buffer('step', torch.tensor([0.]))
def update(self):
self.step += 1
if self.step <= self.update_after_step or (self.step % self.update_every) != 0:
return
if not self.initted:
self.ema_model.state_dict(self.online_model.state_dict())
self.initted.data.copy_(torch.Tensor([True]))
self.update_moving_average(self.ema_model, self.online_model)
def update_moving_average(self, ma_model, current_model):
def calculate_ema(beta, old, new):
if not exists(old):
return new
return old * beta + (1 - beta) * new
for current_params, ma_params in zip(current_model.parameters(), ma_model.parameters()):
old_weight, up_weight = ma_params.data, current_params.data
ma_params.data = calculate_ema(self.beta, old_weight, up_weight)
for current_buffer, ma_buffer in zip(current_model.buffers(), ma_model.buffers()):
new_buffer_value = calculate_ema(self.beta, ma_buffer, current_buffer)
ma_buffer.copy_(new_buffer_value)
def __call__(self, *args, **kwargs):
return self.ema_model(*args, **kwargs)
# trainers
class DecoderTrainer(nn.Module):
def __init__(
self,
decoder,
use_ema = True,
lr = 3e-4,
wd = 1e-2,
max_grad_norm = None,
amp = False,
**kwargs
):
super().__init__()
assert isinstance(decoder, Decoder)
ema_kwargs, kwargs = groupby_prefix_and_trim('ema_', kwargs)
self.decoder = decoder
self.num_unets = len(self.decoder.unets)
self.use_ema = use_ema
if use_ema:
has_lazy_linear = any([type(module) == nn.LazyLinear for module in decoder.modules()])
assert not has_lazy_linear, 'you must set the text_embed_dim on your u-nets if you plan on doing automatic exponential moving average'
self.ema_unets = nn.ModuleList([])
self.amp = amp
# be able to finely customize learning rate, weight decay
# per unet
lr, wd = map(partial(cast_tuple, length = self.num_unets), (lr, wd))
for ind, (unet, unet_lr, unet_wd) in enumerate(zip(self.decoder.unets, lr, wd)):
optimizer = get_optimizer(
unet.parameters(),
lr = unet_lr,
wd = unet_wd,
**kwargs
)
setattr(self, f'optim{ind}', optimizer) # cannot use pytorch ModuleList for some reason with optimizers
if self.use_ema:
self.ema_unets.append(EMA(unet, **ema_kwargs))
scaler = GradScaler(enabled = amp)
setattr(self, f'scaler{ind}', scaler)
# gradient clipping if needed
self.max_grad_norm = max_grad_norm
@property
def unets(self):
return nn.ModuleList([ema.ema_model for ema in self.ema_unets])
def scale(self, loss, *, unet_number):
assert 1 <= unet_number <= self.num_unets
index = unet_number - 1
scaler = getattr(self, f'scaler{index}')
return scaler.scale(loss)
def update(self, unet_number):
assert 1 <= unet_number <= self.num_unets
index = unet_number - 1
unet = self.decoder.unets[index]
optimizer = getattr(self, f'optim{index}')
scaler = getattr(self, f'scaler{index}')
if exists(self.max_grad_norm):
scaler.unscale_(optimizer)
nn.utils.clip_grad_norm_(unet.parameters(), self.max_grad_norm)
scaler.step(optimizer)
scaler.update()
optimizer.zero_grad()
if self.use_ema:
ema_unet = self.ema_unets[index]
ema_unet.update()
@torch.no_grad()
def sample(self, *args, **kwargs):
if self.use_ema:
trainable_unets = self.decoder.unets
self.decoder.unets = self.unets # swap in exponential moving averaged unets for sampling
output = self.decoder.sample(*args, **kwargs)
if self.use_ema:
self.decoder.unets = trainable_unets # restore original training unets
return output
def forward(
self,
x,
*,
unet_number,
divisor = 1,
**kwargs
):
with autocast(enabled = self.amp):
loss = self.decoder(x, unet_number = unet_number, **kwargs)
return self.scale(loss / divisor, unet_number = unet_number)

491
dalle2_pytorch/trainer.py Normal file
View File

@@ -0,0 +1,491 @@
import time
import copy
from math import ceil
from functools import partial, wraps
from collections.abc import Iterable
import torch
from torch import nn
from torch.cuda.amp import autocast, GradScaler
from dalle2_pytorch.dalle2_pytorch import Decoder, DiffusionPrior
from dalle2_pytorch.optimizer import get_optimizer
import numpy as np
# helper functions
def exists(val):
return val is not None
def default(val, d):
return val if exists(val) else d
def cast_tuple(val, length = 1):
return val if isinstance(val, tuple) else ((val,) * length)
def pick_and_pop(keys, d):
values = list(map(lambda key: d.pop(key), keys))
return dict(zip(keys, values))
def group_dict_by_key(cond, d):
return_val = [dict(),dict()]
for key in d.keys():
match = bool(cond(key))
ind = int(not match)
return_val[ind][key] = d[key]
return (*return_val,)
def string_begins_with(prefix, str):
return str.startswith(prefix)
def group_by_key_prefix(prefix, d):
return group_dict_by_key(partial(string_begins_with, prefix), d)
def groupby_prefix_and_trim(prefix, d):
kwargs_with_prefix, kwargs = group_dict_by_key(partial(string_begins_with, prefix), d)
kwargs_without_prefix = dict(map(lambda x: (x[0][len(prefix):], x[1]), tuple(kwargs_with_prefix.items())))
return kwargs_without_prefix, kwargs
def num_to_groups(num, divisor):
groups = num // divisor
remainder = num % divisor
arr = [divisor] * groups
if remainder > 0:
arr.append(remainder)
return arr
# decorators
def cast_torch_tensor(fn):
@wraps(fn)
def inner(model, *args, **kwargs):
device = kwargs.pop('_device', next(model.parameters()).device)
cast_device = kwargs.pop('_cast_device', True)
kwargs_keys = kwargs.keys()
all_args = (*args, *kwargs.values())
split_kwargs_index = len(all_args) - len(kwargs_keys)
all_args = tuple(map(lambda t: torch.from_numpy(t) if exists(t) and isinstance(t, np.ndarray) else t, all_args))
if cast_device:
all_args = tuple(map(lambda t: t.to(device) if exists(t) and isinstance(t, torch.Tensor) else t, all_args))
args, kwargs_values = all_args[:split_kwargs_index], all_args[split_kwargs_index:]
kwargs = dict(tuple(zip(kwargs_keys, kwargs_values)))
out = fn(model, *args, **kwargs)
return out
return inner
# gradient accumulation functions
def split_iterable(it, split_size):
accum = []
for ind in range(ceil(len(it) / split_size)):
start_index = ind * split_size
accum.append(it[start_index: (start_index + split_size)])
return accum
def split(t, split_size = None):
if not exists(split_size):
return t
if isinstance(t, torch.Tensor):
return t.split(split_size, dim = 0)
if isinstance(t, Iterable):
return split_iterable(t, split_size)
return TypeError
def find_first(cond, arr):
for el in arr:
if cond(el):
return el
return None
def split_args_and_kwargs(*args, split_size = None, **kwargs):
all_args = (*args, *kwargs.values())
len_all_args = len(all_args)
first_tensor = find_first(lambda t: isinstance(t, torch.Tensor), all_args)
assert exists(first_tensor)
batch_size = len(first_tensor)
split_size = default(split_size, batch_size)
num_chunks = ceil(batch_size / split_size)
dict_len = len(kwargs)
dict_keys = kwargs.keys()
split_kwargs_index = len_all_args - dict_len
split_all_args = [split(arg, split_size = split_size) if exists(arg) and isinstance(arg, (torch.Tensor, Iterable)) else ((arg,) * num_chunks) for arg in all_args]
chunk_sizes = tuple(map(len, split_all_args[0]))
for (chunk_size, *chunked_all_args) in tuple(zip(chunk_sizes, *split_all_args)):
chunked_args, chunked_kwargs_values = chunked_all_args[:split_kwargs_index], chunked_all_args[split_kwargs_index:]
chunked_kwargs = dict(tuple(zip(dict_keys, chunked_kwargs_values)))
chunk_size_frac = chunk_size / batch_size
yield chunk_size_frac, (chunked_args, chunked_kwargs)
# print helpers
def print_ribbon(s, symbol = '=', repeat = 40):
flank = symbol * repeat
return f'{flank} {s} {flank}'
# saving and loading functions
# for diffusion prior
def load_diffusion_model(dprior_path, device):
dprior_path = Path(dprior_path)
assert dprior_path.exists(), 'Dprior model file does not exist'
loaded_obj = torch.load(str(dprior_path), map_location='cpu')
# Get hyperparameters of loaded model
dpn_config = loaded_obj['hparams']['diffusion_prior_network']
dp_config = loaded_obj['hparams']['diffusion_prior']
image_embed_dim = loaded_obj['image_embed_dim']['image_embed_dim']
# Create DiffusionPriorNetwork and DiffusionPrior with loaded hyperparameters
# DiffusionPriorNetwork
prior_network = DiffusionPriorNetwork( dim = image_embed_dim, **dpn_config).to(device)
# DiffusionPrior with text embeddings and image embeddings pre-computed
diffusion_prior = DiffusionPrior(net = prior_network, **dp_config, image_embed_dim = image_embed_dim).to(device)
# Load state dict from saved model
diffusion_prior.load_state_dict(loaded_obj['model'])
return diffusion_prior, loaded_obj
def save_diffusion_model(save_path, model, optimizer, scaler, config, image_embed_dim):
# Saving State Dict
print_ribbon('Saving checkpoint')
state_dict = dict(model=model.state_dict(),
optimizer=optimizer.state_dict(),
scaler=scaler.state_dict(),
hparams = config,
image_embed_dim = {"image_embed_dim":image_embed_dim})
torch.save(state_dict, save_path+'/'+str(time.time())+'_saved_model.pth')
# exponential moving average wrapper
class EMA(nn.Module):
def __init__(
self,
model,
beta = 0.9999,
update_after_step = 1000,
update_every = 10,
):
super().__init__()
self.beta = beta
self.online_model = model
self.ema_model = copy.deepcopy(model)
self.update_every = update_every
self.update_after_step = update_after_step // update_every # only start EMA after this step number, starting at 0
self.register_buffer('initted', torch.Tensor([False]))
self.register_buffer('step', torch.tensor([0.]))
def restore_ema_model_device(self):
device = self.initted.device
self.ema_model.to(device)
def copy_params_from_model_to_ema(self):
self.ema_model.state_dict(self.online_model.state_dict())
def update(self):
self.step += 1
if (self.step % self.update_every) != 0:
return
if self.step <= self.update_after_step:
self.copy_params_from_model_to_ema()
return
if not self.initted:
self.copy_params_from_model_to_ema()
self.initted.data.copy_(torch.Tensor([True]))
self.update_moving_average(self.ema_model, self.online_model)
def update_moving_average(self, ma_model, current_model):
def calculate_ema(beta, old, new):
if not exists(old):
return new
return old * beta + (1 - beta) * new
for current_params, ma_params in zip(current_model.parameters(), ma_model.parameters()):
old_weight, up_weight = ma_params.data, current_params.data
ma_params.data = calculate_ema(self.beta, old_weight, up_weight)
for current_buffer, ma_buffer in zip(current_model.buffers(), ma_model.buffers()):
new_buffer_value = calculate_ema(self.beta, ma_buffer, current_buffer)
ma_buffer.copy_(new_buffer_value)
def __call__(self, *args, **kwargs):
return self.ema_model(*args, **kwargs)
# diffusion prior trainer
def prior_sample_in_chunks(fn):
@wraps(fn)
def inner(self, *args, max_batch_size = None, **kwargs):
if not exists(max_batch_size):
return fn(self, *args, **kwargs)
outputs = [fn(self, *chunked_args, **chunked_kwargs) for _, (chunked_args, chunked_kwargs) in split_args_and_kwargs(*args, split_size = max_batch_size, **kwargs)]
return torch.cat(outputs, dim = 0)
return inner
class DiffusionPriorTrainer(nn.Module):
def __init__(
self,
diffusion_prior,
use_ema = True,
lr = 3e-4,
wd = 1e-2,
eps = 1e-6,
max_grad_norm = None,
amp = False,
**kwargs
):
super().__init__()
assert isinstance(diffusion_prior, DiffusionPrior)
ema_kwargs, kwargs = groupby_prefix_and_trim('ema_', kwargs)
self.diffusion_prior = diffusion_prior
# exponential moving average
self.use_ema = use_ema
if self.use_ema:
self.ema_diffusion_prior = EMA(diffusion_prior, **ema_kwargs)
# optimizer and mixed precision stuff
self.amp = amp
self.scaler = GradScaler(enabled = amp)
self.optimizer = get_optimizer(
diffusion_prior.parameters(),
lr = lr,
wd = wd,
eps = eps,
**kwargs
)
# gradient clipping if needed
self.max_grad_norm = max_grad_norm
self.register_buffer('step', torch.tensor([0.]))
def update(self):
if exists(self.max_grad_norm):
self.scaler.unscale_(self.optimizer)
nn.utils.clip_grad_norm_(self.diffusion_prior.parameters(), self.max_grad_norm)
self.scaler.step(self.optimizer)
self.scaler.update()
self.optimizer.zero_grad()
if self.use_ema:
self.ema_diffusion_prior.update()
self.step += 1
@torch.no_grad()
@cast_torch_tensor
@prior_sample_in_chunks
def p_sample_loop(self, *args, **kwargs):
return self.ema_diffusion_prior.ema_model.p_sample_loop(*args, **kwargs)
@torch.no_grad()
@cast_torch_tensor
@prior_sample_in_chunks
def sample(self, *args, **kwargs):
return self.ema_diffusion_prior.ema_model.sample(*args, **kwargs)
@torch.no_grad()
def sample_batch_size(self, *args, **kwargs):
return self.ema_diffusion_prior.ema_model.sample_batch_size(*args, **kwargs)
@cast_torch_tensor
def forward(
self,
*args,
max_batch_size = None,
**kwargs
):
total_loss = 0.
for chunk_size_frac, (chunked_args, chunked_kwargs) in split_args_and_kwargs(*args, split_size = max_batch_size, **kwargs):
with autocast(enabled = self.amp):
loss = self.diffusion_prior(*chunked_args, **chunked_kwargs)
loss = loss * chunk_size_frac
total_loss += loss.item()
if self.training:
self.scaler.scale(loss).backward()
return total_loss
# decoder trainer
def decoder_sample_in_chunks(fn):
@wraps(fn)
def inner(self, *args, max_batch_size = None, **kwargs):
if not exists(max_batch_size):
return fn(self, *args, **kwargs)
if self.decoder.unconditional:
batch_size = kwargs.get('batch_size')
batch_sizes = num_to_groups(batch_size, max_batch_size)
outputs = [fn(self, *args, **{**kwargs, 'batch_size': sub_batch_size}) for sub_batch_size in batch_sizes]
else:
outputs = [fn(self, *chunked_args, **chunked_kwargs) for _, (chunked_args, chunked_kwargs) in split_args_and_kwargs(*args, split_size = max_batch_size, **kwargs)]
return torch.cat(outputs, dim = 0)
return inner
class DecoderTrainer(nn.Module):
def __init__(
self,
decoder,
use_ema = True,
lr = 2e-5,
wd = 1e-2,
eps = 1e-8,
max_grad_norm = None,
amp = False,
**kwargs
):
super().__init__()
assert isinstance(decoder, Decoder)
ema_kwargs, kwargs = groupby_prefix_and_trim('ema_', kwargs)
self.decoder = decoder
self.num_unets = len(self.decoder.unets)
self.use_ema = use_ema
self.ema_unets = nn.ModuleList([])
self.amp = amp
# be able to finely customize learning rate, weight decay
# per unet
lr, wd, eps = map(partial(cast_tuple, length = self.num_unets), (lr, wd, eps))
for ind, (unet, unet_lr, unet_wd, unet_eps) in enumerate(zip(self.decoder.unets, lr, wd, eps)):
optimizer = get_optimizer(
unet.parameters(),
lr = unet_lr,
wd = unet_wd,
eps = unet_eps,
**kwargs
)
setattr(self, f'optim{ind}', optimizer) # cannot use pytorch ModuleList for some reason with optimizers
if self.use_ema:
self.ema_unets.append(EMA(unet, **ema_kwargs))
scaler = GradScaler(enabled = amp)
setattr(self, f'scaler{ind}', scaler)
# gradient clipping if needed
self.max_grad_norm = max_grad_norm
self.register_buffer('step', torch.tensor([0.]))
@property
def unets(self):
return nn.ModuleList([ema.ema_model for ema in self.ema_unets])
def scale(self, loss, *, unet_number):
assert 1 <= unet_number <= self.num_unets
index = unet_number - 1
scaler = getattr(self, f'scaler{index}')
return scaler.scale(loss)
def update(self, unet_number = None):
if self.num_unets == 1:
unet_number = default(unet_number, 1)
assert exists(unet_number) and 1 <= unet_number <= self.num_unets
index = unet_number - 1
unet = self.decoder.unets[index]
optimizer = getattr(self, f'optim{index}')
scaler = getattr(self, f'scaler{index}')
if exists(self.max_grad_norm):
scaler.unscale_(optimizer)
nn.utils.clip_grad_norm_(unet.parameters(), self.max_grad_norm)
scaler.step(optimizer)
scaler.update()
optimizer.zero_grad()
if self.use_ema:
ema_unet = self.ema_unets[index]
ema_unet.update()
self.step += 1
@torch.no_grad()
@cast_torch_tensor
@decoder_sample_in_chunks
def sample(self, *args, **kwargs):
if kwargs.pop('use_non_ema', False) or not self.use_ema:
return self.decoder.sample(*args, **kwargs)
trainable_unets = self.decoder.unets
self.decoder.unets = self.unets # swap in exponential moving averaged unets for sampling
output = self.decoder.sample(*args, **kwargs)
self.decoder.unets = trainable_unets # restore original training unets
# cast the ema_model unets back to original device
for ema in self.ema_unets:
ema.restore_ema_model_device()
return output
@cast_torch_tensor
def forward(
self,
*args,
unet_number = None,
max_batch_size = None,
**kwargs
):
if self.num_unets == 1:
unet_number = default(unet_number, 1)
total_loss = 0.
for chunk_size_frac, (chunked_args, chunked_kwargs) in split_args_and_kwargs(*args, split_size = max_batch_size, **kwargs):
with autocast(enabled = self.amp):
loss = self.decoder(*chunked_args, unet_number = unet_number, **chunked_kwargs)
loss = loss * chunk_size_frac
total_loss += loss.item()
if self.training:
self.scale(loss, unet_number = unet_number).backward()
return total_loss

45
dalle2_pytorch/train_vqgan_vae.py → dalle2_pytorch/vqgan_vae_trainer.py
View File

@@ -3,14 +3,15 @@ import copy
from random import choice
from pathlib import Path
from shutil import rmtree
from PIL import Image
import torch
from torch import nn
from PIL import Image
from torchvision.datasets import ImageFolder
import torchvision.transforms as T
from torch.cuda.amp import autocast, GradScaler
from torch.utils.data import Dataset, DataLoader, random_split
import torchvision.transforms as T
from torchvision.datasets import ImageFolder
from torchvision.utils import make_grid, save_image
from einops import rearrange
@@ -99,6 +100,7 @@ class VQGanVAETrainer(nn.Module):
ema_update_after_step = 2000,
ema_update_every = 10,
apply_grad_penalty_every = 4,
amp = False
):
super().__init__()
assert isinstance(vae, VQGanVAE), 'vae must be instance of VQGanVAE'
@@ -120,6 +122,10 @@ class VQGanVAETrainer(nn.Module):
self.optim = get_optimizer(vae_parameters, lr = lr, wd = wd)
self.discr_optim = get_optimizer(discr_parameters, lr = lr, wd = wd)
self.amp = amp
self.scaler = GradScaler(enabled = amp)
self.discr_scaler = GradScaler(enabled = amp)
# create dataset
self.ds = ImageDataset(folder, image_size = image_size)
@@ -178,20 +184,22 @@ class VQGanVAETrainer(nn.Module):
img = next(self.dl)
img = img.to(device)
loss = self.vae(
img,
return_loss = True,
apply_grad_penalty = apply_grad_penalty
)
with autocast(enabled = self.amp):
loss = self.vae(
img,
return_loss = True,
apply_grad_penalty = apply_grad_penalty
)
self.scaler.scale(loss / self.grad_accum_every).backward()
accum_log(logs, {'loss': loss.item() / self.grad_accum_every})
(loss / self.grad_accum_every).backward()
self.optim.step()
self.scaler.step(self.optim)
self.scaler.update()
self.optim.zero_grad()
# update discriminator
if exists(self.vae.discr):
@@ -200,12 +208,15 @@ class VQGanVAETrainer(nn.Module):
img = next(self.dl)
img = img.to(device)
loss = self.vae(img, return_discr_loss = True)
with autocast(enabled = self.amp):
loss = self.vae(img, return_discr_loss = True)
self.discr_scaler.scale(loss / self.grad_accum_every).backward()
accum_log(logs, {'discr_loss': loss.item() / self.grad_accum_every})
(loss / self.grad_accum_every).backward()
self.discr_optim.step()
self.discr_scaler.step(self.discr_optim)
self.discr_scaler.update()
self.discr_optim.zero_grad()
# log

6
setup.py
View File

@@ -10,11 +10,12 @@ setup(
'dream = dalle2_pytorch.cli:dream'
],
},
version = '0.0.107',
version = '0.3.0',
license='MIT',
description = 'DALL-E 2',
author = 'Phil Wang',
author_email = 'lucidrains@gmail.com',
long_description_content_type = 'text/markdown',
url = 'https://github.com/lucidrains/dalle2-pytorch',
keywords = [
'artificial intelligence',
@@ -24,12 +25,15 @@ setup(
install_requires=[
'click',
'clip-anytorch',
'coca-pytorch>=0.0.5',
'einops>=0.4',
'einops-exts>=0.0.3',
'embedding-reader',
'kornia>=0.5.4',
'numpy',
'pillow',
'resize-right>=0.0.2',
'rotary-embedding-torch',
'torch>=1.10',
'torchvision',
'tqdm',

531
train_diffusion_prior.py
View File

@@ -1,288 +1,375 @@
import os
from pathlib import Path
import click
import math
import argparse
import time
import numpy as np
import torch
import clip
from torch import nn
from embedding_reader import EmbeddingReader
from dalle2_pytorch import DiffusionPrior, DiffusionPriorNetwork
from dalle2_pytorch.optimizer import get_optimizer
from torch.cuda.amp import autocast,GradScaler
import time
from dalle2_pytorch.dataloaders import make_splits
from dalle2_pytorch import DiffusionPrior, DiffusionPriorNetwork, OpenAIClipAdapter
from dalle2_pytorch.trainer import DiffusionPriorTrainer, load_diffusion_model, save_diffusion_model, print_ribbon
from dalle2_pytorch.trackers import ConsoleTracker, WandbTracker
from embedding_reader import EmbeddingReader
from tqdm import tqdm
import wandb
os.environ["WANDB_SILENT"] = "true"
NUM_TEST_EMBEDDINGS = 100 # for cosine similarity reporting during training
REPORT_METRICS_EVERY = 100 # for cosine similarity and other metric reporting during training
# constants
REPORT_METRICS_EVERY = 250 # for cosine similarity and other metric reporting during training
def eval_model(model,device,image_reader,text_reader,start,end,batch_size,loss_type,phase="Validation"):
tracker = WandbTracker()
# helpers functions
def exists(val):
val is not None
class Timer:
def __init__(self):
self.reset()
def reset(self):
self.last_time = time.time()
def elapsed(self):
return time.time() - self.last_time
# functions
def eval_model(model, dataloader, text_conditioned, loss_type, phase="Validation"):
model.eval()
with torch.no_grad():
total_loss = 0.
total_samples = 0.
for emb_images, emb_text in zip(image_reader(batch_size=batch_size, start=start, end=end),
text_reader(batch_size=batch_size, start=start, end=end)):
for image_embeddings, text_data in tqdm(dataloader):
emb_images_tensor = torch.tensor(emb_images[0]).to(device)
emb_text_tensor = torch.tensor(emb_text[0]).to(device)
batches = image_embeddings.shape[0]
batches = emb_images_tensor.shape[0]
input_args = dict(image_embed=image_embeddings)
if text_conditioned:
input_args = dict(**input_args, text = text_data)
else:
input_args = dict(**input_args, text_embed=text_data)
loss = model(text_embed = emb_text_tensor, image_embed = emb_images_tensor)
loss = model(**input_args)
total_loss += loss.item() * batches
total_loss += loss * batches
total_samples += batches
avg_loss = (total_loss / total_samples)
wandb.log({f'{phase} {loss_type}': avg_loss})
def save_model(save_path, state_dict):
# Saving State Dict
print("====================================== Saving checkpoint ======================================")
torch.save(state_dict, save_path+'/'+str(time.time())+'_saved_model.pth')
tracker.log({f'{phase} {loss_type}': avg_loss})
def report_cosine_sims(diffusion_prior, dataloader, text_conditioned):
diffusion_prior.eval()
def report_cosine_sims(diffusion_prior,image_reader,text_reader,train_set_size,val_set_size,NUM_TEST_EMBEDDINGS,device):
cos = nn.CosineSimilarity(dim=1, eps=1e-6)
tstart = train_set_size+val_set_size
tend = train_set_size+val_set_size+NUM_TEST_EMBEDDINGS
for test_image_embeddings, text_data in tqdm(dataloader):
for embt, embi in zip(text_reader(batch_size = NUM_TEST_EMBEDDINGS, start=tstart, end = tend),image_reader(batch_size = NUM_TEST_EMBEDDINGS, start=tstart, end = tend)):
text_embed = torch.tensor(embt[0]).to(device)
text_embed = text_embed / text_embed.norm(dim=1, keepdim=True)
test_text_cond = dict(text_embed = text_embed)
# we are text conditioned, we produce an embedding from the tokenized text
if text_conditioned:
text_embedding, text_encodings, text_mask = diffusion_prior.clip.embed_text(
text_data)
text_cond = dict(text_embed=text_embedding,
text_encodings=text_encodings, mask=text_mask)
else:
text_embedding = text_data
text_cond = dict(text_embed=text_embedding)
test_image_embeddings = torch.tensor(embi[0]).to(device)
test_image_embeddings = test_image_embeddings / test_image_embeddings.norm(dim=1, keepdim=True)
# make a copy of the text embeddings for shuffling
text_embed_shuffled = text_embedding.clone()
predicted_image_embeddings = diffusion_prior.p_sample_loop((NUM_TEST_EMBEDDINGS, 768), text_cond = test_text_cond)
predicted_image_embeddings = predicted_image_embeddings / predicted_image_embeddings.norm(dim=1, keepdim=True)
# roll the text to simulate "unrelated" captions
rolled_idx = torch.roll(torch.arange(text_embedding.shape[0]), 1)
text_embed_shuffled = text_embed_shuffled[rolled_idx]
text_embed_shuffled = text_embed_shuffled / \
text_embed_shuffled.norm(dim=1, keepdim=True)
original_similarity = cos(text_embed,test_image_embeddings).cpu().numpy()
predicted_similarity = cos(text_embed,predicted_image_embeddings).cpu().numpy()
if text_conditioned:
text_encodings_shuffled = text_encodings[rolled_idx]
text_mask_shuffled = text_mask[rolled_idx]
else:
text_encodings_shuffled = None
text_mask_shuffled = None
wandb.log({"CosineSimilarity(text_embed,image_embed)": np.mean(original_similarity)})
wandb.log({"CosineSimilarity(text_embed,predicted_image_embed)":np.mean(predicted_similarity)})
text_cond_shuffled = dict(text_embed=text_embed_shuffled,
text_encodings=text_encodings_shuffled, mask=text_mask_shuffled)
return np.mean(predicted_similarity - original_similarity)
# prepare the text embedding
text_embed = text_embedding / text_embedding.norm(dim=1, keepdim=True)
# prepare image embeddings
test_image_embeddings = test_image_embeddings / \
test_image_embeddings.norm(dim=1, keepdim=True)
# predict on the unshuffled text embeddings
predicted_image_embeddings = diffusion_prior.p_sample_loop(
test_image_embeddings.shape, text_cond)
predicted_image_embeddings = predicted_image_embeddings / \
predicted_image_embeddings.norm(dim=1, keepdim=True)
# predict on the shuffled embeddings
predicted_unrelated_embeddings = diffusion_prior.p_sample_loop(
test_image_embeddings.shape, text_cond_shuffled)
predicted_unrelated_embeddings = predicted_unrelated_embeddings / \
predicted_unrelated_embeddings.norm(dim=1, keepdim=True)
# calculate similarities
original_similarity = cos(
text_embed, test_image_embeddings).cpu().numpy()
predicted_similarity = cos(
text_embed, predicted_image_embeddings).cpu().numpy()
unrelated_similarity = cos(
text_embed, predicted_unrelated_embeddings).cpu().numpy()
predicted_img_similarity = cos(
test_image_embeddings, predicted_image_embeddings).cpu().numpy()
tracker.log({"CosineSimilarity(text_embed,image_embed)": np.mean(original_similarity),
"CosineSimilarity(text_embed,predicted_image_embed)":np.mean(predicted_similarity),
"CosineSimilarity(orig_image_embed,predicted_image_embed)":np.mean(predicted_img_similarity),
"CosineSimilarity(text_embed,predicted_unrelated_embed)": np.mean(unrelated_similarity),
"Cosine similarity difference":np.mean(predicted_similarity - original_similarity)})
@click.command()
@click.option("--wandb-entity", default="laion")
@click.option("--wandb-project", default="diffusion-prior")
@click.option("--wandb-dataset", default="LAION-5B")
@click.option("--wandb-arch", default="DiffusionPrior")
@click.option("--image-embed-url", default="https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/img_emb/")
@click.option("--text-embed-url", default="https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/text_emb/")
@click.option("--meta-url", default="https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/laion2B-en-metadata/")
@click.option("--learning-rate", default=1.1e-4)
@click.option("--weight-decay", default=6.02e-2)
@click.option("--dropout", default=5e-2)
@click.option("--max-grad-norm", default=0.5)
@click.option("--num-data-points", default=250e6)
@click.option("--batch-size", default=320)
@click.option("--num-epochs", default=5)
@click.option("--image-embed-dim", default=768)
@click.option("--train-percent", default=0.9)
@click.option("--val-percent", default=1e-7)
@click.option("--test-percent", default=0.0999999)
@click.option("--dpn-depth", default=12)
@click.option("--dpn-dim-head", default=64)
@click.option("--dpn-heads", default=12)
@click.option("--dp-condition-on-text-encodings", default=True)
@click.option("--dp-timesteps", default=1000)
@click.option("--dp-normformer", default=True)
@click.option("--dp-cond-drop-prob", default=0.1)
@click.option("--dp-loss-type", default="l2")
@click.option("--clip", default="ViT-L/14")
@click.option("--amp", default=False)
@click.option("--save-interval", default=120)
@click.option("--save-path", default="./diffusion_prior_checkpoints")
@click.option("--pretrained-model-path", default=None)
@click.option("--gpu-device", default=0)
def train(
wandb_entity,
wandb_project,
wandb_dataset,
wandb_arch,
image_embed_url,
text_embed_url,
meta_url,
learning_rate,
weight_decay,
dropout,
max_grad_norm,
num_data_points,
batch_size,
num_epochs,
image_embed_dim,
train_percent,
val_percent,
test_percent,
dpn_depth,
dpn_dim_head,
dpn_heads,
dp_condition_on_text_encodings,
dp_timesteps,
dp_normformer,
dp_cond_drop_prob,
dp_loss_type,
clip,
amp,
save_interval,
save_path,
pretrained_model_path,
gpu_device
):
config = {
"learning_rate": learning_rate,
"architecture": wandb_arch,
"dataset": wandb_dataset,
"weight_decay": weight_decay,
"max_gradient_clipping_norm": max_grad_norm,
"batch_size": batch_size,
"epochs": num_epochs,
"diffusion_prior_network": {
"depth": dpn_depth,
"dim_head": dpn_dim_head,
"heads": dpn_heads,
"normformer": dp_normformer
},
"diffusion_prior": {
"condition_on_text_encodings": dp_condition_on_text_encodings,
"timesteps": dp_timesteps,
"cond_drop_prob": dp_cond_drop_prob,
"loss_type": dp_loss_type,
"clip": clip
}
}
def train(image_embed_dim,
image_embed_url,
text_embed_url,
batch_size,
train_percent,
val_percent,
test_percent,
num_epochs,
dp_loss_type,
clip,
dp_condition_on_text_encodings,
dp_timesteps,
dp_normformer,
dp_cond_drop_prob,
dpn_depth,
dpn_dim_head,
dpn_heads,
save_interval,
save_path,
device,
learning_rate=0.001,
max_grad_norm=0.5,
weight_decay=0.01,
amp=False):
# Check if DPRIOR_PATH exists(saved model path)
DPRIOR_PATH = pretrained_model_path
RESUME = exists(DPRIOR_PATH)
if not RESUME:
tracker.init(
entity = wandb_entity,
project = wandb_project,
config = config
)
# Obtain the utilized device.
has_cuda = torch.cuda.is_available()
if has_cuda:
device = torch.device(f"cuda:{gpu_device}")
torch.cuda.set_device(device)
# Training loop
# diffusion prior network
# DiffusionPriorNetwork
prior_network = DiffusionPriorNetwork(
dim = image_embed_dim,
depth = dpn_depth,
dim_head = dpn_dim_head,
heads = dpn_heads,
normformer = dp_normformer).to(device)
dim = image_embed_dim,
depth = dpn_depth,
dim_head = dpn_dim_head,
heads = dpn_heads,
attn_dropout = dropout,
ff_dropout = dropout,
normformer = dp_normformer
)
# DiffusionPrior with text embeddings and image embeddings pre-computed
diffusion_prior = DiffusionPrior(
net = prior_network,
clip = clip,
image_embed_dim = image_embed_dim,
timesteps = dp_timesteps,
cond_drop_prob = dp_cond_drop_prob,
loss_type = dp_loss_type,
condition_on_text_encodings = dp_condition_on_text_encodings).to(device)
# Load clip model if text-conditioning
if dp_condition_on_text_encodings:
clip_adapter = OpenAIClipAdapter(clip)
else:
clip_adapter = None
# diffusion prior with text embeddings and image embeddings pre-computed
# Get image and text embeddings from the servers
print("==============Downloading embeddings - image and text====================")
image_reader = EmbeddingReader(embeddings_folder=image_embed_url, file_format="npy")
text_reader = EmbeddingReader(embeddings_folder=text_embed_url, file_format="npy")
num_data_points = text_reader.count
diffusion_prior = DiffusionPrior(
net = prior_network,
clip = clip_adapter,
image_embed_dim = image_embed_dim,
timesteps = dp_timesteps,
cond_drop_prob = dp_cond_drop_prob,
loss_type = dp_loss_type,
condition_on_text_encodings = dp_condition_on_text_encodings
)
# Load pre-trained model from DPRIOR_PATH
if RESUME:
diffusion_prior, loaded_obj = load_diffusion_model(DPRIOR_PATH, device)
tracker.init(entity = wandb_entity, project = wandb_project, config = config)
# diffusion prior trainer
trainer = DiffusionPriorTrainer(
diffusion_prior = diffusion_prior,
lr = learning_rate,
wd = weight_decay,
max_grad_norm = max_grad_norm,
amp = amp,
).to(device)
# load optimizer and scaler
if RESUME:
trainer.optimizer.load_state_dict(loaded_obj['optimizer'])
trainer.scaler.load_state_dict(loaded_obj['scaler'])
# Create save_path if it doesn't exist
if not os.path.exists(save_path):
os.makedirs(save_path)
Path(save_path).mkdir(exist_ok = True, parents = True)
# Utilize wrapper to abstract away loader logic
print_ribbon("Downloading Embeddings")
loader_args = dict(text_conditioned=dp_condition_on_text_encodings, batch_size=batch_size, num_data_points=num_data_points,
train_split=train_percent, eval_split=val_percent, device=device, img_url=image_embed_url)
if dp_condition_on_text_encodings:
loader_args = dict(**loader_args, meta_url=meta_url)
else:
loader_args = dict(**loader_args, txt_url=text_embed_url)
train_loader, eval_loader, test_loader = make_splits(**loader_args)
### Training code ###
scaler = GradScaler(enabled=amp)
optimizer = get_optimizer(diffusion_prior.net.parameters(), wd=weight_decay, lr=learning_rate)
step = 1
timer = Timer()
epochs = num_epochs
step = 0
t = time.time()
train_set_size = int(train_percent*num_data_points)
val_set_size = int(val_percent*num_data_points)
for _ in range(epochs):
diffusion_prior.train()
for emb_images,emb_text in zip(image_reader(batch_size=batch_size, start=0, end=train_set_size),
text_reader(batch_size=batch_size, start=0, end=train_set_size)):
emb_images_tensor = torch.tensor(emb_images[0]).to(device)
emb_text_tensor = torch.tensor(emb_text[0]).to(device)
for image, text in tqdm(train_loader):
diffusion_prior.train()
input_args = dict(image_embed=image)
if dp_condition_on_text_encodings:
input_args = dict(**input_args, text = text)
else:
input_args = dict(**input_args, text_embed=text)
with autocast(enabled=amp):
loss = diffusion_prior(text_embed = emb_text_tensor,image_embed = emb_images_tensor)
scaler.scale(loss).backward()
loss = trainer(**input_args)
# Samples per second
step+=1
samples_per_sec = batch_size*step/(time.time()-t)
# Save checkpoint every save_interval minutes
if(int(time.time()-t) >= 60*save_interval):
t = time.time()
save_model(
samples_per_sec = batch_size * step / timer.elapsed()
# Save checkpoint every save_interval minutes
if(int(timer.elapsed()) >= 60 * save_interval):
timer.reset()
save_diffusion_model(
save_path,
dict(model=diffusion_prior.state_dict(), optimizer=optimizer.state_dict(), scaler=scaler.state_dict()))
diffusion_prior,
trainer.optimizer,
trainer.scaler,
config,
image_embed_dim)
# Log to wandb
wandb.log({"Training loss": loss.item(),
tracker.log({"Training loss": loss,
"Steps": step,
"Samples per second": samples_per_sec})
# Log cosineSim(text_embed,predicted_image_embed) - cosineSim(text_embed,image_embed)
# Use NUM_TEST_EMBEDDINGS samples from the test set each time
# Get embeddings from the most recently saved model
if(step % REPORT_METRICS_EVERY) == 0:
diff_cosine_sim = report_cosine_sims(diffusion_prior,
image_reader,
text_reader,
train_set_size,
val_set_size,
NUM_TEST_EMBEDDINGS,
device)
wandb.log({"Cosine similarity difference": diff_cosine_sim})
report_cosine_sims(diffusion_prior, eval_loader, dp_condition_on_text_encodings)
### Evaluate model(validation run) ###
eval_model(diffusion_prior, eval_loader, dp_condition_on_text_encodings, dp_loss_type, phase="Validation")
scaler.unscale_(optimizer)
nn.utils.clip_grad_norm_(diffusion_prior.parameters(), max_grad_norm)
scaler.step(optimizer)
scaler.update()
optimizer.zero_grad()
### Evaluate model(validation run) ###
start = train_set_size
end=start+val_set_size
eval_model(diffusion_prior,device,image_reader,text_reader,start,end,batch_size,dp_loss_type,phase="Validation")
step += 1
trainer.update()
### Test run ###
test_set_size = int(test_percent*train_set_size)
start=train_set_size+val_set_size
end=num_data_points
eval_model(diffusion_prior,device,image_reader,text_reader,start,end,batch_size,dp_loss_type,phase="Test")
eval_model(diffusion_prior, test_loader, dp_condition_on_text_encodings, dp_loss_type, phase="Test")
def main():
parser = argparse.ArgumentParser()
# Logging
parser.add_argument("--wandb-entity", type=str, default="laion")
parser.add_argument("--wandb-project", type=str, default="diffusion-prior")
parser.add_argument("--wandb-name", type=str, default="laion-dprior")
parser.add_argument("--wandb-dataset", type=str, default="LAION-5B")
parser.add_argument("--wandb-arch", type=str, default="DiffusionPrior")
# URLs for embeddings
parser.add_argument("--image-embed-url", type=str, default="https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/img_emb/")
parser.add_argument("--text-embed-url", type=str, default="https://mystic.the-eye.eu/public/AI/cah/laion5b/embeddings/laion2B-en/text_emb/")
# Hyperparameters
parser.add_argument("--learning-rate", type=float, default=1.1e-4)
parser.add_argument("--weight-decay", type=float, default=6.02e-2)
parser.add_argument("--max-grad-norm", type=float, default=0.5)
parser.add_argument("--batch-size", type=int, default=10**4)
parser.add_argument("--num-epochs", type=int, default=5)
# Image embed dimension
parser.add_argument("--image-embed-dim", type=int, default=768)
# Train-test split
parser.add_argument("--train-percent", type=float, default=0.7)
parser.add_argument("--val-percent", type=float, default=0.2)
parser.add_argument("--test-percent", type=float, default=0.1)
# LAION training(pre-computed embeddings)
# DiffusionPriorNetwork(dpn) parameters
parser.add_argument("--dpn-depth", type=int, default=6)
parser.add_argument("--dpn-dim-head", type=int, default=64)
parser.add_argument("--dpn-heads", type=int, default=8)
# DiffusionPrior(dp) parameters
parser.add_argument("--dp-condition-on-text-encodings", type=bool, default=False)
parser.add_argument("--dp-timesteps", type=int, default=100)
parser.add_argument("--dp-l2norm-output", type=bool, default=False)
parser.add_argument("--dp-normformer", type=bool, default=False)
parser.add_argument("--dp-cond-drop-prob", type=float, default=0.1)
parser.add_argument("--dp-loss-type", type=str, default="l2")
parser.add_argument("--clip", type=str, default=None)
parser.add_argument("--amp", type=bool, default=False)
# Model checkpointing interval(minutes)
parser.add_argument("--save-interval", type=int, default=30)
parser.add_argument("--save-path", type=str, default="./diffusion_prior_checkpoints")
args = parser.parse_args()
print("Setting up wandb logging... Please wait...")
wandb.init(
entity=args.wandb_entity,
project=args.wandb_project,
config={
"learning_rate": args.learning_rate,
"architecture": args.wandb_arch,
"dataset": args.wandb_dataset,
"epochs": args.num_epochs,
})
print("wandb logging setup done!")
# Obtain the utilized device.
has_cuda = torch.cuda.is_available()
if has_cuda:
device = torch.device("cuda:0")
torch.cuda.set_device(device)
# Training loop
train(args.image_embed_dim,
args.image_embed_url,
args.text_embed_url,
args.batch_size,
args.train_percent,
args.val_percent,
args.test_percent,
args.num_epochs,
args.dp_loss_type,
args.clip,
args.dp_condition_on_text_encodings,
args.dp_timesteps,
args.dp_normformer,
args.dp_cond_drop_prob,
args.dpn_depth,
args.dpn_dim_head,
args.dpn_heads,
args.save_interval,
args.save_path,
device,
args.learning_rate,
args.max_grad_norm,
args.weight_decay,
args.amp)
if __name__ == "__main__":
main()
train()