give time tokens a surface area of 2 tokens as default, make it so researcher can customize which unet actually is conditioned on image embeddings and/or text encodings

README.md

@@ -410,9 +410,9 @@ Offer training wrappers
 - [x] figure out all the current bag of tricks needed to make DDPMs great (starting with the blur trick mentioned in paper)
 - [x] build the cascading ddpm by having Decoder class manage multiple unets at different resolutions
 - [x] add efficient attention in unet
-- [ ] be able to finely customize what to condition on (text, image embed) for specific unet in the cascade (super resolution ddpms near the end may not need too much conditioning)
-- [ ] offload unets not being trained on to CPU for memory efficiency (for training each resolution unets separately)
+- [x] be able to finely customize what to condition on (text, image embed) for specific unet in the cascade (super resolution ddpms near the end may not need too much conditioning)
 - [ ] build out latent diffusion architecture in separate file, as it is not faithful to dalle-2 (but offer it as as setting)
+- [ ] offload unets not being trained on to CPU for memory efficiency (for training each resolution unets separately)
 - [ ] become an expert with unets, cleanup unet code, make it fully configurable, port all learnings over to https://github.com/lucidrains/x-unet
 - [ ] train on a toy task, offer in colab
 

dalle2_pytorch/cli.py

@@ -6,4 +6,4 @@ def main():
 @click.command()
 @click.argument('text')
 def dream(text):
-    return image
+    return 'not ready yet'

dalle2_pytorch/dalle2_pytorch.py

@@ -820,6 +820,7 @@ class Unet(nn.Module):
         image_embed_dim,
         cond_dim = None,
         num_image_tokens = 4,
+        num_time_tokens = 2,
         out_dim = None,
         dim_mults=(1, 2, 4, 8),
         channels = 3,
@@ -830,6 +831,8 @@ class Unet(nn.Module):
         sparse_attn = False,
         sparse_attn_window = 8,  # window size for sparse attention
         attend_at_middle = True, # whether to have a layer of attention at the bottleneck (can turn off for higher resolution in cascading DDPM, before bringing in efficient attention)
+        cond_on_text_encodings = False,
+        cond_on_image_embeds = False,
     ):
         super().__init__()
         # save locals to take care of some hyperparameters for cascading DDPM
@@ -862,8 +865,8 @@ class Unet(nn.Module):
             SinusoidalPosEmb(dim),
             nn.Linear(dim, dim * 4),
             nn.GELU(),
-            nn.Linear(dim * 4, cond_dim),
-            Rearrange('b d -> b 1 d')
+            nn.Linear(dim * 4, cond_dim * num_time_tokens),
+            Rearrange('b (r d) -> b r d', r = num_time_tokens)
         )
 
         self.image_to_cond = nn.Sequential(
@@ -873,6 +876,12 @@ class Unet(nn.Module):
 
         self.text_to_cond = nn.LazyLinear(cond_dim)
 
+        # finer control over whether to condition on image embeddings and text encodings
+        # so one can have the latter unets in the cascading DDPMs only focus on super-resoluting
+
+        self.cond_on_text_encodings = cond_on_text_encodings
+        self.cond_on_image_embeds = cond_on_image_embeds
+
         # for classifier free guidance
 
         self.null_image_embed = nn.Parameter(torch.randn(1, num_image_tokens, cond_dim))
@@ -982,17 +991,22 @@ class Unet(nn.Module):
         # mask out image embedding depending on condition dropout
         # for classifier free guidance
 
-        image_tokens = self.image_to_cond(image_embed)
+        image_tokens = None
 
-        image_tokens = torch.where(
-            cond_prob_mask,
-            image_tokens,
-            self.null_image_embed
-        )
+        if self.cond_on_image_embeds:
+            image_tokens = self.image_to_cond(image_embed)
+
+            image_tokens = torch.where(
+                cond_prob_mask,
+                image_tokens,
+                self.null_image_embed
+            )
 
         # take care of text encodings (optional)
 
-        if exists(text_encodings):
+        text_tokens = None
+
+        if exists(text_encodings) and self.cond_on_text_encodings:
             text_tokens = self.text_to_cond(text_encodings)
             text_tokens = torch.where(
                 cond_prob_mask,
@@ -1002,12 +1016,15 @@ class Unet(nn.Module):
 
         # main conditioning tokens (c)
 
-        c = torch.cat((time_tokens, image_tokens), dim = -2)
+        c = time_tokens
+
+        if exists(image_tokens):
+            c = torch.cat((c, image_tokens), dim = -2)
 
         # text and image conditioning tokens (mid_c)
         # to save on compute, only do cross attention based conditioning on the inner most layers of the Unet
 
-        mid_c = c if not exists(text_encodings) else torch.cat((c, text_tokens), dim = -2)
+        mid_c = c if not exists(text_tokens) else torch.cat((c, text_tokens), dim = -2)
 
         # go through the layers of the unet, down and up
 

setup.py

@@ -10,7 +10,7 @@ setup(
       'dream = dalle2_pytorch.cli:dream'
     ],
   },
-  version = '0.0.26',
+  version = '0.0.27',
   license='MIT',
   description = 'DALL-E 2',
   author = 'Phil Wang',