Fixed issue where batched inpainting (batch size > 1) wouldn't work because of mismatched tensor sizes. The 'already_decoded' decoded case should also be handled correctly (tested indirectly).

modules/soft_inpainting.py

@@ -25,26 +25,32 @@ def latent_blend(soft_inpainting, a, b, t):
 
     # NOTE: We use inplace operations wherever possible.
 
-    one_minus_t = 1 - t
+    # [4][w][h] to [1][4][w][h]
+    t2 = t.unsqueeze(0)
+    # [4][w][h] to [1][1][w][h] - the [4] seem redundant.
+    t3 = t[0].unsqueeze(0).unsqueeze(0)
+
+    one_minus_t2 = 1 - t2
+    one_minus_t3 = 1 - t3
 
     # Linearly interpolate the image vectors.
-    a_scaled = a * one_minus_t
-    b_scaled = b * t
+    a_scaled = a * one_minus_t2
+    b_scaled = b * t2
     image_interp = a_scaled
     image_interp.add_(b_scaled)
     result_type = image_interp.dtype
-    del a_scaled, b_scaled
+    del a_scaled, b_scaled, t2, one_minus_t2
 
     # Calculate the magnitude of the interpolated vectors. (We will remove this magnitude.)
     # 64-bit operations are used here to allow large exponents.
-    current_magnitude = torch.norm(image_interp, p=2, dim=1).to(torch.float64).add_(0.00001)
+    current_magnitude = torch.norm(image_interp, p=2, dim=1, keepdim=True).to(torch.float64).add_(0.00001)
 
     # Interpolate the powered magnitudes, then un-power them (bring them back to a power of 1).
-    a_magnitude = torch.norm(a, p=2, dim=1).to(torch.float64).pow_(soft_inpainting.inpaint_detail_preservation) * one_minus_t
-    b_magnitude = torch.norm(b, p=2, dim=1).to(torch.float64).pow_(soft_inpainting.inpaint_detail_preservation) * t
+    a_magnitude = torch.norm(a, p=2, dim=1, keepdim=True).to(torch.float64).pow_(soft_inpainting.inpaint_detail_preservation) * one_minus_t3
+    b_magnitude = torch.norm(b, p=2, dim=1, keepdim=True).to(torch.float64).pow_(soft_inpainting.inpaint_detail_preservation) * t3
     desired_magnitude = a_magnitude
     desired_magnitude.add_(b_magnitude).pow_(1 / soft_inpainting.inpaint_detail_preservation)
-    del a_magnitude, b_magnitude, one_minus_t
+    del a_magnitude, b_magnitude, t3, one_minus_t3
 
     # Change the linearly interpolated image vectors' magnitudes to the value we want.
     # This is the last 64-bit operation.
@@ -78,10 +84,11 @@ def get_modified_nmask(soft_inpainting, nmask, sigma):
     NOTE: "mask" is not used
     """
     import torch
-    return torch.pow(nmask, (sigma ** soft_inpainting.mask_blend_power) * soft_inpainting.mask_blend_scale)
+    # todo: Why is sigma 2D? Both values are the same.
+    return torch.pow(nmask, (sigma[0] ** soft_inpainting.mask_blend_power) * soft_inpainting.mask_blend_scale)
 
 
-def generate_adaptive_masks(
+def apply_adaptive_masks(
         latent_orig,
         latent_processed,
         overlay_images,
@@ -142,6 +149,45 @@ def generate_adaptive_masks(
 
         overlay_images[i] = image_masked.convert('RGBA')
 
+def apply_masks(
+        soft_inpainting,
+        nmask,
+        overlay_images,
+        masks_for_overlay,
+        width, height,
+        paste_to):
+    import torch
+    import numpy as np
+    import modules.processing as proc
+    import modules.images as images
+    from PIL import Image, ImageOps, ImageFilter
+
+    converted_mask = nmask[0].float()
+    converted_mask = torch.clamp(converted_mask, min=0, max=1).pow_(soft_inpainting.mask_blend_scale / 2)
+    converted_mask = 255. * converted_mask
+    converted_mask = converted_mask.cpu().numpy().astype(np.uint8)
+    converted_mask = Image.fromarray(converted_mask)
+    converted_mask = images.resize_image(2, converted_mask, width, height)
+    converted_mask = proc.create_binary_mask(converted_mask, round=False)
+
+    # Remove aliasing artifacts using a gaussian blur.
+    converted_mask = converted_mask.filter(ImageFilter.GaussianBlur(radius=4))
+
+    # Expand the mask to fit the whole image if needed.
+    if paste_to is not None:
+        converted_mask = proc.uncrop(converted_mask,
+                                     (width, height),
+                                     paste_to)
+
+    for i, overlay_image in enumerate(overlay_images):
+        masks_for_overlay[i] = converted_mask
+
+        image_masked = Image.new('RGBa', (overlay_image.width, overlay_image.height))
+        image_masked.paste(overlay_image.convert("RGBA").convert("RGBa"),
+                           mask=ImageOps.invert(converted_mask.convert('L')))
+
+        overlay_images[i] = image_masked.convert('RGBA')
+
 
 # ------------------- Constants -------------------