Spaces:

Astridkraft
/

Stable-ControlNet-GPU

Paused

File size: 6,821 Bytes

61a2a11
d18cc2e
61a2a11
 
 
073e1ec
61a2a11
073e1ec
 
7e166d0
073e1ec
 
 
 
 
7e166d0
073e1ec
 
 
7e166d0
073e1ec
 
 
7e166d0
073e1ec
 
61a2a11
3a6d54d
61a2a11
 
 
 
 
d18cc2e
 
336c145
d18cc2e
 
336c145
 
 
7e166d0
61a2a11
 
 
d18cc2e
61a2a11
7e166d0
61a2a11
d18cc2e
61a2a11
7e166d0
61a2a11
d18cc2e
61a2a11
 
 
 
d18cc2e
61a2a11
 
 
 
7e166d0
61a2a11
 
 
 
 
 
d18cc2e
7bbb34d
61a2a11
 
 
 
7e166d0
7bbb34d
d18cc2e
7bbb34d
 
d18cc2e
202d583
7bbb34d
202d583
d18cc2e
 
7bbb34d
 
d18cc2e
336c145
7bbb34d
 
d18cc2e
7bbb34d
 
336c145
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
9b14886
ffb4be7
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
4d8b990
7bbb34d
 
 
 
3f045c5
 
 
7bbb34d
 
336c145
 
 
 
 
 
 
7bbb34d
336c145
 
 
61a2a11
7e166d0
d18cc2e
61a2a11

import torch
from diffusers import StableDiffusionControlNetPipeline, ControlNetModel
from controlnet_aux import OpenposeDetector
from PIL import Image
import random
import cv2
import numpy as np
import gradio as gr


class ControlNetProgressCallback:
    def __init__(self, progress, total_steps):
        self.progress = progress
        self.total_steps = total_steps
        self.current_step = 0

    def __call__(self, pipe, step_index, timestep, callback_kwargs):
        self.current_step = step_index + 1
        progress_percentage = self.current_step / self.total_steps

        # Fortschritt aktualisieren
        if self.progress is not None:
            self.progress(progress_percentage, desc=f"ControlNet: Schritt {self.current_step}/{self.total_steps}")

        print(f"ControlNet Fortschritt: {self.current_step}/{self.total_steps} ({progress_percentage:.1%})")
        return callback_kwargs


class ControlNetProcessor:
    def __init__(self, device="cuda", torch_dtype=torch.float32):
        self.device = device
        self.torch_dtype = torch_dtype
        self.pose_detector = None
        self.controlnet_openpose = None
        self.controlnet_canny = None
        self.controlnet_depth = None
        self.pipe_openpose = None
        self.pipe_canny = None
        self.pipe_depth = None
        self.pipe_multi_inside = None  # OpenPose + Canny für Inside-Box
        self.pipe_multi_outside = None  # Depth + Canny für Outside-Box

    def load_pose_detector(self):
        """Lädt nur den Pose-Detector"""
        if self.pose_detector is None:
            print("Loading Pose Detector...")
            try:
                self.pose_detector = OpenposeDetector.from_pretrained("lllyasviel/ControlNet")
            except Exception as e:
                print(f"Warnung: Pose-Detector konnte nicht geladen werden: {e}")
        return self.pose_detector

    def extract_pose_simple(self, image):
        """Einfache Pose-Extraktion ohne komplexe Abhängigkeiten"""
        try:
            img_array = np.array(image.convert("RGB"))
            edges = cv2.Canny(img_array, 100, 200)
            pose_image = Image.fromarray(edges).convert("RGB")
            print("⚠️ Verwende Kanten-basierte Pose-Approximation")
            return pose_image
        except Exception as e:
            print(f"Fehler bei einfacher Pose-Extraktion: {e}")
            return image.convert("RGB").resize((512, 512))

    def extract_pose(self, image):
        """Extrahiert Pose-Map aus Bild mit Fallback"""
        try:
            detector = self.load_pose_detector()
            if detector is None:
                return self.extract_pose_simple(image)

            pose_image = detector(image, hand_and_face=True)
            return pose_image
        except Exception as e:
            print(f"Fehler bei Pose-Extraktion: {e}")
            return self.extract_pose_simple(image)

    def extract_canny_edges(self, image):
        """Extrahiert Canny Edges für Umgebungserhaltung"""
        try:
            img_array = np.array(image.convert("RGB"))
            
            # Canny Edge Detection
            gray = cv2.cvtColor(img_array, cv2.COLOR_RGB2GRAY)
            edges = cv2.Canny(gray, 100, 200)
            
            # Zu 3-Kanal Bild konvertieren
            edges_rgb = cv2.cvtColor(edges, cv2.COLOR_GRAY2RGB)
            edges_image = Image.fromarray(edges_rgb)
            
            print("✅ Canny Edge Map erstellt")
            return edges_image
        except Exception as e:
            print(f"Fehler bei Canny Edge Extraction: {e}")
            return image.convert("RGB").resize((512, 512))

    def extract_depth_map(self, image):
        """Extrahiert Depth Map für räumliche Konsistenz"""
        try:
            # Für echte Depth-Maps würde man ein Depth-Estimation-Modell verwenden
            # Hier als Fallback: Konvertierung zu Grayscale als Depth-Approximation
            img_array = np.array(image.convert("RGB"))
            gray = cv2.cvtColor(img_array, cv2.COLOR_RGB2GRAY)
            
            # Depth-ähnliche Map erstellen (helle Bereiche = nah, dunkle = fern)
            depth_map = cv2.GaussianBlur(gray, (5, 5), 0)
            depth_rgb = cv2.cvtColor(depth_map, cv2.COLOR_GRAY2RGB)
            depth_image = Image.fromarray(depth_rgb)
            
            print("✅ Depth Map erstellt (Grayscale Approximation)")
            return depth_image
        except Exception as e:
            print(f"Fehler bei Depth Map Extraction: {e}")
            return image.convert("RGB").resize((512, 512))


    def prepare_controlnet_maps(self, image, keep_environment=False):
        """
        ERSTELLT NUR CONDITIONING-MAPS, generiert KEIN Bild.
        """
        print("🎯 ControlNet: Erstelle Conditioning-Maps...")
        
        if keep_environment:
            # Depth + Canny
            print("   Modus: Depth + Canny")
            conditioning_images = [
                self.extract_depth_map(image),
                self.extract_canny_edges(image)
            ]
        else:
            # OpenPose + Canny
            print("   Modus: OpenPose + Canny")
            conditioning_images = [
                self.extract_pose(image),
                self.extract_canny_edges(image)
            ]
        
        print(f"✅ {len(conditioning_images)} Conditioning-Maps erstellt.")
        return conditioning_images  # Rückgabe: Liste der PIL Images
             

    def prepare_inpaint_input(self, image, keep_environment=False):
        """
        Bereitet das Input-Bild für Inpaint vor
        Rückgabe: (image_für_inpaint, conditioning_info)
        
        HINWEIS: Diese Funktion wird nicht direkt von app.py verwendet,
        da die Logik in generate_with_controlnet enthalten ist.
        """
        if keep_environment:
            # OUTSIDE-BOX ÄNDERN: Depth+Canny Info für Umgebung
            print("🎯 Inpaint: Übergebe Depth+Canny Info (Outside-Box ändern)")
            depth_image = self.extract_depth_map(image)
            canny_image = self.extract_canny_edges(image)
            # Für Inpaint kann eine kombinierte Map verwendet werden
            combined_map = Image.blend(depth_image.convert("RGB"), canny_image.convert("RGB"), alpha=0.5)
            return combined_map, {"type": "depth_canny", "image": combined_map}
        else:
            # INSIDE-BOX ÄNDERN: Originalbild an Inpaint übergeben
            print("🎯 Inpaint: Übergebe Originalbild (Inside-Box ändern)")
            return image, {"type": "original", "image": image}


# Globale Instanz
device = "cuda" if torch.cuda.is_available() else "cpu"
torch_dtype = torch.float16 if device == "cuda" else torch.float32
controlnet_processor = ControlNetProcessor(device=device, torch_dtype=torch_dtype)