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# utils/editor.py
import os
import io
import math
from typing import Tuple, Dict, Any
from PIL import Image, ImageOps
import numpy as np
import torch
from diffusers import StableDiffusionControlNetPipeline, ControlNetModel, UniPCMultistepScheduler
from transformers import logging as hf_logging
hf_logging.set_verbosity_error()
# detector auxiliar para gerar mapa de pose OpenPose-like
from controlnet_aux import OpenposeDetector
# para remoção de fundo da peça (extrair RGBA)
from rembg import remove
# parâmetros padrão (você pode ajustar)
MODEL_ID = "runwayml/stable-diffusion-v1-5" # base SD v1.5
CONTROLNET_ID = "lllyasviel/sd-controlnet-openpose" # controlnet openpose
DEVICE = "cuda" if torch.cuda.is_available() else "cpu"
# pipeline cache globals
_PIPELINE = None
_OP_DETECTOR = None
def get_openpose_detector():
global _OP_DETECTOR
if _OP_DETECTOR is None:
_OP_DETECTOR = OpenposeDetector()
return _OP_DETECTOR
def load_pipeline():
"""
Carrega o pipeline ControlNet + Stable Diffusion (com half precision quando possível).
"""
global _PIPELINE
if _PIPELINE is not None:
return _PIPELINE
# Carregar ControlNet
controlnet = ControlNetModel.from_pretrained(CONTROLNET_ID, torch_dtype=torch.float16 if DEVICE=="cuda" else torch.float32)
# Carregar pipeline SD + ControlNet
pipe = StableDiffusionControlNetPipeline.from_pretrained(
MODEL_ID,
controlnet=controlnet,
safety_checker=None,
torch_dtype=torch.float16 if DEVICE=="cuda" else torch.float32,
)
# usar UniPC scheduler — melhora velocidade/qualidade
pipe.scheduler = UniPCMultistepScheduler.from_config(pipe.scheduler.config)
if DEVICE == "cuda":
pipe.enable_attention_slicing() # economiza VRAM
pipe.to("cuda")
else:
pipe.to("cpu")
# reduzir torch_autocast config handled later in inference
_PIPELINE = pipe
return _PIPELINE
def remove_background(pil_img: Image.Image) -> Image.Image:
"""
Remove fundo da imagem da peça usando rembg (retorna RGBA com alpha).
"""
# rembg expects bytes
img_bytes = io.BytesIO()
pil_img.convert("RGBA").save(img_bytes, format="PNG")
img_bytes = img_bytes.getvalue()
out = remove(img_bytes)
# out is bytes of PNG with alpha
out_img = Image.open(io.BytesIO(out)).convert("RGBA")
return out_img
def simple_align_garment_to_model(model_img: Image.Image, garment_rgba: Image.Image, pose_keypoints=None) -> Image.Image:
"""
Faz um alinhamento simples: escala a peça pela distância entre ombros (estimada)
e cola-a sobre a modelo aproximadamente no torso. Retorna imagem RGBA (com a modelo).
Isso é só a iniciação — o SD+ControlNet fará o refinamento.
"""
model = model_img.convert("RGBA")
g = garment_rgba
Wm, Hm = model.size
Wg, Hg = g.size
# fallback: centragem se não houver keypoints
if pose_keypoints is None:
# escala para metade da largura do modelo
target_w = int(Wm * 0.5)
scale = target_w / Wg
new_size = (max(1, int(Wg * scale)), max(1, int(Hg * scale)))
g_resized = g.resize(new_size, resample=Image.LANCZOS)
pos = ((Wm - new_size[0]) // 2, int(Hm * 0.28)) # 28% from top as rough torso position
canvas = model.copy()
canvas.paste(g_resized, pos, g_resized)
return canvas
# se houver keypoints, tentamos usar ombros para dimensionar
try:
# keypoints: dict with names->(x,y) in pixel coords (as returned below)
ls = pose_keypoints.get("left_shoulder")
rs = pose_keypoints.get("right_shoulder")
if ls and rs:
shoulder_dist = math.hypot(rs[0]-ls[0], rs[1]-ls[1])
# queremos que a peça cubra ~1.4x a largura dos ombros (ajustar conforme peça)
target_w = int(shoulder_dist * 1.4)
scale = max(0.1, target_w / Wg)
new_size = (max(1, int(Wg * scale)), max(1, int(Hg * scale)))
g_resized = g.resize(new_size, resample=Image.LANCZOS)
# center position between shoulders, and slightly below
center_x = int((ls[0] + rs[0]) / 2)
top_y = int((ls[1] + rs[1]) / 1.8) # move slightly up/down
pos = (max(0, center_x - new_size[0]//2), max(0, top_y - new_size[1]//6))
canvas = model.copy()
canvas.paste(g_resized, pos, g_resized)
return canvas
except Exception:
pass
# fallback
return simple_align_garment_to_model(model_img, garment_rgba, pose_keypoints=None)
def extract_pose_and_keypoints(model_img: Image.Image) -> Tuple[Image.Image, Dict[str, Tuple[int,int]]]:
"""
Usa controlnet_aux.OpenposeDetector para gerar a pose map (imagem) e tenta retornar
keypoints úteis (ombros). keypoints dict = {"left_shoulder":(x,y), ...}
"""
detector = get_openpose_detector()
# detect returns a PIL image of the pose map; but also returns 'keypoints' structure if requested
# controlnet_aux OpenposeDetector has method detect which returns images; to get keypoints we call detect_and_return_info
# We'll attempt to call 'detect' and fallback if not available
try:
detected = detector.detect(model_img)
# detector.detect returns a pose image (PIL)
pose_image = detected
# try to get keypoints via internal method if present (may vary by version)
try:
info = detector.get_pose(model_img) # some versions provide get_pose
# info parsing: try to find shoulders - adapt defensively
keypoints = {}
for person in info:
# each person: list of points or dict depending implementation
# attempt to parse common formats
if isinstance(person, dict):
if "left_shoulder" in person and "right_shoulder" in person:
keypoints["left_shoulder"] = tuple(person["left_shoulder"])
keypoints["right_shoulder"] = tuple(person["right_shoulder"])
break
elif isinstance(person, list) or isinstance(person, tuple):
# fallback: OpenPose ordering often uses indices:
# 2 = right shoulder, 5 = left shoulder OR vice-versa depending on lib.
# We'll try both orders defensively
try:
p2 = person[2]
p5 = person[5]
# p2/p5 are (x,y,confidence) or similar
keypoints["right_shoulder"] = (int(p2[0]), int(p2[1]))
keypoints["left_shoulder"] = (int(p5[0]), int(p5[1]))
break
except Exception:
continue
return pose_image.convert("RGB"), keypoints
except Exception:
# if we can't get structured keypoints, just return pose image and empty dict
return pose_image.convert("RGB"), {}
except Exception as e:
# last fallback: return blank pose (grayscale) and empty keypoints
blank = Image.new("RGB", model_img.size, (255,255,255))
return blank, {}
def run_pipeline(model_image: Image.Image, garment_image: Image.Image, prompt_extra: str = "") -> Tuple[Image.Image, Dict[str,Any]]:
"""
Função principal que:
1) extrai pose (pose_map)
2) remove fundo da peça (garment) e alinha simplisticamente
3) monta uma imagem inicial (init_image) com a peça sobre a modelo (RGBA)
4) chama Stable Diffusion + ControlNet (image2image) usando pose_map como conditioning image
Retorna: pil_image_result, info_dict
"""
# Convert PIL to consistent size (we'll resize to 768 on larger side to balance quality/VRAM)
max_side = 768
model_img = model_image.convert("RGB")
W, H = model_img.size
scale = max_side / max(W, H) if max(W, H) > max_side else 1.0
if scale != 1.0:
model_img = model_img.resize((int(W*scale), int(H*scale)), Image.LANCZOS)
# garment: remove background to get alpha
garment_rgba = remove_background(garment_image)
# get pose map and shoulder keypoints
pose_map, keypoints = extract_pose_and_keypoints(model_img)
# align garment roughly
init_composite = simple_align_garment_to_model(model_img, garment_rgba, pose_keypoints=keypoints)
# prepare pipeline and control image
pipe = load_pipeline()
# create prompt: combine prompt_extra with description of garment (basic default)
prompt = ("photo-realistic fashion try-on, ultra detailed, high resolution, realistic lighting. "
+ (prompt_extra or "garment applied on person, preserve texture and zippers, realistic folds."))
# convert images to correct formats
init_image = init_composite.convert("RGB")
control_image = pose_map.convert("RGB")
# inference parameters (tune if OOM)
num_inference_steps = 20
guidance_scale = 7.5
strength = 0.75 # image2image strength (how much to change)
# Run in autocast for fp16 if GPU is available
generator = torch.Generator(device=DEVICE).manual_seed(torch.randint(0, 2**31 - 1, (1,)).item())
# Note: Some versions of diffusers expect 'image' and 'control_image' keyword arguments
# We'll call the pipeline defensively.
device = DEVICE
pipe.to(device)
try:
# The StableDiffusionControlNetPipeline supports image2image by passing 'image' and 'control_image'
with torch.autocast(device_type="cuda") if device == "cuda" else torch.cpu.amp.autocast(enabled=False):
out = pipe(
prompt=prompt,
image=init_image,
control_image=control_image,
num_inference_steps=num_inference_steps,
guidance_scale=guidance_scale,
strength=strength,
generator=generator
)
# out.images is a list
result_img = out.images[0]
except TypeError:
# Some diffusers versions use different signature; try alternate call
out = pipe(
prompt=prompt,
init_image=init_image,
controlnet_conditioning_image=control_image,
num_inference_steps=num_inference_steps,
guidance_scale=guidance_scale,
strength=strength,
generator=generator
)
result_img = out.images[0]
info = {
"model_id": MODEL_ID,
"controlnet_id": CONTROLNET_ID,
"steps": num_inference_steps,
"guidance_scale": guidance_scale,
"strength": strength
}
return result_img, info |