Add files using upload-large-folder tool

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	import os
	import comfy.samplers
	import comfy.sample
	import torch
	from nodes import common_ksampler, CLIPTextEncode
	from comfy.utils import ProgressBar
	from .utils import expand_mask, FONTS_DIR, parse_string_to_list
	import torchvision.transforms.v2 as T
	import torch.nn.functional as F
	import logging
	import folder_paths

	# From https://github.com/BlenderNeko/ComfyUI_Noise/
	def slerp(val, low, high):
	dims = low.shape

	low = low.reshape(dims[0], -1)
	high = high.reshape(dims[0], -1)

	low_norm = low/torch.norm(low, dim=1, keepdim=True)
	high_norm = high/torch.norm(high, dim=1, keepdim=True)

	low_norm[low_norm != low_norm] = 0.0
	high_norm[high_norm != high_norm] = 0.0

	omega = torch.acos((low_norm*high_norm).sum(1))
	so = torch.sin(omega)
	res = (torch.sin((1.0-val)omega)/so).unsqueeze(1)low + (torch.sin(valomega)/so).unsqueeze(1) high

	return res.reshape(dims)

	class KSamplerVariationsWithNoise:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	"model": ("MODEL", ),
	"latent_image": ("LATENT", ),
	"main_seed": ("INT:seed", {"default": 0, "min": 0, "max": 0xffffffffffffffff}),
	"steps": ("INT", {"default": 20, "min": 1, "max": 10000}),
	"cfg": ("FLOAT", {"default": 8.0, "min": 0.0, "max": 100.0, "step":0.1, "round": 0.01}),
	"sampler_name": (comfy.samplers.KSampler.SAMPLERS, ),
	"scheduler": (comfy.samplers.KSampler.SCHEDULERS, ),
	"positive": ("CONDITIONING", ),
	"negative": ("CONDITIONING", ),
	"variation_strength": ("FLOAT", {"default": 0.17, "min": 0.0, "max": 1.0, "step":0.01, "round": 0.01}),
	#"start_at_step": ("INT", {"default": 0, "min": 0, "max": 10000}),
	#"end_at_step": ("INT", {"default": 10000, "min": 0, "max": 10000}),
	#"return_with_leftover_noise": (["disable", "enable"], ),
	"variation_seed": ("INT:seed", {"default": 12345, "min": 0, "max": 0xffffffffffffffff}),
	"denoise": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 1.0, "step":0.01, "round": 0.01}),
	}}

	RETURN_TYPES = ("LATENT",)
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def prepare_mask(self, mask, shape):
	mask = torch.nn.functional.interpolate(mask.reshape((-1, 1, mask.shape[-2], mask.shape[-1])), size=(shape[2], shape[3]), mode="bilinear")
	mask = mask.expand((-1,shape[1],-1,-1))
	if mask.shape[0] < shape[0]:
	mask = mask.repeat((shape[0] -1) // mask.shape[0] + 1, 1, 1, 1)[:shape[0]]
	return mask

	def execute(self, model, latent_image, main_seed, steps, cfg, sampler_name, scheduler, positive, negative, variation_strength, variation_seed, denoise):
	if main_seed == variation_seed:
	variation_seed += 1

	end_at_step = steps #min(steps, end_at_step)
	start_at_step = round(end_at_step - end_at_step * denoise)

	force_full_denoise = True
	disable_noise = True

	device = comfy.model_management.get_torch_device()

	# Generate base noise
	batch_size, _, height, width = latent_image["samples"].shape
	generator = torch.manual_seed(main_seed)
	base_noise = torch.randn((1, 4, height, width), dtype=torch.float32, device="cpu", generator=generator).repeat(batch_size, 1, 1, 1).cpu()

	# Generate variation noise
	generator = torch.manual_seed(variation_seed)
	variation_noise = torch.randn((batch_size, 4, height, width), dtype=torch.float32, device="cpu", generator=generator).cpu()

	slerp_noise = slerp(variation_strength, base_noise, variation_noise)

	# Calculate sigma
	comfy.model_management.load_model_gpu(model)
	sampler = comfy.samplers.KSampler(model, steps=steps, device=device, sampler=sampler_name, scheduler=scheduler, denoise=1.0, model_options=model.model_options)
	sigmas = sampler.sigmas
	sigma = sigmas[start_at_step] - sigmas[end_at_step]
	sigma /= model.model.latent_format.scale_factor
	sigma = sigma.detach().cpu().item()

	work_latent = latent_image.copy()
	work_latent["samples"] = latent_image["samples"].clone() + slerp_noise * sigma

	# if there's a mask we need to expand it to avoid artifacts, 5 pixels should be enough
	if "noise_mask" in latent_image:
	noise_mask = self.prepare_mask(latent_image["noise_mask"], latent_image['samples'].shape)
	work_latent["samples"] = noise_mask * work_latent["samples"] + (1-noise_mask) * latent_image["samples"]
	work_latent['noise_mask'] = expand_mask(latent_image["noise_mask"].clone(), 5, True)

	return common_ksampler(model, main_seed, steps, cfg, sampler_name, scheduler, positive, negative, work_latent, denoise=1.0, disable_noise=disable_noise, start_step=start_at_step, last_step=end_at_step, force_full_denoise=force_full_denoise)


	class KSamplerVariationsStochastic:
	@classmethod
	def INPUT_TYPES(s):
	return {"required":{
	"model": ("MODEL",),
	"latent_image": ("LATENT", ),
	"noise_seed": ("INT", {"default": 0, "min": 0, "max": 0xffffffffffffffff}),
	"steps": ("INT", {"default": 25, "min": 1, "max": 10000}),
	"cfg": ("FLOAT", {"default": 7.0, "min": 0.0, "max": 100.0, "step":0.1, "round": 0.01}),
	"sampler": (comfy.samplers.KSampler.SAMPLERS, ),
	"scheduler": (comfy.samplers.KSampler.SCHEDULERS, ),
	"positive": ("CONDITIONING", ),
	"negative": ("CONDITIONING", ),
	"variation_seed": ("INT:seed", {"default": 0, "min": 0, "max": 0xffffffffffffffff}),
	"variation_strength": ("FLOAT", {"default": 0.2, "min": 0.0, "max": 1.0, "step":0.05, "round": 0.01}),
	#"variation_sampler": (comfy.samplers.KSampler.SAMPLERS, ),
	"cfg_scale": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 1.0, "step":0.05, "round": 0.01}),
	}}

	RETURN_TYPES = ("LATENT", )
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, model, latent_image, noise_seed, steps, cfg, sampler, scheduler, positive, negative, variation_seed, variation_strength, cfg_scale, variation_sampler="dpmpp_2m_sde"):
	# Stage 1: composition sampler
	force_full_denoise = False # return with leftover noise = "enable"
	disable_noise = False # add noise = "enable"

	end_at_step = max(int(steps * (1-variation_strength)), 1)
	start_at_step = 0

	work_latent = latent_image.copy()
	batch_size = work_latent["samples"].shape[0]
	work_latent["samples"] = work_latent["samples"][0].unsqueeze(0)

	stage1 = common_ksampler(model, noise_seed, steps, cfg, sampler, scheduler, positive, negative, work_latent, denoise=1.0, disable_noise=disable_noise, start_step=start_at_step, last_step=end_at_step, force_full_denoise=force_full_denoise)[0]

	if batch_size > 1:
	stage1["samples"] = stage1["samples"].clone().repeat(batch_size, 1, 1, 1)

	# Stage 2: variation sampler
	force_full_denoise = True
	disable_noise = True
	cfg = max(cfg * cfg_scale, 1.0)
	start_at_step = end_at_step
	end_at_step = steps

	return common_ksampler(model, variation_seed, steps, cfg, variation_sampler, scheduler, positive, negative, stage1, denoise=1.0, disable_noise=disable_noise, start_step=start_at_step, last_step=end_at_step, force_full_denoise=force_full_denoise)

	class InjectLatentNoise:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	"latent": ("LATENT", ),
	"noise_seed": ("INT", {"default": 0, "min": 0, "max": 0xffffffffffffffff}),
	"noise_strength": ("FLOAT", {"default": 1.0, "min": -20.0, "max": 20.0, "step":0.01, "round": 0.01}),
	"normalize": (["false", "true"], {"default": "false"}),
	},
	"optional": {
	"mask": ("MASK", ),
	}}

	RETURN_TYPES = ("LATENT",)
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, latent, noise_seed, noise_strength, normalize="false", mask=None):
	torch.manual_seed(noise_seed)
	noise_latent = latent.copy()
	original_samples = noise_latent["samples"].clone()
	random_noise = torch.randn_like(original_samples)

	if normalize == "true":
	mean = original_samples.mean()
	std = original_samples.std()
	random_noise = random_noise * std + mean

	random_noise = original_samples + random_noise * noise_strength

	if mask is not None:
	mask = F.interpolate(mask.reshape((-1, 1, mask.shape[-2], mask.shape[-1])), size=(random_noise.shape[2], random_noise.shape[3]), mode="bilinear")
	mask = mask.expand((-1,random_noise.shape[1],-1,-1)).clamp(0.0, 1.0)
	if mask.shape[0] < random_noise.shape[0]:
	mask = mask.repeat((random_noise.shape[0] -1) // mask.shape[0] + 1, 1, 1, 1)[:random_noise.shape[0]]
	elif mask.shape[0] > random_noise.shape[0]:
	mask = mask[:random_noise.shape[0]]
	random_noise = mask * random_noise + (1-mask) * original_samples

	noise_latent["samples"] = random_noise

	return (noise_latent, )

	class TextEncodeForSamplerParams:
	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"text": ("STRING", {"multiline": True, "dynamicPrompts": True, "default": "Separate prompts with at least three dashes\n---\nLike so"}),
	"clip": ("CLIP", )
	}}

	RETURN_TYPES = ("CONDITIONING", )
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, text, clip):
	import re
	output_text = []
	output_encoded = []
	text = re.sub(r'[-*=~]{4,}\n', '---\n', text)
	text = text.split("---\n")

	for t in text:
	t = t.strip()
	if t:
	output_text.append(t)
	output_encoded.append(CLIPTextEncode().encode(clip, t)[0])

	#if len(output_encoded) == 1:
	# output = output_encoded[0]
	#else:
	output = {"text": output_text, "encoded": output_encoded}

	return (output, )

	class SamplerSelectHelper:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	**{s: ("BOOLEAN", { "default": False }) for s in comfy.samplers.KSampler.SAMPLERS},
	}}

	RETURN_TYPES = ("STRING", )
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, **values):
	values = [v for v in values if values[v]]
	values = ", ".join(values)

	return (values, )

	class SchedulerSelectHelper:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	**{s: ("BOOLEAN", { "default": False }) for s in comfy.samplers.KSampler.SCHEDULERS},
	}}

	RETURN_TYPES = ("STRING", )
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, **values):
	values = [v for v in values if values[v]]
	values = ", ".join(values)

	return (values, )

	class LorasForFluxParams:
	@classmethod
	def INPUT_TYPES(s):
	optional_loras = ['none'] + folder_paths.get_filename_list("loras")
	return {
	"required": {
	"lora_1": (folder_paths.get_filename_list("loras"), {"tooltip": "The name of the LoRA."}),
	"strength_model_1": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "1.0" }),
	},
	#"optional": {
	# "lora_2": (optional_loras, ),
	# "strength_lora_2": ("STRING", { "multiline": False, "dynamicPrompts": False }),
	# "lora_3": (optional_loras, ),
	# "strength_lora_3": ("STRING", { "multiline": False, "dynamicPrompts": False }),
	# "lora_4": (optional_loras, ),
	# "strength_lora_4": ("STRING", { "multiline": False, "dynamicPrompts": False }),
	#}
	}

	RETURN_TYPES = ("LORA_PARAMS", )
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, lora_1, strength_model_1, lora_2="none", strength_lora_2="", lora_3="none", strength_lora_3="", lora_4="none", strength_lora_4=""):
	output = { "loras": [], "strengths": [] }
	output["loras"].append(lora_1)
	output["strengths"].append(parse_string_to_list(strength_model_1))

	if lora_2 != "none":
	output["loras"].append(lora_2)
	if strength_lora_2 == "":
	strength_lora_2 = "1.0"
	output["strengths"].append(parse_string_to_list(strength_lora_2))
	if lora_3 != "none":
	output["loras"].append(lora_3)
	if strength_lora_3 == "":
	strength_lora_3 = "1.0"
	output["strengths"].append(parse_string_to_list(strength_lora_3))
	if lora_4 != "none":
	output["loras"].append(lora_4)
	if strength_lora_4 == "":
	strength_lora_4 = "1.0"
	output["strengths"].append(parse_string_to_list(strength_lora_4))

	return (output,)


	class FluxSamplerParams:
	def __init__(self):
	self.loraloader = None
	self.lora = (None, None)

	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	"model": ("MODEL", ),
	"conditioning": ("CONDITIONING", ),
	"latent_image": ("LATENT", ),

	"seed": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "?" }),
	"sampler": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "euler" }),
	"scheduler": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "simple" }),
	"steps": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "20" }),
	"guidance": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "3.5" }),
	"max_shift": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "" }),
	"base_shift": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "" }),
	"denoise": ("STRING", { "multiline": False, "dynamicPrompts": False, "default": "1.0" }),
	},
	"optional": {
	"loras": ("LORA_PARAMS",),
	}}

	RETURN_TYPES = ("LATENT","SAMPLER_PARAMS")
	RETURN_NAMES = ("latent", "params")
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, model, conditioning, latent_image, seed, sampler, scheduler, steps, guidance, max_shift, base_shift, denoise, loras=None):
	import random
	import time
	from comfy_extras.nodes_custom_sampler import Noise_RandomNoise, BasicScheduler, BasicGuider, SamplerCustomAdvanced
	from comfy_extras.nodes_latent import LatentBatch
	from comfy_extras.nodes_model_advanced import ModelSamplingFlux, ModelSamplingAuraFlow
	from node_helpers import conditioning_set_values
	from nodes import LoraLoader

	is_schnell = model.model.model_type == comfy.model_base.ModelType.FLOW

	noise = seed.replace("\n", ",").split(",")
	noise = [random.randint(0, 999999) if "?" in n else int(n) for n in noise]
	if not noise:
	noise = [random.randint(0, 999999)]

	if sampler == '*':
	sampler = comfy.samplers.KSampler.SAMPLERS
	elif sampler.startswith("!"):
	sampler = sampler.replace("\n", ",").split(",")
	sampler = [s.strip("! ") for s in sampler]
	sampler = [s for s in comfy.samplers.KSampler.SAMPLERS if s not in sampler]
	else:
	sampler = sampler.replace("\n", ",").split(",")
	sampler = [s.strip() for s in sampler if s.strip() in comfy.samplers.KSampler.SAMPLERS]
	if not sampler:
	sampler = ['ipndm']

	if scheduler == '*':
	scheduler = comfy.samplers.KSampler.SCHEDULERS
	elif scheduler.startswith("!"):
	scheduler = scheduler.replace("\n", ",").split(",")
	scheduler = [s.strip("! ") for s in scheduler]
	scheduler = [s for s in comfy.samplers.KSampler.SCHEDULERS if s not in scheduler]
	else:
	scheduler = scheduler.replace("\n", ",").split(",")
	scheduler = [s.strip() for s in scheduler]
	scheduler = [s for s in scheduler if s in comfy.samplers.KSampler.SCHEDULERS]
	if not scheduler:
	scheduler = ['simple']

	if steps == "":
	if is_schnell:
	steps = "4"
	else:
	steps = "20"
	steps = parse_string_to_list(steps)

	denoise = "1.0" if denoise == "" else denoise
	denoise = parse_string_to_list(denoise)

	guidance = "3.5" if guidance == "" else guidance
	guidance = parse_string_to_list(guidance)

	if not is_schnell:
	max_shift = "1.15" if max_shift == "" else max_shift
	base_shift = "0.5" if base_shift == "" else base_shift
	else:
	max_shift = "0"
	base_shift = "1.0" if base_shift == "" else base_shift

	max_shift = parse_string_to_list(max_shift)
	base_shift = parse_string_to_list(base_shift)

	cond_text = None
	if isinstance(conditioning, dict) and "encoded" in conditioning:
	cond_text = conditioning["text"]
	cond_encoded = conditioning["encoded"]
	else:
	cond_encoded = [conditioning]

	out_latent = None
	out_params = []

	basicschedueler = BasicScheduler()
	basicguider = BasicGuider()
	samplercustomadvanced = SamplerCustomAdvanced()
	latentbatch = LatentBatch()
	modelsamplingflux = ModelSamplingFlux() if not is_schnell else ModelSamplingAuraFlow()
	width = latent_image["samples"].shape[3]*8
	height = latent_image["samples"].shape[2]*8

	lora_strength_len = 1
	if loras:
	lora_model = loras["loras"]
	lora_strength = loras["strengths"]
	lora_strength_len = sum(len(i) for i in lora_strength)

	if self.loraloader is None:
	self.loraloader = LoraLoader()

	# count total number of samples
	total_samples = len(cond_encoded) * len(noise) * len(max_shift) * len(base_shift) * len(guidance) * len(sampler) * len(scheduler) * len(steps) * len(denoise) * lora_strength_len
	current_sample = 0
	if total_samples > 1:
	pbar = ProgressBar(total_samples)

	lora_strength_len = 1
	if loras:
	lora_strength_len = len(lora_strength[0])

	for los in range(lora_strength_len):
	if loras:
	patched_model = self.loraloader.load_lora(model, None, lora_model[0], lora_strength[0][los], 0)[0]
	else:
	patched_model = model

	for i in range(len(cond_encoded)):
	conditioning = cond_encoded[i]
	ct = cond_text[i] if cond_text else None
	for n in noise:
	randnoise = Noise_RandomNoise(n)
	for ms in max_shift:
	for bs in base_shift:
	if is_schnell:
	work_model = modelsamplingflux.patch_aura(patched_model, bs)[0]
	else:
	work_model = modelsamplingflux.patch(patched_model, ms, bs, width, height)[0]
	for g in guidance:
	cond = conditioning_set_values(conditioning, {"guidance": g})
	guider = basicguider.get_guider(work_model, cond)[0]
	for s in sampler:
	samplerobj = comfy.samplers.sampler_object(s)
	for sc in scheduler:
	for st in steps:
	for d in denoise:
	sigmas = basicschedueler.get_sigmas(work_model, sc, st, d)[0]
	current_sample += 1
	log = f"Sampling {current_sample}/{total_samples} with seed {n}, sampler {s}, scheduler {sc}, steps {st}, guidance {g}, max_shift {ms}, base_shift {bs}, denoise {d}"
	lora_name = None
	lora_str = 0
	if loras:
	lora_name = lora_model[0]
	lora_str = lora_strength[0][los]
	log += f", lora {lora_name}, lora_strength {lora_str}"
	logging.info(log)
	start_time = time.time()
	latent = samplercustomadvanced.sample(randnoise, guider, samplerobj, sigmas, latent_image)[1]
	elapsed_time = time.time() - start_time
	out_params.append({"time": elapsed_time,
	"seed": n,
	"width": width,
	"height": height,
	"sampler": s,
	"scheduler": sc,
	"steps": st,
	"guidance": g,
	"max_shift": ms,
	"base_shift": bs,
	"denoise": d,
	"prompt": ct,
	"lora": lora_name,
	"lora_strength": lora_str})

	if out_latent is None:
	out_latent = latent
	else:
	out_latent = latentbatch.batch(out_latent, latent)[0]
	if total_samples > 1:
	pbar.update(1)

	return (out_latent, out_params)

	class PlotParameters:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	"images": ("IMAGE", ),
	"params": ("SAMPLER_PARAMS", ),
	"order_by": (["none", "time", "seed", "steps", "denoise", "sampler", "scheduler", "guidance", "max_shift", "base_shift", "lora_strength"], ),
	"cols_value": (["none", "time", "seed", "steps", "denoise", "sampler", "scheduler", "guidance", "max_shift", "base_shift", "lora_strength"], ),
	"cols_num": ("INT", {"default": -1, "min": -1, "max": 1024 }),
	"add_prompt": (["false", "true", "excerpt"], ),
	"add_params": (["false", "true", "changes only"], {"default": "true"}),
	}}

	RETURN_TYPES = ("IMAGE", )
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, images, params, order_by, cols_value, cols_num, add_prompt, add_params):
	from PIL import Image, ImageDraw, ImageFont
	import math
	import textwrap

	if images.shape[0] != len(params):
	raise ValueError("Number of images and number of parameters do not match.")

	_params = params.copy()

	if order_by != "none":
	sorted_params = sorted(_params, key=lambda x: x[order_by])
	indices = [_params.index(item) for item in sorted_params]
	images = images[torch.tensor(indices)]
	_params = sorted_params

	if cols_value != "none" and cols_num > -1:
	groups = {}
	for p in _params:
	value = p[cols_value]
	if value not in groups:
	groups[value] = []
	groups[value].append(p)
	cols_num = len(groups)

	sorted_params = []
	groups = list(groups.values())
	for g in zip(*groups):
	sorted_params.extend(g)

	indices = [_params.index(item) for item in sorted_params]
	images = images[torch.tensor(indices)]
	_params = sorted_params
	elif cols_num == 0:
	cols_num = int(math.sqrt(images.shape[0]))
	cols_num = max(1, min(cols_num, 1024))

	width = images.shape[2]
	out_image = []

	font = ImageFont.truetype(os.path.join(FONTS_DIR, 'ShareTechMono-Regular.ttf'), min(48, int(32*(width/1024))))
	text_padding = 3
	line_height = font.getmask('Q').getbbox()[3] + font.getmetrics()[1] + text_padding*2
	char_width = font.getbbox('M')[2]+1 # using monospace font

	if add_params == "changes only":
	value_tracker = {}
	for p in _params:
	for key, value in p.items():
	if key != "time":
	if key not in value_tracker:
	value_tracker[key] = set()
	value_tracker[key].add(value)
	changing_keys = {key for key, values in value_tracker.items() if len(values) > 1 or key == "prompt"}

	result = []
	for p in _params:
	changing_params = {key: value for key, value in p.items() if key in changing_keys}
	result.append(changing_params)

	_params = result

	for (image, param) in zip(images, _params):
	image = image.permute(2, 0, 1)

	if add_params != "false":
	if add_params == "changes only":
	text = "\n".join([f"{key}: {value}" for key, value in param.items() if key != "prompt"])
	else:
	text = f"time: {param['time']:.2f}s, seed: {param['seed']}, steps: {param['steps']}, size: {param['width']}×{param['height']}\ndenoise: {param['denoise']}, sampler: {param['sampler']}, sched: {param['scheduler']}\nguidance: {param['guidance']}, max/base shift: {param['max_shift']}/{param['base_shift']}"
	if 'lora' in param and param['lora']:
	text += f"\nLoRA: {param['lora'][:32]}, str: {param['lora_strength']}"

	lines = text.split("\n")
	text_height = line_height * len(lines)
	text_image = Image.new('RGB', (width, text_height), color=(0, 0, 0))

	for i, line in enumerate(lines):
	draw = ImageDraw.Draw(text_image)
	draw.text((text_padding, i * line_height + text_padding), line, font=font, fill=(255, 255, 255))

	text_image = T.ToTensor()(text_image).to(image.device)
	image = torch.cat([image, text_image], 1)

	if 'prompt' in param and param['prompt'] and add_prompt != "false":
	prompt = param['prompt']
	if add_prompt == "excerpt":
	prompt = " ".join(param['prompt'].split()[:64])
	prompt += "..."

	cols = math.ceil(width / char_width)
	prompt_lines = textwrap.wrap(prompt, width=cols)
	prompt_height = line_height * len(prompt_lines)
	prompt_image = Image.new('RGB', (width, prompt_height), color=(0, 0, 0))

	for i, line in enumerate(prompt_lines):
	draw = ImageDraw.Draw(prompt_image)
	draw.text((text_padding, i * line_height + text_padding), line, font=font, fill=(255, 255, 255))

	prompt_image = T.ToTensor()(prompt_image).to(image.device)
	image = torch.cat([image, prompt_image], 1)

	# a little cleanup
	image = torch.nan_to_num(image, nan=0.0).clamp(0.0, 1.0)
	out_image.append(image)

	# ensure all images have the same height
	if add_prompt != "false" or add_params == "changes only":
	max_height = max([image.shape[1] for image in out_image])
	out_image = [F.pad(image, (0, 0, 0, max_height - image.shape[1])) for image in out_image]

	out_image = torch.stack(out_image, 0).permute(0, 2, 3, 1)

	# merge images
	if cols_num > -1:
	cols = min(cols_num, out_image.shape[0])
	b, h, w, c = out_image.shape
	rows = math.ceil(b / cols)

	# Pad the tensor if necessary
	if b % cols != 0:
	padding = cols - (b % cols)
	out_image = F.pad(out_image, (0, 0, 0, 0, 0, 0, 0, padding))
	b = out_image.shape[0]

	# Reshape and transpose
	out_image = out_image.reshape(rows, cols, h, w, c)
	out_image = out_image.permute(0, 2, 1, 3, 4)
	out_image = out_image.reshape(rows * h, cols * w, c).unsqueeze(0)

	"""
	width = out_image.shape[2]
	# add the title and notes on top
	if title and export_labels:
	title_font = ImageFont.truetype(os.path.join(FONTS_DIR, 'ShareTechMono-Regular.ttf'), 48)
	title_width = title_font.getbbox(title)[2]
	title_padding = 6
	title_line_height = title_font.getmask(title).getbbox()[3] + title_font.getmetrics()[1] + title_padding*2
	title_text_height = title_line_height
	title_text_image = Image.new('RGB', (width, title_text_height), color=(0, 0, 0, 0))

	draw = ImageDraw.Draw(title_text_image)
	draw.text((width//2 - title_width//2, title_padding), title, font=title_font, fill=(255, 255, 255))

	title_text_image = T.ToTensor()(title_text_image).unsqueeze(0).permute([0,2,3,1]).to(out_image.device)
	out_image = torch.cat([title_text_image, out_image], 1)
	"""

	return (out_image, )

	class GuidanceTimestepping:
	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"model": ("MODEL",),
	"value": ("FLOAT", {"default": 2.0, "min": 0.0, "max": 100.0, "step": 0.05}),
	"start_at": ("FLOAT", {"default": 0.2, "min": 0.0, "max": 1.0, "step": 0.01}),
	"end_at": ("FLOAT", {"default": 0.8, "min": 0.0, "max": 1.0, "step": 0.01}),
	}
	}

	RETURN_TYPES = ("MODEL",)
	FUNCTION = "execute"
	CATEGORY = "essentials/sampling"

	def execute(self, model, value, start_at, end_at):
	sigma_start = model.get_model_object("model_sampling").percent_to_sigma(start_at)
	sigma_end = model.get_model_object("model_sampling").percent_to_sigma(end_at)

	def apply_apg(args):
	cond = args["cond"]
	uncond = args["uncond"]
	cond_scale = args["cond_scale"]
	sigma = args["sigma"]

	sigma = sigma.detach().cpu()[0].item()

	if sigma <= sigma_start and sigma > sigma_end:
	cond_scale = value

	return uncond + (cond - uncond) * cond_scale

	m = model.clone()
	m.set_model_sampler_cfg_function(apply_apg)
	return (m,)

	class ModelSamplingDiscreteFlowCustom(torch.nn.Module):
	def __init__(self, model_config=None):
	super().__init__()
	if model_config is not None:
	sampling_settings = model_config.sampling_settings
	else:
	sampling_settings = {}

	self.set_parameters(shift=sampling_settings.get("shift", 1.0), multiplier=sampling_settings.get("multiplier", 1000))

	def set_parameters(self, shift=1.0, timesteps=1000, multiplier=1000, cut_off=1.0, shift_multiplier=0):
	self.shift = shift
	self.multiplier = multiplier
	self.cut_off = cut_off
	self.shift_multiplier = shift_multiplier
	ts = self.sigma((torch.arange(1, timesteps + 1, 1) / timesteps) * multiplier)
	self.register_buffer('sigmas', ts)

	@property
	def sigma_min(self):
	return self.sigmas[0]

	@property
	def sigma_max(self):
	return self.sigmas[-1]

	def timestep(self, sigma):
	return sigma * self.multiplier

	def sigma(self, timestep):
	shift = self.shift
	if timestep.dim() == 0:
	t = timestep.cpu().item() / self.multiplier
	if t <= self.cut_off:
	shift = shift * self.shift_multiplier

	return comfy.model_sampling.time_snr_shift(shift, timestep / self.multiplier)

	def percent_to_sigma(self, percent):
	if percent <= 0.0:
	return 1.0
	if percent >= 1.0:
	return 0.0
	return 1.0 - percent

	class ModelSamplingSD3Advanced:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": { "model": ("MODEL",),
	"shift": ("FLOAT", {"default": 3.0, "min": 0.0, "max": 100.0, "step":0.01}),
	"cut_off": ("FLOAT", {"default": 0.5, "min": 0.0, "max": 1.0, "step":0.05}),
	"shift_multiplier": ("FLOAT", {"default": 2, "min": 0, "max": 10, "step":0.05}),
	}}

	RETURN_TYPES = ("MODEL",)
	FUNCTION = "execute"

	CATEGORY = "essentials/sampling"

	def execute(self, model, shift, multiplier=1000, cut_off=1.0, shift_multiplier=0):
	m = model.clone()


	sampling_base = ModelSamplingDiscreteFlowCustom
	sampling_type = comfy.model_sampling.CONST

	class ModelSamplingAdvanced(sampling_base, sampling_type):
	pass

	model_sampling = ModelSamplingAdvanced(model.model.model_config)
	model_sampling.set_parameters(shift=shift, multiplier=multiplier, cut_off=cut_off, shift_multiplier=shift_multiplier)
	m.add_object_patch("model_sampling", model_sampling)

	return (m, )

	SAMPLING_CLASS_MAPPINGS = {
	"KSamplerVariationsStochastic+": KSamplerVariationsStochastic,
	"KSamplerVariationsWithNoise+": KSamplerVariationsWithNoise,
	"InjectLatentNoise+": InjectLatentNoise,
	"FluxSamplerParams+": FluxSamplerParams,
	"GuidanceTimestepping+": GuidanceTimestepping,
	"PlotParameters+": PlotParameters,
	"TextEncodeForSamplerParams+": TextEncodeForSamplerParams,
	"SamplerSelectHelper+": SamplerSelectHelper,
	"SchedulerSelectHelper+": SchedulerSelectHelper,
	"LorasForFluxParams+": LorasForFluxParams,
	"ModelSamplingSD3Advanced+": ModelSamplingSD3Advanced,
	}

	SAMPLING_NAME_MAPPINGS = {
	"KSamplerVariationsStochastic+": "🔧 KSampler Stochastic Variations",
	"KSamplerVariationsWithNoise+": "🔧 KSampler Variations with Noise Injection",
	"InjectLatentNoise+": "🔧 Inject Latent Noise",
	"FluxSamplerParams+": "🔧 Flux Sampler Parameters",
	"GuidanceTimestepping+": "🔧 Guidance Timestep (experimental)",
	"PlotParameters+": "🔧 Plot Sampler Parameters",
	"TextEncodeForSamplerParams+": "🔧Text Encode for Sampler Params",
	"SamplerSelectHelper+": "🔧 Sampler Select Helper",
	"SchedulerSelectHelper+": "🔧 Scheduler Select Helper",
	"LorasForFluxParams+": "🔧 LoRA for Flux Parameters",
	"ModelSamplingSD3Advanced+": "🔧 Model Sampling SD3 Advanced",
	}