# import os import spaces import time import gradio as gr import torch from PIL import Image from torchvision import transforms from dataclasses import dataclass import math from typing import Callable from tqdm import tqdm import bitsandbytes as bnb from bitsandbytes.nn.modules import Params4bit, QuantState import torch import random from einops import rearrange, repeat from diffusers import AutoencoderKL from torch import Tensor, nn from transformers import CLIPTextModel, CLIPTokenizer from transformers import T5EncoderModel, T5Tokenizer # from optimum.quanto import freeze, qfloat8, quantize # ---------------- Encoders ---------------- class HFEmbedder(nn.Module): def __init__(self, version: str, max_length: int, **hf_kwargs): super().__init__() self.is_clip = version.startswith("openai") self.max_length = max_length self.output_key = "pooler_output" if self.is_clip else "last_hidden_state" if self.is_clip: self.tokenizer: CLIPTokenizer = CLIPTokenizer.from_pretrained(version, max_length=max_length) self.hf_module: CLIPTextModel = CLIPTextModel.from_pretrained(version, **hf_kwargs) else: self.tokenizer: T5Tokenizer = T5Tokenizer.from_pretrained(version, max_length=max_length) self.hf_module: T5EncoderModel = T5EncoderModel.from_pretrained(version, **hf_kwargs) self.hf_module = self.hf_module.eval().requires_grad_(False) def forward(self, text: list[str]) -> Tensor: batch_encoding = self.tokenizer( text, truncation=True, max_length=self.max_length, return_length=False, return_overflowing_tokens=False, padding="max_length", return_tensors="pt", ) outputs = self.hf_module( input_ids=batch_encoding["input_ids"].to(self.hf_module.device), attention_mask=None, output_hidden_states=False, ) return outputs[self.output_key] device = "cuda" t5 = HFEmbedder("DeepFloyd/t5-v1_1-xxl", max_length=512, torch_dtype=torch.bfloat16).to(device) clip = HFEmbedder("openai/clip-vit-large-patch14", max_length=77, torch_dtype=torch.bfloat16).to(device) ae = AutoencoderKL.from_pretrained("black-forest-labs/FLUX.1-dev", subfolder="vae", torch_dtype=torch.bfloat16).to(device) # quantize(t5, weights=qfloat8) # freeze(t5) # ---------------- NF4 ---------------- def functional_linear_4bits(x, weight, bias): out = bnb.matmul_4bit(x, weight.t(), bias=bias, quant_state=weight.quant_state) out = out.to(x) return out def copy_quant_state(state: QuantState, device: torch.device = None) -> QuantState: if state is None: return None device = device or state.absmax.device state2 = ( QuantState( absmax=state.state2.absmax.to(device), shape=state.state2.shape, code=state.state2.code.to(device), blocksize=state.state2.blocksize, quant_type=state.state2.quant_type, dtype=state.state2.dtype, ) if state.nested else None ) return QuantState( absmax=state.absmax.to(device), shape=state.shape, code=state.code.to(device), blocksize=state.blocksize, quant_type=state.quant_type, dtype=state.dtype, offset=state.offset.to(device) if state.nested else None, state2=state2, ) class ForgeParams4bit(Params4bit): def to(self, *args, **kwargs): device, dtype, non_blocking, convert_to_format = torch._C._nn._parse_to(*args, **kwargs) if device is not None and device.type == "cuda" and not self.bnb_quantized: return self._quantize(device) else: n = ForgeParams4bit( torch.nn.Parameter.to(self, device=device, dtype=dtype, non_blocking=non_blocking), requires_grad=self.requires_grad, quant_state=copy_quant_state(self.quant_state, device), # blocksize=self.blocksize, # compress_statistics=self.compress_statistics, compress_statistics=False, blocksize=64, quant_type=self.quant_type, quant_storage=self.quant_storage, bnb_quantized=self.bnb_quantized, module=self.module ) self.module.quant_state = n.quant_state self.data = n.data self.quant_state = n.quant_state return n class ForgeLoader4Bit(torch.nn.Module): def __init__(self, *, device, dtype, quant_type, **kwargs): super().__init__() self.dummy = torch.nn.Parameter(torch.empty(1, device=device, dtype=dtype)) self.weight = None self.quant_state = None self.bias = None self.quant_type = quant_type def _save_to_state_dict(self, destination, prefix, keep_vars): super()._save_to_state_dict(destination, prefix, keep_vars) quant_state = getattr(self.weight, "quant_state", None) if quant_state is not None: for k, v in quant_state.as_dict(packed=True).items(): destination[prefix + "weight." + k] = v if keep_vars else v.detach() return def _load_from_state_dict(self, state_dict, prefix, local_metadata, strict, missing_keys, unexpected_keys, error_msgs): quant_state_keys = {k[len(prefix + "weight."):] for k in state_dict.keys() if k.startswith(prefix + "weight.")} if any('bitsandbytes' in k for k in quant_state_keys): quant_state_dict = {k: state_dict[prefix + "weight." + k] for k in quant_state_keys} self.weight = ForgeParams4bit.from_prequantized( data=state_dict[prefix + 'weight'], quantized_stats=quant_state_dict, requires_grad=False, # device=self.dummy.device, device=torch.device('cuda'), module=self ) self.quant_state = self.weight.quant_state if prefix + 'bias' in state_dict: self.bias = torch.nn.Parameter(state_dict[prefix + 'bias'].to(self.dummy)) del self.dummy elif hasattr(self, 'dummy'): if prefix + 'weight' in state_dict: self.weight = ForgeParams4bit( state_dict[prefix + 'weight'].to(self.dummy), requires_grad=False, compress_statistics=True, quant_type=self.quant_type, quant_storage=torch.uint8, module=self, ) self.quant_state = self.weight.quant_state if prefix + 'bias' in state_dict: self.bias = torch.nn.Parameter(state_dict[prefix + 'bias'].to(self.dummy)) del self.dummy else: super()._load_from_state_dict(state_dict, prefix, local_metadata, strict, missing_keys, unexpected_keys, error_msgs) class Linear(ForgeLoader4Bit): def __init__(self, *args, device=None, dtype=None, **kwargs): super().__init__(device=device, dtype=dtype, quant_type='nf4') def forward(self, x): self.weight.quant_state = self.quant_state if self.bias is not None and self.bias.dtype != x.dtype: # Maybe this can also be set to all non-bnb ops since the cost is very low. # And it only invokes one time, and most linear does not have bias self.bias.data = self.bias.data.to(x.dtype) return functional_linear_4bits(x, self.weight, self.bias) nn.Linear = Linear # ---------------- Model ---------------- def attention(q: Tensor, k: Tensor, v: Tensor, pe: Tensor) -> Tensor: q, k = apply_rope(q, k, pe) x = torch.nn.functional.scaled_dot_product_attention(q, k, v) # x = rearrange(x, "B H L D -> B L (H D)") x = x.permute(0, 2, 1, 3).reshape(x.size(0), x.size(2), -1) return x def rope(pos, dim, theta): scale = torch.arange(0, dim, 2, dtype=torch.float64, device=pos.device) / dim omega = 1.0 / (theta ** scale) # out = torch.einsum("...n,d->...nd", pos, omega) out = pos.unsqueeze(-1) * omega.unsqueeze(0) cos_out = torch.cos(out) sin_out = torch.sin(out) out = torch.stack([cos_out, -sin_out, sin_out, cos_out], dim=-1) # out = rearrange(out, "b n d (i j) -> b n d i j", i=2, j=2) b, n, d, _ = out.shape out = out.view(b, n, d, 2, 2) return out.float() def apply_rope(xq: Tensor, xk: Tensor, freqs_cis: Tensor) -> tuple[Tensor, Tensor]: xq_ = xq.float().reshape(*xq.shape[:-1], -1, 1, 2) xk_ = xk.float().reshape(*xk.shape[:-1], -1, 1, 2) xq_out = freqs_cis[..., 0] * xq_[..., 0] + freqs_cis[..., 1] * xq_[..., 1] xk_out = freqs_cis[..., 0] * xk_[..., 0] + freqs_cis[..., 1] * xk_[..., 1] return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk) class EmbedND(nn.Module): def __init__(self, dim: int, theta: int, axes_dim: list[int]): super().__init__() self.dim = dim self.theta = theta self.axes_dim = axes_dim def forward(self, ids: Tensor) -> Tensor: n_axes = ids.shape[-1] emb = torch.cat( [rope(ids[..., i], self.axes_dim[i], self.theta) for i in range(n_axes)], dim=-3, ) return emb.unsqueeze(1) def timestep_embedding(t: Tensor, dim, max_period=10000, time_factor: float = 1000.0): """ Create sinusoidal timestep embeddings. :param t: a 1-D Tensor of N indices, one per batch element. These may be fractional. :param dim: the dimension of the output. :param max_period: controls the minimum frequency of the embeddings. :return: an (N, D) Tensor of positional embeddings. """ t = time_factor * t half = dim // 2 # Do not block CUDA steam, but having about 1e-4 differences with Flux official codes: # freqs = torch.exp(-math.log(max_period) * torch.arange(start=0, end=half, dtype=torch.float32, device=t.device) / half) # Block CUDA steam, but consistent with official codes: freqs = torch.exp(-math.log(max_period) * torch.arange(start=0, end=half, dtype=torch.float32) / half).to(t.device) args = t[:, None].float() * freqs[None] embedding = torch.cat([torch.cos(args), torch.sin(args)], dim=-1) if dim % 2: embedding = torch.cat([embedding, torch.zeros_like(embedding[:, :1])], dim=-1) if torch.is_floating_point(t): embedding = embedding.to(t) return embedding class MLPEmbedder(nn.Module): def __init__(self, in_dim: int, hidden_dim: int): super().__init__() self.in_layer = nn.Linear(in_dim, hidden_dim, bias=True) self.silu = nn.SiLU() self.out_layer = nn.Linear(hidden_dim, hidden_dim, bias=True) def forward(self, x: Tensor) -> Tensor: return self.out_layer(self.silu(self.in_layer(x))) class RMSNorm(torch.nn.Module): def __init__(self, dim: int): super().__init__() self.scale = nn.Parameter(torch.ones(dim)) def forward(self, x: Tensor): x_dtype = x.dtype x = x.float() rrms = torch.rsqrt(torch.mean(x**2, dim=-1, keepdim=True) + 1e-6) return (x * rrms).to(dtype=x_dtype) * self.scale class QKNorm(torch.nn.Module): def __init__(self, dim: int): super().__init__() self.query_norm = RMSNorm(dim) self.key_norm = RMSNorm(dim) def forward(self, q: Tensor, k: Tensor, v: Tensor) -> tuple[Tensor, Tensor]: q = self.query_norm(q) k = self.key_norm(k) return q.to(v), k.to(v) class SelfAttention(nn.Module): def __init__(self, dim: int, num_heads: int = 8, qkv_bias: bool = False): super().__init__() self.num_heads = num_heads head_dim = dim // num_heads self.qkv = nn.Linear(dim, dim * 3, bias=qkv_bias) self.norm = QKNorm(head_dim) self.proj = nn.Linear(dim, dim) def forward(self, x: Tensor, pe: Tensor) -> Tensor: qkv = self.qkv(x) # q, k, v = rearrange(qkv, "B L (K H D) -> K B H L D", K=3, H=self.num_heads) B, L, _ = qkv.shape qkv = qkv.view(B, L, 3, self.num_heads, -1) q, k, v = qkv.permute(2, 0, 3, 1, 4) q, k = self.norm(q, k, v) x = attention(q, k, v, pe=pe) x = self.proj(x) return x @dataclass class ModulationOut: shift: Tensor scale: Tensor gate: Tensor class Modulation(nn.Module): def __init__(self, dim: int, double: bool): super().__init__() self.is_double = double self.multiplier = 6 if double else 3 self.lin = nn.Linear(dim, self.multiplier * dim, bias=True) def forward(self, vec: Tensor) -> tuple[ModulationOut, ModulationOut | None]: out = self.lin(nn.functional.silu(vec))[:, None, :].chunk(self.multiplier, dim=-1) return ( ModulationOut(*out[:3]), ModulationOut(*out[3:]) if self.is_double else None, ) class DoubleStreamBlock(nn.Module): def __init__(self, hidden_size: int, num_heads: int, mlp_ratio: float, qkv_bias: bool = False): super().__init__() mlp_hidden_dim = int(hidden_size * mlp_ratio) self.num_heads = num_heads self.hidden_size = hidden_size self.img_mod = Modulation(hidden_size, double=True) self.img_norm1 = nn.LayerNorm(hidden_size, elementwise_affine=False, eps=1e-6) self.img_attn = SelfAttention(dim=hidden_size, num_heads=num_heads, qkv_bias=qkv_bias) self.img_norm2 = nn.LayerNorm(hidden_size, elementwise_affine=False, eps=1e-6) self.img_mlp = nn.Sequential( nn.Linear(hidden_size, mlp_hidden_dim, bias=True), nn.GELU(approximate="tanh"), nn.Linear(mlp_hidden_dim, hidden_size, bias=True), ) self.txt_mod = Modulation(hidden_size, double=True) self.txt_norm1 = nn.LayerNorm(hidden_size, elementwise_affine=False, eps=1e-6) self.txt_attn = SelfAttention(dim=hidden_size, num_heads=num_heads, qkv_bias=qkv_bias) self.txt_norm2 = nn.LayerNorm(hidden_size, elementwise_affine=False, eps=1e-6) self.txt_mlp = nn.Sequential( nn.Linear(hidden_size, mlp_hidden_dim, bias=True), nn.GELU(approximate="tanh"), nn.Linear(mlp_hidden_dim, hidden_size, bias=True), ) def forward(self, img: Tensor, txt: Tensor, vec: Tensor, pe: Tensor) -> tuple[Tensor, Tensor]: img_mod1, img_mod2 = self.img_mod(vec) txt_mod1, txt_mod2 = self.txt_mod(vec) # prepare image for attention img_modulated = self.img_norm1(img) img_modulated = (1 + img_mod1.scale) * img_modulated + img_mod1.shift img_qkv = self.img_attn.qkv(img_modulated) # img_q, img_k, img_v = rearrange(img_qkv, "B L (K H D) -> K B H L D", K=3, H=self.num_heads) B, L, _ = img_qkv.shape H = self.num_heads D = img_qkv.shape[-1] // (3 * H) img_q, img_k, img_v = img_qkv.view(B, L, 3, H, D).permute(2, 0, 3, 1, 4) img_q, img_k = self.img_attn.norm(img_q, img_k, img_v) # prepare txt for attention txt_modulated = self.txt_norm1(txt) txt_modulated = (1 + txt_mod1.scale) * txt_modulated + txt_mod1.shift txt_qkv = self.txt_attn.qkv(txt_modulated) # txt_q, txt_k, txt_v = rearrange(txt_qkv, "B L (K H D) -> K B H L D", K=3, H=self.num_heads) B, L, _ = txt_qkv.shape txt_q, txt_k, txt_v = txt_qkv.view(B, L, 3, H, D).permute(2, 0, 3, 1, 4) txt_q, txt_k = self.txt_attn.norm(txt_q, txt_k, txt_v) # run actual attention q = torch.cat((txt_q, img_q), dim=2) k = torch.cat((txt_k, img_k), dim=2) v = torch.cat((txt_v, img_v), dim=2) attn = attention(q, k, v, pe=pe) txt_attn, img_attn = attn[:, : txt.shape[1]], attn[:, txt.shape[1] :] # calculate the img bloks img = img + img_mod1.gate * self.img_attn.proj(img_attn) img = img + img_mod2.gate * self.img_mlp((1 + img_mod2.scale) * self.img_norm2(img) + img_mod2.shift) # calculate the txt bloks txt = txt + txt_mod1.gate * self.txt_attn.proj(txt_attn) txt = txt + txt_mod2.gate * self.txt_mlp((1 + txt_mod2.scale) * self.txt_norm2(txt) + txt_mod2.shift) return img, txt class SingleStreamBlock(nn.Module): """ A DiT block with parallel linear layers as described in https://arxiv.org/abs/2302.05442 and adapted modulation interface. """ def __init__( self, hidden_size: int, num_heads: int, mlp_ratio: float = 4.0, qk_scale: float | None = None, ): super().__init__() self.hidden_dim = hidden_size self.num_heads = num_heads head_dim = hidden_size // num_heads self.scale = qk_scale or head_dim**-0.5 self.mlp_hidden_dim = int(hidden_size * mlp_ratio) # qkv and mlp_in self.linear1 = nn.Linear(hidden_size, hidden_size * 3 + self.mlp_hidden_dim) # proj and mlp_out self.linear2 = nn.Linear(hidden_size + self.mlp_hidden_dim, hidden_size) self.norm = QKNorm(head_dim) self.hidden_size = hidden_size self.pre_norm = nn.LayerNorm(hidden_size, elementwise_affine=False, eps=1e-6) self.mlp_act = nn.GELU(approximate="tanh") self.modulation = Modulation(hidden_size, double=False) def forward(self, x: Tensor, vec: Tensor, pe: Tensor) -> Tensor: mod, _ = self.modulation(vec) x_mod = (1 + mod.scale) * self.pre_norm(x) + mod.shift qkv, mlp = torch.split(self.linear1(x_mod), [3 * self.hidden_size, self.mlp_hidden_dim], dim=-1) # q, k, v = rearrange(qkv, "B L (K H D) -> K B H L D", K=3, H=self.num_heads) qkv = qkv.view(qkv.size(0), qkv.size(1), 3, self.num_heads, self.hidden_size // self.num_heads) q, k, v = qkv.permute(2, 0, 3, 1, 4) q, k = self.norm(q, k, v) # compute attention attn = attention(q, k, v, pe=pe) # compute activation in mlp stream, cat again and run second linear layer output = self.linear2(torch.cat((attn, self.mlp_act(mlp)), 2)) return x + mod.gate * output class LastLayer(nn.Module): def __init__(self, hidden_size: int, patch_size: int, out_channels: int): super().__init__() self.norm_final = nn.LayerNorm(hidden_size, elementwise_affine=False, eps=1e-6) self.linear = nn.Linear(hidden_size, patch_size * patch_size * out_channels, bias=True) self.adaLN_modulation = nn.Sequential(nn.SiLU(), nn.Linear(hidden_size, 2 * hidden_size, bias=True)) def forward(self, x: Tensor, vec: Tensor) -> Tensor: shift, scale = self.adaLN_modulation(vec).chunk(2, dim=1) x = (1 + scale[:, None, :]) * self.norm_final(x) + shift[:, None, :] x = self.linear(x) return x class FluxParams: in_channels: int = 64 vec_in_dim: int = 768 context_in_dim: int = 4096 hidden_size: int = 3072 mlp_ratio: float = 4.0 num_heads: int = 24 depth: int = 19 depth_single_blocks: int = 38 axes_dim: list = [16, 56, 56] theta: int = 10_000 qkv_bias: bool = True guidance_embed: bool = True class Flux(nn.Module): """ Transformer model for flow matching on sequences. """ def __init__(self, params = FluxParams()): super().__init__() self.params = params self.in_channels = params.in_channels self.out_channels = self.in_channels if params.hidden_size % params.num_heads != 0: raise ValueError( f"Hidden size {params.hidden_size} must be divisible by num_heads {params.num_heads}" ) pe_dim = params.hidden_size // params.num_heads if sum(params.axes_dim) != pe_dim: raise ValueError(f"Got {params.axes_dim} but expected positional dim {pe_dim}") self.hidden_size = params.hidden_size self.num_heads = params.num_heads self.pe_embedder = EmbedND(dim=pe_dim, theta=params.theta, axes_dim=params.axes_dim) self.img_in = nn.Linear(self.in_channels, self.hidden_size, bias=True) self.time_in = MLPEmbedder(in_dim=256, hidden_dim=self.hidden_size) self.vector_in = MLPEmbedder(params.vec_in_dim, self.hidden_size) self.guidance_in = ( MLPEmbedder(in_dim=256, hidden_dim=self.hidden_size) if params.guidance_embed else nn.Identity() ) self.txt_in = nn.Linear(params.context_in_dim, self.hidden_size) self.double_blocks = nn.ModuleList( [ DoubleStreamBlock( self.hidden_size, self.num_heads, mlp_ratio=params.mlp_ratio, qkv_bias=params.qkv_bias, ) for _ in range(params.depth) ] ) self.single_blocks = nn.ModuleList( [ SingleStreamBlock(self.hidden_size, self.num_heads, mlp_ratio=params.mlp_ratio) for _ in range(params.depth_single_blocks) ] ) self.final_layer = LastLayer(self.hidden_size, 1, self.out_channels) def forward( self, img: Tensor, img_ids: Tensor, txt: Tensor, txt_ids: Tensor, timesteps: Tensor, y: Tensor, guidance: Tensor | None = None, ) -> Tensor: if img.ndim != 3 or txt.ndim != 3: raise ValueError("Input img and txt tensors must have 3 dimensions.") # running on sequences img img = self.img_in(img) vec = self.time_in(timestep_embedding(timesteps, 256)) if self.params.guidance_embed: if guidance is None: raise ValueError("Didn't get guidance strength for guidance distilled model.") vec = vec + self.guidance_in(timestep_embedding(guidance, 256)) vec = vec + self.vector_in(y) txt = self.txt_in(txt) ids = torch.cat((txt_ids, img_ids), dim=1) pe = self.pe_embedder(ids) for block in self.double_blocks: img, txt = block(img=img, txt=txt, vec=vec, pe=pe) img = torch.cat((txt, img), 1) for block in self.single_blocks: img = block(img, vec=vec, pe=pe) img = img[:, txt.shape[1] :, ...] img = self.final_layer(img, vec) # (N, T, patch_size ** 2 * out_channels) return img def prepare(t5: HFEmbedder, clip: HFEmbedder, img: Tensor, prompt: str | list[str]) -> dict[str, Tensor]: bs, c, h, w = img.shape if bs == 1 and not isinstance(prompt, str): bs = len(prompt) img = rearrange(img, "b c (h ph) (w pw) -> b (h w) (c ph pw)", ph=2, pw=2) if img.shape[0] == 1 and bs > 1: img = repeat(img, "1 ... -> bs ...", bs=bs) img_ids = torch.zeros(h // 2, w // 2, 3) img_ids[..., 1] = img_ids[..., 1] + torch.arange(h // 2)[:, None] img_ids[..., 2] = img_ids[..., 2] + torch.arange(w // 2)[None, :] img_ids = repeat(img_ids, "h w c -> b (h w) c", b=bs) if isinstance(prompt, str): prompt = [prompt] txt = t5(prompt) if txt.shape[0] == 1 and bs > 1: txt = repeat(txt, "1 ... -> bs ...", bs=bs) txt_ids = torch.zeros(bs, txt.shape[1], 3) vec = clip(prompt) if vec.shape[0] == 1 and bs > 1: vec = repeat(vec, "1 ... -> bs ...", bs=bs) return { "img": img, "img_ids": img_ids.to(img.device), "txt": txt.to(img.device), "txt_ids": txt_ids.to(img.device), "vec": vec.to(img.device), } def time_shift(mu: float, sigma: float, t: Tensor): return math.exp(mu) / (math.exp(mu) + (1 / t - 1) ** sigma) def get_lin_function( x1: float = 256, y1: float = 0.5, x2: float = 4096, y2: float = 1.15 ) -> Callable[[float], float]: m = (y2 - y1) / (x2 - x1) b = y1 - m * x1 return lambda x: m * x + b def get_schedule( num_steps: int, image_seq_len: int, base_shift: float = 0.5, max_shift: float = 1.15, shift: bool = True, ) -> list[float]: # extra step for zero timesteps = torch.linspace(1, 0, num_steps + 1) # shifting the schedule to favor high timesteps for higher signal images if shift: # eastimate mu based on linear estimation between two points mu = get_lin_function(y1=base_shift, y2=max_shift)(image_seq_len) timesteps = time_shift(mu, 1.0, timesteps) return timesteps.tolist() def denoise( model: Flux, # model input img: Tensor, img_ids: Tensor, txt: Tensor, txt_ids: Tensor, vec: Tensor, # sampling parameters timesteps: list[float], guidance: float = 4.0, ): # this is ignored for schnell guidance_vec = torch.full((img.shape[0],), guidance, device=img.device, dtype=img.dtype) for t_curr, t_prev in tqdm(zip(timesteps[:-1], timesteps[1:]), total=len(timesteps) - 1): t_vec = torch.full((img.shape[0],), t_curr, dtype=img.dtype, device=img.device) pred = model( img=img, img_ids=img_ids, txt=txt, txt_ids=txt_ids, y=vec, timesteps=t_vec, guidance=guidance_vec, ) img = img + (t_prev - t_curr) * pred return img def unpack(x: Tensor, height: int, width: int) -> Tensor: return rearrange( x, "b (h w) (c ph pw) -> b c (h ph) (w pw)", h=math.ceil(height / 16), w=math.ceil(width / 16), ph=2, pw=2, ) @dataclass class SamplingOptions: prompt: str width: int height: int guidance: float seed: int | None def get_image(image) -> torch.Tensor | None: if image is None: return None image = Image.fromarray(image).convert("RGB") transform = transforms.Compose([ transforms.ToTensor(), transforms.Lambda(lambda x: 2.0 * x - 1.0), ]) img: torch.Tensor = transform(image) return img[None, ...] # ---------------- Demo ---------------- from huggingface_hub import hf_hub_download from safetensors.torch import load_file sd = load_file(hf_hub_download(repo_id="lllyasviel/flux1-dev-bnb-nf4", filename="flux1-dev-bnb-nf4-v2.safetensors")) sd = {k.replace("model.diffusion_model.", ""): v for k, v in sd.items() if "model.diffusion_model" in k} model = Flux().to(dtype=torch.bfloat16, device="cuda") result = model.load_state_dict(sd) model_zero_init = False # model = Flux().to(dtype=torch.bfloat16, device="cuda") # result = model.load_state_dict(load_file("/storage/dev/nyanko/flux-dev/flux1-dev.sft")) @spaces.GPU @torch.no_grad() def generate_image( prompt, width, height, guidance, inference_steps, seed, do_img2img, init_image, image2image_strength, resize_img, progress=gr.Progress(track_tqdm=True), ): if seed == 0: seed = int(random.random() * 1000000) device = "cuda" if torch.cuda.is_available() else "cpu" torch_device = torch.device(device) global model, model_zero_init if not model_zero_init: model = model.to(torch_device) model_zero_init = True if do_img2img and init_image is not None: init_image = get_image(init_image) if resize_img: init_image = torch.nn.functional.interpolate(init_image, (height, width)) else: h, w = init_image.shape[-2:] init_image = init_image[..., : 16 * (h // 16), : 16 * (w // 16)] height = init_image.shape[-2] width = init_image.shape[-1] init_image = ae.encode(init_image.to(torch_device).to(torch.bfloat16)).latent_dist.sample() init_image = (init_image - ae.config.shift_factor) * ae.config.scaling_factor generator = torch.Generator(device=device).manual_seed(seed) x = torch.randn(1, 16, 2 * math.ceil(height / 16), 2 * math.ceil(width / 16), device=device, dtype=torch.bfloat16, generator=generator) num_steps = inference_steps timesteps = get_schedule(num_steps, (x.shape[-1] * x.shape[-2]) // 4, shift=True) if do_img2img and init_image is not None: t_idx = int((1 - image2image_strength) * num_steps) t = timesteps[t_idx] timesteps = timesteps[t_idx:] x = t * x + (1.0 - t) * init_image.to(x.dtype) inp = prepare(t5=t5, clip=clip, img=x, prompt=prompt) x = denoise(model, **inp, timesteps=timesteps, guidance=guidance) # with profile(activities=[ProfilerActivity.CPU],record_shapes=True,profile_memory=True) as prof: # print(prof.key_averages().table(sort_by="cpu_time_total", row_limit=20)) x = unpack(x.float(), height, width) with torch.autocast(device_type=torch_device.type, dtype=torch.bfloat16): x = x = (x / ae.config.scaling_factor) + ae.config.shift_factor x = ae.decode(x).sample x = x.clamp(-1, 1) x = rearrange(x[0], "c h w -> h w c") img = Image.fromarray((127.5 * (x + 1.0)).cpu().byte().numpy()) return img, seed def create_demo(): with gr.Blocks(theme="bethecloud/storj_theme") as demo: gr.HTML( """

FLUX.1 dev NF4 Quantized Demo

12B param rectified flow transformer guidance-distilled from FLUX.1 [pro] [non-commercial license] [blog] [model]

""" ) with gr.Row(): with gr.Column(): prompt = gr.Textbox(label="Prompt", value="a photo of a forest with mist swirling around the tree trunks. The word 'FLUX' is painted over it in big, red brush strokes with visible texture") width = gr.Slider(minimum=128, maximum=2048, step=64, label="Width", value=1360) height = gr.Slider(minimum=128, maximum=2048, step=64, label="Height", value=768) guidance = gr.Slider(minimum=1.0, maximum=5.0, step=0.1, label="Guidance", value=3.5) inference_steps = gr.Slider( label="Inference steps", minimum=1, maximum=30, step=1, value=16, ) seed = gr.Number(label="Seed", precision=-1) do_img2img = gr.Checkbox(label="Image to Image", value=False) init_image = gr.Image(label="Input Image", visible=False) image2image_strength = gr.Slider(minimum=0.0, maximum=1.0, step=0.01, label="Noising strength", value=0.8, visible=False) resize_img = gr.Checkbox(label="Resize image", value=True, visible=False) generate_button = gr.Button("Generate") with gr.Column(): output_image = gr.Image(label="Generated Image") output_seed = gr.Text(label="Used Seed") do_img2img.change( fn=lambda x: [gr.update(visible=x), gr.update(visible=x), gr.update(visible=x)], inputs=[do_img2img], outputs=[init_image, image2image_strength, resize_img] ) generate_button.click( fn=generate_image, inputs=[prompt, width, height, guidance, inference_steps, seed, do_img2img, init_image, image2image_strength, resize_img], outputs=[output_image, output_seed] ) examples = [ "a tiny astronaut hatching from an egg on the moon", "a cat holding a sign that says hello world", "an anime illustration of a wiener schnitzel", ] return demo if __name__ == "__main__": demo = create_demo() demo.launch()