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	"""
	TinyFlux: A /12 scaled Flux architecture for experimentation.

	Architecture:
	- hidden: 256 (3072/12)
	- num_heads: 2 (24/12)
	- head_dim: 128 (preserved for RoPE compatibility)
	- in_channels: 16 (Flux VAE output channels)
	- double_layers: 3
	- single_layers: 3

	Text Encoders (runtime):
	- flan-t5-base (768 dim) → txt_in projects to hidden
	- CLIP-L (768 dim pooled) → vector_in projects to hidden
	"""

	import torch
	import torch.nn as nn
	import torch.nn.functional as F
	import math
	from dataclasses import dataclass
	from typing import Optional, Tuple


	@dataclass
	class TinyFluxConfig:
	"""Configuration for TinyFlux model."""
	# Core dimensions
	hidden_size: int = 256
	num_attention_heads: int = 2
	attention_head_dim: int = 128 # Preserved for RoPE

	# Input/output (Flux VAE has 16 channels)
	in_channels: int = 16 # Flux VAE output channels
	patch_size: int = 1 # No 2x2 patchification, raw latent tokens

	# Text encoder interfaces (runtime encoding)
	joint_attention_dim: int = 768 # flan-t5-base output dim
	pooled_projection_dim: int = 768 # CLIP-L pooled dim

	# Layers
	num_double_layers: int = 3
	num_single_layers: int = 3

	# MLP
	mlp_ratio: float = 4.0

	# RoPE (must sum to head_dim)
	axes_dims_rope: Tuple[int, int, int] = (16, 56, 56)

	# Misc
	guidance_embeds: bool = True

	def __post_init__(self):
	assert self.num_attention_heads * self.attention_head_dim == self.hidden_size, \
	f"heads ({self.num_attention_heads}) * head_dim ({self.attention_head_dim}) != hidden ({self.hidden_size})"
	assert sum(self.axes_dims_rope) == self.attention_head_dim, \
	f"RoPE dims {self.axes_dims_rope} must sum to head_dim {self.attention_head_dim}"


	class RMSNorm(nn.Module):
	"""Root Mean Square Layer Normalization."""
	def __init__(self, dim: int, eps: float = 1e-6):
	super().__init__()
	self.eps = eps
	self.weight = nn.Parameter(torch.ones(dim))

	def forward(self, x: torch.Tensor) -> torch.Tensor:
	norm = x.float().pow(2).mean(-1, keepdim=True).add(self.eps).rsqrt()
	return (x * norm).type_as(x) * self.weight


	class RotaryEmbedding(nn.Module):
	"""Rotary Position Embedding for 2D + temporal."""
	def __init__(self, dim: int, axes_dims: Tuple[int, int, int], theta: float = 10000.0):
	super().__init__()
	self.dim = dim
	self.axes_dims = axes_dims # (temporal, height, width)
	self.theta = theta

	def forward(self, ids: torch.Tensor, dtype: torch.dtype = None) -> torch.Tensor:
	"""
	ids: (B, N, 3) - temporal, height, width indices
	dtype: output dtype (defaults to ids.dtype, but use model dtype for bf16)
	Returns: (B, N, dim) rotary embeddings
	"""
	B, N, _ = ids.shape
	device = ids.device
	# Compute in float32 for precision, cast at the end
	compute_dtype = torch.float32
	output_dtype = dtype if dtype is not None else ids.dtype

	embeddings = []
	dim_offset = 0

	for axis_idx, axis_dim in enumerate(self.axes_dims):
	# Compute frequencies for this axis
	freqs = 1.0 / (self.theta ** (torch.arange(0, axis_dim, 2, device=device, dtype=compute_dtype) / axis_dim))
	# Get positions for this axis
	positions = ids[:, :, axis_idx].to(compute_dtype) # (B, N)
	# Outer product: (B, N) x (axis_dim/2) -> (B, N, axis_dim/2)
	angles = positions.unsqueeze(-1) * freqs.unsqueeze(0).unsqueeze(0)
	# Interleave sin/cos
	emb = torch.stack([angles.cos(), angles.sin()], dim=-1) # (B, N, axis_dim/2, 2)
	emb = emb.flatten(-2) # (B, N, axis_dim)
	embeddings.append(emb)
	dim_offset += axis_dim

	result = torch.cat(embeddings, dim=-1) # (B, N, dim)
	return result.to(output_dtype)


	def apply_rope(x: torch.Tensor, rope: torch.Tensor) -> torch.Tensor:
	"""Apply rotary embeddings to input tensor."""
	# x: (B, heads, N, head_dim)
	# rope: (B, N, head_dim)
	B, H, N, D = x.shape

	# Ensure rope matches x dtype
	rope = rope.to(x.dtype).unsqueeze(1) # (B, 1, N, D)

	# Split into pairs
	x_pairs = x.reshape(B, H, N, D // 2, 2)
	rope_pairs = rope.reshape(B, 1, N, D // 2, 2)

	cos = rope_pairs[..., 0]
	sin = rope_pairs[..., 1]

	x0 = x_pairs[..., 0]
	x1 = x_pairs[..., 1]

	out0 = x0 * cos - x1 * sin
	out1 = x1 * cos + x0 * sin

	return torch.stack([out0, out1], dim=-1).flatten(-2)


	class MLPEmbedder(nn.Module):
	"""MLP for embedding scalars (timestep, guidance)."""
	def __init__(self, hidden_size: int):
	super().__init__()
	self.mlp = nn.Sequential(
	nn.Linear(256, hidden_size),
	nn.SiLU(),
	nn.Linear(hidden_size, hidden_size),
	)

	def forward(self, x: torch.Tensor) -> torch.Tensor:
	# Sinusoidal embedding first
	half_dim = 128
	emb = math.log(10000) / (half_dim - 1)
	emb = torch.exp(torch.arange(half_dim, device=x.device, dtype=x.dtype) * -emb)
	emb = x.unsqueeze(-1) * emb.unsqueeze(0)
	emb = torch.cat([emb.sin(), emb.cos()], dim=-1) # (B, 256)
	return self.mlp(emb)


	class AdaLayerNormZero(nn.Module):
	"""
	AdaLN-Zero for double-stream blocks.
	Outputs 6 modulation params: (shift_msa, scale_msa, gate_msa, shift_mlp, scale_mlp, gate_mlp)
	"""
	def __init__(self, hidden_size: int):
	super().__init__()
	self.silu = nn.SiLU()
	self.linear = nn.Linear(hidden_size, 6 * hidden_size, bias=True)
	self.norm = RMSNorm(hidden_size)

	def forward(
	self, x: torch.Tensor, emb: torch.Tensor
	) -> Tuple[torch.Tensor, torch.Tensor, torch.Tensor, torch.Tensor, torch.Tensor]:
	"""
	Args:
	x: hidden states (B, N, D)
	emb: conditioning embedding (B, D)
	Returns:
	(normed_x, gate_msa, shift_mlp, scale_mlp, gate_mlp)
	"""
	emb_out = self.linear(self.silu(emb))
	shift_msa, scale_msa, gate_msa, shift_mlp, scale_mlp, gate_mlp = emb_out.chunk(6, dim=-1)
	x = self.norm(x) * (1 + scale_msa.unsqueeze(1)) + shift_msa.unsqueeze(1)
	return x, gate_msa, shift_mlp, scale_mlp, gate_mlp


	class AdaLayerNormZeroSingle(nn.Module):
	"""
	AdaLN-Zero for single-stream blocks.
	Outputs 3 modulation params: (shift, scale, gate)
	"""
	def __init__(self, hidden_size: int):
	super().__init__()
	self.silu = nn.SiLU()
	self.linear = nn.Linear(hidden_size, 3 * hidden_size, bias=True)
	self.norm = RMSNorm(hidden_size)

	def forward(
	self, x: torch.Tensor, emb: torch.Tensor
	) -> Tuple[torch.Tensor, torch.Tensor]:
	"""
	Args:
	x: hidden states (B, N, D)
	emb: conditioning embedding (B, D)
	Returns:
	(normed_x, gate)
	"""
	emb_out = self.linear(self.silu(emb))
	shift, scale, gate = emb_out.chunk(3, dim=-1)
	x = self.norm(x) * (1 + scale.unsqueeze(1)) + shift.unsqueeze(1)
	return x, gate


	class Attention(nn.Module):
	"""Multi-head attention with optional RoPE."""
	def __init__(self, hidden_size: int, num_heads: int, head_dim: int):
	super().__init__()
	self.num_heads = num_heads
	self.head_dim = head_dim
	self.scale = head_dim ** -0.5

	self.qkv = nn.Linear(hidden_size, 3 * num_heads * head_dim, bias=False)
	self.out_proj = nn.Linear(num_heads * head_dim, hidden_size, bias=False)

	def forward(
	self,
	x: torch.Tensor,
	rope: Optional[torch.Tensor] = None,
	mask: Optional[torch.Tensor] = None
	) -> torch.Tensor:
	B, N, _ = x.shape
	dtype = x.dtype

	# Ensure RoPE matches input dtype
	if rope is not None:
	rope = rope.to(dtype)

	qkv = self.qkv(x).reshape(B, N, 3, self.num_heads, self.head_dim)
	q, k, v = qkv.permute(2, 0, 3, 1, 4) # 3 x (B, heads, N, head_dim)

	if rope is not None:
	q = apply_rope(q, rope)
	k = apply_rope(k, rope)

	# Scaled dot-product attention
	attn = (q @ k.transpose(-2, -1)) * self.scale
	if mask is not None:
	attn = attn.masked_fill(mask == 0, float('-inf'))
	attn = attn.softmax(dim=-1)

	out = (attn @ v).transpose(1, 2).reshape(B, N, -1)
	return self.out_proj(out)


	class JointAttention(nn.Module):
	"""Joint attention for double-stream blocks (separate Q,K,V for txt and img)."""
	def __init__(self, hidden_size: int, num_heads: int, head_dim: int):
	super().__init__()
	self.num_heads = num_heads
	self.head_dim = head_dim
	self.scale = head_dim ** -0.5

	# Separate projections for text and image
	self.txt_qkv = nn.Linear(hidden_size, 3 * num_heads * head_dim, bias=False)
	self.img_qkv = nn.Linear(hidden_size, 3 * num_heads * head_dim, bias=False)

	self.txt_out = nn.Linear(num_heads * head_dim, hidden_size, bias=False)
	self.img_out = nn.Linear(num_heads * head_dim, hidden_size, bias=False)

	def forward(
	self,
	txt: torch.Tensor,
	img: torch.Tensor,
	rope: Optional[torch.Tensor] = None,
	) -> Tuple[torch.Tensor, torch.Tensor]:
	B, L, _ = txt.shape
	_, N, _ = img.shape

	# Ensure consistent dtype (use img dtype as reference)
	dtype = img.dtype
	txt = txt.to(dtype)
	if rope is not None:
	rope = rope.to(dtype)

	# Compute Q, K, V for both streams
	txt_qkv = self.txt_qkv(txt).reshape(B, L, 3, self.num_heads, self.head_dim)
	img_qkv = self.img_qkv(img).reshape(B, N, 3, self.num_heads, self.head_dim)

	txt_q, txt_k, txt_v = txt_qkv.permute(2, 0, 3, 1, 4)
	img_q, img_k, img_v = img_qkv.permute(2, 0, 3, 1, 4)

	# Apply RoPE to image queries/keys only (text doesn't have positions)
	if rope is not None:
	img_q = apply_rope(img_q, rope)
	img_k = apply_rope(img_k, rope)

	# Concatenate keys and values for joint attention
	k = torch.cat([txt_k, img_k], dim=2) # (B, heads, L+N, head_dim)
	v = torch.cat([txt_v, img_v], dim=2)

	# Text attends to all
	txt_attn = (txt_q @ k.transpose(-2, -1)) * self.scale
	txt_attn = txt_attn.softmax(dim=-1)
	txt_out = (txt_attn @ v).transpose(1, 2).reshape(B, L, -1)

	# Image attends to all
	img_attn = (img_q @ k.transpose(-2, -1)) * self.scale
	img_attn = img_attn.softmax(dim=-1)
	img_out = (img_attn @ v).transpose(1, 2).reshape(B, N, -1)

	return self.txt_out(txt_out), self.img_out(img_out)


	class MLP(nn.Module):
	"""Feed-forward network."""
	def __init__(self, hidden_size: int, mlp_ratio: float = 4.0):
	super().__init__()
	mlp_hidden = int(hidden_size * mlp_ratio)
	self.fc1 = nn.Linear(hidden_size, mlp_hidden)
	self.act = nn.GELU(approximate='tanh')
	self.fc2 = nn.Linear(mlp_hidden, hidden_size)

	def forward(self, x: torch.Tensor) -> torch.Tensor:
	return self.fc2(self.act(self.fc1(x)))


	class DoubleStreamBlock(nn.Module):
	"""
	Double-stream transformer block (MMDiT style).
	Text and image have separate weights but attend to each other.
	Uses AdaLN-Zero with 6 modulation params per stream.
	"""
	def __init__(self, config: TinyFluxConfig):
	super().__init__()
	hidden = config.hidden_size
	heads = config.num_attention_heads
	head_dim = config.attention_head_dim
	mlp_hidden = int(hidden * config.mlp_ratio)

	# AdaLN-Zero for each stream (outputs 6 params each)
	self.img_norm1 = AdaLayerNormZero(hidden)
	self.txt_norm1 = AdaLayerNormZero(hidden)

	# Joint attention (separate QKV projections)
	self.attn = JointAttention(hidden, heads, head_dim)

	# Second norm for MLP (not adaptive, uses params from norm1)
	self.img_norm2 = RMSNorm(hidden)
	self.txt_norm2 = RMSNorm(hidden)

	# MLPs
	self.img_mlp = MLP(hidden, config.mlp_ratio)
	self.txt_mlp = MLP(hidden, config.mlp_ratio)

	def forward(
	self,
	txt: torch.Tensor,
	img: torch.Tensor,
	vec: torch.Tensor,
	rope: Optional[torch.Tensor] = None,
	) -> Tuple[torch.Tensor, torch.Tensor]:
	# Image stream: norm + modulation, get MLP params for later
	img_normed, img_gate_msa, img_shift_mlp, img_scale_mlp, img_gate_mlp = self.img_norm1(img, vec)

	# Text stream: norm + modulation, get MLP params for later
	txt_normed, txt_gate_msa, txt_shift_mlp, txt_scale_mlp, txt_gate_mlp = self.txt_norm1(txt, vec)

	# Joint attention
	txt_attn_out, img_attn_out = self.attn(txt_normed, img_normed, rope)

	# Residual with gate
	txt = txt + txt_gate_msa.unsqueeze(1) * txt_attn_out
	img = img + img_gate_msa.unsqueeze(1) * img_attn_out

	# MLP with modulation (using params from norm1)
	txt_mlp_in = self.txt_norm2(txt) * (1 + txt_scale_mlp.unsqueeze(1)) + txt_shift_mlp.unsqueeze(1)
	img_mlp_in = self.img_norm2(img) * (1 + img_scale_mlp.unsqueeze(1)) + img_shift_mlp.unsqueeze(1)

	txt = txt + txt_gate_mlp.unsqueeze(1) * self.txt_mlp(txt_mlp_in)
	img = img + img_gate_mlp.unsqueeze(1) * self.img_mlp(img_mlp_in)

	return txt, img


	class SingleStreamBlock(nn.Module):
	"""
	Single-stream transformer block.
	Text and image are concatenated and share weights.
	Uses AdaLN-Zero with 3 modulation params (no separate MLP modulation).
	"""
	def __init__(self, config: TinyFluxConfig):
	super().__init__()
	hidden = config.hidden_size
	heads = config.num_attention_heads
	head_dim = config.attention_head_dim
	mlp_hidden = int(hidden * config.mlp_ratio)

	# AdaLN-Zero (outputs 3 params: shift, scale, gate)
	self.norm = AdaLayerNormZeroSingle(hidden)

	# Combined QKV + MLP projection (Flux fuses these)
	# Linear attention: QKV projection
	self.attn = Attention(hidden, heads, head_dim)

	# MLP
	self.mlp = MLP(hidden, config.mlp_ratio)

	# Pre-MLP norm (not modulated in single-stream)
	self.norm2 = RMSNorm(hidden)

	def forward(
	self,
	txt: torch.Tensor,
	img: torch.Tensor,
	vec: torch.Tensor,
	txt_rope: Optional[torch.Tensor] = None,
	img_rope: Optional[torch.Tensor] = None,
	) -> Tuple[torch.Tensor, torch.Tensor]:
	L = txt.shape[1]

	# Concatenate txt and img
	x = torch.cat([txt, img], dim=1)

	# Concatenate RoPE (zeros for text positions)
	if img_rope is not None:
	B, N, D = img_rope.shape
	txt_rope_zeros = torch.zeros(B, L, D, device=img_rope.device, dtype=img_rope.dtype)
	rope = torch.cat([txt_rope_zeros, img_rope], dim=1)
	else:
	rope = None

	# Norm + modulation (only 3 params for single stream)
	x_normed, gate = self.norm(x, vec)

	# Attention with gated residual
	x = x + gate.unsqueeze(1) * self.attn(x_normed, rope)

	# MLP (no separate modulation in single-stream Flux)
	x = x + self.mlp(self.norm2(x))

	# Split back
	txt, img = x.split([L, x.shape[1] - L], dim=1)
	return txt, img


	class TinyFlux(nn.Module):
	"""
	TinyFlux: A scaled-down Flux diffusion transformer.

	Scaling: /12 from original Flux
	- hidden: 3072 → 256
	- heads: 24 → 2
	- head_dim: 128 (preserved)
	- in_channels: 16 (Flux VAE)
	"""
	def __init__(self, config: Optional[TinyFluxConfig] = None):
	super().__init__()
	self.config = config or TinyFluxConfig()
	cfg = self.config

	# Input projections
	self.img_in = nn.Linear(cfg.in_channels, cfg.hidden_size)
	self.txt_in = nn.Linear(cfg.joint_attention_dim, cfg.hidden_size)

	# Conditioning projections
	self.time_in = MLPEmbedder(cfg.hidden_size)
	self.vector_in = nn.Sequential(
	nn.SiLU(),
	nn.Linear(cfg.pooled_projection_dim, cfg.hidden_size)
	)
	if cfg.guidance_embeds:
	self.guidance_in = MLPEmbedder(cfg.hidden_size)

	# RoPE
	self.rope = RotaryEmbedding(cfg.attention_head_dim, cfg.axes_dims_rope)

	# Transformer blocks
	self.double_blocks = nn.ModuleList([
	DoubleStreamBlock(cfg) for _ in range(cfg.num_double_layers)
	])
	self.single_blocks = nn.ModuleList([
	SingleStreamBlock(cfg) for _ in range(cfg.num_single_layers)
	])

	# Output
	self.final_norm = RMSNorm(cfg.hidden_size)
	self.final_linear = nn.Linear(cfg.hidden_size, cfg.in_channels)

	self._init_weights()

	def _init_weights(self):
	"""Initialize weights."""
	def _init(module):
	if isinstance(module, nn.Linear):
	nn.init.xavier_uniform_(module.weight)
	if module.bias is not None:
	nn.init.zeros_(module.bias)
	self.apply(_init)

	# Zero-init output projection for residual
	nn.init.zeros_(self.final_linear.weight)

	def forward(
	self,
	hidden_states: torch.Tensor, # (B, N, in_channels) - image patches
	encoder_hidden_states: torch.Tensor, # (B, L, joint_attention_dim) - T5 tokens
	pooled_projections: torch.Tensor, # (B, pooled_projection_dim) - CLIP pooled
	timestep: torch.Tensor, # (B,) - diffusion timestep
	img_ids: torch.Tensor, # (B, N, 3) - image position ids
	guidance: Optional[torch.Tensor] = None, # (B,) - guidance scale
	) -> torch.Tensor:
	"""
	Forward pass.

	Returns:
	Predicted noise/velocity of shape (B, N, in_channels)
	"""
	# Input projections
	img = self.img_in(hidden_states) # (B, N, hidden)
	txt = self.txt_in(encoder_hidden_states) # (B, L, hidden)

	# Conditioning vector
	vec = self.time_in(timestep)
	vec = vec + self.vector_in(pooled_projections)
	if self.config.guidance_embeds and guidance is not None:
	vec = vec + self.guidance_in(guidance)

	# RoPE for image positions (match model dtype)
	img_rope = self.rope(img_ids, dtype=img.dtype)

	# Double-stream blocks
	for block in self.double_blocks:
	txt, img = block(txt, img, vec, img_rope)

	# Single-stream blocks
	for block in self.single_blocks:
	txt, img = block(txt, img, vec, img_rope=img_rope)

	# Output (image only)
	img = self.final_norm(img)
	img = self.final_linear(img)

	return img

	@staticmethod
	def create_img_ids(batch_size: int, height: int, width: int, device: torch.device) -> torch.Tensor:
	"""Create image position IDs for RoPE."""
	# height, width are in latent space (image_size / 8)
	img_ids = torch.zeros(batch_size, height * width, 3, device=device)

	for i in range(height):
	for j in range(width):
	idx = i * width + j
	img_ids[:, idx, 0] = 0 # temporal (always 0 for images)
	img_ids[:, idx, 1] = i # height
	img_ids[:, idx, 2] = j # width

	return img_ids

	def count_parameters(self) -> dict:
	"""Count parameters by component."""
	counts = {}
	counts['img_in'] = sum(p.numel() for p in self.img_in.parameters())
	counts['txt_in'] = sum(p.numel() for p in self.txt_in.parameters())
	counts['time_in'] = sum(p.numel() for p in self.time_in.parameters())
	counts['vector_in'] = sum(p.numel() for p in self.vector_in.parameters())
	if hasattr(self, 'guidance_in'):
	counts['guidance_in'] = sum(p.numel() for p in self.guidance_in.parameters())
	counts['double_blocks'] = sum(p.numel() for p in self.double_blocks.parameters())
	counts['single_blocks'] = sum(p.numel() for p in self.single_blocks.parameters())
	counts['final'] = sum(p.numel() for p in self.final_norm.parameters()) + \
	sum(p.numel() for p in self.final_linear.parameters())
	counts['total'] = sum(p.numel() for p in self.parameters())
	return counts


	def test_tiny_flux():
	"""Quick test of the model."""
	print("=" * 60)
	print("TinyFlux Model Test")
	print("=" * 60)

	config = TinyFluxConfig()
	print(f"\nConfig:")
	print(f" hidden_size: {config.hidden_size}")
	print(f" num_heads: {config.num_attention_heads}")
	print(f" head_dim: {config.attention_head_dim}")
	print(f" in_channels: {config.in_channels}")
	print(f" double_layers: {config.num_double_layers}")
	print(f" single_layers: {config.num_single_layers}")
	print(f" joint_attention_dim: {config.joint_attention_dim}")
	print(f" pooled_projection_dim: {config.pooled_projection_dim}")

	model = TinyFlux(config)

	# Count parameters
	counts = model.count_parameters()
	print(f"\nParameters:")
	for name, count in counts.items():
	print(f" {name}: {count:,} ({count/1e6:.2f}M)")

	# Test forward pass
	device = 'cuda' if torch.cuda.is_available() else 'cpu'
	model = model.to(device)

	batch_size = 2
	latent_h, latent_w = 64, 64 # 512x512 image / 8
	num_patches = latent_h * latent_w
	text_len = 77

	# Create dummy inputs
	hidden_states = torch.randn(batch_size, num_patches, config.in_channels, device=device)
	encoder_hidden_states = torch.randn(batch_size, text_len, config.joint_attention_dim, device=device)
	pooled_projections = torch.randn(batch_size, config.pooled_projection_dim, device=device)
	timestep = torch.rand(batch_size, device=device)
	img_ids = TinyFlux.create_img_ids(batch_size, latent_h, latent_w, device)
	guidance = torch.ones(batch_size, device=device) * 3.5

	print(f"\nInput shapes:")
	print(f" hidden_states: {hidden_states.shape}")
	print(f" encoder_hidden_states: {encoder_hidden_states.shape}")
	print(f" pooled_projections: {pooled_projections.shape}")
	print(f" img_ids: {img_ids.shape}")

	# Forward pass
	with torch.no_grad():
	output = model(
	hidden_states=hidden_states,
	encoder_hidden_states=encoder_hidden_states,
	pooled_projections=pooled_projections,
	timestep=timestep,
	img_ids=img_ids,
	guidance=guidance,
	)

	print(f"\nOutput shape: {output.shape}")
	print(f"Output range: [{output.min():.4f}, {output.max():.4f}]")
	print("\n✓ Forward pass successful!")


	if __name__ == "__main__":
	test_tiny_flux()