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	# chat.py
	#!/usr/bin/env python3
	# chat.py
	# Copyright (c) 2025 Anemll
	# Licensed under the MIT License

	import argparse
	import os
	import re
	import glob
	from pathlib import Path
	import json
	import sys
	import coremltools as ct
	from transformers import LlamaTokenizer, AutoTokenizer
	import torch
	import torch.nn.functional as F
	import numpy as np
	import queue
	import threading
	import time
	import yaml
	import sys
	import resource


	def _get_rss_mb() -> float:
	"""Best-effort RSS in MB (macOS/Linux)."""
	try:
	# On macOS ru_maxrss is bytes; on Linux it is kilobytes.
	rss = resource.getrusage(resource.RUSAGE_SELF).ru_maxrss
	if rss > 10_000_000: # heuristic: likely bytes
	return rss / (1024 * 1024)
	return rss / 1024 # kB -> MB
	except Exception:
	return -1.0


	def _maybe_report_mem(label: str, enabled: bool):
	if not enabled:
	return
	rss_mb = _get_rss_mb()
	if rss_mb >= 0:
	print(f"[mem] {label}: rss≈{rss_mb:.1f} MB")

	# ANSI color codes
	LIGHT_BLUE = "\033[94m"
	DARK_BLUE = "\033[34m"
	LIGHT_GREEN = "\033[92m"
	RESET_COLOR = "\033[0m"

	# Add at top with other constants
	WARMUP_TOKEN_LIMIT = 10 # Maximum tokens to generate during warmup

	class TokenPrinter:
	"""Handles background printing of generated tokens."""
	def __init__(self, tokenizer):
	self.tokenizer = tokenizer
	self.token_queue = queue.Queue()
	self.stop_event = threading.Event()
	self.thread = None
	self.buffer = ""
	self.lock = threading.Lock()
	self.thinking = True # Track if we're still in thinking mode
	self.decoding_buffer = [] # Buffer for token IDs
	# Add token counting and timing
	self.start_time = time.time()
	self.token_count = 0
	self.start()

	def start(self):
	"""Start the printer thread."""
	if self.thread is None:
	self.thread = threading.Thread(target=self._print_worker)
	self.thread.daemon = True
	self.thread.start()

	def add_token(self, token_id):
	"""Add a token to the print queue."""
	if not self.stop_event.is_set():
	self.token_queue.put(token_id)
	self.token_count += 1

	def drain_buffer(self, eval_mode=False):
	"""Decode token IDs from decoding_buffer in the main thread."""
	if not self.decoding_buffer:
	return

	# Decode all tokens at once in the main thread
	token_str = self.tokenizer.decode(self.decoding_buffer)
	self.decoding_buffer.clear()

	# Store the text in buffer for later saving to file
	with self.lock:
	self.buffer += token_str

	# Skip printing in eval mode
	if eval_mode:
	return

	# Color-handling logic
	if self.thinking and "</think>" in token_str:
	self.thinking = False
	parts = token_str.split("</think>")
	if len(parts) > 0:
	print(parts[0] + "</think>", end='', flush=True)
	if len(parts) > 1:
	print(LIGHT_BLUE + parts[1], end='', flush=True)
	else:
	if not self.thinking:
	print(LIGHT_BLUE + token_str, end='', flush=True)
	else:
	print(token_str, end='', flush=True)

	def _print_worker(self):
	"""Worker thread that takes token_ids from the queue."""
	while not self.stop_event.is_set():
	try:
	token_id = self.token_queue.get(timeout=0.01)
	with self.lock:
	self.decoding_buffer.append(token_id)
	self.token_queue.task_done()
	except queue.Empty:
	continue
	except Exception as e:
	print(f"\nError: Token printer error: {str(e)}")
	break

	def stop(self, eval_mode=False):
	"""Stop the printer thread."""
	if self.thread and self.thread.is_alive():
	# Ensure any remaining tokens are processed
	self.drain_buffer()
	self.stop_event.set()
	try:
	self.thread.join(timeout=1.0)
	except Exception:
	pass
	# Calculate and print tokens/s with shorter format in blue (unless in eval mode)
	if not eval_mode:
	elapsed = time.time() - self.start_time
	if elapsed > 0 and self.token_count > 0:
	tokens_per_sec = self.token_count / elapsed
	print(f"\n{DARK_BLUE}{tokens_per_sec:.1f} t/s{RESET_COLOR}")
	else:
	print(RESET_COLOR) # Reset color at the end
	return self.buffer

	def parse_model_path(path):
	"""Parse model path and return full path with .mlmodelc or .mlpackage extension."""
	path = Path(path)

	# If path exists exactly as specified, return it
	if path.exists():
	return str(path)

	# Try with both extensions
	candidates = [
	path, # Original path
	path.with_suffix('.mlmodelc'), # With .mlmodelc
	path.with_suffix('.mlpackage'), # With .mlpackage
	Path(str(path) + '.mlmodelc'), # Handle case where extension is included
	Path(str(path) + '.mlpackage')
	]

	# Try all possible paths
	for candidate in candidates:
	if candidate.exists():
	return str(candidate)

	# If embeddings with LUT suffix not found, try without LUT suffix
	if "_lut" in str(path) and "embeddings" in str(path):
	print(f"Failed to find {path}, trying without LUT suffix...")
	# Remove LUT suffix
	path_no_lut = str(path).split("_lut")[0]
	path_no_lut = Path(path_no_lut)

	# Try candidates without LUT suffix
	candidates_no_lut = [
	path_no_lut,
	path_no_lut.with_suffix('.mlmodelc'),
	path_no_lut.with_suffix('.mlpackage'),
	Path(str(path_no_lut) + '.mlmodelc'),
	Path(str(path_no_lut) + '.mlpackage')
	]

	for candidate in candidates_no_lut:
	if candidate.exists():
	return str(candidate)

	# Add no-LUT candidates to the list for error reporting
	candidates.extend(candidates_no_lut)

	# If FFN path isn't chunked, try to find chunked variants.
	path_str = str(path)
	base_str = str(path.with_suffix('')) if path.suffix in ('.mlmodelc', '.mlpackage') else path_str
	if "_chunk_" not in base_str:
	chunk_pattern = f"{base_str}_chunk_of"
	chunk_candidates = sorted(glob.glob(chunk_pattern + ".mlmodelc"))
	if not chunk_candidates:
	chunk_candidates = sorted(glob.glob(chunk_pattern + ".mlpackage"))
	if chunk_candidates:
	return str(Path(chunk_candidates[0]))
	candidates.extend([Path(p) for p in sorted(glob.glob(chunk_pattern + ".mlmodelc"))])
	candidates.extend([Path(p) for p in sorted(glob.glob(chunk_pattern + ".mlpackage"))])

	# If we get here, no valid path was found
	print("\nError: Model not found. Tried following paths:")
	for candidate in candidates:
	print(f" {candidate}")
	raise FileNotFoundError(f"Model not found: {path}")

	def build_stop_token_ids(tokenizer):
	"""Collect token IDs that should stop generation."""
	def _get_token_id_if_present(token_str):
	if not token_str:
	return None
	if hasattr(tokenizer, "get_vocab"):
	vocab = tokenizer.get_vocab()
	if token_str in vocab:
	return vocab[token_str]
	token_id = tokenizer.convert_tokens_to_ids(token_str)
	if isinstance(token_id, list):
	if len(token_id) == 1:
	token_id = token_id[0]
	else:
	return None
	if token_id is None:
	return None
	if tokenizer.unk_token_id is not None and token_id == tokenizer.unk_token_id:
	return None
	return token_id

	stop_ids = set()
	eos_token_ids = tokenizer.eos_token_id
	if isinstance(eos_token_ids, list):
	stop_ids.update(eos_token_ids)
	elif eos_token_ids is not None:
	stop_ids.add(eos_token_ids)

	for token_str in ("<\|endoftext\|>", "<end_of_turn>", "<\|eot_id\|>"):
	token_id = _get_token_id_if_present(token_str)
	if token_id is not None:
	stop_ids.add(token_id)

	return stop_ids

	def parse_ffn_filename(path):
	"""Parse FFN model filename to extract chunk information."""
	path = Path(path)
	# Support multiple naming conventions:
	# - FFN_PF_lut6_chunk_01of04 (legacy/prefill style)
	# - gemma3_1b_FFN_lut6_chunk_01of04 (new Gemma3 style)
	# - any_prefix_FFN_*_chunk_NNofNN
	pattern = r'FFN[^/]*_chunk_(\d+)of(\d+)'
	match = re.search(pattern, path.name)

	if match:
	current_chunk = int(match.group(1))
	total_chunks = int(match.group(2))
	return current_chunk, total_chunks
	return None, None

	def find_all_chunks(base_path):
	"""Find all chunk files matching the base FFN path pattern."""
	path = Path(base_path)
	pattern = re.sub(r'_chunk_\d+of\d+', '_chunk_*', str(path))
	return sorted(glob.glob(pattern))

	def load_model(path, function_name=None, compute_unit=None):
	"""Load a CoreML model, handling both .mlmodelc and .mlpackage formats."""
	path = Path(path)
	if compute_unit is None:
	compute_unit = ct.ComputeUnit.CPU_AND_NE

	try:
	if path.suffix == '.mlmodelc':
	# For compiled models (.mlmodelc), use CompiledMLModel
	if function_name:
	return ct.models.CompiledMLModel(str(path), compute_unit, function_name=function_name)
	else:
	return ct.models.CompiledMLModel(str(path), compute_unit)
	else:
	# For packages (.mlpackage)
	if function_name:
	return ct.models.MLModel(str(path), function_name=function_name)
	else:
	return ct.models.MLModel(str(path))

	except RuntimeError as e:
	if "valid manifest does not exist" in str(e):
	print(f"\nError: Could not load compiled model at {path}")
	print("This might be because:")
	print("1. The model is not properly compiled")
	print("2. The model was compiled for a different OS version")
	print("3. The model needs to be recompiled")
	print("\nTry using the .mlpackage version instead, or recompile the model.")
	raise

	def load_metadata(model,args):
	# Extract metadata and config parameters
	metadata = {}
	if hasattr(model, 'user_defined_metadata'):
	meta = model.user_defined_metadata

	# Extract key parameters with defaults
	metadata['context_length'] = int(meta.get('com.anemll.context_length', 512))
	metadata['state_length'] = int(meta.get('com.anemll.state_length', metadata['context_length'])) # Added state_length
	metadata['batch_size'] = int(meta.get('com.anemll.batch_size', 64))
	metadata['lut_bits'] = int(meta.get('com.anemll.lut_bits', 0))
	metadata['num_chunks'] = int(meta.get('com.anemll.num_chunks', 1))

	if not args.eval:
	print("\nExtracted Parameters:")
	print(f" Context Length: {metadata['context_length']}")
	print(f" State Length: {metadata['state_length']}")
	print(f" Prefill Batch Size: {metadata['batch_size']}")
	print(f" LUT Bits: {metadata['lut_bits']}")
	print(f" Number of Chunks: {metadata['num_chunks']}")

	# Print model info
	print("\nModel Info:")
	if 'com.anemll.info' in meta:
	print(f" {meta['com.anemll.info']}")
	if 'com.github.apple.coremltools.version' in meta:
	print(f" CoreML Tools: {meta['com.github.apple.coremltools.version']}")

	# Print model input/output shapes
	print("\nModel Shapes:")
	if hasattr(model, 'input_description'):
	print(" Inputs:")
	try:
	if hasattr(model.input_description, 'items'):
	for name, desc in model.input_description.items():
	print(f" {name}: {desc}")
	else:
	print(f" {model.input_description}")
	except:
	print(f" Input description: {type(model.input_description)}")
	if hasattr(model, 'output_description'):
	print(" Outputs:")
	try:
	if hasattr(model.output_description, 'items'):
	for name, desc in model.output_description.items():
	print(f" {name}: {desc}")
	else:
	print(f" {model.output_description}")
	except:
	print(f" Output description: {type(model.output_description)}")
	else:
	if not args.eval:
	print("\nWarning: No metadata found in model")

	# Check if model directory name contains context length pattern (ctxXXX)
	ctx_len = 512
	if args.context_length is None:
	import re
	ctx_match = re.search(r'ctx(\d+)', str(args.d))
	if ctx_match:
	ctx_len0 = int(ctx_match.group(1))
	if 512 <= ctx_len0 <= 8096:
	ctx_len = ctx_len0
	print(f"\nDetected context length {ctx_len} from directory name")
	else:
	print(f"\nWarning: No context length found in directory {ctx_len} from directory name {args.d}")
	else:
	ctx_len = args.context_length

	# Use defaults or values from args
	metadata['context_length'] = ctx_len
	metadata['state_length'] = ctx_len
	# Get batch size from args or use default
	metadata['batch_size'] = getattr(args, 'batch_size', 64)
	metadata['lut_bits'] = 4
	metadata['num_chunks'] = getattr(args, 'num_chunks', 4)
	if not args.eval:
	print("\nUsing parameters:")
	print(f" Context Length: {metadata['context_length']}")
	print(f" State Length: {metadata['state_length']}")
	print(f" Prefill Batch Size: {metadata['batch_size']}")
	print(f" LUT Bits: {metadata['lut_bits']}")
	print(f" Number of Chunks: {metadata['num_chunks']}")

	# Override with values from args if they exist
	if hasattr(args, 'batch_size') and args.batch_size is not None:
	metadata['batch_size'] = args.batch_size
	if not args.eval:
	print(f"\nOverriding batch size from args: {args.batch_size}")
	if hasattr(args, 'num_chunks') and args.num_chunks is not None:
	metadata['num_chunks'] = args.num_chunks
	if not args.eval:
	print(f"\nOverriding num chunks from args: {args.num_chunks}")

	return metadata

	def load_models(args,metadata):
	"""Load all required models and extract metadata."""
	if not args.eval:
	print("\nLoading models...")
	_maybe_report_mem("start load_models", getattr(args, "mem_report", False))

	# Determine compute unit
	compute_unit = ct.ComputeUnit.CPU_ONLY if getattr(args, 'cpu', False) else ct.ComputeUnit.CPU_AND_NE
	if not args.eval and getattr(args, 'cpu', False):
	print("Running in CPU-only mode")

	try:
	# Load embeddings model
	if not args.eval:
	print("\nLoading embeddings model...")
	embed_path = parse_model_path(args.embed)
	if not args.eval:
	print(f"Loading from: {embed_path}")
	embed_model = load_model(embed_path, compute_unit=compute_unit)
	if not args.eval:
	print("Embeddings model loaded successfully")
	_maybe_report_mem("after embeddings load", getattr(args, "mem_report", False))
	metadata = load_metadata(embed_model,args)



	# Load LM head model
	if not args.eval:
	print("\nLoading LM head model...")
	lmhead_path = parse_model_path(args.lmhead)
	if not args.eval:
	print(f"Loading from: {lmhead_path}")
	lmhead_model = load_model(lmhead_path, compute_unit=compute_unit)
	if not args.eval:
	print("LM head model loaded successfully")
	_maybe_report_mem("after lmhead load", getattr(args, "mem_report", False))

	# Parse FFN path and find chunks if needed
	if not args.eval:
	print("\nLoading FFN+PREFILL model(s)...")
	ffn_path = parse_model_path(args.ffn)
	chunk_no, total_chunks = parse_ffn_filename(ffn_path)

	ffn_models = []
	if chunk_no and total_chunks:
	if not args.eval:
	print(f"\nDetected chunked FFN+PREFILL model ({total_chunks} chunks)")
	# Find and load all chunks
	chunk_paths = find_all_chunks(ffn_path)
	if len(chunk_paths) != total_chunks:
	raise ValueError(f"Found {len(chunk_paths)} chunks but filename indicates {total_chunks} chunks")

	for chunk_path in chunk_paths:
	if not args.eval:
	print(f"\nLoading FFN+PREFILL chunk: {Path(chunk_path).name}")
	try:
	# For chunked models, we need both infer and prefill functions
	chunk_dict = {
	'infer': load_model(chunk_path, function_name='infer', compute_unit=compute_unit),
	'prefill': load_model(chunk_path, function_name='prefill', compute_unit=compute_unit)
	}
	# Try to load rotation functions (Gemma3 with context > 512)
	try:
	chunk_dict['infer_rotate'] = load_model(chunk_path, function_name='infer_rotate', compute_unit=compute_unit)
	chunk_dict['prefill_rotate'] = load_model(chunk_path, function_name='prefill_rotate', compute_unit=compute_unit)
	if not args.eval:
	print(" Rotation functions loaded (4-function model)")
	except Exception:
	# Rotation functions not available - standard 2-function model
	pass
	ffn_models.append(chunk_dict)
	if not args.eval:
	print("Chunk loaded successfully")
	_maybe_report_mem(f"after FFN chunk load {Path(chunk_path).name}", getattr(args, "mem_report", False))
	except Exception as e:
	if not args.eval:
	print(f"Error loading chunk {chunk_path}: {str(e)}")
	raise
	metadata = load_metadata(ffn_models[0],args)

	else:
	if not args.eval:
	print("\nLoading single FFN model...")
	ffn_models.append(load_model(ffn_path, compute_unit=compute_unit))
	if not args.eval:
	print("FFN model loaded successfully")
	_maybe_report_mem("after FFN load", getattr(args, "mem_report", False))

	return embed_model, ffn_models, lmhead_model, metadata

	except Exception as e:
	print(f"\nError loading models: {str(e)}")
	print("\nPlease ensure all model files exist and are accessible.")
	print("Expected files:")
	print(f" Embeddings: {args.embed}")
	print(f" LM Head: {args.lmhead}")
	print(f" FFN: {args.ffn}")
	raise

	# At the top of the file, make this a default path

	def initialize_tokenizer(model_path=None, eval_mode=False):
	"""Initialize and configure the tokenizer."""
	try:


	tokenizer = AutoTokenizer.from_pretrained(
	str(model_path),
	use_fast=False,
	trust_remote_code=True
	)

	# Try to load a chat template if the tokenizer doesn't have one.
	if getattr(tokenizer, "chat_template", None) in (None, "") and model_path:
	template = None
	config_path = Path(model_path) / "tokenizer_config.json"
	if config_path.exists():
	try:
	config_data = json.loads(config_path.read_text())
	template = config_data.get("chat_template")
	except Exception as e:
	if not eval_mode:
	print(f"Warning: Failed to read tokenizer_config.json chat_template: {e}")
	if template is None:
	jinja_path = Path(model_path) / "chat_template.jinja"
	if jinja_path.exists():
	template = jinja_path.read_text()
	if template:
	tokenizer.chat_template = template
	if not eval_mode:
	print("Loaded chat_template from model files")

	if not eval_mode:
	print("\nTokenizer Configuration:")
	print(f"Tokenizer type: {type(tokenizer)}")
	print(f"Tokenizer name: {tokenizer.__class__.__name__}")
	print(f"Vocabulary size: {len(tokenizer)}")
	print(f"Model max length: {tokenizer.model_max_length}")

	if tokenizer.pad_token is None:
	tokenizer.pad_token = tokenizer.eos_token
	tokenizer.pad_token_id = tokenizer.eos_token_id
	if not eval_mode:
	print("Set PAD token to EOS token")

	tokenizer.padding_side = "left"

	if not eval_mode:
	print(f"\nSpecial Tokens:")
	print(f"PAD token: '{tokenizer.pad_token}' (ID: {tokenizer.pad_token_id})")
	print(f"EOS token: '{tokenizer.eos_token}' (ID: {tokenizer.eos_token_id})")
	print(f"BOS token: '{tokenizer.bos_token}' (ID: {tokenizer.bos_token_id})")
	print(f"UNK token: '{tokenizer.unk_token}' (ID: {tokenizer.unk_token_id})")

	return tokenizer

	except Exception as e:
	print(f"\nError: Failed to load tokenizer from {model_path}")
	print(f"Error details: {str(e)}")
	print(f"Error type: {type(e)}")
	print("\nThis appears to be a tokenizer loading issue.")

	# Check if it's the specific Qwen tokenizer file issue
	if "expected str, bytes or os.PathLike object, not NoneType" in str(e):
	print("\nThis error suggests the tokenizer files are missing or incomplete.")
	print("For Qwen models, you need the original model directory with tokenizer files.")
	print("Try using: --tokenizer ~/.cache/huggingface/hub/models--Qwen--Qwen3-0.6B/snapshots/YOUR_SNAPSHOT_ID")
	else:
	print("Please provide the path to a compatible model directory with tokenizer files.")
	import traceback
	traceback.print_exc()
	raise



	def make_causal_mask(length, start):
	"""Create causal attention mask."""
	mask = np.full((1, 1, length, length), -np.inf, dtype=np.float16)
	row_indices = np.arange(length).reshape(length, 1)
	col_indices = np.arange(length).reshape(1, length)
	mask[:, :, col_indices <= (row_indices + start)] = 0
	return mask

	def initialize_causal_mask(context_length, eval_mode=False):
	"""Initialize causal mask for transformer attention."""
	causal_mask = make_causal_mask(context_length, 0)
	causal_mask = torch.tensor(causal_mask, dtype=torch.float16)
	if not eval_mode:
	print(f"\nInitialized causal mask for context length {context_length}")
	return causal_mask

	def run_prefill(embed_model, ffn_models, input_ids, context_pos, context_length, batch_size=64, state=None, causal_mask=None, sliding_window=None):
	"""Run prefill on the input sequence.

	For Gemma3 with 4-function models:
	- Uses 'prefill' for positions < sliding_window
	- Uses 'prefill_rotate' for positions >= sliding_window (if available)
	"""
	# Use provided causal mask or create one if not provided
	if causal_mask is None:
	causal_mask = make_causal_mask(context_length, 0)
	causal_mask = torch.tensor(causal_mask, dtype=torch.float16)

	# Check if rotation functions are available
	has_rotation = isinstance(ffn_models[0], dict) and 'prefill_rotate' in ffn_models[0]

	# If no rotation or no sliding_window, use standard prefill
	if not has_rotation or sliding_window is None:
	sliding_window = context_length # Effectively disables rotation mode

	# Process in batches
	batch_pos = 0
	while batch_pos < context_pos:
	batch_end = min(batch_pos + batch_size, context_pos)
	current_batch_size = batch_end - batch_pos

	# Get current batch
	batch_input = input_ids[:, batch_pos:batch_end]

	# Always pad to full batch size for prefill
	batch_input = F.pad(
	batch_input,
	(0, batch_size - current_batch_size),
	value=0
	)

	# Generate position IDs for full batch size
	position_ids = torch.arange(batch_pos, batch_pos+batch_size, dtype=torch.int32) # Changed: Always use full batch size
	batch_causal_mask = causal_mask[:, :, batch_pos:batch_pos+batch_size, :] # Changed: Use full batch size

	# Run embeddings
	hidden_states = torch.from_numpy(
	embed_model.predict({
	'input_ids': batch_input.numpy().astype(np.int32)
	})['hidden_states']
	)

	# Determine which prefill function to use based on position
	# Use prefill_rotate for positions >= sliding_window
	prefill_func_name = 'prefill_rotate' if batch_pos >= sliding_window and has_rotation else 'prefill'

	# Run through FFN chunks with state
	for ffn_model in ffn_models:
	if isinstance(ffn_model, dict):
	inputs = {
	'hidden_states': hidden_states.numpy().astype(np.float16), # [1, 64, hidden_size]
	'position_ids': position_ids.numpy().astype(np.int32), # [64]
	'causal_mask': batch_causal_mask.numpy().astype(np.float16), # [1, 1, 64, context_length]
	'current_pos': np.array([batch_pos], dtype=np.int32) # [1]
	}
	output = ffn_model[prefill_func_name].predict(inputs, state)
	hidden_states = torch.from_numpy(output['output_hidden_states'])

	batch_pos = batch_end

	return torch.tensor([context_pos], dtype=torch.int32)

	def generate_next_token(embed_model, ffn_models, lmhead_model, input_ids, pos, context_length, metadata, state=None, causal_mask=None, temperature=0.0):
	"""Generate the next token.

	For Gemma3 with 4-function models:
	- Uses 'infer' for positions < sliding_window
	- Uses 'infer_rotate' for positions >= sliding_window (if available)
	"""
	debug = metadata.get('debug', False)
	attention_size = metadata.get('attention_size', context_length)
	sliding_window = metadata.get('sliding_window', None)

	# Check if rotation functions are available
	has_rotation = isinstance(ffn_models[0], dict) and 'infer_rotate' in ffn_models[0]

	# Determine which infer function to use
	# Use infer_rotate for positions >= sliding_window (0-indexed, so pos-1 is the actual position)
	use_rotation = has_rotation and sliding_window is not None and (pos - 1) >= sliding_window
	infer_func_name = 'infer_rotate' if use_rotation else 'infer'

	# Get current token
	current_token = input_ids[:, pos-1:pos] # [1, 1]

	# Ensure proper data type for CoreML
	current_token_array = current_token.numpy().astype(np.int32)

	# Run embeddings
	hidden_states = torch.from_numpy(
	embed_model.predict({'input_ids': current_token_array})['hidden_states']
	) # [1, 1, hidden_size]

	# Create masks
	update_mask = torch.zeros((1, 1, context_length, 1), dtype=torch.float16)
	update_mask[0, 0, pos-1, 0] = 1.0
	position_ids = torch.tensor([pos-1], dtype=torch.int32) # [1]

	# Use provided causal mask or create one if not provided
	if causal_mask is None:
	causal_mask_data = make_causal_mask(context_length, 0)
	single_causal_mask = torch.tensor(causal_mask_data[:, :, pos-1:pos, :], dtype=torch.float16) # [1, 1, 1, context_length]
	else:
	single_causal_mask = causal_mask[:, :, pos-1:pos, :]

	if debug:
	print(f"\n[DEBUG] generate_next_token: pos={pos}, context_length={context_length}, attention_size={attention_size}")
	print(f"[DEBUG] position_ids={position_ids.item()}, current_token={current_token.item()}")
	print(f"[DEBUG] causal_mask shape={single_causal_mask.shape}")
	print(f"[DEBUG] hidden_states shape={hidden_states.shape}")

	# Run through FFN chunks with state
	for ffn_model in ffn_models:
	if isinstance(ffn_model, dict):
	# Build inputs dict - only include inputs that the model expects
	inputs = {
	'hidden_states': hidden_states.numpy().astype(np.float16),
	'position_ids': position_ids.numpy().astype(np.int32),
	'causal_mask': single_causal_mask.numpy().astype(np.float16),
	'current_pos': position_ids.numpy().astype(np.int32)
	}
	# Add update_mask only if model expects it (older models)
	# Get model input names from the spec
	try:
	model_inputs = {inp.name for inp in ffn_model[infer_func_name].get_spec().description.input}
	except:
	model_inputs = set()
	if 'update_mask' in model_inputs:
	inputs['update_mask'] = update_mask.numpy().astype(np.float16)
	if debug:
	print(f"[DEBUG] FFN {infer_func_name} inputs: position_ids={inputs['position_ids']}, current_pos={inputs['current_pos']}")
	print(f"[DEBUG] FFN {infer_func_name} causal_mask shape={inputs['causal_mask'].shape}")
	try:
	output = ffn_model[infer_func_name].predict(inputs, state)
	except Exception as e:
	print(f"\n[ERROR] FFN {infer_func_name} failed at pos={pos}, position_ids={position_ids.item()}")
	print(f"[ERROR] context_length={context_length}, attention_size={attention_size}")
	print(f"[ERROR] causal_mask shape={single_causal_mask.shape}")
	print(f"[ERROR] Exception: {e}")
	raise
	hidden_states = torch.from_numpy(output['output_hidden_states'])

	# Run LM head
	lm_output = lmhead_model.predict({'hidden_states': hidden_states.numpy().astype(np.float16)})

	# Check if model uses argmax_in_model mode (outputs argmax_idx/argmax_val instead of logits)
	argmax_in_model = metadata.get('argmax_in_model', False)

	# Debug: show LM head output keys if argmax mode expected but not found
	if argmax_in_model and 'argmax_idx' not in lm_output:
	print(f"\n[WARNING] argmax_in_model=True but model outputs: {list(lm_output.keys())}")
	print("[WARNING] Model may need to be reconverted with --argmax flag")
	# Fall through to logits processing

	if argmax_in_model and 'argmax_idx' in lm_output:
	# Argmax-in-model mode: find the chunk with highest value and compute global index
	# Model outputs LOCAL indices (0 to chunk_size-1) for each chunk
	# We compute: global_idx = local_idx + (best_chunk * chunk_size)
	argmax_idx = lm_output['argmax_idx'] # shape: [num_chunks], LOCAL indices
	argmax_val = lm_output['argmax_val'] # shape: [num_chunks]

	# Flatten arrays
	argmax_idx_flat = argmax_idx.flatten()
	argmax_val_flat = argmax_val.flatten()

	# Find best chunk (highest value)
	best_chunk = int(np.argmax(argmax_val_flat))
	local_idx = int(argmax_idx_flat[best_chunk])

	# Compute global index: local_idx + (best_chunk * chunk_size)
	num_chunks = len(argmax_idx_flat)
	chunk_size = 262144 // num_chunks # Gemma3 vocab = 262144
	global_idx = local_idx + (best_chunk * chunk_size)

	if metadata.get('debug_argmax', False):
	print(f"\nLM head argmax mode (chunked):")
	print(f" argmax_idx shape: {argmax_idx.shape}, dtype: {argmax_idx.dtype}")
	print(f" argmax_val shape: {argmax_val.shape}, dtype: {argmax_val.dtype}")
	print(f" best_chunk={best_chunk}, local_idx={local_idx}, global_idx={global_idx}")
	print(f" best_val={argmax_val_flat[best_chunk]:.4f}")

	return global_idx

	# Get number of logits from metadata, using split_lm_head if available
	# First check for split_lm_head (new), then num_logits (legacy), default to 8
	num_logits = metadata.get('split_lm_head', metadata.get('num_logits', 8))

	# Combine logits1-N if they exist
	if 'logits1' in lm_output:
	# Concatenate all logits parts
	logits_parts = []
	for i in range(1, num_logits + 1):
	key = f'logits{i}'
	if key in lm_output:
	logits_parts.append(torch.from_numpy(lm_output[key]))
	logits = torch.cat(logits_parts, dim=-1) # Concatenate along vocab dimension
	else:
	# Try output_logits as fallback
	logits = torch.from_numpy(lm_output['output_logits'])

	# Apply temperature and sample
	if temperature > 0:
	logits = logits / temperature
	probs = F.softmax(logits[0, -1, :], dim=-1)
	next_token = torch.multinomial(probs, num_samples=1).item()
	else:
	next_token = torch.argmax(logits[0, -1, :]).item()

	return next_token

	def create_unified_state(ffn_models, context_length, eval_mode=False):
	"""Create unified KV cache state for transformer."""
	if isinstance(ffn_models[0], dict):
	# Use first FFN model's prefill function to create state
	state = ffn_models[0]['prefill'].make_state()
	if not eval_mode:
	print(f"\nCreated unified transformer state for {len(ffn_models)} chunks")
	return state
	else:
	state = ffn_models[0].make_state()
	if not eval_mode:
	print("\nCreated unified transformer state")
	return state

	def chat_loop(embed_model, ffn_models, lmhead_model, tokenizer, metadata, state, causal_mask=None, auto_prompt=None, warmup=False, save_file=None, max_tokens=None, no_template=False, eval_mode=False):
	"""Interactive chat loop."""
	context_length = metadata.get('context_length')
	batch_size = metadata.get('batch_size', 64)

	if not warmup and not eval_mode:
	print(f"\nUsing context length: {context_length}")
	print("\nStarting chat session. Press Ctrl+D to exit.")
	print("Type your message and press Enter to chat.")

	# Check if tokenizer has chat template and if it works
	has_chat_template = False
	try:
	# Test if chat template works
	test_messages = [{"role": "user", "content": "test"}]
	tokenizer.apply_chat_template(test_messages, return_tensors="pt")
	has_chat_template = True
	if not warmup and not eval_mode:
	print("\nUsing chat template for prompts")
	except:
	if not warmup and not eval_mode:
	print("\nUsing manual formatting for prompts")

	stop_token_ids = build_stop_token_ids(tokenizer)

	conversation = []

	try:
	while True:
	try:
	if not warmup and not eval_mode:
	print(f"\n{LIGHT_GREEN}You:{RESET_COLOR}", end=' ', flush=True)
	if auto_prompt is not None:
	user_input = auto_prompt
	if not warmup and not eval_mode:
	print(user_input)
	else:
	user_input = input().strip()
	except EOFError:
	if not warmup and not eval_mode:
	print("\nExiting chat...")
	break

	if not user_input:
	continue

	# Format prompt based on no_template flag and tokenizer capabilities
	if no_template:
	# Use raw input without any chat template formatting
	input_ids = tokenizer(
	user_input,
	return_tensors="pt",
	add_special_tokens=True
	).input_ids.to(torch.int32)
	if not warmup and not eval_mode:
	print("Using raw input without chat template")
	elif has_chat_template:
	messages = [{"role": "user", "content": user_input}]
	input_ids = tokenizer.apply_chat_template(
	messages,
	return_tensors="pt",
	add_generation_prompt=True
	).to(torch.int32)
	else:
	# Manual formatting for Llama models without chat template
	formatted_prompt = f"[INST] {user_input} [/INST]"
	input_ids = tokenizer(
	formatted_prompt,
	return_tensors="pt",
	add_special_tokens=True
	).input_ids.to(torch.int32)

	context_pos = input_ids.size(1)

	if not warmup and not eval_mode:
	print(f"\n{LIGHT_BLUE}Assistant:{RESET_COLOR}", end=' ', flush=True)

	# Initialize token printer
	token_printer = TokenPrinter(tokenizer)
	tokens_generated = 0 # Track number of tokens

	try:
	# Start prefill timing
	prefill_start = time.time()

	# Run prefill with state and causal mask
	# Ensure batch_size is not None
	if batch_size is None:
	batch_size = 64
	if not eval_mode:
	print(f"Warning: batch_size was None, using default: {batch_size}")

	# Get sliding_window for rotation support (Gemma3)
	sliding_window = metadata.get('sliding_window', None)

	_ = run_prefill(
	embed_model,
	ffn_models,
	input_ids,
	context_pos,
	context_length,
	batch_size,
	state,
	causal_mask,
	sliding_window
	)

	# Calculate prefill timing
	prefill_time = time.time() - prefill_start
	prefill_tokens = context_pos # Number of tokens in input
	prefill_tokens_per_sec = prefill_tokens / prefill_time if prefill_time > 0 else 0

	# Generation loop with state
	input_ids = input_ids
	pos = context_pos
	inference_start = time.time()
	inference_tokens = 0

	while pos < context_length - 1:
	# Generate next token with causal mask
	next_token = generate_next_token(
	embed_model,
	ffn_models,
	lmhead_model,
	input_ids,
	pos,
	context_length,
	metadata,
	state,
	causal_mask
	)

	# Add token to sequence
	if pos < input_ids.size(1):
	input_ids[0, pos] = next_token
	else:
	input_ids = torch.cat([
	input_ids,
	torch.tensor([[next_token]], dtype=torch.int32)
	], dim=1)

	# Add to printer only if not in warmup
	if not warmup:
	token_printer.add_token(next_token)
	token_printer.drain_buffer(eval_mode)

	pos += 1
	tokens_generated += 1
	inference_tokens += 1

	# Check limits
	if warmup and tokens_generated >= WARMUP_TOKEN_LIMIT:
	break

	# Check max_tokens limit
	if max_tokens is not None and tokens_generated >= max_tokens:
	break

	if next_token in stop_token_ids:
	break

	# Calculate inference timing
	inference_time = time.time() - inference_start
	inference_tokens_per_sec = inference_tokens / inference_time if inference_time > 0 else 0

	# Get final response and add to conversation
	if not warmup:
	response = token_printer.stop(eval_mode)
	if eval_mode:
	# In eval mode, only print the model response
	print(response, end='')
	else:
	# Print timing stats
	prefill_ms = prefill_time * 1000 # Convert to milliseconds
	print(f"\nPrefill: {prefill_ms:.1f}ms ({prefill_tokens_per_sec:.1f} t/s)")
	print(f"Inference: {inference_tokens_per_sec:.1f} t/s")
	print(f"Total: Generated {tokens_generated} tokens in {prefill_time + inference_time:.2f}s")
	conversation.append({"role": "assistant", "content": response})

	# Save response to file if requested
	if save_file and not eval_mode:
	try:
	# Add small delay to ensure all tokens are processed
	time.sleep(0.5)

	# Make sure response ends with EOS token if it's supposed to
	if response and not response.endswith("<\|eot_id\|>") and not response.endswith("</s>") and not response.endswith("<end_of_turn>"):
	if tokenizer.eos_token:
	eos_text = tokenizer.decode([tokenizer.eos_token_id])
	if not response.endswith(eos_text):
	print(f"\n{DARK_BLUE}Adding missing EOS token for consistency{RESET_COLOR}")
	response += eos_text

	with open(save_file, 'w') as f:
	f.write(response)
	print(f"\n{DARK_BLUE}Response saved to file: {save_file}{RESET_COLOR}")
	except Exception as e:
	print(f"\n{DARK_BLUE}Error saving to file: {str(e)}{RESET_COLOR}")
	else:
	token_printer.stop(eval_mode) # Clean up without printing stats

	# Exit after one response in auto_prompt mode
	if auto_prompt is not None:
	break

	except KeyboardInterrupt:
	if not eval_mode:
	print("\nGeneration interrupted")
	token_printer.stop(eval_mode)
	continue

	except Exception as e:
	print(f"\nError in chat loop: {str(e)}")
	import traceback
	traceback.print_exc()

	def parse_args():
	parser = argparse.ArgumentParser(description='Chat with CoreML LLaMA, gil resolved (c) 2025 Anemll')

	# Add meta.yaml option
	parser.add_argument('--meta', type=str, help='Path to meta.yaml to load all parameters')

	# Model paths
	parser.add_argument('--d', '--dir', type=str, default='.',
	help='Directory containing model files (default: current directory)')
	parser.add_argument('--embed', type=str, required=False,
	help='Path to embeddings model (relative to --dir)')
	parser.add_argument('--ffn', type=str, required=False,
	help='Path to FFN model (can be chunked, relative to --dir)')
	parser.add_argument('--lmhead', type=str, required=False,
	help='Path to LM head model (relative to --dir)')
	parser.add_argument('--tokenizer', type=str, required=False,
	help='Path to tokenizer')

	# Add new argument for auto-generation
	parser.add_argument('--prompt', type=str,
	help='If specified, run once with this prompt and exit')

	# Add save option
	parser.add_argument('--save', type=str,
	help='Save assistant\'s response to specified file')

	# Add max-tokens option
	parser.add_argument('--max-tokens', type=int,
	help='Maximum number of tokens to generate')

	# Add no-warmup flag
	parser.add_argument('--nw', action='store_true',
	help='Skip warmup phase')

	# Add no-template flag
	parser.add_argument('--no-template', action='store_true',
	help='Prefill the question itself and start inference directly without chat template')

	# Add eval mode flag
	parser.add_argument('--eval', action='store_true',
	help='Evaluation mode: suppress all output except model response')

	# Add CPU-only mode
	parser.add_argument('--cpu', action='store_true',
	help='Run on CPU only (no ANE/GPU)')
	parser.add_argument('--mem-report', action='store_true',
	help='Print approximate RSS after large steps (debugging)')

	# Model configuration
	parser.add_argument('--context-length', type=int,
	help='Context length for the model (default: 512), if not provided, it will be detected from the model directory name ctxNUMBER')
	parser.add_argument('--batch-size', type=int,
	help='Batch size for prefill (default: 64)')
	parser.add_argument('--num-logits', type=int, default=8,
	help='Number of logits outputs from LM head (default: 8, legacy)')
	parser.add_argument('--split-lm-head', type=int,
	help='Number of logits splits from LM head (default: 8 for llama, 16 for qwen)')
	parser.add_argument('--debug-argmax', action='store_true',
	help='Enable debug output for argmax mode (print indices and values)')
	parser.add_argument('--debug', action='store_true',
	help='Enable debug output (position, state, shapes)')

	args = parser.parse_args()

	def _strip_model_ext(value):
	if value is None:
	return None
	return value.replace('.mlmodelc', '').replace('.mlpackage', '')

	# If meta.yaml is provided, load parameters from it
	if args.meta:
	try:
	with open(args.meta, 'r') as f:
	meta = yaml.safe_load(f)
	params = meta['model_info']['parameters']

	# Set model directory to meta.yaml directory if not specified
	if not args.d or args.d == '.':
	args.d = str(Path(args.meta).parent)

	# Check if this is a monolithic model
	model_type = meta['model_info'].get('model_type', 'chunked')
	args.is_monolithic = (model_type == 'monolithic')

	if args.is_monolithic:
	# Monolithic model configuration
	prefix = params.get('model_prefix', 'qwen')
	lut_bits = params.get('lut_bits', 'none')
	lut_suffix = f"_lut{lut_bits}" if lut_bits != 'none' else ''

	# Set monolithic model path
	args.monolithic_model = params.get('monolithic_model', f'{prefix}_monolithic_full{lut_suffix}.mlmodelc')

	# Set other parameters
	if args.context_length is None:
	args.context_length = int(params['context_length'])
	# state_length for split cache models (defaults to context_length if not specified)
	args.state_length = int(params.get('state_length', args.context_length))
	if args.batch_size is None:
	args.batch_size = int(params['batch_size'])
	args.num_chunks = 1 # Monolithic has no chunks

	# Set split_lm_head, but allow CLI override
	if args.split_lm_head is None:
	if 'split_lm_head' in params:
	args.split_lm_head = int(params['split_lm_head'])
	else:
	args.split_lm_head = 16 if 'qwen' in prefix.lower() else 8

	# Check for argmax_in_model flag
	args.argmax_in_model = params.get('argmax_in_model', False)

	# Set tokenizer path
	if not args.tokenizer:
	if 'tokenizer_path' in params:
	args.tokenizer = params['tokenizer_path']
	else:
	args.tokenizer = args.d

	if not args.eval:
	print(f"\nLoaded MONOLITHIC model from {args.meta}:")
	print(f" Model: {args.monolithic_model}")
	print(f" Context Length: {args.context_length}")
	print(f" State Length: {args.state_length}")
	print(f" Batch Size: {args.batch_size}")
	print(f" Split LM Head: {args.split_lm_head}")
	print(f" Argmax in Model: {args.argmax_in_model}")
	print(f" Models Directory: {args.d}")
	else:
	# Standard chunked model configuration
	args.is_monolithic = False
	prefix = params.get('model_prefix', 'llama')
	lut_ffn = f"_lut{params['lut_ffn']}" if params['lut_ffn'] != 'none' else ''
	lut_lmhead = f"_lut{params['lut_lmhead']}" if params['lut_lmhead'] != 'none' else ''
	lut_embeddings = f"_lut{params['lut_embeddings']}" if params['lut_embeddings'] != 'none' else ''
	num_chunks = int(params['num_chunks'])

	# Set model paths if not specified
	if not args.lmhead:
	if 'lm_head' in params:
	args.lmhead = _strip_model_ext(params['lm_head'])
	else:
	args.lmhead = f'{prefix}_lm_head{lut_lmhead}'
	if not args.embed:
	if 'embeddings' in params:
	args.embed = _strip_model_ext(params['embeddings'])
	else:
	args.embed = f'{prefix}_embeddings{lut_embeddings}'
	if not args.ffn:
	if 'ffn' in params:
	ffn_candidate = _strip_model_ext(params['ffn'])
	ffn_path = Path(ffn_candidate)
	if "_chunk_" not in ffn_candidate:
	default_ffn = f'{prefix}_FFN_PF{lut_ffn}_chunk_01of{num_chunks:02d}'
	base_dir = ffn_path.parent if ffn_path.is_absolute() else Path(args.d)
	if (base_dir / f"{default_ffn}.mlmodelc").exists() or (base_dir / f"{default_ffn}.mlpackage").exists():
	args.ffn = str(base_dir / default_ffn) if ffn_path.is_absolute() else default_ffn
	else:
	args.ffn = ffn_candidate
	else:
	args.ffn = ffn_candidate
	else:
	args.ffn = f'{prefix}_FFN_PF{lut_ffn}_chunk_01of{num_chunks:02d}'
	if not args.tokenizer:
	if 'tokenizer_path' in params:
	args.tokenizer = params['tokenizer_path']
	else:
	args.tokenizer = args.d

	# Set other parameters if not overridden by command line
	if args.context_length is None:
	args.context_length = int(params['context_length'])
	if args.batch_size is None:
	args.batch_size = int(params['batch_size'])
	args.num_chunks = num_chunks
	if 'num_logits' in params:
	args.num_logits = int(params['num_logits'])
	# attention_size is used for causal mask (sliding window for Gemma3)
	args.attention_size = int(params.get('attention_size', args.context_length))

	# sliding_window for Gemma3 rotation support (default 512 for Gemma3)
	# Only set if the model has a sliding window configured or if prefix is gemma3
	if 'sliding_window' in params:
	args.sliding_window = int(params['sliding_window'])
	elif prefix.lower().startswith('gemma3'):
	args.sliding_window = 512 # Default Gemma3 sliding window
	else:
	args.sliding_window = None # No rotation for other models

	# Set split_lm_head, but allow CLI override
	if args.split_lm_head is None:
	if 'split_lm_head' in params:
	args.split_lm_head = int(params['split_lm_head'])
	else:
	args.split_lm_head = 8

	# Check for argmax_in_model flag (for chunked models)
	args.argmax_in_model = params.get('argmax_in_model', False)

	if not args.eval:
	print(f"\nLoaded parameters from {args.meta}:")
	print(f" Context Length: {args.context_length}")
	print(f" Batch Size: {args.batch_size}")
	print(f" Num Chunks: {args.num_chunks}")
	print(f" Num Logits: {args.num_logits}")
	print(f" Split LM Head: {args.split_lm_head}")
	print(f" Argmax in Model: {args.argmax_in_model}")
	print(f" Models Directory: {args.d}")
	print(f" Embeddings: {args.embed}")
	print(f" LM Head: {args.lmhead}")
	print(f" FFN: {args.ffn}")

	except Exception as e:
	print(f"\nError loading meta.yaml: {str(e)}")
	sys.exit(1)
	else:
	# If no meta.yaml, set defaults
	args.is_monolithic = False
	if not hasattr(args, 'split_lm_head') or args.split_lm_head is None:
	args.split_lm_head = args.num_logits # Use num_logits as fallback

	return args


	def load_monolithic_model(args, metadata):
	"""Load monolithic model with infer, infer_rotate, and prefill functions."""
	if not args.eval:
	print("\nLoading monolithic model...")
	_maybe_report_mem("start load_monolithic_model", getattr(args, "mem_report", False))

	# Determine compute unit
	compute_unit = ct.ComputeUnit.CPU_ONLY if getattr(args, 'cpu', False) else ct.ComputeUnit.CPU_AND_NE
	if not args.eval and getattr(args, 'cpu', False):
	print("Running in CPU-only mode")

	model_path = str(Path(args.d) / args.monolithic_model)
	model_path = parse_model_path(model_path)

	if not args.eval:
	print(f"Loading from: {model_path}")

	def _progress_bar(done, total, label, width=18):
	if total <= 0:
	total = 1
	filled = int(width * done / total)
	bar = "[" + ("#" * filled) + ("." * (width - filled)) + "]"
	sys.stdout.write(f"\r{bar} {done}/{total} {label}")
	sys.stdout.flush()
	if done == total:
	sys.stdout.write("\n")

	# Decide whether to attempt rotate functions
	attempt_rotate = True
	if getattr(args, "context_length", None) is not None and args.context_length <= 512:
	attempt_rotate = False

	functions_to_load = [("infer", True), ("prefill", True)]
	if attempt_rotate:
	functions_to_load += [("infer_rotate", False), ("prefill_rotate", False)]

	infer_model = None
	prefill_model = None
	infer_rotate_model = None
	prefill_rotate_model = None
	loaded = []
	missing = []

	total = len(functions_to_load)
	for idx, (name, required) in enumerate(functions_to_load, start=1):
	if not args.eval:
	_progress_bar(idx, total, name)
	try:
	model = load_model(model_path, function_name=name, compute_unit=compute_unit)
	loaded.append(name)
	if name == "infer":
	infer_model = model
	elif name == "prefill":
	prefill_model = model
	elif name == "infer_rotate":
	infer_rotate_model = model
	elif name == "prefill_rotate":
	prefill_rotate_model = model
	except Exception:
	if required:
	raise
	missing.append(name)

	_maybe_report_mem("after load monolithic functions", getattr(args, "mem_report", False))

	if not args.eval:
	summary = "Monolithic model loaded (" + ", ".join(loaded) + ")"
	if missing:
	summary += f" [missing: {', '.join(missing)}]"
	print(summary)

	# Extract metadata from model
	metadata = load_metadata(infer_model, args)

	return infer_model, infer_rotate_model, prefill_model, prefill_rotate_model, metadata


	def run_monolithic_prefill(model, input_ids, context_pos, context_length, batch_size, state, causal_mask):
	"""Run prefill on monolithic model."""
	batch_pos = 0
	while batch_pos < context_pos:
	batch_end = min(batch_pos + batch_size, context_pos)
	current_batch_size = batch_end - batch_pos

	# Get current batch
	batch_input = input_ids[:, batch_pos:batch_end]

	# Pad to full batch size
	batch_input = F.pad(batch_input, (0, batch_size - current_batch_size), value=0)

	# Generate position IDs for full batch size
	position_ids = torch.arange(batch_pos, batch_pos + batch_size, dtype=torch.int32)
	batch_causal_mask = causal_mask[:, :, batch_pos:batch_pos + batch_size, :]

	# Run monolithic prefill (input_ids -> logits directly)
	inputs = {
	'input_ids': batch_input.numpy().astype(np.int32),
	'position_ids': position_ids.numpy().astype(np.int32),
	'causal_mask': batch_causal_mask.numpy().astype(np.float16),
	'current_pos': np.array([batch_pos], dtype=np.int32)
	}
	output = model.predict(inputs, state)
	# We don't need the output logits for prefill, just updating KV cache

	batch_pos = batch_end

	return torch.tensor([context_pos], dtype=torch.int32)


	def run_monolithic_prefill_with_rotation(prefill_model, prefill_rotate_model, input_ids, context_pos,
	context_length, batch_size, state, causal_mask, sliding_window,
	infer_rotate_model=None):
	"""Run prefill with rotation support for long contexts.

	When context_pos > sliding_window, this splits the prefill into two phases:
	- Phase 1: Fill mode (prefill_model) for positions 0 to sliding_window-1
	- Phase 2: Rotation mode (prefill_rotate_model) for positions sliding_window to context_pos-1

	If prefill_rotate_model is None or context_pos <= sliding_window, falls back to standard prefill.
	"""
	# If no rotation model or short context, use standard prefill
	if prefill_rotate_model is None or context_pos <= sliding_window:
	return run_monolithic_prefill(prefill_model, input_ids, context_pos, context_length,
	batch_size, state, causal_mask)

	# Phase 1: Fill mode for positions 0 to sliding_window-1
	batch_pos = 0
	while batch_pos < sliding_window:
	batch_end = min(batch_pos + batch_size, sliding_window)
	current_batch_size = batch_end - batch_pos

	batch_input = input_ids[:, batch_pos:batch_end]
	batch_input = F.pad(batch_input, (0, batch_size - current_batch_size), value=0)

	position_ids = torch.arange(batch_pos, batch_pos + batch_size, dtype=torch.int32)
	batch_causal_mask = causal_mask[:, :, batch_pos:batch_pos + batch_size, :]

	inputs = {
	'input_ids': batch_input.numpy().astype(np.int32),
	'position_ids': position_ids.numpy().astype(np.int32),
	'causal_mask': batch_causal_mask.numpy().astype(np.float16),
	'current_pos': np.array([batch_pos], dtype=np.int32)
	}
	prefill_model.predict(inputs, state)
	batch_pos = batch_end

	# Phase 2: Rotation mode for positions sliding_window to context_pos-1
	batch_pos = sliding_window
	# Process full batches with prefill_rotate
	while batch_pos + batch_size <= context_pos:
	batch_end = batch_pos + batch_size

	batch_input = input_ids[:, batch_pos:batch_end]
	position_ids = torch.arange(batch_pos, batch_end, dtype=torch.int32)
	batch_causal_mask = causal_mask[:, :, batch_pos:batch_end, :]

	inputs = {
	'input_ids': batch_input.numpy().astype(np.int32),
	'position_ids': position_ids.numpy().astype(np.int32),
	'causal_mask': batch_causal_mask.numpy().astype(np.float16),
	'current_pos': np.array([batch_pos], dtype=np.int32)
	}
	prefill_rotate_model.predict(inputs, state)
	batch_pos = batch_end

	# Handle remainder tokens without padding (token-by-token rotation)
	if batch_pos < context_pos:
	if infer_rotate_model is not None:
	while batch_pos < context_pos:
	token = input_ids[:, batch_pos:batch_pos + 1]
	position_ids = torch.tensor([batch_pos], dtype=torch.int32)
	single_causal_mask = causal_mask[:, :, batch_pos:batch_pos + 1, :]

	inputs = {
	'input_ids': token.numpy().astype(np.int32),
	'position_ids': position_ids.numpy().astype(np.int32),
	'causal_mask': single_causal_mask.numpy().astype(np.float16),
	'current_pos': position_ids.numpy().astype(np.int32)
	}
	infer_rotate_model.predict(inputs, state)
	batch_pos += 1
	else:
	# Fallback to padded batch if infer_rotate is unavailable
	batch_end = context_pos
	current_batch_size = batch_end - batch_pos
	batch_input = input_ids[:, batch_pos:batch_end]
	batch_input = F.pad(batch_input, (0, batch_size - current_batch_size), value=0)

	position_ids = torch.arange(batch_pos, batch_pos + batch_size, dtype=torch.int32)
	batch_causal_mask = causal_mask[:, :, batch_pos:batch_pos + batch_size, :]

	inputs = {
	'input_ids': batch_input.numpy().astype(np.int32),
	'position_ids': position_ids.numpy().astype(np.int32),
	'causal_mask': batch_causal_mask.numpy().astype(np.float16),
	'current_pos': np.array([batch_pos], dtype=np.int32)
	}
	prefill_rotate_model.predict(inputs, state)

	return torch.tensor([context_pos], dtype=torch.int32)


	def generate_next_token_monolithic(model, input_ids, pos, context_length, metadata, state, causal_mask, temperature=0.0):
	"""Generate next token using monolithic model."""
	# Get current token
	current_token = input_ids[:, pos-1:pos] # [1, 1]

	# Create inputs
	position_ids = torch.tensor([pos-1], dtype=torch.int32)
	single_causal_mask = causal_mask[:, :, pos-1:pos, :]

	# Run monolithic infer
	inputs = {
	'input_ids': current_token.numpy().astype(np.int32),
	'position_ids': position_ids.numpy().astype(np.int32),
	'causal_mask': single_causal_mask.numpy().astype(np.float16),
	'current_pos': position_ids.numpy().astype(np.int32)
	}
	output = model.predict(inputs, state)

	# Check if model uses argmax_in_model mode (outputs 2 tensors instead of logits)
	argmax_in_model = metadata.get('argmax_in_model', False)

	if argmax_in_model and 'argmax_idx' in output:
	# Argmax-in-model mode: find the chunk with highest value and compute global index
	# Model outputs LOCAL indices (0 to chunk_size-1) for each chunk
	# We compute: global_idx = local_idx + (best_chunk * chunk_size)
	argmax_idx = output['argmax_idx'] # shape: [num_chunks], LOCAL indices
	argmax_val = output['argmax_val'] # shape: [num_chunks]

	# Flatten in case of extra dimensions
	argmax_idx_flat = argmax_idx.flatten()
	argmax_val_flat = argmax_val.flatten()

	# Find chunk with highest value
	best_chunk = int(np.argmax(argmax_val_flat))
	local_idx = int(argmax_idx_flat[best_chunk])

	# Compute global token ID: local_idx + (chunk * chunk_size)
	chunk_size = 16384 # 262144 / 16
	global_idx = local_idx + (best_chunk * chunk_size)

	# Debug: print shapes and values
	if metadata.get('debug_argmax', False):
	print(f"\n=== Argmax Debug (pos={pos}) ===")
	print(f"argmax_idx shape: {argmax_idx.shape}, dtype: {argmax_idx.dtype}")
	print(f"argmax_val shape: {argmax_val.shape}, dtype: {argmax_val.dtype}")
	print(f"Per-chunk results (LOCAL indices, chunk_size={chunk_size}):")

	# Find top 3 chunks by value for comparison
	sorted_indices = np.argsort(argmax_val_flat)[::-1][:3]

	for i in range(min(16, len(argmax_idx_flat))):
	local = int(argmax_idx_flat[i])
	val = float(argmax_val_flat[i])
	computed_global = local + (i * chunk_size)
	in_range = 0 <= local < chunk_size
	marker = " <-- SELECTED" if i == best_chunk else ""
	if i in sorted_indices and i != best_chunk:
	marker += f" (top-{list(sorted_indices).index(i)+1})"
	range_ok = "✓" if in_range else f"✗ (expected 0-{chunk_size-1})"
	print(f" Chunk {i:2d}: local={local:5d}, global={computed_global:6d}, val={val:8.4f}, range={range_ok}{marker}")

	print(f"Result: best_chunk={best_chunk}, local_idx={local_idx}, global_idx={global_idx}, best_val={argmax_val_flat[best_chunk]:.4f}")

	# Value comparison: show if there are close competing values
	top_values = [float(argmax_val_flat[i]) for i in sorted_indices]
	if len(top_values) >= 2:
	val_diff = abs(top_values[0] - top_values[1])
	print(f"Value comparison: top-1={top_values[0]:.6f}, top-2={top_values[1]:.6f}, diff={val_diff:.6f}")
	if val_diff < 0.01:
	print(f" WARNING: Values are very close - possible precision issue!")

	return global_idx

	# Get number of logits from metadata
	num_logits = metadata.get('split_lm_head', metadata.get('num_logits', 8))

	# Combine logits1-N if they exist
	if 'logits1' in output:
	logits_parts = []
	for i in range(1, num_logits + 1):
	key = f'logits{i}'
	if key in output:
	logits_parts.append(torch.from_numpy(output[key]))
	logits = torch.cat(logits_parts, dim=-1)
	elif 'logits' in output:
	logits = torch.from_numpy(output['logits'])
	else:
	# Try other common output names
	for key in output.keys():
	if 'logit' in key.lower():
	logits = torch.from_numpy(output[key])
	break

	# Apply temperature and sample
	if temperature > 0:
	logits = logits / temperature
	probs = F.softmax(logits[0, -1, :], dim=-1)
	next_token = torch.multinomial(probs, num_samples=1).item()
	else:
	next_token = torch.argmax(logits[0, -1, :]).item()

	return next_token


	def chat_loop_monolithic(infer_model, prefill_model, tokenizer, metadata, state, causal_mask=None,
	auto_prompt=None, warmup=False, save_file=None, max_tokens=None,
	no_template=False, eval_mode=False, infer_rotate_model=None, prefill_rotate_model=None):
	"""Chat loop for monolithic models.

	Args:
	infer_model: Model for single-token inference (fill mode, pos < sliding_window)
	prefill_model: Model for batch prefill (fill mode, for positions 0 to sliding_window-1)
	tokenizer: Tokenizer
	metadata: Model metadata dict
	state: CoreML state object
	causal_mask: Causal mask tensor
	auto_prompt: Optional auto-prompt string
	warmup: If True, skip output
	save_file: Optional file to save conversation
	max_tokens: Maximum tokens to generate
	no_template: If True, don't use chat template
	eval_mode: If True, minimal output for evaluation
	infer_rotate_model: Optional model for single-token inference with cache rotation
	(rotation mode, pos >= sliding_window). If None, uses infer_model.
	prefill_rotate_model: Optional model for batch prefill with cache rotation
	(rotation mode, for positions >= sliding_window). If None,
	uses prefill_model for all positions (legacy behavior).
	"""
	context_length = metadata.get('context_length')
	batch_size = metadata.get('batch_size', 64)
	sliding_window = metadata.get('sliding_window', 512) # For switching between infer modes

	if not warmup and not eval_mode:
	print(f"\nUsing context length: {context_length}")
	if infer_rotate_model is not None:
	print(f"Cache rotation: ENABLED (infer_rotate function available)")
	else:
	print(f"Cache rotation: NOT AVAILABLE (using infer for all positions)")
	print("\nStarting chat session. Press Ctrl+D to exit.")

	# Check chat template
	has_chat_template = False
	try:
	test_messages = [{"role": "user", "content": "test"}]
	tokenizer.apply_chat_template(test_messages, return_tensors="pt")
	has_chat_template = True
	if not warmup and not eval_mode:
	print("\nUsing chat template for prompts")
	except:
	if not warmup and not eval_mode:
	print("\nUsing manual formatting for prompts")

	stop_token_ids = build_stop_token_ids(tokenizer)

	try:
	while True:
	try:
	if not warmup and not eval_mode:
	print(f"\n{LIGHT_GREEN}You:{RESET_COLOR}", end=' ', flush=True)
	if auto_prompt is not None:
	user_input = auto_prompt
	if not warmup and not eval_mode:
	print(user_input)
	else:
	user_input = input().strip()
	except EOFError:
	if not warmup and not eval_mode:
	print("\nExiting chat...")
	break

	if not user_input:
	continue

	# Format prompt
	if no_template:
	input_ids = tokenizer(user_input, return_tensors="pt", add_special_tokens=True).input_ids.to(torch.int32)
	elif has_chat_template:
	messages = [{"role": "user", "content": user_input}]
	input_ids = tokenizer.apply_chat_template(messages, return_tensors="pt", add_generation_prompt=True).to(torch.int32)
	else:
	formatted_prompt = f"[INST] {user_input} [/INST]"
	input_ids = tokenizer(formatted_prompt, return_tensors="pt", add_special_tokens=True).input_ids.to(torch.int32)

	context_pos = input_ids.size(1)

	if not warmup and not eval_mode:
	print(f"\n{LIGHT_BLUE}Assistant:{RESET_COLOR}", end=' ', flush=True)

	token_printer = TokenPrinter(tokenizer)
	tokens_generated = 0

	try:
	prefill_start = time.time()

	# Run prefill with monolithic model (uses rotation for pos >= sliding_window if available)
	_ = run_monolithic_prefill_with_rotation(
	prefill_model, prefill_rotate_model, input_ids, context_pos, context_length,
	batch_size, state, causal_mask, sliding_window, infer_rotate_model
	)

	prefill_time = time.time() - prefill_start
	prefill_tokens_per_sec = context_pos / prefill_time if prefill_time > 0 else 0

	# Generation loop
	pos = context_pos
	inference_start = time.time()
	inference_tokens = 0

	while pos < context_length - 1:
	# Select the appropriate model based on position:
	# - pos < sliding_window: use infer_model (fill mode)
	# - pos >= sliding_window: use infer_rotate_model (rotation mode) if available
	if pos >= sliding_window and infer_rotate_model is not None:
	current_infer_model = infer_rotate_model
	else:
	current_infer_model = infer_model

	next_token = generate_next_token_monolithic(
	current_infer_model, input_ids, pos, context_length, metadata, state, causal_mask
	)

	if pos < input_ids.size(1):
	input_ids[0, pos] = next_token
	else:
	input_ids = torch.cat([input_ids, torch.tensor([[next_token]], dtype=torch.int32)], dim=1)

	if not warmup:
	token_printer.add_token(next_token)
	token_printer.drain_buffer(eval_mode)

	pos += 1
	tokens_generated += 1
	inference_tokens += 1

	if warmup and tokens_generated >= WARMUP_TOKEN_LIMIT:
	break
	if max_tokens is not None and tokens_generated >= max_tokens:
	break

	if next_token in stop_token_ids:
	break

	inference_time = time.time() - inference_start
	inference_tokens_per_sec = inference_tokens / inference_time if inference_time > 0 else 0

	if not warmup:
	response = token_printer.stop(eval_mode)
	if eval_mode:
	print(response, end='')
	else:
	prefill_ms = prefill_time * 1000
	print(f"\nPrefill: {prefill_ms:.1f}ms ({prefill_tokens_per_sec:.1f} t/s)")
	print(f"Inference: {inference_tokens_per_sec:.1f} t/s")
	print(f"Total: Generated {tokens_generated} tokens in {prefill_time + inference_time:.2f}s")

	if save_file and not eval_mode:
	try:
	time.sleep(0.5)
	with open(save_file, 'w') as f:
	f.write(response)
	print(f"\n{DARK_BLUE}Response saved to file: {save_file}{RESET_COLOR}")
	except Exception as e:
	print(f"\n{DARK_BLUE}Error saving to file: {str(e)}{RESET_COLOR}")
	else:
	token_printer.stop(eval_mode)

	if auto_prompt is not None:
	break

	except KeyboardInterrupt:
	if not eval_mode:
	print("\nGeneration interrupted")
	token_printer.stop(eval_mode)
	continue

	except Exception as e:
	print(f"\nError in chat loop: {str(e)}")
	import traceback
	traceback.print_exc()


	def main():
	args = parse_args()

	# Convert directory to absolute path
	model_dir = Path(args.d).resolve()
	if not model_dir.exists():
	if not args.eval:
	print(f"\nError: Model directory not found: {model_dir}")
	return 1

	if not args.eval:
	print(f"\nUsing model directory: {model_dir}")
	print(f"Context length: {args.context_length}")

	try:
	# Handle tokenizer path
	if args.tokenizer is None:
	args.tokenizer = str(model_dir)

	# Check if tokenizer directory exists and has required files
	tokenizer_path = Path(args.tokenizer)
	if not tokenizer_path.exists():
	if not args.eval:
	print(f"\nError: Tokenizer directory not found: {args.tokenizer}")
	return 1

	required_files = ['tokenizer.json', 'tokenizer_config.json']
	missing_files = [f for f in required_files if not (tokenizer_path / f).exists()]

	if missing_files and not args.eval:
	print(f"\nWarning: Tokenizer directory missing required files: {missing_files}")
	print(f"Current tokenizer path: {args.tokenizer}")
	print("\nFor Qwen models, you may need to specify the original model directory:")
	print(" python chat.py --meta /tmp/qwen/meta.yaml --tokenizer ~/.cache/huggingface/hub/models--Qwen--Qwen3-0.6B/snapshots/YOUR_SNAPSHOT_ID")

	args.tokenizer = str(Path(args.tokenizer).resolve())
	if not args.eval:
	print(f"Using tokenizer path: {args.tokenizer}")

	# Load tokenizer
	tokenizer = initialize_tokenizer(args.tokenizer, args.eval)
	if tokenizer is None:
	raise RuntimeError("Failed to initialize tokenizer")

	metadata = {}

	# Branch based on model type
	if getattr(args, 'is_monolithic', False):
	# MONOLITHIC MODEL PATH
	infer_model, infer_rotate_model, prefill_model, prefill_rotate_model, metadata = load_monolithic_model(args, metadata)

	# Override context length from command line if provided
	if args.context_length is not None:
	metadata['context_length'] = args.context_length
	# Use state_length from args (parsed from YAML) or default to context_length
	metadata['state_length'] = getattr(args, 'state_length', metadata['context_length'])

	# Set metadata values
	metadata['batch_size'] = getattr(args, 'batch_size', 64)
	metadata['split_lm_head'] = getattr(args, 'split_lm_head', 16)
	metadata['argmax_in_model'] = getattr(args, 'argmax_in_model', False)
	metadata['debug_argmax'] = getattr(args, 'debug_argmax', False)
	metadata['debug'] = getattr(args, 'debug', False)
	metadata['sliding_window'] = 512 # Local attention window for Gemma3

	if not args.eval:
	print(f"\nMonolithic metadata: {metadata}")

	# Create state from infer model
	state = infer_model.make_state()
	if not args.eval:
	print("\nCreated unified transformer state for monolithic model")
	_maybe_report_mem("after monolithic make_state", getattr(args, "mem_report", False))

	# Initialize causal mask - use state_length for split cache models
	causal_mask = initialize_causal_mask(metadata['state_length'], args.eval)

	# Warmup runs
	if not args.nw and not args.eval:
	for _ in range(2):
	chat_loop_monolithic(
	infer_model=infer_model,
	infer_rotate_model=infer_rotate_model,
	prefill_model=prefill_model,
	prefill_rotate_model=prefill_rotate_model,
	tokenizer=tokenizer,
	metadata=metadata,
	state=state,
	causal_mask=causal_mask,
	warmup=True,
	auto_prompt="who are you?",
	no_template=args.no_template,
	eval_mode=args.eval
	)

	# Main run
	chat_loop_monolithic(
	infer_model=infer_model,
	infer_rotate_model=infer_rotate_model,
	prefill_model=prefill_model,
	prefill_rotate_model=prefill_rotate_model,
	tokenizer=tokenizer,
	metadata=metadata,
	state=state,
	causal_mask=causal_mask,
	warmup=False,
	auto_prompt=args.prompt,
	save_file=args.save,
	max_tokens=args.max_tokens,
	no_template=args.no_template,
	eval_mode=args.eval
	)

	else:
	# CHUNKED MODEL PATH (original code)
	# Update paths to be relative to model directory
	args.embed = str(model_dir / args.embed)
	args.ffn = str(model_dir / args.ffn)
	args.lmhead = str(model_dir / args.lmhead)

	# Load models and extract metadata
	embed_model, ffn_models, lmhead_model, metadata = load_models(args, metadata)

	if not args.eval:
	print(f"\nMetadata befor args.context_length: {metadata}")

	# Override context length from command line if provided
	if args.context_length is not None:
	metadata['context_length'] = args.context_length
	metadata['state_length'] = args.context_length
	if not args.eval:
	print(f"\nOverriding context length from command line: {args.context_length}")

	# Add num_logits to metadata (legacy support)
	metadata['num_logits'] = getattr(args, 'num_logits', 8)

	# Add split_lm_head to metadata (preferred)
	metadata['split_lm_head'] = getattr(args, 'split_lm_head', getattr(args, 'num_logits', 8))

	# Add debug flag
	metadata['debug'] = getattr(args, 'debug', False)

	# Add argmax_in_model flag for chunked models
	metadata['argmax_in_model'] = getattr(args, 'argmax_in_model', False)
	metadata['debug_argmax'] = getattr(args, 'debug_argmax', False)

	if not args.eval:
	print(f"\nMetadata after load_models: {metadata}")
	print(f"Using split_lm_head value: {metadata.get('split_lm_head', 8)}")
	if metadata.get('argmax_in_model'):
	print("Argmax mode enabled for LM head")

	# Create unified state once
	state = create_unified_state(ffn_models, metadata['context_length'], args.eval)
	_maybe_report_mem("after chunked make_state", getattr(args, "mem_report", False))

	# Initialize causal mask once
	# For Gemma3 with split cache, use attention_size (sliding window) for causal mask
	attention_size = getattr(args, 'attention_size', metadata['context_length'])
	metadata['attention_size'] = attention_size

	# Add sliding_window for Gemma3 rotation support
	sliding_window = getattr(args, 'sliding_window', None)
	metadata['sliding_window'] = sliding_window
	if sliding_window is not None and not args.eval:
	print(f"Sliding window: {sliding_window} (rotation enabled for pos >= {sliding_window})")

	causal_mask = initialize_causal_mask(attention_size, args.eval)

	# Warmup runs to prevent Python GIL issues with CoreML
	if not args.nw and not args.eval:
	for _ in range(2):
	chat_loop(
	embed_model=embed_model,
	ffn_models=ffn_models,
	lmhead_model=lmhead_model,
	tokenizer=tokenizer,
	metadata=metadata,
	state=state,
	causal_mask=causal_mask,
	warmup=True,
	auto_prompt="who are you?",
	no_template=args.no_template,
	eval_mode=args.eval
	)

	# Main run
	chat_loop(
	embed_model=embed_model,
	ffn_models=ffn_models,
	lmhead_model=lmhead_model,
	tokenizer=tokenizer,
	metadata=metadata,
	state=state,
	causal_mask=causal_mask,
	warmup=False,
	auto_prompt=args.prompt,
	save_file=args.save,
	max_tokens=args.max_tokens,
	no_template=args.no_template,
	eval_mode=args.eval
	)

	except Exception as e:
	if not args.eval:
	print(f"\nError: {str(e)}")
	import traceback
	traceback.print_exc()
	return 1

	return 0

	if __name__ == "__main__":
	exit(main())