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syllables_matching_experiment

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	import os
	import io
	import gradio as gr
	import torch
	import numpy as np
	import re
	import pronouncing
	import functools
	from transformers import (
	AutoModelForAudioClassification,
	AutoFeatureExtractor,
	AutoTokenizer,
	pipeline,
	AutoModelForCausalLM,
	BitsAndBytesConfig
	)
	from huggingface_hub import login
	from utils import (
	load_audio,
	extract_audio_duration,
	extract_mfcc_features,
	format_genre_results,
	ensure_cuda_availability
	)
	from emotionanalysis import MusicAnalyzer
	import librosa
	from beat_analysis import BeatAnalyzer # Import the BeatAnalyzer class

	# Initialize beat analyzer
	beat_analyzer = BeatAnalyzer()

	# Login to Hugging Face Hub if token is provided
	if "HF_TOKEN" in os.environ:
	login(token=os.environ["HF_TOKEN"])

	# Constants
	GENRE_MODEL_NAME = "dima806/music_genres_classification"
	MUSIC_DETECTION_MODEL = "MIT/ast-finetuned-audioset-10-10-0.4593"
	LLM_MODEL_NAME = "Qwen/Qwen3-32B"
	SAMPLE_RATE = 22050 # Standard sample rate for audio processing

	# Check CUDA availability (for informational purposes)
	CUDA_AVAILABLE = ensure_cuda_availability()

	# Load models at initialization time
	print("Loading genre classification model...")
	try:
	genre_feature_extractor = AutoFeatureExtractor.from_pretrained(GENRE_MODEL_NAME)
	genre_model = AutoModelForAudioClassification.from_pretrained(
	GENRE_MODEL_NAME,
	device_map="auto" if CUDA_AVAILABLE else None
	)
	# Create a convenience wrapper function with the same interface as before
	def get_genre_model():
	return genre_model, genre_feature_extractor
	except Exception as e:
	print(f"Error loading genre model: {str(e)}")
	genre_model = None
	genre_feature_extractor = None

	# Load LLM and tokenizer at initialization time
	print("Loading Qwen LLM model with 4-bit quantization...")
	try:
	# Configure 4-bit quantization for better performance
	quantization_config = BitsAndBytesConfig(
	load_in_4bit=True,
	bnb_4bit_quant_type="nf4",
	bnb_4bit_compute_dtype=torch.float16,
	bnb_4bit_use_double_quant=True
	)

	llm_tokenizer = AutoTokenizer.from_pretrained(LLM_MODEL_NAME)
	llm_model = AutoModelForCausalLM.from_pretrained(
	LLM_MODEL_NAME,
	quantization_config=quantization_config,
	device_map="auto",
	trust_remote_code=True,
	torch_dtype=torch.float16,
	use_cache=True
	)
	except Exception as e:
	print(f"Error loading LLM model: {str(e)}")
	llm_tokenizer = None
	llm_model = None

	# Create music analyzer instance
	music_analyzer = MusicAnalyzer()

	# Process uploaded audio file
	def process_audio(audio_file):
	if audio_file is None:
	return "No audio file provided", None, None, None, None, None, None, None

	try:
	# Load and analyze audio
	y, sr = load_audio(audio_file, sr=SAMPLE_RATE)

	# Basic audio information
	duration = extract_audio_duration(y, sr)

	# Analyze music with MusicAnalyzer
	music_analysis = music_analyzer.analyze_music(audio_file)

	# Extract key information
	tempo = music_analysis["rhythm_analysis"]["tempo"]
	emotion = music_analysis["emotion_analysis"]["primary_emotion"]
	theme = music_analysis["theme_analysis"]["primary_theme"]

	# Use genre classification directly instead of pipeline
	if genre_model is not None and genre_feature_extractor is not None:
	# Resample audio to 16000 Hz for the genre model
	y_16k = librosa.resample(y, orig_sr=sr, target_sr=16000)

	# Extract features
	inputs = genre_feature_extractor(
	y_16k,
	sampling_rate=16000,
	return_tensors="pt"
	).to(genre_model.device)

	# Classify genre
	with torch.no_grad():
	outputs = genre_model(**inputs)
	logits = outputs.logits
	probs = torch.nn.functional.softmax(logits, dim=-1)

	# Get top genres
	values, indices = torch.topk(probs[0], k=5)
	top_genres = [(genre_model.config.id2label[idx.item()], val.item()) for val, idx in zip(values, indices)]
	else:
	# Fallback if model loading failed
	top_genres = [("Unknown", 1.0)]

	# Format genre results for display
	genre_results_text = format_genre_results(top_genres)
	primary_genre = top_genres[0][0]

	# Override time signature for pop and disco genres to always be 4/4
	if any(genre.lower() in primary_genre.lower() for genre in ['pop', 'disco']):
	music_analysis["rhythm_analysis"]["estimated_time_signature"] = "4/4"
	time_signature = "4/4"
	else:
	# Use detected time signature for other genres
	time_signature = music_analysis["rhythm_analysis"]["estimated_time_signature"]

	# Ensure time signature is one of the supported ones (4/4, 3/4, 6/8)
	if time_signature not in ["4/4", "3/4", "6/8"]:
	time_signature = "4/4" # Default to 4/4 if unsupported
	music_analysis["rhythm_analysis"]["estimated_time_signature"] = time_signature

	# Analyze beat patterns and create lyrics template using the time signature
	beat_analysis = beat_analyzer.analyze_beat_pattern(audio_file, time_signature=time_signature)
	lyric_templates = beat_analyzer.create_lyric_template(beat_analysis)

	# Store these in the music_analysis dict for use in lyrics generation
	music_analysis["beat_analysis"] = beat_analysis
	music_analysis["lyric_templates"] = lyric_templates

	# Prepare analysis summary
	analysis_summary = f"""
	### Music Analysis Results

	Duration: {duration:.2f} seconds
	Tempo: {tempo:.1f} BPM
	Time Signature: {time_signature}
	Key: {music_analysis["tonal_analysis"]["key"]} {music_analysis["tonal_analysis"]["mode"]}
	Primary Emotion: {emotion}
	Primary Theme: {theme}
	Top Genre: {primary_genre}

	{genre_results_text}
	"""

	# Add beat analysis summary
	if lyric_templates:
	analysis_summary += f"""
	### Beat Analysis

	Total Phrases: {len(lyric_templates)}
	Average Beats Per Phrase: {np.mean([t['num_beats'] for t in lyric_templates]):.1f}
	Beat Pattern Examples:
	- Phrase 1: {lyric_templates[0]['stress_pattern'] if lyric_templates else 'N/A'}
	- Phrase 2: {lyric_templates[1]['stress_pattern'] if len(lyric_templates) > 1 else 'N/A'}
	"""

	# Check if genre is supported for lyrics generation
	# Use the supported_genres list from BeatAnalyzer
	genre_supported = any(genre.lower() in primary_genre.lower() for genre in beat_analyzer.supported_genres)

	# Generate lyrics only for supported genres
	if genre_supported:
	lyrics = generate_lyrics(music_analysis, primary_genre, duration)
	beat_match_analysis = analyze_lyrics_rhythm_match(lyrics, lyric_templates, primary_genre)
	else:
	supported_genres_str = ", ".join([genre.capitalize() for genre in beat_analyzer.supported_genres])
	lyrics = f"Lyrics generation is only supported for the following genres: {supported_genres_str}.\n\nDetected genre '{primary_genre}' doesn't have strong syllable-to-beat patterns required for our lyric generation algorithm."
	beat_match_analysis = "Lyrics generation not available for this genre."

	return analysis_summary, lyrics, tempo, time_signature, emotion, theme, primary_genre, beat_match_analysis

	except Exception as e:
	error_msg = f"Error processing audio: {str(e)}"
	print(error_msg)
	return error_msg, None, None, None, None, None, None, None

	def generate_lyrics(music_analysis, genre, duration):
	try:
	# Extract meaningful information for context
	tempo = music_analysis["rhythm_analysis"]["tempo"]
	key = music_analysis["tonal_analysis"]["key"]
	mode = music_analysis["tonal_analysis"]["mode"]
	emotion = music_analysis["emotion_analysis"]["primary_emotion"]
	theme = music_analysis["theme_analysis"]["primary_theme"]

	# Get beat analysis and templates
	lyric_templates = music_analysis.get("lyric_templates", [])

	# Verify LLM is loaded
	if llm_model is None or llm_tokenizer is None:
	return "Error: LLM model not properly loaded"

	# If no templates, fall back to original method
	if not lyric_templates:
	# Simplified prompt
	prompt = f"""Write song lyrics for a {genre} song in {key} {mode} with tempo {tempo} BPM. The emotion is {emotion} and theme is {theme}.

	ONLY WRITE THE ACTUAL LYRICS. NO EXPLANATIONS OR META-TEXT.
	"""
	else:
	# Create phrase examples
	num_phrases = len(lyric_templates)

	# Calculate the typical syllable range for this genre
	if num_phrases > 0:
	# Get max syllables per line from templates
	max_syllables = max([t.get('max_expected', 7) for t in lyric_templates]) if lyric_templates[0].get('max_expected') else 7
	min_syllables = min([t.get('min_expected', 2) for t in lyric_templates]) if lyric_templates[0].get('min_expected') else 2
	avg_syllables = (min_syllables + max_syllables) // 2
	else:
	min_syllables = 2
	max_syllables = 7
	avg_syllables = 4

	# Create a more direct prompt with examples and specific syllable count guidance
	prompt = f"""Write song lyrics for a {genre} song in {key} {mode} with tempo {tempo} BPM. The emotion is {emotion} and theme is {theme}.

	I need EXACTLY {num_phrases} lines of lyrics - one line for each musical phrase. Not one more, not one less.

	CRITICAL INSTRUCTIONS:
	- Each line MUST be VERY SHORT with only {min_syllables}-{max_syllables} syllables (aim for {avg_syllables} or fewer)
	- PRIORITIZE BREVITY - use fewer syllables rather than more
	- CONNECT YOUR LINES - spread complete thoughts across 2-3 consecutive lines
	- Create SENTENCE FLOW across lines instead of making each line independent
	- Let sentence clauses and phrases flow naturally across multiple lines
	- Each individual line should still fit into one measure of music
	- Use simple, short words whenever possible

	FORMAT:
	- Just write {num_phrases} plain text lines
	- Each line should be simple song lyrics (no annotations)
	- Don't include any explanations or commentary
	- Don't use any tags or markers
	- Don't include section labels like [Verse] or [Chorus]

	EXAMPLE OF CONNECTED THOUGHTS ACROSS LINES:

	Moonlight falls (3 syllables)
	through my window pane (5 syllables)
	as I wait for you (5 syllables)

	Notice how these 3 lines form ONE complete sentence.

	Another example:

	Whispers fade (3 syllables)
	in the morning light (5 syllables)
	leaving memories (5 syllables)
	of our last goodbye (5 syllables)

	These 4 lines form a connected thought, not independent statements.

	JUST THE PLAIN LYRICS, EXACTLY {num_phrases} LINES, KEEPING EACH LINE TO {min_syllables}-{max_syllables} SYLLABLES, WITH CONNECTED THOUGHTS ACROSS LINES.
	"""

	# Generate lyrics using the LLM model
	messages = [
	{"role": "user", "content": prompt}
	]

	# Apply chat template
	text = llm_tokenizer.apply_chat_template(
	messages,
	tokenize=False,
	add_generation_prompt=True
	)

	# Tokenize and move to model device
	model_inputs = llm_tokenizer([text], return_tensors="pt").to(llm_model.device)

	# Generate with optimized parameters
	generated_ids = llm_model.generate(
	**model_inputs,
	max_new_tokens=1024,
	do_sample=True,
	temperature=0.7,
	top_p=0.9,
	repetition_penalty=1.2,
	pad_token_id=llm_tokenizer.eos_token_id
	)

	# Decode the output
	output_ids = generated_ids[0][len(model_inputs.input_ids[0]):].tolist()
	lyrics = llm_tokenizer.decode(output_ids, skip_special_tokens=True).strip()

	# ULTRA AGGRESSIVE CLEANING - COMPLETELY REVISED
	# ------------------------------------------------

	# 1. First, look for any standard dividers that might separate thinking from lyrics
	divider_patterns = [
	r'Here are the lyrics:',
	r'Here is my song:',
	r'The lyrics:',
	r'My lyrics:',
	r'Song lyrics:',
	r'\\\*+',
	r'===+',
	r'---+',
	r'```',
	r'Lyrics:'
	]

	for pattern in divider_patterns:
	matches = re.finditer(pattern, lyrics, re.IGNORECASE)
	for match in matches:
	# Keep only content after the divider
	lyrics = lyrics[match.end():].strip()

	# 2. Remove thinking tags completely before splitting into lines
	lyrics = re.sub(r'<think>.*?</think>', '', lyrics, flags=re.DOTALL)
	lyrics = re.sub(r'\[thinking\].*?\[/thinking\]', '', lyrics, flags=re.DOTALL)
	lyrics = re.sub(r'<think>', '', lyrics, flags=re.DOTALL)
	lyrics = re.sub(r'</think>', '', lyrics, flags=re.DOTALL)
	lyrics = re.sub(r'\[thinking\]', '', lyrics, flags=re.DOTALL)
	lyrics = re.sub(r'\[/thinking\]', '', lyrics, flags=re.DOTALL)

	# 3. Split text into lines for aggressive line-by-line filtering
	lines = lyrics.strip().split('\n')
	clean_lines = []

	# 4. Define comprehensive patterns for non-lyrical content
	non_lyric_patterns = [
	# Meta-commentary
	r'^(note\|thinking\|thoughts\|let me\|i will\|i am going\|i would\|i can\|i need to\|i have to\|i should\|let\'s\|here\|now)',
	r'^(first\|second\|third\|next\|finally\|importantly\|remember\|so\|ok\|okay\|as requested\|as asked\|considering)',
	# Explanations
	r'syllable[s]?\|phrase\|rhythm\|beats?\|tempo\|bpm\|instruction\|follow\|alignment\|match\|corresponding',
	r'verses?\|chorus\|bridge\|section\|stanza\|part\|template\|format\|pattern\|example',
	r'requirements?\|guidelines?\|song structure\|stressed\|unstressed',
	# Technical language
	r'generated\|output\|result\|provide\|create\|write\|draft\|version',
	# Annotations and numbering
	r'^line \d+\|^\d+[\.\):]\|^\[\w+\]\|^[\*\-\+] ',
	# Questions or analytical statements
	r'\?$\|analysis\|evaluate\|review\|check\|ensure',
	# Instruction-like statements
	r'make sure\|please note\|important\|notice\|pay attention'
	]

	# 5. Identify which lines are likely actual lyrics vs non-lyrics
	for line in lines:
	line = line.strip()

	# Skip empty lines or lines with just spaces/tabs
	if not line or line.isspace():
	continue

	# Skip lines that match any non-lyric pattern
	should_skip = False
	for pattern in non_lyric_patterns:
	if re.search(pattern, line.lower()):
	should_skip = True
	break

	if should_skip:
	continue

	# Skip section headers
	if (line.startswith('[') and ']' in line) or (line.startswith('(') and ')' in line and len(line) < 20):
	continue

	# Skip lines that look like annotations (not prose-like)
	if ':' in line and not any(word in line.lower() for word in ['like', 'when', 'where', 'how', 'why', 'what']):
	if len(line.split(':')[0]) < 15: # Short prefixes followed by colon are likely annotations
	continue

	# Skip very short lines that aren't likely to be lyrics (unless it's just a few words which could be valid)
	if len(line) < 3:
	continue

	# Skip lines that are numbered or bulleted
	if re.match(r'^\d+\.\|$#\d+$\|\d+\)', line):
	continue

	# Skip markdown-style emphasis or headers
	if re.match(r'^#{1,6} \|^\\\|^__', line):
	continue

	# Skip lines with think tags
	if '<think>' in line.lower() or '</think>' in line.lower() or '[thinking]' in line.lower() or '[/thinking]' in line.lower():
	continue

	# Add this line as it passed all filters
	clean_lines.append(line)

	# 6. Additional block-level filters for common patterns
	# Check beginning of lyrics for common prefixes
	if clean_lines and any(clean_lines[0].lower().startswith(prefix) for prefix in
	['here are', 'these are', 'below are', 'following are']):
	clean_lines = clean_lines[1:] # Skip the first line

	# 7. Process blocks of lines to detect explanation blocks
	if len(clean_lines) > 3:
	# Check for explanation blocks at the beginning
	first_three = ' '.join(clean_lines[:3]).lower()
	if any(term in first_three for term in ['i will', 'i have created', 'i\'ll provide', 'i\'ll write']):
	# This looks like an explanation, skip the first few lines
	start_idx = 0
	for i, line in enumerate(clean_lines):
	if i >= 3 and not any(term in line.lower() for term in ['i will', 'created', 'write', 'provide']):
	start_idx = i
	break
	clean_lines = clean_lines[start_idx:]

	# Check for explanation blocks at the end
	last_three = ' '.join(clean_lines[-3:]).lower()
	if any(term in last_three for term in ['hope this', 'these lyrics', 'as you can see', 'this song', 'i have']):
	# This looks like an explanation at the end, truncate
	end_idx = len(clean_lines)
	for i in range(len(clean_lines) - 1, max(0, len(clean_lines) - 4), -1):
	if i < len(clean_lines) and not any(term in clean_lines[i].lower() for term in
	['hope', 'these lyrics', 'as you can see', 'this song']):
	end_idx = i + 1
	break
	clean_lines = clean_lines[:end_idx]

	# 8. Cleanup - Remove remaining annotations or thinking
	for i in range(len(clean_lines)):
	# Remove trailing thoughts/annotations
	clean_lines[i] = re.sub(r'\s+//.*$', '', clean_lines[i])
	clean_lines[i] = re.sub(r'\s+$.*?$$', '', clean_lines[i])

	# Remove thinking tags completely
	clean_lines[i] = re.sub(r'<think>.*?</think>', '', clean_lines[i], flags=re.DOTALL)
	clean_lines[i] = re.sub(r'\[thinking\].*?\[/thinking\]', '', clean_lines[i], flags=re.DOTALL)
	clean_lines[i] = re.sub(r'<think>', '', clean_lines[i])
	clean_lines[i] = re.sub(r'</think>', '', clean_lines[i])
	clean_lines[i] = re.sub(r'\[thinking\]', '', clean_lines[i])
	clean_lines[i] = re.sub(r'\[/thinking\]', '', clean_lines[i])

	# Remove syllable count annotations
	clean_lines[i] = re.sub(r'\s$\d+\ssyllables?$', '', clean_lines[i])

	# 9. Filter out any remaining empty lines after tag removal
	clean_lines = [line for line in clean_lines if line.strip() and not line.isspace()]

	# 10. If we have lyric templates, ensure we have the correct number of lines
	if lyric_templates:
	num_required = len(lyric_templates)

	# If we have too many lines, keep just the best ones
	if len(clean_lines) > num_required:
	# Keep the first num_required lines
	clean_lines = clean_lines[:num_required]

	# If we don't have enough lines, generate placeholders that fit the syllable count
	while len(clean_lines) < num_required:
	i = len(clean_lines)
	if i < len(lyric_templates):
	template = lyric_templates[i]
	target_syllables = min(max_syllables, (template.get('min_expected', 2) + template.get('max_expected', 7)) // 2)

	# Create a diverse set of placeholders that match the theme/emotion
	placeholders = {
	# 2-3 syllables
	2: [
	"Night falls",
	"Time stops",
	"Hearts beat",
	"Rain falls",
	"Stars shine"
	],
	# 3-4 syllables
	3: [
	"Empty chair",
	"Shadows dance",
	"Whispers fade",
	"Memories",
	"Silent room"
	],
	# 4-5 syllables
	4: [
	"Moonlight shimmers",
	"Echoes of time",
	"Footsteps fading",
	"Memories drift",
	"Silence speaks loud"
	],
	# 5-6 syllables
	5: [
	"Walking in the rain",
	"Whispers in the dark",
	"Echoes of your voice",
	"Traces left behind",
	"Time moves ever on"
	],
	# 6-7 syllables
	6: [
	"Dancing in the moonlight",
	"Shadows play on the wall",
	"Memories fade to silence",
	"Moments lost in the wind",
	"Whispers of a better time"
	]
	}

	# Get the closest matching syllable group
	closest_group = min(placeholders.keys(), key=lambda k: abs(k - target_syllables))

	# Choose a placeholder that hasn't been used yet
	available_placeholders = [p for p in placeholders[closest_group]
	if p not in clean_lines]

	if available_placeholders:
	placeholder = available_placeholders[i % len(available_placeholders)]
	else:
	# If we've used all placeholders in this group, create a custom one
	if emotion.lower() in ["sad", "nostalgic", "calm"]:
	placeholder = f"Memories of {emotion}"
	elif emotion.lower() in ["happy", "energetic"]:
	placeholder = f"Dancing through {emotion}"
	else:
	placeholder = f"Feeling {emotion} now"
	else:
	placeholder = "Silence speaks volumes"

	clean_lines.append(placeholder)

	# Assemble final lyrics
	final_lyrics = '\n'.join(clean_lines)

	# 11. Final sanity check - if we have nothing or garbage, return an error
	if not final_lyrics or len(final_lyrics) < 10:
	return "The model generated only thinking content but no actual lyrics. Please try again."

	return final_lyrics

	except Exception as e:
	error_msg = f"Error generating lyrics: {str(e)}"
	print(error_msg)
	return error_msg

	def analyze_lyrics_rhythm_match(lyrics, lyric_templates, genre="pop"):
	"""Analyze how well the generated lyrics match the beat patterns and syllable requirements"""
	if not lyric_templates or not lyrics:
	return "No beat templates or lyrics available for analysis."

	# Split lyrics into lines
	lines = lyrics.strip().split('\n')
	lines = [line for line in lines if line.strip()] # Remove empty lines

	# Prepare analysis result
	result = "### Beat & Syllable Match Analysis\n\n"
	result += "\| Line \| Syllables \| Target Range \| Match \| Stress Pattern \|\n"
	result += "\| ---- \| --------- \| ------------ \| ----- \| -------------- \|\n"

	# Maximum number of lines to analyze (either all lines or all templates)
	line_count = min(len(lines), len(lyric_templates))

	# Track overall match statistics
	total_matches = 0
	total_range_matches = 0
	total_stress_matches = 0
	total_stress_percentage = 0
	total_ideal_matches = 0

	for i in range(line_count):
	line = lines[i]
	template = lyric_templates[i]

	# Check match between line and template with genre awareness
	check_result = beat_analyzer.check_syllable_stress_match(line, template, genre)

	# Get match symbols
	if check_result["close_to_ideal"]:
	syllable_match = "✓" # Ideal or very close
	elif check_result["within_range"]:
	syllable_match = "✓*" # Within range but not ideal
	else:
	syllable_match = "✗" # Outside range

	stress_match = "✓" if check_result["stress_matches"] else f"{int(check_result['stress_match_percentage']*100)}%"

	# Update stats
	if check_result["close_to_ideal"]:
	total_matches += 1
	total_ideal_matches += 1
	elif check_result["within_range"]:
	total_range_matches += 1

	if check_result["stress_matches"]:
	total_stress_matches += 1
	total_stress_percentage += check_result["stress_match_percentage"]

	# Create visual representation of the stress pattern
	stress_visual = ""
	for char in template['stress_pattern']:
	if char == "S":
	stress_visual += "X" # Strong
	elif char == "M":
	stress_visual += "x" # Medium
	else:
	stress_visual += "." # Weak

	# Add line to results table
	result += f"\| {i+1} \| {check_result['syllable_count']} \| {check_result['min_expected']}-{check_result['max_expected']} \| {syllable_match} \| {stress_visual} \|\n"

	# Add summary statistics
	if line_count > 0:
	exact_match_rate = (total_matches / line_count) * 100
	range_match_rate = ((total_matches + total_range_matches) / line_count) * 100
	ideal_match_rate = (total_ideal_matches / line_count) * 100
	stress_match_rate = (total_stress_matches / line_count) * 100
	avg_stress_percentage = (total_stress_percentage / line_count) * 100

	result += f"\nSummary:\n"
	result += f"- Ideal or near-ideal syllable match rate: {exact_match_rate:.1f}%\n"
	result += f"- Genre-appropriate syllable range match rate: {range_match_rate:.1f}%\n"
	result += f"- Perfect stress pattern match rate: {stress_match_rate:.1f}%\n"
	result += f"- Average stress pattern accuracy: {avg_stress_percentage:.1f}%\n"
	result += f"- Overall rhythmic accuracy: {((range_match_rate + avg_stress_percentage) / 2):.1f}%\n"

	# Analyze sentence flow across lines
	sentence_flow_analysis = analyze_sentence_flow(lines)
	result += f"\nSentence Flow Analysis:\n"
	result += f"- Connected thought groups: {sentence_flow_analysis['connected_groups']} detected\n"
	result += f"- Average lines per thought: {sentence_flow_analysis['avg_lines_per_group']:.1f}\n"
	result += f"- Flow quality: {sentence_flow_analysis['flow_quality']}\n"

	# Add guidance on ideal distribution for syllables and sentence flow
	result += f"\nSyllable & Flow Guidance:\n"
	result += f"- Aim for {min([t.get('min_expected', 3) for t in lyric_templates])}-{max([t.get('max_expected', 7) for t in lyric_templates])} syllables per line\n"
	result += f"- Break complete thoughts across 2-3 lines for natural flow\n"
	result += f"- Connect your lyrics with sentence fragments that flow across lines\n"
	result += f"- Use conjunctions, prepositions, and dependent clauses to connect lines\n"

	# Add genre-specific notes
	result += f"\nGenre Notes ({genre}):\n"

	# Add appropriate genre notes based on genre
	if genre.lower() == "pop":
	result += "- Pop lyrics work well with thoughts spanning 2-3 musical phrases\n"
	result += "- Create flow by connecting lines with transitions like 'as', 'when', 'through'\n"
	elif genre.lower() == "rock":
	result += "- Rock lyrics benefit from short phrases that build into complete thoughts\n"
	result += "- Use line breaks strategically to emphasize key words\n"
	elif genre.lower() == "country":
	result += "- Country lyrics tell stories that flow naturally across multiple lines\n"
	result += "- Connect narrative elements across phrases for authentic storytelling\n"
	elif genre.lower() == "disco":
	result += "- Disco lyrics work well with phrases that create rhythmic momentum\n"
	result += "- Use line transitions that maintain energy and flow\n"
	elif genre.lower() == "metal":
	result += "- Metal lyrics can create intensity by breaking phrases at dramatic points\n"
	result += "- Connect lines to build tension and release across measures\n"
	else:
	result += "- This genre works well with connected thoughts across multiple lines\n"
	result += "- Aim for natural speech flow rather than complete thoughts per line\n"

	return result

	def analyze_sentence_flow(lines):
	"""Analyze how well the lyrics create sentence flow across multiple lines"""
	if not lines or len(lines) < 2:
	return {
	"connected_groups": 0,
	"avg_lines_per_group": 0,
	"flow_quality": "Insufficient lines to analyze"
	}

	# Simplified analysis looking for grammatical clues of sentence continuation
	continuation_starters = [
	'and', 'but', 'or', 'nor', 'for', 'yet', 'so', # Coordinating conjunctions
	'as', 'when', 'while', 'before', 'after', 'since', 'until', 'because', 'although', 'though', # Subordinating conjunctions
	'with', 'without', 'through', 'throughout', 'beyond', 'beneath', 'under', 'over', 'into', 'onto', # Prepositions
	'to', 'from', 'by', 'at', 'in', 'on', 'of', # Common prepositions
	'where', 'how', 'who', 'whom', 'whose', 'which', 'that', # Relative pronouns
	'if', 'then', # Conditional connectors
	]

	# Check for lines that likely continue a thought from previous line
	connected_lines = []
	potential_groups = []
	current_group = [0] # Start with first line

	for i in range(1, len(lines)):
	# Check if line starts with a continuation word
	words = lines[i].lower().split()

	# Empty line or no words
	if not words:
	if len(current_group) > 1: # Only consider groups of 2+ lines
	potential_groups.append(current_group.copy())
	current_group = [i]
	continue

	# Check first word for continuation clues
	first_word = words[0].strip(',.!?;:')
	if first_word in continuation_starters:
	connected_lines.append(i)
	current_group.append(i)
	# Check for absence of capitalization as continuation clue
	elif not first_word[0].isupper() and first_word[0].isalpha():
	connected_lines.append(i)
	current_group.append(i)
	# Check if current line is very short (likely part of a continued thought)
	elif len(words) <= 3 and i < len(lines) - 1:
	# Look ahead to see if next line could be a continuation
	if i+1 < len(lines):
	next_words = lines[i+1].lower().split()
	if next_words and next_words[0] in continuation_starters:
	connected_lines.append(i)
	current_group.append(i)
	else:
	# This might end a group
	if len(current_group) > 1: # Only consider groups of 2+ lines
	potential_groups.append(current_group.copy())
	current_group = [i]
	else:
	# This likely starts a new thought
	if len(current_group) > 1: # Only consider groups of 2+ lines
	potential_groups.append(current_group.copy())
	current_group = [i]

	# Add the last group if it has multiple lines
	if len(current_group) > 1:
	potential_groups.append(current_group)

	# Calculate metrics
	connected_groups = len(potential_groups)

	if connected_groups > 0:
	avg_lines_per_group = sum(len(group) for group in potential_groups) / connected_groups

	# Determine flow quality
	if connected_groups >= len(lines) / 3 and avg_lines_per_group >= 2.5:
	flow_quality = "Excellent - multiple connected thoughts across lines"
	elif connected_groups >= len(lines) / 4 and avg_lines_per_group >= 2:
	flow_quality = "Good - some connected thoughts across lines"
	elif connected_groups > 0:
	flow_quality = "Fair - limited connection between lines"
	else:
	flow_quality = "Poor - mostly independent lines"
	else:
	avg_lines_per_group = 0
	flow_quality = "Poor - no connected thoughts detected"

	return {
	"connected_groups": connected_groups,
	"avg_lines_per_group": avg_lines_per_group,
	"flow_quality": flow_quality
	}

	# Create Gradio interface
	def create_interface():
	with gr.Blocks(title="Music Analysis & Lyrics Generator") as demo:
	gr.Markdown("# Music Analysis & Lyrics Generator")
	gr.Markdown("Upload a music file or record audio to analyze it and generate matching lyrics")

	with gr.Row():
	with gr.Column(scale=1):
	audio_input = gr.Audio(
	label="Upload or Record Audio",
	type="filepath",
	sources=["upload", "microphone"]
	)
	analyze_btn = gr.Button("Analyze and Generate Lyrics", variant="primary")

	with gr.Column(scale=2):
	with gr.Tab("Analysis"):
	analysis_output = gr.Textbox(label="Music Analysis Results", lines=10)

	with gr.Row():
	tempo_output = gr.Number(label="Tempo (BPM)")
	time_sig_output = gr.Textbox(label="Time Signature")
	emotion_output = gr.Textbox(label="Primary Emotion")
	theme_output = gr.Textbox(label="Primary Theme")
	genre_output = gr.Textbox(label="Primary Genre")

	with gr.Tab("Generated Lyrics"):
	lyrics_output = gr.Textbox(label="Generated Lyrics", lines=20)

	with gr.Tab("Beat Matching"):
	beat_match_output = gr.Markdown(label="Beat & Syllable Matching Analysis")

	# Set up event handlers
	analyze_btn.click(
	fn=process_audio,
	inputs=[audio_input],
	outputs=[analysis_output, lyrics_output, tempo_output, time_sig_output,
	emotion_output, theme_output, genre_output, beat_match_output]
	)

	# Format supported genres for display
	supported_genres_md = "\n".join([f"- {genre.capitalize()}" for genre in beat_analyzer.supported_genres])

	gr.Markdown(f"""
	## How it works
	1. Upload or record a music file
	2. The system analyzes tempo, beats, time signature and other musical features
	3. It detects emotion, theme, and music genre
	4. Using beat patterns and syllable stress analysis, it generates perfectly aligned lyrics
	5. Each line of the lyrics is matched to the beat pattern of the corresponding musical phrase

	## Supported Genres
	Note: Lyrics generation is currently only supported for the following genres:
	{supported_genres_md}

	These genres have consistent syllable-to-beat patterns that work well with our algorithm.
	For other genres, only music analysis will be provided.
	""")

	return demo

	# Launch the app
	demo = create_interface()

	if __name__ == "__main__":
	demo.launch()
	else:
	# For Hugging Face Spaces
	app = demo