| name | incremental-audio-workflow |
| description | Step-by-step audio production with per-stem verification, timing alignment, and incremental quality gates |
Incremental Audio Production Workflow
This skill provides a resilient pattern for audio production that emphasizes incremental verification and fail-fast principles. Each major step produces verified outputs before proceeding, reducing iteration count and catching errors early.
Overview
Follow these steps in strict order. Each step must complete successfully and pass verification before proceeding to the next:
- Early timing calculation - Derive section transitions from BPM and duration first
- Verify reference audio - Validate input file properties
- Generate and verify each stem individually - One stem at a time with immediate verification
- Generate drum stem separately - Dedicated drum extension with rhythm patterns
- Apply effects with verification - Process each stem and verify output
- Export master track - Mix all verified stems
- Archive and final verification - Package deliverables with comprehensive checks
Key Differences from Standard Workflow
- Incremental verification: Verify each stem immediately after generation, not just at the end
- Fail-fast approach: Stop and report errors at each step rather than accumulating failures
- Early timing: Calculate section transitions before any audio generation
- Separated drums: Drum stem generation is a distinct step with rhythm-specific processing
- Memory-efficient: Process stems individually to avoid large array operations that cause sandbox failures
Step 1: Calculate Timing Parameters (Early)
Calculate all timing parameters before generating any audio. This ensures consistent timing across all stems:
def calculate_section_transitions(bpm, total_duration_sec, sections):
"""Calculate beat-aligned transition points for song sections."""
beats_per_second = bpm / 60.0
section_durations = {}
cumulative_time = 0
for section_name, beat_count in sections.items():
duration = beat_count / beats_per_second
section_durations[section_name] = {
'start': cumulative_time,
'end': cumulative_time + duration,
'beats': beat_count,
'start_beat': cumulative_time * beats_per_second
}
cumulative_time += duration
return section_durations
BPM = 120
DURATION = 137
SECTIONS = {'intro': 16, 'verse': 32, 'chorus': 32, 'bridge': 16, 'outro': 16}
timing = calculate_section_transitions(BPM, DURATION, SECTIONS)
print("Timing calculated:")
for section, data in timing.items():
print(f" {section}: {data['start']:.2f}s - {data['end']:.2f}s ({data['beats']} beats)")
Step 2: Verify Reference Audio
Validate the reference file exists and has expected properties:
import soundfile as sf
import os
def verify_reference_file(filepath, expected_sample_rate=None, min_duration=None):
"""Verify reference audio file and return info dict."""
if not os.path.exists(filepath):
raise FileNotFoundError(f"Reference file not found: {filepath}")
info = sf.info(filepath)
errors = []
if expected_sample_rate and info.samplerate != expected_sample_rate:
errors.append(f"Sample rate mismatch: expected {expected_sample_rate}, got {info.samplerate}")
if min_duration and info.duration < min_duration:
errors.append(f"Duration too short: expected >= {min_duration}s, got {info.duration}s")
if errors:
raise ValueError(f"Reference file validation failed: {'; '.join(errors)}")
print(f"Reference verified: {info.duration:.2f}s @ {info.samplerate}Hz, {info.channels}ch, {info.subtype}")
return {
'sample_rate': info.samplerate,
'duration': info.duration,
'channels': info.channels,
'subtype': info.subtype
}
ref_info = verify_reference_file('reference.wav', expected_sample_rate=48000, min_duration=130)
Step 3: Generate and Verify Each Stem Individually
Generate one stem at a time, verify it immediately before proceeding to the next:
import numpy as np
def generate_stem(name, duration_sec, sample_rate, subtype='FLOAT', section_timing=None):
"""Generate a single stem with explicit sample type."""
frames = int(duration_sec * sample_rate)
t = np.linspace(0, duration_sec, frames)
if name == 'bass':
freq = 110
audio_data = np.sin(2 * np.pi * freq * t) * 0.8
elif name == 'guitars':
freq = 440
audio_data = np.sin(2 * np.pi * freq * t) * 0.6
elif name == 'synths':
freq = 880
audio_data = np.sin(2 * np.pi * freq * t) * 0.5
elif name == 'bridge':
freq = 220
audio_data = np.sin(2 * np.pi * freq * t) * 0.7
else:
audio_data = np.sin(2 * np.pi * 440 * t) * 0.5
if subtype == 'FLOAT':
audio_data = audio_data.astype(np.float32)
elif subtype == 'PCM_24':
audio_data = np.clip(audio_data, -1, 1) * (2**23 - 1)
audio_data = audio_data.astype(np.int32)
filepath = f'{name}_stem.wav'
sf.write(filepath, audio_data, sample_rate, subtype=subtype, format='WAV')
return filepath, audio_data
def verify_stem(filepath, expected_sample_rate, expected_subtype, expected_duration):
"""Verify a single stem meets specifications."""
if not os.path.exists(filepath):
return {'success': False, 'error': f'File not found: {filepath}'}
info = sf.info(filepath)
errors = []
if info.samplerate != expected_sample_rate:
errors.append(f'sample_rate: expected {expected_sample_rate}, got {info.samplerate}')
if info.subtype != expected_subtype:
errors.append(f'subtype: expected {expected_subtype}, got {info.subtype}')
if abs(info.duration - expected_duration) > 1.0:
errors.append(f'duration: expected ~{expected_duration}s, got {info.duration}s')
if errors:
return {'success': False, 'error': '; '.join(errors)}
return {'success': True, 'info': info}
SAMPLE_RATE = 48000
SUBTYPE = 'FLOAT'
STEM_NAMES = ['bass', 'guitars', 'synths', 'bridge']
generated_stems = []
for stem_name in STEM_NAMES:
print(f"\n=== Generating {stem_name} stem ===")
filepath, data = generate_stem(stem_name, DURATION, SAMPLE_RATE, subtype=SUBTYPE)
result = verify_stem(filepath, SAMPLE_RATE, SUBTYPE, DURATION)
if result['success']:
print(f"✓ {stem_name} stem verified: {result['info'].duration:.2f}s @ {result['info'].samplerate}Hz")
generated_stems.append(filepath)
else:
print(f"✗ {stem_name} stem FAILED: {result['error']}")
raise RuntimeError(f"Stem generation failed for {stem_name}: {result['error']}")
print(f"\nAll {len(generated_stems)} stems generated and verified successfully")
Step 4: Generate Drum Stem Separately
Drums require different processing (rhythm patterns, percussion sounds):
def generate_drum_stem(duration_sec, sample_rate, bpm, section_timing, subtype='FLOAT'):
"""Generate drum stem with rhythm patterns aligned to sections."""
frames = int(duration_sec * sample_rate)
audio_data = np.zeros(frames, dtype=np.float32)
beats_per_second = bpm / 60.0
kick_freq = 60
kick_duration = 0.1
kick_frames = int(kick_duration * sample_rate)
for beat_time in np.arange(0, duration_sec, 1.0 / beats_per_second):
start_frame = int(beat_time * sample_rate)
end_frame = min(start_frame + kick_frames, frames)
if start_frame < frames:
t = np.linspace(0, kick_duration, end_frame - start_frame)
kick = np.exp(-5 * t) * np.sin(2 * np.pi * kick_freq * t)
audio_data[start_frame:end_frame] += kick * 0.9
snare_freq = 200
snare_duration = 0.05
snare_frames = int(snare_duration * sample_rate)
for beat_time in np.arange(0, duration_sec, 2.0 / beats_per_second):
start_frame = int((beat_time + 0.5 / beats_per_second) * sample_rate)
end_frame = min(start_frame + snare_frames, frames)
if start_frame < frames:
t = np.linspace(0, snare_duration, end_frame - start_frame)
snare = np.exp(-10 * t) * np.random.uniform(-1, 1, len(t)) * 0.5
audio_data[start_frame:end_frame] += snare * 0.7
audio_data = np.clip(audio_data, -1, 1)
filepath = 'drums_stem.wav'
sf.write(filepath, audio_data, sample_rate, subtype=subtype, format='WAV')
return filepath, audio_data
print("\n=== Generating drum stem ===")
drums_filepath, drums_data = generate_drum_stem(DURATION, SAMPLE_RATE, BPM, timing, subtype=SUBTYPE)
drums_result = verify_stem(drums_filepath, SAMPLE_RATE, SUBTYPE, DURATION)
if drums_result['success']:
print(f"✓ Drum stem verified: {drums_result['info'].duration:.2f}s @ {drums_result['info'].samplerate}Hz")
generated_stems.append(drums_filepath)
else:
print(f"✗ Drum stem FAILED: {drums_result['error']}")
raise RuntimeError(f"Drum stem generation failed: {drums_result['error']}")
Step 5: Apply Effects with Verification
Process each stem and verify the output:
from scipy import signal
def apply_lowpass_filter(audio_data, sample_rate, cutoff_freq=8000):
"""Apply lowpass filter using scipy.signal."""
nyquist = sample_rate / 2
normalized_cutoff = cutoff_freq / nyquist
b, a = signal.butter(4, normalized_cutoff, btype='low')
return signal.filtfilt(b, a, audio_data)
def apply_effects_and_verify(input_filepath, output_filepath, sample_rate, subtype):
"""Apply effects to stem and verify output."""
data, sr = sf.read(input_filepath)
processed = apply_lowpass_filter(data, sr, cutoff_freq=8000)
processed = np.clip(processed, -1, 1)
sf.write(output_filepath, processed, sample_rate, subtype=subtype, format='WAV')
result = verify_stem(output_filepath, sample_rate, subtype, DURATION)
return result, processed
print("\n=== Applying effects to all stems ===")
processed_stems = []
for stem_name in STEM_NAMES:
input_file = f'{stem_name}_stem.wav'
output_file = f'{stem_name}_processed.wav'
print(f"Processing {stem_name}...")
result, _ = apply_effects_and_verify(input_file, output_file, SAMPLE_RATE, SUBTYPE)
if result['success']:
print(f"✓ {stem_name} processed and verified")
processed_stems.append(output_file)
else:
print(f"✗ {stem_name} processing FAILED: {result['error']}")
raise RuntimeError(f"Effects processing failed for {stem_name}")
drums_output = 'drums_processed.wav'
drums_result, _ = apply_effects_and_verify('drums_stem.wav', drums_output, SAMPLE_RATE, SUBTYPE)
if drums_result['success']:
print(f"✓ Drums processed and verified")
processed_stems.append(drums_output)
else:
raise RuntimeError(f"Drums processing failed: {drums_result['error']}")
Step 6: Export Master Track
Mix all verified stems into master track:
def create_master_track(stem_files, output_filepath, sample_rate, subtype):
"""Create master track from verified stems."""
first_data, sr = sf.read(stem_files[0])
master_audio = np.zeros(len(first_data), dtype=np.float32)
gain_per_stem = 0.4
for stem_file in stem_files:
data, _ = sf.read(stem_file)
if len(data) == len(master_audio):
master_audio += data * gain_per_stem
else:
print(f"WARNING: {stem_file} has different length, skipping")
master_audio = np.clip(master_audio, -1, 1)
sf.write(output_filepath, master_audio, sample_rate, subtype=subtype, format='WAV')
info = sf.info(output_filepath)
return {'success': True, 'info': info}
print("\n=== Creating master track ===")
master_result = create_master_track(processed_stems, 'master_track.wav', SAMPLE_RATE, SUBTYPE)
if master_result['success']:
print(f"✓ Master track created: {master_result['info'].duration:.2f}s @ {master_result['info'].samplerate}Hz")
else:
raise RuntimeError("Master track creation failed")
Step 7: Archive and Final Verification
Package all deliverables and perform comprehensive verification:
import zipfile
def create_archive(archive_name, file_list):
"""Create zip archive and verify contents."""
with zipfile.ZipFile(archive_name, 'w', zipfile.ZIP_DEFLATED) as zipf:
for filepath in file_list:
if os.path.exists(filepath):
zipf.write(filepath, os.path.basename(filepath))
else:
raise FileNotFoundError(f"Cannot archive: {filepath} not found")
with zipfile.ZipFile(archive_name, 'r') as zipf:
contents = zipf.namelist()
return {'success': True, 'file_count': len(contents), 'files': contents}
def final_verification(specs):
"""Comprehensive final verification of all outputs."""
results = {'passed': 0, 'failed': 0, 'details': []}
for filepath, expected in specs.items():
if not os.path.exists(filepath):
results['failed'] += 1
results['details'].append(f"MISSING: {filepath}")
continue
info = sf.info(filepath)
errors = []
if expected.get('sample_rate') and info.samplerate != expected['sample_rate']:
errors.append(f"sample_rate: {info.samplerate} != {expected['sample_rate']}")
if expected.get('subtype') and info.subtype != expected['subtype']:
errors.append(f"subtype: {info.subtype} != {expected['subtype']}")
if expected.get('min_duration') and info.duration < expected['min_duration']:
errors.append(f"duration: {info.duration}s < {expected['min_duration']}s")
if errors:
results['failed'] += 1
results['details'].append(f"FAILED: {filepath} - {'; '.join(errors)}")
else:
results['passed'] += 1
results['details'].append(f"PASSED: {filepath} ({info.duration:.2f}s, {info.samplerate}Hz)")
return results
print("\n=== Creating archive ===")
deliverables = ['master_track.wav'] + STEM_NAMES + ['drums']
deliverable_files = [f'{name}.wav' if name != 'drums' else 'drums_processed.wav' for name in ['master_track'] + STEM_NAMES + ['drums_processed']]
deliverable_files = ['master_track.wav'] + [f'{s}_processed.wav' for s in STEM_NAMES] + ['drums_processed.wav']
archive_result = create_archive('audio_deliverables.zip', deliverable_files)
print(f"✓ Archive created with {archive_result['file_count']} files")
print("\n=== Final verification ===")
expected_specs = {
'master_track.wav': {'sample_rate': SAMPLE_RATE, 'subtype': SUBTYPE, 'min_duration': DURATION - 5},
}
for stem in STEM_NAMES:
expected_specs[f'{stem}_processed.wav'] = {'sample_rate': SAMPLE_RATE, 'subtype': SUBTYPE, 'min_duration': DURATION - 5}
expected_specs['drums_processed.wav'] = {'sample_rate': SAMPLE_RATE, 'subtype': SUBTYPE, 'min_duration': DURATION - 5}
verification = final_verification(expected_specs)
print(f"\nFinal verification: {verification['passed']} passed, {verification['failed']} failed")
for detail in verification['details']:
print(f" {detail}")
assert verification['failed'] == 0, f"Final verification failed: {verification['details']}"
print("\n✓ Workflow completed successfully!")
Complete Workflow Script
"""
Incremental Audio Production Workflow
Generates, verifies, and archives audio stems with fail-fast checkpoints.
"""
import soundfile as sf
import numpy as np
from scipy import signal
import zipfile
import os
import sys
SAMPLE_RATE = 48000
DURATION = 137
BPM = 120
SUBTYPE = 'FLOAT'
STEM_NAMES = ['bass', 'guitars', 'synths', 'bridge']
SECTIONS = {'intro': 16, 'verse': 32, 'chorus': 32, 'bridge': 16, 'outro': 16}
def calculate_section_transitions(bpm, total_duration_sec, sections):
beats_per_second = bpm / 60.0
section_durations = {}
cumulative_time = 0
for section_name, beat_count in sections.items():
duration = beat_count / beats_per_second
section_durations[section_name] = {
'start': cumulative_time,
'end': cumulative_time + duration,
'beats': beat_count
}
cumulative_time += duration
return section_durations
def verify_stem(filepath, expected_sample_rate, expected_subtype, expected_duration):
if not os.path.exists(filepath):
return {'success': False, 'error': f'File not found: {filepath}'}
info = sf.info(filepath)
errors = []
if info.samplerate != expected_sample_rate:
errors.append(f'sample_rate mismatch')
if info.subtype != expected_subtype:
errors.append(f'subtype mismatch')
if abs(info.duration - expected_duration) > 1.0:
errors.append(f'duration mismatch')
if errors:
return {'success': False, 'error': '; '.join(errors)}
return {'success': True, 'info': info}
def generate_stem(name, duration_sec, sample_rate, subtype='FLOAT'):
frames = int(duration_sec * sample_rate)
t = np.linspace(0, duration_sec, frames)
freqs = {'bass': 110, 'guitars': 440, 'synths': 880, 'bridge': 220}
freq = freqs.get(name, 440)
audio_data = (np.sin(2 * np.pi * freq * t) * 0.5).astype(np.float32)
filepath = f'{name}_stem.wav'
sf.write(filepath, audio_data, sample_rate, subtype=subtype, format='WAV')
return filepath, audio_data
def generate_drum_stem(duration_sec, sample_rate, bpm, subtype='FLOAT'):
frames = int(duration_sec * sample_rate)
audio_data = np.zeros(frames, dtype=np.float32)
beats_per_second = bpm / 60.0
for beat_time in np.arange(0, duration_sec, 1.0 / beats_per_second):
start_frame = int(beat_time * sample_rate)
if start_frame < frames:
kick_duration = 0.1
kick_frames = int(kick_duration * sample_rate)
end_frame = min(start_frame + kick_frames, frames)
t = np.linspace(0, kick_duration, end_frame - start_frame)
kick = np.exp(-5 * t) * np.sin(2 * np.pi * 60 * t)
audio_data[start_frame:end_frame] += kick * 0.9
audio_data = np.clip(audio_data, -1, 1)
filepath = 'drums_stem.wav'
sf.write(filepath, audio_data, sample_rate, subtype=subtype, format='WAV')
return filepath, audio_data
def apply_effects(input_filepath, output_filepath, sample_rate, subtype):
data, sr = sf.read(input_filepath)
nyquist = sample_rate / 2
b, a = signal.butter(4, 8000 / nyquist, btype='low')
processed = signal.filtfilt(b, a, data)
processed = np.clip(processed, -1, 1)
sf.write(output_filepath, processed, sample_rate, subtype=subtype, format='WAV')
return verify_stem(output_filepath, sample_rate, subtype, DURATION)
def run_workflow():
print("=" * 60)
print("INCREMENTAL AUDIO PRODUCTION WORKFLOW")
print("=" * 60)
print("\n[Step 1] Calculating timing parameters...")
timing = calculate_section_transitions(BPM, DURATION, SECTIONS)
print(f"✓ Timing calculated for {len(SECTIONS)} sections")
print("\n[Step 2] Verifying reference file...")
if os.path.exists('reference.wav'):
ref_info = sf.info('reference.wav')
print(f"✓ Reference: {ref_info.duration:.2f}s @ {ref_info.samplerate}Hz")
else:
print("! No reference file found, proceeding with defaults")
print("\n[Step 3] Generating stems (one at a time)...")
generated_stems = []
for stem_name in STEM_NAMES:
print(f" Generating {stem_name}...")
filepath, _ = generate_stem(stem_name, DURATION, SAMPLE_RATE, subtype=SUBTYPE)
result = verify_stem(filepath, SAMPLE_RATE, SUBTYPE, DURATION)
if result['success']:
print(f" ✓ {stem_name} verified")
generated_stems.append(filepath)
else:
print(f" ✗ {stem_name} FAILED: {result['error']}")
sys.exit(1)
print("\n[Step 4] Generating drum stem...")
drums_filepath, _ = generate_drum_stem(DURATION, SAMPLE_RATE, BPM, subtype=SUBTYPE)
drums_result = verify_stem(drums_filepath, SAMPLE_RATE, SUBTYPE, DURATION)
if drums_result['success']:
print(f"✓ Drums verified")
generated_stems.append(drums_filepath)
else:
print(f"✗ Drums FAILED: {drums_result['error']}")
sys.exit(1)
print("\n[Step 5] Applying effects...")
processed_stems = []
for stem_name in STEM_NAMES:
input_file = f'{stem_name}_stem.wav'
output_file = f'{stem_name}_processed.wav'
result = apply_effects(input_file, output_file, SAMPLE_RATE, SUBTYPE)
if result['success']:
print(f" ✓ {stem_name} processed")
processed_stems.append(output_file)
else:
print(f" ✗ {stem_name} processing FAILED")
sys.exit(1)
drums_processed = 'drums_processed.wav'
drums_fx_result = apply_effects('drums_stem.wav', drums_processed, SAMPLE_RATE, SUBTYPE)
if drums_fx_result['success']:
print(f" ✓ Drums processed")
processed_stems.append(drums_processed)
else:
sys.exit(1)
print("\n[Step 6] Creating master track...")
first_data, _ = sf.read(processed_stems[0])
master_audio = np.zeros(len(first_data), dtype=np.float32)
for stem_file in processed_stems:
data, _ = sf.read(stem_file)
master_audio += data * 0.4
master_audio = np.clip(master_audio, -1, 1)
sf.write('master_track.wav', master_audio, SAMPLE_RATE, subtype=SUBTYPE, format='WAV')
master_info = sf.info('master_track.wav')
print(f"✓ Master track: {master_info.duration:.2f}s @ {master_info.samplerate}Hz")
print("\n[Step 7] Creating archive and final verification...")
all_files = ['master_track.wav'] + processed_stems
with zipfile.ZipFile('audio_deliverables.zip', 'w', zipfile.ZIP_DEFLATED) as zf:
for f in all_files:
zf.write(f)
with zipfile.ZipFile('audio_deliverables.zip', 'r') as zf:
print(f"✓ Archive contains {len(zf.namelist())} files")
specs = {f: {'sample_rate': SAMPLE_RATE, 'subtype': SUBTYPE} for f in all_files}
passed = failed = 0
for filepath, expected in specs.items():
info = sf.info(filepath)
if info.samplerate == expected['sample_rate'] and info.subtype == expected['subtype']:
passed += 1
else:
failed += 1
print(f" ✗ {filepath} verification failed")
print(f"\nFinal verification: {passed} passed, {failed} failed")
if failed > 0:
sys.exit(1)
print("\n" + "=" * 60)
print("WORKFLOW COMPLETED SUCCESSFULLY")
print("=" * 60)
return 0
if __name__ == '__main__':
sys.exit(run_workflow())
Troubleshooting
Common Issues
Memory errors during stem generation:
- Process stems one at a time (this skill's default approach)
- Reduce duration or sample rate for testing
- Use
np.float32 instead of np.float64
Sample rate mismatches:
- Always specify
sample_rate explicitly in sf.write()
- Verify with
sf.info() after each write operation
- Check that
subtype parameter is specified
Archive creation failures:
- Verify all files exist before archiving
- Use
zipfile.ZIP_DEFLATED for compression
- Check file permissions
Best Practices
- Run incrementally: Test each step independently before running full workflow
- Verify early: Check output properties immediately after generation
- Use explicit types: Always specify
subtype and format parameters
- Monitor memory: Process large files in chunks if needed
- Keep logs: Save verification results for debugging