بنقرة واحدة
audio-track-production
End-to-end audio production workflow with stems, effects, archiving, and verification
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القائمة
End-to-end audio production workflow with stems, effects, archiving, and verification
التثبيت باستخدام Codex أو Claude انسخ هذا Prompt والصقه في Codex أو Claude أو مساعد آخر ليراجع صفحة Skill ويثبّتها لك.
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Incremental audio production with duration mismatch handling, adaptive stem extension, and pre-mix alignment verification
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Incremental audio production with duration alignment handling, per-stem verification, and adaptive extension strategies
Step-by-step audio production with per-stem verification, timing alignment, and incremental quality gates
Handle cascading data retrieval tool failures by falling back to embedded knowledge generation
| name | audio-track-production |
| description | End-to-end audio production workflow with stems, effects, archiving, and verification |
This skill provides a reusable pattern for executing audio production tasks that require generating a master track and multiple stems, applying effects, and delivering verified outputs in an archive.
Follow these steps in order to ensure consistent, verifiable audio production outputs:
Before processing, verify the reference audio file is valid and readable:
import soundfile as sf
# Verify reference file exists and is readable
info = sf.info('reference_track.wav')
print(f"Sample rate: {info.samplerate} Hz")
print(f"Duration: {info.frames / info.samplerate:.2f} seconds")
print(f"Channels: {info.channels}")
print(f"Subtype: {info.subtype}")
Derive timing for key section transitions from BPM and total duration:
def calculate_section_transitions(bpm, total_duration_sec, sections):
"""Calculate beat-aligned transition points for song sections."""
beats_per_second = bpm / 60.0
total_beats = total_duration_sec * beats_per_second
# Distribute sections proportionally or by specified ratios
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
# Example usage
sections = calculate_section_transitions(
bpm=120,
total_duration_sec=137,
sections={'intro': 16, 'verse': 32, 'chorus': 32, 'bridge': 16, 'outro': 16}
)
Always specify sample type explicitly when generating stems to ensure bit-depth consistency:
import numpy as np
import soundfile as sf
def generate_stem(name, duration_sec, sample_rate, subtype='FLOAT'):
"""Generate a stem with explicit sample type specification."""
frames = int(duration_sec * sample_rate)
# Generate audio content (replace with actual synthesis/processing)
t = np.linspace(0, duration_sec, frames)
audio_data = np.sin(2 * np.pi * 440 * t) # Example: 440Hz tone
# Ensure proper data type for specified subtype
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)
sf.write(
f'{name}_stem.wav',
audio_data,
sample_rate,
subtype=subtype, # Explicit subtype for 24-bit float or other
format='WAV'
)
return audio_data
# Example: Generate 4 stems at 48kHz, 137s, 24-bit float
sample_rate = 48000
duration = 137
stems = ['guitars', 'synths', 'bridge', 'bass']
for stem_name in stems:
generate_stem(stem_name, duration, sample_rate, subtype='FLOAT')
Use scipy.signal for applying audio effects and processing:
from scipy import signal
import numpy as np
def apply_lowpass_filter(audio_data, sample_rate, cutoff_freq=5000):
"""Apply a lowpass filter using scipy.signal."""
nyquist = sample_rate / 2
normalized_cutoff = cutoff_freq / nyquist
# Design Butterworth filter
b, a = signal.butter(4, normalized_cutoff, btype='low')
# Apply filter
filtered_data = signal.filtfilt(b, a, audio_data)
return filtered_data
def apply_reverb_simple(audio_data, sample_rate, decay=0.5, delay_samples=1000):
"""Apply simple reverb effect."""
reverbed = np.copy(audio_data)
decay_factor = decay
for i in range(1, 6):
delayed = np.zeros_like(audio_data)
if len(audio_data) > delay_samples * i:
delayed[delay_samples * i:] = audio_data[:-delay_samples * i]
reverbed += delayed * (decay_factor ** i)
return np.clip(reverbed, -1, 1)
# Apply effects to stems
for stem_name in stems:
data, sr = sf.read(f'{stem_name}_stem.wav')
processed = apply_lowpass_filter(data, sr, cutoff_freq=8000)
processed = apply_reverb_simple(processed, sr, decay=0.3)
sf.write(f'{stem_name}_stem_processed.wav', processed, sr, subtype='FLOAT')
Export all final deliverables with consistent specifications:
def export_audio(filepath, audio_data, sample_rate, subtype='FLOAT'):
"""Export audio file with verified specifications."""
sf.write(
filepath,
audio_data,
sample_rate,
subtype=subtype,
format='WAV'
)
# Verify export
info = sf.info(filepath)
assert info.samplerate == sample_rate, f"Sample rate mismatch: {info.samplerate}"
assert info.subtype == subtype, f"Subtype mismatch: {info.subtype}"
print(f"Exported: {filepath} ({info.duration:.2f}s, {info.samplerate}Hz)")
# Export master (mix of all stems)
master_audio = np.zeros_like(stem_audio) # Replace with actual mix
for stem_name in stems:
stem_data, _ = sf.read(f'{stem_name}_stem_processed.wav')
master_audio += stem_data * 0.5 # Simple mix with gain staging
master_audio = np.clip(master_audio, -1, 1)
export_audio('master_track.wav', master_audio, sample_rate=48000, subtype='FLOAT')
# Export final stems
for stem_name in stems:
stem_data, sr = sf.read(f'{stem_name}_stem_processed.wav')
export_audio(f'{stem_name}.wav', stem_data, sample_rate=48000, subtype='FLOAT')
Package all outputs in a zip archive:
import zipfile
import os
def create_archive(archive_name, file_list):
"""Create zip archive of deliverables."""
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))
print(f"Added to archive: {filepath}")
else:
print(f"WARNING: File not found: {filepath}")
# Verify archive
with zipfile.ZipFile(archive_name, 'r') as zipf:
contents = zipf.namelist()
print(f"Archive contains {len(contents)} files: {contents}")
return archive_name
# Archive master and stems
deliverables = ['master_track.wav'] + [f'{stem}.wav' for stem in stems]
create_archive('audio_deliverables.zip', deliverables)
Final verification that all outputs match specifications:
def verify_outputs(expected_specs):
"""Verify all output files match expected specifications."""
results = {'passed': 0, 'failed': 0, 'details': []}
for filepath, specs in expected_specs.items():
if not os.path.exists(filepath):
results['failed'] += 1
results['details'].append(f"MISSING: {filepath}")
continue
info = sf.info(filepath)
errors = []
if specs.get('sample_rate') and info.samplerate != specs['sample_rate']:
errors.append(f"sample_rate: expected {specs['sample_rate']}, got {info.samplerate}")
if specs.get('subtype') and info.subtype != specs['subtype']:
errors.append(f"subtype: expected {specs['subtype']}, got {info.subtype}")
if specs.get('min_duration') and info.duration < specs['min_duration']:
errors.append(f"duration: expected >= {specs['min_duration']}s, got {info.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, {info.subtype})")
return results
# Verification specifications
expected_specs = {
'master_track.wav': {'sample_rate': 48000, 'subtype': 'FLOAT', 'min_duration': 137},
'guitars.wav': {'sample_rate': 48000, 'subtype': 'FLOAT', 'min_duration': 137},
'synths.wav': {'sample_rate': 48000, 'subtype': 'FLOAT', 'min_duration': 137},
'bridge.wav': {'sample_rate': 48000, 'subtype': 'FLOAT', 'min_duration': 137},
'bass.wav': {'sample_rate': 48000, 'subtype': 'FLOAT', 'min_duration': 137},
}
verification = verify_outputs(expected_specs)
print(f"\nVerification: {verification['passed']} passed, {verification['failed']} failed")
for detail in verification['details']:
print(detail)
assert verification['failed'] == 0, "Output verification failed!"
#!/usr/bin/env python3
"""Complete audio production workflow execution."""
import soundfile as sf
import numpy as np
from scipy import signal
import zipfile
import os
# Configuration
SAMPLE_RATE = 48000
DURATION = 137
BPM = 120
STEM_NAMES = ['guitars', 'synths', 'bridge', 'bass']
SUBTYPE = 'FLOAT'
def run_workflow():
# Step 1: Verify reference
ref_info = sf.info('reference.wav')
print(f"Reference: {ref_info.duration}s @ {ref_info.samplerate}Hz")
# Step 2: Calculate timing
bpm = BPM
beats_per_sec = bpm / 60
# Step 3-4: Generate and process stems
for stem in STEM_NAMES:
frames = int(DURATION * SAMPLE_RATE)
t = np.linspace(0, DURATION, frames)
audio = np.sin(2 * np.pi * 220 * t) # Example content
# Apply effects
audio = apply_lowpass_filter(audio, SAMPLE_RATE, 8000)
# Export with explicit subtype
sf.write(f'{stem}.wav', audio, SAMPLE_RATE, subtype=SUBTYPE)
# Step 5: Export master
master = np.zeros(int(DURATION * SAMPLE_RATE))
for stem in STEM_NAMES:
data, _ = sf.read(f'{stem}.wav')
master += data * 0.5
master = np.clip(master, -1, 1)
sf.write('master_track.wav', master, SAMPLE_RATE, subtype=SUBTYPE)
# Step 6: Archive
files = ['master_track.wav'] + [f'{s}.wav' for s in STEM_NAMES]
with zipfile.ZipFile('deliverables.zip', 'w') as zf:
for f in files:
zf.write(f)
# Step 7: Verify
specs = {f: {'sample_rate': SAMPLE_RATE, 'subtype': SUBTYPE} for f in files}
results = verify_outputs(specs)
assert results['failed'] == 0
print("Workflow complete!")
if __name__ == '__main__':
run_workflow()
subtype parameter (e.g., subtype='FLOAT' for 24-bit float WAV)