using DeepDrftContent.Constants;
using DeepDrftContent.FileDatabase.Services;
using DeepDrftContent.FileDatabase.Models;
using DeepDrftContent.Processors;
using DeepDrftModels.Entities;
namespace DeepDrftContent;
///
/// Service for managing tracks in both SQL and FileDatabase
///
public class TrackContentService
{
private readonly FileDatabase.Services.FileDatabase _fileDatabase;
private readonly AudioProcessorRouter _audioProcessorRouter;
public TrackContentService(FileDatabase.Services.FileDatabase fileDatabase, AudioProcessorRouter audioProcessorRouter)
{
_fileDatabase = fileDatabase;
_audioProcessorRouter = audioProcessorRouter;
}
///
/// Adds a new track from a supported audio file (.wav, .mp3, .flac) to both databases. The
/// router selects the processor by extension; original bytes are stored for mp3/flac (no
/// transcoding), while EXTENSIBLE WAVs are normalized to standard PCM at storage time.
///
/// Path to the audio file
/// Name of the track
/// Artist name
/// Optional album name
/// Optional genre
/// Optional release date
/// Optional original browser filename captured at upload time
/// The track entity with generated ID and media path
public async Task AddTrackAsync(
string audioFilePath,
string trackName,
string artist,
string? album = null,
string? genre = null,
DateOnly? releaseDate = null,
string? originalFileName = null,
CancellationToken cancellationToken = default)
{
try
{
// Process the audio file (routed by extension). The returned plan carries metadata plus a
// streamed writer — no whole-file buffer (the store-path OOM fix).
var processed = await _audioProcessorRouter.ProcessAudioFileAsync(audioFilePath, cancellationToken);
if (processed == null)
{
throw new InvalidOperationException("Failed to process audio file");
}
// Generate a unique track ID
var trackId = Guid.NewGuid().ToString();
// Ensure tracks vault exists
if (!_fileDatabase.HasVault(VaultConstants.Tracks))
{
await _fileDatabase.CreateVaultAsync(VaultConstants.Tracks, MediaVaultType.Audio);
}
// Stream the audio into the vault. The metadata is supplied directly (there is no in-memory
// AudioBinary on this path), and the bytes are written progressively from the staging file.
var metaData = MetaDataFactory.CreateAudioMetaData(trackId, processed.Extension, processed.Duration, processed.Bitrate);
var success = await _fileDatabase.RegisterResourceStreamingAsync(
VaultConstants.Tracks, trackId, metaData, processed.WriteToAsync, cancellationToken);
if (!success)
{
throw new InvalidOperationException("Failed to store audio in FileDatabase");
}
// Create the track entity for SQL database. Post Phase 8 §8.0 the entity holds only
// track-cardinal fields; release-cardinal data (artist/album/genre/releaseDate) is
// resolved into a ReleaseEntity by the caller (UnifiedTrackService) and linked via FK.
var trackEntity = new TrackEntity
{
EntryKey = trackId, // FileDatabase entry ID
TrackName = trackName,
OriginalFileName = originalFileName,
// Persist the processor-extracted runtime to SQL so aggregate queries (total mix runtime)
// need not touch the vault. Same value the high-res waveform compute reads downstream.
DurationSeconds = processed.Duration
};
return trackEntity;
}
catch (Exception ex) when (ex is not OperationCanceledException)
{
Console.WriteLine($"TrackContentService.AddTrackAsync failed: {ex.Message}");
return null;
}
}
///
/// Backward-compatible shim — delegates to . The router accepts WAV
/// alongside MP3 and FLAC, so this carries no WAV-specific logic of its own.
///
public Task AddTrackFromWavAsync(
string wavFilePath,
string trackName,
string artist,
string? album = null,
string? genre = null,
DateOnly? releaseDate = null,
string? originalFileName = null,
CancellationToken cancellationToken = default) =>
AddTrackAsync(wavFilePath, trackName, artist, album, genre, releaseDate, originalFileName, cancellationToken);
///
/// Swaps the audio bytes for an existing track in place: processes a new audio file and
/// re-registers it under the SAME in the tracks vault. The track's
/// vault key — and therefore its SQL link, release membership, position, and metadata — is
/// untouched; only the binary changes. The new audio is streamed to the vault first; only on
/// confirmed success is a stale old backing file cleaned up. A cross-format replacement (e.g.
/// .wav → .flac) leaves the old file on disk under its former filename once the index is updated;
/// the post-success cleanup removes it. For a same-extension overwrite the register alone suffices.
/// If the register fails the original audio is left intact and null is returned, so the track
/// remains playable. Returns the freshly stored audio's duration on success (the caller
/// re-reads the vault for waveform regen and uses this for the SQL duration write) — matching the
/// FileDatabase swallow-and-return-null contract. The new bytes are never materialized in memory.
///
public async Task ReplaceTrackAudioAsync(string entryKey, string audioFilePath, CancellationToken cancellationToken = default)
{
try
{
// Capture the old extension from the index metadata (not by loading the file — that would
// pull the whole old audio into memory). After register the index points to the new
// extension, so we need the old value now to detect a cross-format swap and clean up the
// stale file post-success.
var trackVault = _fileDatabase.GetVault(VaultConstants.Tracks);
var existingMeta = trackVault is null ? null : await trackVault.GetEntryMetadata(entryKey);
var oldExtension = existingMeta?.Extension;
var processed = await _audioProcessorRouter.ProcessAudioFileAsync(audioFilePath, cancellationToken);
if (processed == null)
{
Console.WriteLine($"TrackContentService.ReplaceTrackAudioAsync: processing returned null for {entryKey}");
return null;
}
if (!_fileDatabase.HasVault(VaultConstants.Tracks))
{
await _fileDatabase.CreateVaultAsync(VaultConstants.Tracks, MediaVaultType.Audio);
}
// Stream the new audio in. This upserts the index entry (new extension recorded) and writes
// the new file to disk. If this fails the original entry and file are untouched.
var metaData = MetaDataFactory.CreateAudioMetaData(entryKey, processed.Extension, processed.Duration, processed.Bitrate);
var success = await _fileDatabase.RegisterResourceStreamingAsync(
VaultConstants.Tracks, entryKey, metaData, processed.WriteToAsync, cancellationToken);
if (!success)
{
Console.WriteLine($"TrackContentService.ReplaceTrackAudioAsync: vault write failed for {entryKey}; original audio preserved");
return null;
}
// Post-success stale-file cleanup for cross-format swaps. The register wrote the new
// file (e.g. .flac) and updated the index to the new extension, but the old backing
// file (e.g. .wav) is now unreferenced on disk. Delete it directly by constructing the
// old path — RemoveResourceAsync would now resolve to the new extension and delete the
// wrong file. Non-fatal: an orphaned old file is a disk-hygiene concern, not a
// playback issue (the index no longer references it).
if (oldExtension != null && oldExtension != processed.Extension)
{
var vault = _fileDatabase.GetVault(VaultConstants.Tracks);
if (vault != null)
{
var sanitizedKey = System.Text.RegularExpressions.Regex.Replace(entryKey, @"[^a-zA-Z0-9]", "-");
var staleFilePath = Path.Combine(vault.RootPath, $"{sanitizedKey}{oldExtension}");
try
{
if (File.Exists(staleFilePath))
File.Delete(staleFilePath);
}
catch (Exception ex)
{
Console.WriteLine($"TrackContentService.ReplaceTrackAudioAsync: stale backing-file removal failed for {entryKey} ({staleFilePath}): {ex.Message} — new audio is live; orphaned file may remain on disk");
}
}
}
return processed.Duration;
}
catch (Exception ex) when (ex is not OperationCanceledException)
{
Console.WriteLine($"TrackContentService.ReplaceTrackAudioAsync failed: {ex.Message}");
return null;
}
}
///
/// Retrieves audio binary from FileDatabase
///
/// Track ID (EntryKey)
/// Audio binary or null if not found
public async Task GetAudioBinaryAsync(string trackId)
{
return await _fileDatabase.LoadResourceAsync(VaultConstants.Tracks, trackId);
}
///
/// Opens a read-only, seekable stream over a track's vault audio, or null if the entry has no
/// backing file. The caller owns the stream and must dispose it. Unlike
/// this never buffers the whole file — it is the source for the streaming waveform compute. Follows
/// the FileDatabase swallow-and-return-null contract.
///
/// Track ID (EntryKey)
public async Task OpenAudioStreamAsync(string trackId)
{
var vault = _fileDatabase.GetVault(VaultConstants.Tracks);
if (vault is null)
{
return null;
}
var media = await vault.GetEntryStreamAsync(trackId);
return media?.Stream;
}
///
/// Opens a read-only stream over a track's vault audio together with its stored extension, or null if
/// the entry has no backing file. Same non-buffering contract as ,
/// but keeps the the caller needs to name a staging file for a
/// format-detecting consumer (the Opus transcode reopens the source by extension for ffmpeg). The
/// caller owns the returned and must dispose it. Follows the FileDatabase
/// swallow-and-return-null contract.
///
/// Track ID (EntryKey)
public async Task OpenAudioMediaStreamAsync(string trackId)
{
var vault = _fileDatabase.GetVault(VaultConstants.Tracks);
if (vault is null)
{
return null;
}
return await vault.GetEntryStreamAsync(trackId);
}
///
/// Reads a track's stored audio duration from the vault index metadata WITHOUT loading the audio
/// body — the cheap counterpart of GetAudioBinaryAsync(...).Duration. Returns null if the
/// entry is unknown or carries no audio metadata. The streaming high-res waveform path uses this to
/// derive the duration-based bucket count, matching the value the whole-buffer path read off
/// so the stored datum is byte-identical.
///
/// Track ID (EntryKey)
public async Task GetAudioDurationAsync(string trackId)
{
var vault = _fileDatabase.GetVault(VaultConstants.Tracks);
if (vault is null)
{
return null;
}
var metaData = await vault.GetEntryMetadata(trackId);
return metaData is AudioMetaData audio ? audio.Duration : null;
}
///
/// Checks if FileDatabase is available and tracks vault exists
///
public bool IsFileDatabaseReady()
{
return _fileDatabase.HasVault(VaultConstants.Tracks);
}
///
/// Initializes the tracks vault if it doesn't exist
///
public async Task InitializeTracksVaultAsync()
{
if (!_fileDatabase.HasVault(VaultConstants.Tracks))
{
await _fileDatabase.CreateVaultAsync(VaultConstants.Tracks, MediaVaultType.Audio);
}
}
}