From 1d7b8b22fdf402feca3ce3f7819e7b2e3faa02d2 Mon Sep 17 00:00:00 2001 From: pat-e Date: Mon, 13 Apr 2026 13:06:40 +0200 Subject: [PATCH] Replace with newest version from Github 2/2 --- README.md | 216 +++--- svt_opus_encoder.py | 1550 ++++++++++++++++++++++--------------------- 2 files changed, 893 insertions(+), 873 deletions(-) diff --git a/README.md b/README.md index fbc94f2..f737262 100644 --- a/README.md +++ b/README.md @@ -1,100 +1,116 @@ -# AV1 Encoding Scripts - -## Overview -This repository contains Python scripts for batch-processing MKV files to encode video to AV1 and audio to Opus. The scripts prioritize high-quality encoding, handle complex audio track downmixing, VFR (Variable Frame Rate) conversions, and offer features like automatic cropping and resumable encoding. - -## Scripts Overview - -* **`aom_opus_encoder.py`**: Uses the `aom` encoder (specifically designed for the `aom-psy101` fork) via `av1an`. It is tuned for high perceptual quality with specific psychovisual parameters and film grain synthesis. -* **`svt_opus_encoder.py`**: Uses the `svt-av1` encoder (specifically designed for the `SVT-AV1-Essential` fork) via `av1an`. It provides a good balance between encoding speed and quality, and allows customization of speed, quality, and film-grain presets from the command line. - -## Encoding Parameters Documentation - -For detailed information on the specific FFmpeg arguments, audio downmixing logic, VFR-to-CFR conversion processes, and the special SVT-AV1/AomEnc parameters used by these scripts, please refer to the [`parameters.md`](parameters.md) file. - -## Prerequisites - -Both scripts require several external tools to be installed and available in your system's `PATH`: - -* **ffmpeg** & **ffprobe**: For video/audio extraction, filtering (cropdetect), and loudnorm analysis. -* **mkvtoolnix** (`mkvmerge`, `mkvpropedit`): For remuxing the final MKV file. -* **opusenc** (opus-tools): For encoding audio tracks to the Opus codec. -* **mediainfo**: For extracting detailed media information (especially frame rate details). -* **av1an**: The core chunking encoder used to run multiple encode workers in parallel. -* **HandBrakeCLI**: Used as a fallback/pre-processor to convert VFR (Variable Frame Rate) video to CFR (Constant Frame Rate) before the main encode. -* **ffmsindex** (ffms2): For indexing the intermediate UTVideo file for Vapoursynth. -* **Vapoursynth**: Required by `av1an` as the frame server via the generated `.vpy` scripts. -* *(Specific to `aom_opus_encoder.py`)*: **aom-psy101** encoder. You must download the correct version from [Damian101's aom-psy101 GitLab](https://gitlab.com/damian101/aom-psy101). -* *(Specific to `svt_opus_encoder.py`)*: **SVT-AV1-Essential** encoder. You must download the correct version from [nekotrix's SVT-AV1-Essential GitHub](https://github.com/nekotrix/SVT-AV1-Essential/). - -## Features - -* **Automated Batch Processing**: Simply place your `.mkv` files in the same directory as the script. The script will process them one by one. -* **Resumable Encoding**: Because it uses `av1an`, if an encode is interrupted, you can restart the script, and it will resume from where it left off. -* **Audio Normalization and Downmixing**: - * Extracts audio tracks to FLAC. - * Applies a 2-pass `loudnorm` normalization (Target: -23 LUFS, True Peak: -1 dB). - * Downmixes 5.1/7.1 surround sound to stereo (unless `--no-downmix` is specified). - * Encodes to Opus with bitrates automatically chosen based on the channel count (e.g., 128k for Stereo, 256k for 5.1). - * Directly remuxes existing `aac` or `opus` tracks without re-encoding. - * Preserves track languages, titles, and delays. -* **VFR to CFR Conversion**: Detects Variable Frame Rate (VFR) media and automatically converts it to Constant Frame Rate (CFR) using HandBrakeCLI (virtually lossless `x264_10bit` CRF 0 intermediate) to prevent audio desync issues. -* **Automatic Cropping**: Optional `--autocrop` flag detects black bars and determines the optimal cropping parameters before encoding. -* **Organized Output**: - * Completed files are moved to a `completed/` directory. - * Original files are moved to an `original/` directory. - * Per-file processing logs are saved in a `conv_logs/` directory. - * Temporary files are automatically cleaned up upon success. - -## Usage - -Place the script in the directory containing your `.mkv` files and execute it. - -### `aom_opus_encoder.py` - -```bash -python aom_opus_encoder.py [options] -``` - -**Options:** -* `--no-downmix`: Preserve original audio channel layout (do not downmix 5.1/7.1 to stereo). -* `--autocrop`: Automatically detect and crop black bars from the video. -* `--grain `: Set the `photon-noise` value for grain synthesis (default: 8). -* `--crf `: Set the constant quality level (`cq-level`) for video encoding (default: 28). - -### `svt_opus_encoder.py` - -```bash -python svt_opus_encoder.py [options] -``` - -**Options:** -* `--no-downmix`: Preserve original audio channel layout (do not downmix 5.1/7.1 to stereo). -* `--autocrop`: Automatically detect and crop black bars from the video. -* `--speed `: Set the SVT-AV1 encoding speed preset (e.g., `slower`, `slow`, `medium`, `fast`, `faster`). Defaults to `slower`. -* `--quality `: Set the SVT-AV1 encoding quality preset (e.g., `lowest`, `low`, `medium`, `high`, `higher`). Defaults to `medium`. -* `--grain `: Set the `film-grain` value. Adjusts the film grain synthesis level. Defaults to 6. - -## Process Workflow - -1. **Preparation**: Scans for `.mkv` files and checks for required tools. -2. **Analysis**: Examines video and audio tracks using `ffprobe` and `mediainfo`. -3. **Video Processing**: - * Runs crop detection (if `--autocrop` is enabled). - * Converts VFR to CFR (if VFR is detected). - * Extracts an intermediate lossless video (`utvideo`). - * Encodes the video using `av1an`. -4. **Audio Processing**: - * Remuxes AAC/Opus. - * Normalizes, downmixes (if applicable), and encodes other formats to Opus. -5. **Muxing**: Combines the newly encoded video and audio tracks using `mkvmerge`, preserving synchronization delays, metadata, and languages. -6. **Cleanup**: Moves files to respective folders (`completed/`, `original/`) and deletes temporary working files. - -## Notes - -- Encoding AV1 takes a significant amount of time and CPU resources. -- Ensure you have sufficient disk space, as the scripts generate intermediate lossless `utvideo` files which can be very large depending on the length and resolution of the source media. - -## License - -This project is licensed under the MIT License - see the [`LICENSE.md`](LICENSE.md) file for details. +# AV1 Encoding Scripts + +## Overview +This repository contains Python scripts for batch-processing MKV files to encode video to AV1 and audio to Opus. The scripts prioritize high-quality encoding, handle complex audio track downmixing, VFR (Variable Frame Rate) conversions, and offer features like automatic cropping and resumable encoding. + +## Scripts Overview + +* **`aom_opus_encoder.py`**: Uses the `aom` encoder (specifically designed for the `aom-psy101` fork) via `av1an`. It is tuned for high perceptual quality with specific psychovisual parameters and film grain synthesis. +* **`svt_opus_encoder.py`**: Uses the `svt-av1` encoder (specifically designed for the `SVT-AV1-Essential` fork) via `av1an`. It provides a good balance between encoding speed and quality, and allows customization of preset, crf, and film-grain from the command line. +* **`hdr_svt_opus_encoder.py`**: A specialized script for 4K HDR movies using the `SVT-AV1-Essential` encoder. It is designed for pre-processed CFR inputs, preserves original surround sound audio without downmixing, and retains HDR metadata. + +## Encoding Parameters Documentation + +For detailed information on the specific FFmpeg arguments, audio downmixing logic, VFR-to-CFR conversion processes, and the special SVT-AV1/AomEnc parameters used by the standard scripts, please refer to the [`parameters.md`](parameters.md) file. + +For the HDR-specific encoder parameters and settings used in `hdr_svt_opus_encoder.py`, please see [`parameters_hdr.md`](parameters_hdr.md). + +## Prerequisites + +Both scripts require several external tools to be installed and available in your system's `PATH`: + +* **ffmpeg** & **ffprobe**: For video/audio extraction, filtering (cropdetect), and loudnorm analysis. +* **mkvtoolnix** (`mkvmerge`, `mkvpropedit`): For remuxing the final MKV file. +* **opusenc** (opus-tools): For encoding audio tracks to the Opus codec. +* **mediainfo**: For extracting detailed media information (especially frame rate details). +* **av1an**: The core chunking encoder used to run multiple encode workers in parallel. +* **HandBrakeCLI**: Used as a fallback/pre-processor to convert VFR (Variable Frame Rate) video to CFR (Constant Frame Rate) before the main encode. +* **ffmsindex** (ffms2): For indexing the intermediate UTVideo file for Vapoursynth. +* **Vapoursynth**: Required by `av1an` as the frame server via the generated `.vpy` scripts. +* *(Specific to `aom_opus_encoder.py`)*: **aom-psy101** encoder. You must download the correct version from [Damian101's aom-psy101 GitLab](https://gitlab.com/damian101/aom-psy101). +* *(Specific to `svt_opus_encoder.py`)*: **SVT-AV1-Essential** encoder. You must download the correct version from [nekotrix's SVT-AV1-Essential GitHub](https://github.com/nekotrix/SVT-AV1-Essential/). + +## Features + +* **Automated Batch Processing**: Simply place your `.mkv` files in the same directory as the script. The script will process them one by one. +* **Resumable Encoding**: Because it uses `av1an`, if an encode is interrupted, you can restart the script, and it will resume from where it left off. +* **Audio Normalization and Downmixing**: + * Extracts audio tracks to FLAC. + * Applies a 2-pass `loudnorm` normalization (Target: -23 LUFS, True Peak: -1 dB). + * Downmixes 5.1/7.1 surround sound to stereo (unless `--no-downmix` is specified). + * Encodes to Opus with bitrates automatically chosen based on the channel count (e.g., 128k for Stereo, 256k for 5.1). + * Directly remuxes existing `aac` or `opus` tracks without re-encoding. + * Preserves track languages, titles, and delays. +* **VFR to CFR Conversion**: Detects Variable Frame Rate (VFR) media and automatically converts it to Constant Frame Rate (CFR) using HandBrakeCLI (virtually lossless `x264_10bit` CRF 0 intermediate) to prevent audio desync issues. +* **Automatic Cropping**: Optional `--autocrop` flag detects black bars and determines the optimal cropping parameters before encoding. +* **Organized Output**: + * Completed files are moved to a `completed/` directory. + * Original files are moved to an `original/` directory. + * Per-file processing logs are saved in a `conv_logs/` directory. + * Temporary files are automatically cleaned up upon success. + +## Usage + +It is highly recommended to place these scripts (or symbolic links to them) in a directory that is included in your system's `PATH` variable (e.g., `~/bin` on Linux/macOS, or a custom Scripts folder on Windows). This allows you to run the commands directly from any directory. + +To use the scripts, open your terminal (bash, PowerShell, etc.), navigate to the folder containing your `.mkv` files, and simply type the name of the script. + +### `aom_opus_encoder.py` + +```bash +aom_opus_encoder.py [options] +``` + +**Options:** +* `--no-downmix`: Preserve original audio channel layout (do not downmix 5.1/7.1 to stereo). +* `--autocrop`: Automatically detect and crop black bars from the video. +* `--grain `: Set the `photon-noise` value for grain synthesis (default: 8). +* `--crf `: Set the constant quality level (`cq-level`) for video encoding (default: 25). + +### `svt_opus_encoder.py` + +```bash +svt_opus_encoder.py [options] +``` + +**Options:** +* `--no-downmix`: Preserve original audio channel layout (do not downmix 5.1/7.1 to stereo). +* `--autocrop`: Automatically detect and crop black bars from the video. +* `--preset `: Set the SVT-AV1 encoding speed preset (e.g., 0-13). Lower is slower and yields better compression. Defaults to 1. +* `--crf `: Set the SVT-AV1 Constant Rate Factor (CRF) for video quality (e.g., 0-63). Lower is better quality. Defaults to 30. +* `--grain `: Set the `film-grain` value. Adjusts the film grain synthesis level. Defaults to 6. + +### `hdr_svt_opus_encoder.py` + +```bash +hdr_svt_opus_encoder.py [options] +``` + +**Options:** +* `--preset `: Set the SVT-AV1 encoding speed preset (e.g., 0-13). Lower is slower and yields better compression. Defaults to 1. +* `--crf `: Set the SVT-AV1 Constant Rate Factor (CRF) for video quality (e.g., 0-63). Lower is better quality. Defaults to 30. +* `--grain `: Set the `film-grain` value. Adjusts the film grain synthesis level. Defaults to 12. + +## Process Workflow + +1. **Preparation**: Scans for `.mkv` files and checks for required tools. +2. **Analysis**: Examines video and audio tracks using `ffprobe` and `mediainfo`. +3. **Video Processing**: + * Runs crop detection (if `--autocrop` is enabled). + * Converts VFR to CFR (if VFR is detected). + * Extracts an intermediate lossless video (`utvideo`). + * Encodes the video using `av1an`. +4. **Audio Processing**: + * Remuxes AAC/Opus. + * Normalizes, downmixes (if applicable), and encodes other formats to Opus. +5. **Muxing**: Combines the newly encoded video and audio tracks using `mkvmerge`, preserving synchronization delays, metadata, and languages. +6. **Cleanup**: Moves files to respective folders (`completed/`, `original/`) and deletes temporary working files. + +## Notes + +- Encoding AV1 takes a significant amount of time and CPU resources. +- Ensure you have sufficient disk space, as the scripts generate intermediate lossless `utvideo` files which can be very large depending on the length and resolution of the source media. + +## License + +This project is licensed under the MIT License - see the [`LICENSE.md`](LICENSE.md) file for details. diff --git a/svt_opus_encoder.py b/svt_opus_encoder.py index c98f6ff..e46781a 100644 --- a/svt_opus_encoder.py +++ b/svt_opus_encoder.py @@ -1,773 +1,777 @@ -#!/usr/bin/env python3 -import os -import sys -import subprocess -import shutil -import tempfile -import json -import re # Added for VFR frame rate parsing -from datetime import datetime -from pathlib import Path - -REQUIRED_TOOLS = [ - "ffmpeg", "ffprobe", "mkvmerge", "mkvpropedit", - "opusenc", "mediainfo", "av1an", "HandBrakeCLI", "ffmsindex" # Added HandBrakeCLI and ffmsindex -] -DIR_COMPLETED = Path("completed") -DIR_ORIGINAL = Path("original") -DIR_CONV_LOGS = Path("conv_logs") # Directory for conversion logs - -REMUX_CODECS = {"aac", "opus"} # Using a set for efficient lookups - -SVT_AV1_PARAMS = { - "speed": "slower", # "slower", "slow", "medium", "fast", "faster" - "quality": "medium", # "higher", "high", "medium", "low", "lower" - "film-grain": 6, - "color-primaries": 1, - "transfer-characteristics": 1, - "matrix-coefficients": 1, - "scd": 0, # Scene change detection OFF for Av1an use - "keyint": 0, # Keyframe interval, 0 disables automatic keyframes placement at a constant interval - "lp": 2, # Level of parallelism - "auto-tiling": 1, # Auto tiling ON - "tune": 1, # 0 = VQ, 1 = PSNR, 2 = SSIM - "progress": 2, # Detailed progress output -} - -def check_tools(): - for tool in REQUIRED_TOOLS: - if shutil.which(tool) is None: - print(f"Required tool '{tool}' not found in PATH.") - sys.exit(1) - -def run_cmd(cmd, capture_output=False, check=True): - if capture_output: - result = subprocess.run(cmd, stdout=subprocess.PIPE, stderr=subprocess.PIPE, check=check, text=True) - return result.stdout - else: - subprocess.run(cmd, check=check) - -def convert_audio_track(index, ch, lang, audio_temp_dir, source_file, should_downmix): - audio_temp_path = Path(audio_temp_dir) - temp_extracted = audio_temp_path / f"track_{index}_extracted.flac" - temp_normalized = audio_temp_path / f"track_{index}_normalized.flac" - final_opus = audio_temp_path / f"track_{index}_final.opus" - - print(f" - Extracting Audio Track #{index} to FLAC...") - ffmpeg_args = [ - "ffmpeg", "-v", "quiet", "-stats", "-y", "-i", str(source_file), "-map", f"0:{index}", "-map_metadata", "-1" - ] - if should_downmix and ch >= 6: - if ch == 6: - ffmpeg_args += ["-af", "pan=stereo|c0=c2+0.30*c0+0.30*c4|c1=c2+0.30*c1+0.30*c5"] - elif ch == 8: - ffmpeg_args += ["-af", "pan=stereo|c0=c2+0.30*c0+0.30*c4+0.30*c6|c1=c2+0.30*c1+0.30*c5+0.30*c7"] - else: # Other multi-channel (e.g. 7ch, 10ch) - ffmpeg_args += ["-ac", "2"] - ffmpeg_args += ["-c:a", "flac", str(temp_extracted)] - run_cmd(ffmpeg_args) - - print(f" - Normalizing Audio Track #{index} with ffmpeg (loudnorm 2-pass)...") - # First pass: Analyze the audio to get loudnorm stats - # The stats are printed to stderr, so we must use subprocess.run directly to capture it. - print(" - Pass 1: Analyzing...") - result = subprocess.run( - ["ffmpeg", "-v", "info", "-i", str(temp_extracted), "-af", "loudnorm=I=-23:LRA=7:tp=-1:print_format=json", "-f", "null", "-"], - capture_output=True, text=True, check=True) - - # Find the start of the JSON block in stderr and parse it. - # This is more robust than slicing the last N lines. - # We find the start and end of the JSON block to avoid parsing extra data. - stderr_output = result.stderr - json_start_index = stderr_output.find('{') - if json_start_index == -1: - raise ValueError("Could not find start of JSON block in ffmpeg output for loudnorm analysis.") - - brace_level = 0 - json_end_index = -1 - for i, char in enumerate(stderr_output[json_start_index:]): - if char == '{': - brace_level += 1 - elif char == '}': - brace_level -= 1 - if brace_level == 0: - json_end_index = json_start_index + i + 1 - break - - stats = json.loads(stderr_output[json_start_index:json_end_index]) - - # Second pass: Apply the normalization using the stats from the first pass - print(" - Pass 2: Applying normalization...") - run_cmd([ - "ffmpeg", "-v", "quiet", "-stats", "-y", "-i", str(temp_extracted), "-af", - f"loudnorm=I=-23:LRA=7:tp=-1:measured_i={stats['input_i']}:measured_lra={stats['input_lra']}:measured_tp={stats['input_tp']}:measured_thresh={stats['input_thresh']}:offset={stats['target_offset']}", - "-c:a", "flac", str(temp_normalized) - ]) - - # Set bitrate based on the final channel count of the Opus file. - # If we are downmixing, the result is stereo. - # If not, the result has the original channel count. - is_being_downmixed = should_downmix and ch >= 6 - - if is_being_downmixed: - # Downmixing from 5.1 or 7.1 results in a stereo track. - bitrate = "128k" - else: - # Not downmixing (or source is already stereo or less). - # Base bitrate on the source channel count. - if ch == 1: # Mono - bitrate = "64k" - elif ch == 2: # Stereo - bitrate = "128k" - elif ch == 6: # 5.1 Surround - bitrate = "256k" - elif ch == 8: # 7.1 Surround - bitrate = "384k" - else: # Other layouts - bitrate = "192k" # A sensible default for other/uncommon layouts. - - print(f" - Encoding Audio Track #{index} to Opus at {bitrate}...") - run_cmd([ - "opusenc", "--vbr", "--bitrate", bitrate, str(temp_normalized), str(final_opus) - ]) - return final_opus - -def convert_video(source_file_base, source_file_full, is_vfr, target_cfr_fps_for_handbrake, autocrop_filter=None): - print(" --- Starting Video Processing ---") - # source_file_base is file_path.stem (e.g., "my.anime.episode.01") - vpy_file = Path(f"{source_file_base}.vpy") - ut_video_file = Path(f"{source_file_base}.ut.mkv") - encoded_video_file = Path(f"temp-{source_file_base}.mkv") - handbrake_cfr_intermediate_file = None # To store path of HandBrake output if created - - current_input_for_utvideo = Path(source_file_full) - - if is_vfr and target_cfr_fps_for_handbrake: - print(f" - Source is VFR. Converting to CFR ({target_cfr_fps_for_handbrake}) with HandBrakeCLI...") - handbrake_cfr_intermediate_file = Path(f"{source_file_base}.cfr_temp.mkv") - handbrake_args = [ - "HandBrakeCLI", - "--input", str(source_file_full), - "--output", str(handbrake_cfr_intermediate_file), - "--cfr", - "--rate", str(target_cfr_fps_for_handbrake), - "--encoder", "x264_10bit", # Changed to x264_10bit for 10-bit CFR intermediate - "--quality", "0", # CRF 0 for x264 is often considered visually lossless, or near-lossless - "--encoder-preset", "superfast", # Use a fast preset for quicker processing - "--encoder-tune", "fastdecode", # Added tune for faster decoding - "--audio", "none", - "--subtitle", "none", - "--crop-mode", "none" # Disable auto-cropping - ] - print(f" - Running HandBrakeCLI: {' '.join(handbrake_args)}") - try: - run_cmd(handbrake_args) - if handbrake_cfr_intermediate_file.exists() and handbrake_cfr_intermediate_file.stat().st_size > 0: - print(f" - HandBrake VFR to CFR conversion successful: {handbrake_cfr_intermediate_file}") - current_input_for_utvideo = handbrake_cfr_intermediate_file - else: - print(f" - Warning: HandBrakeCLI VFR-to-CFR conversion failed or produced an empty file. Proceeding with original source for UTVideo.") - handbrake_cfr_intermediate_file = None # Ensure it's None if failed - except subprocess.CalledProcessError as e: - print(f" - Error during HandBrakeCLI execution: {e}") - print(f" - Proceeding with original source for UTVideo.") - handbrake_cfr_intermediate_file = None # Ensure it's None if failed - - - print(" - Creating UTVideo intermediate file (overwriting if exists)...") - # Check if source is already UTVideo - ffprobe_cmd = [ - "ffprobe", "-v", "error", "-select_streams", "v:0", - "-show_entries", "stream=codec_name", "-of", "default=noprint_wrappers=1:nokey=1", - str(current_input_for_utvideo) # Use current input, which might be HandBrake output - ] - source_codec = run_cmd(ffprobe_cmd, capture_output=True, check=True).strip() - - video_codec_args = ["-c:v", "utvideo"] - if source_codec == "utvideo" and current_input_for_utvideo == Path(source_file_full): # Only copy if original was UTVideo - print(" - Source is already UTVideo. Copying video stream...") - video_codec_args = ["-c:v", "copy"] - - ffmpeg_args = [ - "ffmpeg", "-hide_banner", "-v", "quiet", "-stats", "-y", "-i", str(current_input_for_utvideo), - "-map", "0:v:0", "-map_metadata", "-1", "-map_chapters", "-1", "-an", "-sn", "-dn", - ] - if autocrop_filter: - ffmpeg_args += ["-vf", autocrop_filter] - ffmpeg_args += video_codec_args + [str(ut_video_file)] - run_cmd(ffmpeg_args) - - print(" - Indexing UTVideo file with ffmsindex for VapourSynth...") - ffmsindex_args = ["ffmsindex", "-f", str(ut_video_file)] - run_cmd(ffmsindex_args) - - ut_video_full_path = os.path.abspath(ut_video_file) - vpy_script_content = f"""import vapoursynth as vs -core = vs.core -core.num_threads = 4 -clip = core.ffms2.Source(source=r'''{ut_video_full_path}''') -clip = core.resize.Point(clip, format=vs.YUV420P10, matrix_in_s="709") # type: ignore -clip.set_output() -""" - with vpy_file.open("w", encoding="utf-8") as f: - f.write(vpy_script_content) - - print(" - Starting AV1 encode with av1an (this will take a long time)...") - total_cores = os.cpu_count() or 4 # Fallback if cpu_count is None - workers = max(1, (total_cores // 2) - 1) # Half the cores minus one, with a minimum of 1 worker. - print(f" - Using {workers} workers for av1an (Total Cores: {total_cores}, Logic: (Cores/2)-1).") - - # Create the parameter string for av1an's -v option, which expects a single string. - av1an_video_params_str = " ".join([f"--{key} {value}" for key, value in SVT_AV1_PARAMS.items()]) - print(f" - Using SVT-AV1 parameters: {av1an_video_params_str}") - - av1an_enc_args = [ - "av1an", "-i", str(vpy_file), "-o", str(encoded_video_file), "-n", - "-e", "svt-av1", "--resume", "--sc-pix-format", "yuv420p", "-c", "mkvmerge", - "--set-thread-affinity", "2", "--pix-format", "yuv420p10le", "--force", "--no-defaults", - "-w", str(workers), - "-v", av1an_video_params_str - ] - run_cmd(av1an_enc_args) - print(" --- Finished Video Processing ---") - return encoded_video_file, handbrake_cfr_intermediate_file - -def is_ffmpeg_decodable(file_path): - """Quickly check if ffmpeg can decode the input file.""" - try: - # Try to decode a short segment of the first audio stream - subprocess.run([ - "ffmpeg", "-v", "error", "-i", str(file_path), "-map", "0:a:0", "-t", "1", "-f", "null", "-" - ], check=True) - return True - except subprocess.CalledProcessError: - return False - -# --- CROPDETECT LOGIC FROM cropdetect.py --- -import argparse as _argparse_cropdetect -import multiprocessing as _multiprocessing_cropdetect -from collections import Counter as _Counter_cropdetect - -COLOR_GREEN = "\033[92m" -COLOR_RED = "\033[91m" -COLOR_YELLOW = "\033[93m" -COLOR_RESET = "\033[0m" - -KNOWN_ASPECT_RATIOS = [ - {"name": "HDTV (16:9)", "ratio": 16/9}, - {"name": "Widescreen (Scope)", "ratio": 2.39}, - {"name": "Widescreen (Flat)", "ratio": 1.85}, - {"name": "IMAX Digital (1.90:1)", "ratio": 1.90}, - {"name": "Fullscreen (4:3)", "ratio": 4/3}, - {"name": "IMAX 70mm (1.43:1)", "ratio": 1.43}, -] - -def _check_prerequisites_cropdetect(): - for tool in ['ffmpeg', 'ffprobe']: - if not shutil.which(tool): - print(f"Error: '{tool}' command not found. Is it installed and in your PATH?") - return False - return True - -def _analyze_segment_cropdetect(task_args): - seek_time, input_file, width, height = task_args - ffmpeg_args = [ - 'ffmpeg', '-hide_banner', - '-ss', str(seek_time), - '-i', input_file, '-t', '1', '-vf', 'cropdetect', - '-f', 'null', '-' - ] - result = subprocess.run(ffmpeg_args, capture_output=True, text=True, encoding='utf-8') - if result.returncode != 0: - return [] - crop_detections = re.findall(r'crop=(\d+):(\d+):(\d+):(\d+)', result.stderr) - significant_crops = [] - for w_str, h_str, x_str, y_str in crop_detections: - w, h, x, y = map(int, [w_str, h_str, x_str, y_str]) - significant_crops.append((f"crop={w}:{h}:{x}:{y}", seek_time)) - return significant_crops - -def _snap_to_known_ar_cropdetect(w, h, x, y, video_w, video_h, tolerance=0.03): - if h == 0: return f"crop={w}:{h}:{x}:{y}", None - detected_ratio = w / h - best_match = None - smallest_diff = float('inf') - for ar in KNOWN_ASPECT_RATIOS: - diff = abs(detected_ratio - ar['ratio']) - if diff < smallest_diff: - smallest_diff = diff - best_match = ar - if not best_match or (smallest_diff / best_match['ratio']) >= tolerance: - return f"crop={w}:{h}:{x}:{y}", None - if abs(w - video_w) < 16: - new_h = round(video_w / best_match['ratio']) - if new_h % 8 != 0: - new_h = new_h + (8 - (new_h % 8)) - new_h = min(new_h, video_h) - new_y = round((video_h - new_h) / 2) - if new_y % 2 != 0: - new_y -= 1 - new_y = max(0, new_y) - return f"crop={video_w}:{new_h}:0:{new_y}", best_match['name'] - if abs(h - video_h) < 16: - new_w = round(video_h * best_match['ratio']) - if new_w % 8 != 0: - new_w = new_w + (8 - (new_w % 8)) - new_w = min(new_w, video_w) - new_x = round((video_w - new_w) / 2) - if new_x % 2 != 0: - new_x -= 1 - new_x = max(0, new_x) - return f"crop={new_w}:{video_h}:{new_x}:0", best_match['name'] - return f"crop={w}:{h}:{x}:{y}", None - -def _cluster_crop_values_cropdetect(crop_counts, tolerance=8): - clusters = [] - temp_counts = crop_counts.copy() - while temp_counts: - center_str, _ = temp_counts.most_common(1)[0] - try: - _, values = center_str.split('='); - cw, ch, cx, cy = map(int, values.split(':')) - except (ValueError, IndexError): - del temp_counts[center_str] - continue - cluster_total_count = 0 - crops_to_remove = [] - for crop_str, count in temp_counts.items(): - try: - _, values = crop_str.split('='); - w, h, x, y = map(int, values.split(':')) - if abs(x - cx) <= tolerance and abs(y - cy) <= tolerance: - cluster_total_count += count - crops_to_remove.append(crop_str) - except (ValueError, IndexError): - continue - if cluster_total_count > 0: - clusters.append({'center': center_str, 'count': cluster_total_count}) - for crop_str in crops_to_remove: - del temp_counts[crop_str] - clusters.sort(key=lambda c: c['count'], reverse=True) - return clusters - -def _parse_crop_string_cropdetect(crop_str): - try: - _, values = crop_str.split('='); - w, h, x, y = map(int, values.split(':')) - return {'w': w, 'h': h, 'x': x, 'y': y} - except (ValueError, IndexError): - return None - -def _calculate_bounding_box_cropdetect(crop_keys): - min_x = min_w = min_y = min_h = float('inf') - max_x = max_w = max_y = max_h = float('-inf') - for key in crop_keys: - parsed = _parse_crop_string_cropdetect(key) - if not parsed: - continue - w, h, x, y = parsed['w'], parsed['h'], parsed['x'], parsed['y'] - min_x = min(min_x, x) - min_y = min(min_y, y) - max_x = max(max_x, x + w) - max_y = max(max_y, y + h) - min_w = min(min_w, w) - min_h = min(min_h, h) - max_w = max(max_w, w) - max_h = max(max_h, h) - if (max_x - min_x) <= 2 and (max_y - min_y) <= 2: - return None - bounding_crop = f"crop={max_x - min_x}:{max_y - min_y}:{min_x}:{min_y}" - return bounding_crop - -def _analyze_video_cropdetect(input_file, duration, width, height, num_workers, significant_crop_threshold, min_crop, debug=False): - num_tasks = num_workers * 4 - segment_duration = max(1, duration // num_tasks) - tasks = [(i * segment_duration, input_file, width, height) for i in range(num_tasks)] - crop_results = [] - with _multiprocessing_cropdetect.Pool(processes=num_workers) as pool: - results_iterator = pool.imap_unordered(_analyze_segment_cropdetect, tasks) - for result in results_iterator: - crop_results.append(result) - all_crops_with_ts = [crop for sublist in crop_results for crop in sublist] - all_crop_strings = [item[0] for item in all_crops_with_ts] - if not all_crop_strings: - return None - crop_counts = _Counter_cropdetect(all_crop_strings) - clusters = _cluster_crop_values_cropdetect(crop_counts) - total_detections = sum(c['count'] for c in clusters) - significant_clusters = [] - for cluster in clusters: - percentage = (cluster['count'] / total_detections) * 100 - if percentage >= significant_crop_threshold: - significant_clusters.append(cluster) - for cluster in significant_clusters: - parsed_crop = _parse_crop_string_cropdetect(cluster['center']) - if parsed_crop: - _, ar_label = _snap_to_known_ar_cropdetect( - parsed_crop['w'], parsed_crop['h'], parsed_crop['x'], parsed_crop['y'], width, height - ) - cluster['ar_label'] = ar_label - else: - cluster['ar_label'] = None - if not significant_clusters: - return None - elif len(significant_clusters) == 1: - dominant_cluster = significant_clusters[0] - parsed_crop = _parse_crop_string_cropdetect(dominant_cluster['center']) - snapped_crop, ar_label = _snap_to_known_ar_cropdetect( - parsed_crop['w'], parsed_crop['h'], parsed_crop['x'], parsed_crop['y'], width, height - ) - parsed_snapped = _parse_crop_string_cropdetect(snapped_crop) - if parsed_snapped and parsed_snapped['w'] == width and parsed_snapped['h'] == height: - return None - else: - return snapped_crop - else: - crop_keys = [c['center'] for c in significant_clusters] - bounding_box_crop = _calculate_bounding_box_cropdetect(crop_keys) - if bounding_box_crop: - parsed_bb = _parse_crop_string_cropdetect(bounding_box_crop) - snapped_crop, ar_label = _snap_to_known_ar_cropdetect( - parsed_bb['w'], parsed_bb['h'], parsed_bb['x'], parsed_bb['y'], width, height - ) - parsed_snapped = _parse_crop_string_cropdetect(snapped_crop) - if parsed_snapped and parsed_snapped['w'] == width and parsed_snapped['h'] == height: - return None - else: - return snapped_crop - else: - return None - -def detect_autocrop_filter(input_file, significant_crop_threshold=5.0, min_crop=10, debug=False): - if not _check_prerequisites_cropdetect(): - return None - try: - probe_duration_args = [ - 'ffprobe', '-v', 'error', '-show_entries', 'format=duration', '-of', 'default=noprint_wrappers=1:nokey=1', - input_file - ] - duration_str = subprocess.check_output(probe_duration_args, stderr=subprocess.STDOUT, text=True) - duration = int(float(duration_str)) - probe_res_args = [ - 'ffprobe', '-v', 'error', - '-select_streams', 'v', - '-show_entries', 'stream=width,height,disposition', - '-of', 'json', - input_file - ] - probe_output = subprocess.check_output(probe_res_args, stderr=subprocess.STDOUT, text=True) - streams_data = json.loads(probe_output) - video_stream = None - for stream in streams_data.get('streams', []): - if stream.get('disposition', {}).get('attached_pic', 0) == 0: - video_stream = stream - break - if not video_stream or 'width' not in video_stream or 'height' not in video_stream: - return None - width = int(video_stream['width']) - height = int(video_stream['height']) - except Exception: - return None - return _analyze_video_cropdetect(input_file, duration, width, height, max(1, os.cpu_count() // 2), significant_crop_threshold, min_crop, debug) - -def main(no_downmix=False, autocrop=False, speed=None, quality=None, grain=None): - check_tools() - - # Override default SVT-AV1 params if provided via command line - if speed: - SVT_AV1_PARAMS["speed"] = speed - if quality: - SVT_AV1_PARAMS["quality"] = quality - if grain is not None: - SVT_AV1_PARAMS["film-grain"] = grain - - current_dir = Path(".") - files_to_process = sorted( - f for f in current_dir.glob("*.mkv") - if not (f.name.endswith(".ut.mkv") or f.name.startswith("temp-") or f.name.startswith("output-") or f.name.endswith(".cfr_temp.mkv")) - ) - if not files_to_process: - print("No MKV files found to process. Exiting.") - return - DIR_COMPLETED.mkdir(exist_ok=True, parents=True) - DIR_ORIGINAL.mkdir(exist_ok=True, parents=True) - DIR_CONV_LOGS.mkdir(exist_ok=True, parents=True) - while True: - files_to_process = sorted( - f for f in current_dir.glob("*.mkv") - if not (f.name.endswith(".ut.mkv") or f.name.startswith("temp-") or f.name.startswith("output-") or f.name.endswith(".cfr_temp.mkv")) - ) - if not files_to_process: - print("No more .mkv files found to process in the current directory. The script will now exit.") - break - file_path = files_to_process[0] - if not is_ffmpeg_decodable(file_path): - print(f"ERROR: ffmpeg cannot decode '{file_path.name}'. Skipping this file.", file=sys.stderr) - shutil.move(str(file_path), DIR_ORIGINAL / file_path.name) - continue - print("-" * shutil.get_terminal_size(fallback=(80, 24)).columns) - log_file_name = f"{file_path.stem}.log" - log_file_path = DIR_CONV_LOGS / log_file_name - original_stdout_console = sys.stdout - original_stderr_console = sys.stderr - print(f"Processing: {file_path.name}", file=original_stdout_console) - print(f"Logging output to: {log_file_path}", file=original_stdout_console) - log_file_handle = None - processing_error_occurred = False - date_for_runtime_calc = datetime.now() - try: - log_file_handle = open(log_file_path, 'w', encoding='utf-8') - sys.stdout = log_file_handle - sys.stderr = log_file_handle - print(f"STARTING LOG FOR: {file_path.name}") - print(f"Processing started at: {date_for_runtime_calc}") - print(f"Full input file path: {file_path.resolve()}") - print("-" * shutil.get_terminal_size(fallback=(80, 24)).columns) - input_file_abs = file_path.resolve() - intermediate_output_file = current_dir / f"output-{file_path.name}" - audio_temp_dir = None - handbrake_intermediate_for_cleanup = None - try: - audio_temp_dir = tempfile.mkdtemp(prefix="anime_audio_") - print(f"Audio temporary directory created at: {audio_temp_dir}") - print(f"Analyzing file: {input_file_abs}") - ffprobe_info_json = run_cmd([ - "ffprobe", "-v", "quiet", "-print_format", "json", "-show_streams", "-show_format", str(input_file_abs) - ], capture_output=True) - ffprobe_info = json.loads(ffprobe_info_json) - mkvmerge_info_json = run_cmd([ - "mkvmerge", "-J", str(input_file_abs) - ], capture_output=True) - mkv_info = json.loads(mkvmerge_info_json) - mediainfo_json = run_cmd([ - "mediainfo", "--Output=JSON", "-f", str(input_file_abs) - ], capture_output=True) - media_info = json.loads(mediainfo_json) - is_vfr = False - target_cfr_fps_for_handbrake = None - video_track_info = None - if media_info.get("media") and media_info["media"].get("track"): - for track in media_info["media"]["track"]: - if track.get("@type") == "Video": - video_track_info = track - break - if video_track_info: - frame_rate_mode = video_track_info.get("FrameRate_Mode") - if frame_rate_mode and frame_rate_mode.upper() in ["VFR", "VARIABLE"]: - is_vfr = True - print(f" - Detected VFR based on MediaInfo FrameRate_Mode: {frame_rate_mode}") - original_fps_str = video_track_info.get("FrameRate_Original_String") - if original_fps_str: - match = re.search(r'\((\d+/\d+)\)', original_fps_str) - if match: - target_cfr_fps_for_handbrake = match.group(1) - else: - target_cfr_fps_for_handbrake = video_track_info.get("FrameRate_Original") - if not target_cfr_fps_for_handbrake: - target_cfr_fps_for_handbrake = video_track_info.get("FrameRate_Original") - if not target_cfr_fps_for_handbrake: - target_cfr_fps_for_handbrake = video_track_info.get("FrameRate") - if target_cfr_fps_for_handbrake: - print(f" - Using MediaInfo FrameRate ({target_cfr_fps_for_handbrake}) as fallback for HandBrake target FPS.") - if target_cfr_fps_for_handbrake: - print(f" - Target CFR for HandBrake: {target_cfr_fps_for_handbrake}") - if isinstance(target_cfr_fps_for_handbrake, str) and "/" in target_cfr_fps_for_handbrake: - try: - num, den = map(float, target_cfr_fps_for_handbrake.split('/')) - target_cfr_fps_for_handbrake = f"{num / den:.3f}" - print(f" - Converted fractional FPS to decimal for HandBrake: {target_cfr_fps_for_handbrake}") - except ValueError: - print(f" - Warning: Could not parse fractional FPS '{target_cfr_fps_for_handbrake}'. HandBrakeCLI might fail.") - is_vfr = False - else: - print(" - Warning: VFR detected, but could not determine target CFR from MediaInfo. Will attempt standard UTVideo conversion without HandBrake.") - is_vfr = False - else: - print(f" - Video appears to be CFR or FrameRate_Mode not specified as VFR/Variable by MediaInfo.") - autocrop_filter = None - if autocrop: - print("--- Running autocrop detection ---") - autocrop_filter = detect_autocrop_filter(str(input_file_abs)) - if autocrop_filter: - print(f" - Autocrop filter detected: {autocrop_filter}") - else: - print(" - No crop needed or detected.") - encoded_video_file, handbrake_intermediate_for_cleanup = convert_video( - file_path.stem, str(input_file_abs), is_vfr, target_cfr_fps_for_handbrake, autocrop_filter=autocrop_filter - ) - - print("--- Starting Audio Processing ---") - processed_audio_files = [] - audio_tracks_to_remux = [] - audio_streams = [s for s in ffprobe_info.get("streams", []) if s.get("codec_type") == "audio"] - - # Build mkvmerge track mapping by track ID - mkv_audio_tracks = {t["id"]: t for t in mkv_info.get("tracks", []) if t.get("type") == "audio"} - - # Build mediainfo track mapping by StreamOrder - media_tracks_data = media_info.get("media", {}).get("track", []) - mediainfo_audio_tracks = {int(t.get("StreamOrder", -1)): t for t in media_tracks_data if t.get("@type") == "Audio"} - - for stream in audio_streams: - stream_index = stream["index"] - codec = stream.get("codec_name") - channels = stream.get("channels", 2) - language = stream.get("tags", {}).get("language", "und") - - # Find mkvmerge track by matching ffprobe stream index to mkvmerge track's 'properties'->'stream_id' - mkv_track = None - for t in mkv_info.get("tracks", []): - if t.get("type") == "audio" and t.get("properties", {}).get("stream_id") == stream_index: - mkv_track = t - break - if not mkv_track: - # Fallback: try by position - mkv_track = mkv_info.get("tracks", [])[stream_index] if stream_index < len(mkv_info.get("tracks", [])) else {} - - track_id = mkv_track.get("id", -1) - track_title = mkv_track.get("properties", {}).get("track_name", "") - - # Find mediainfo track by StreamOrder - audio_track_info = mediainfo_audio_tracks.get(stream_index) - track_delay = 0 - delay_raw = audio_track_info.get("Video_Delay") if audio_track_info else None - if delay_raw is not None: - try: - delay_val = float(delay_raw) - # If the value is a float < 1, it's seconds, so convert to ms. - if delay_val < 1: - track_delay = int(round(delay_val * 1000)) - else: - track_delay = int(round(delay_val)) - except Exception: - track_delay = 0 - - print(f"Processing Audio Stream #{stream_index} (TID: {track_id}, Codec: {codec}, Channels: {channels})") - if codec in REMUX_CODECS: - audio_tracks_to_remux.append(str(track_id)) - else: - # Convert any codec that is not in REMUX_CODECS - opus_file = convert_audio_track( - stream_index, channels, language, audio_temp_dir, str(input_file_abs), not no_downmix - ) - processed_audio_files.append({ - "Path": opus_file, - "Language": language, - "Title": track_title, - "Delay": track_delay - }) - - print("--- Finished Audio Processing ---") - - # Final mux - print("Assembling final file with mkvmerge...") - mkvmerge_args = ["mkvmerge", "-o", str(intermediate_output_file), str(encoded_video_file)] - for file_info in processed_audio_files: - sync_switch = ["--sync", f"0:{file_info['Delay']}"] if file_info["Delay"] else [] - mkvmerge_args += [ - "--language", f"0:{file_info['Language']}", - "--track-name", f"0:{file_info['Title']}" - ] + sync_switch + [str(file_info["Path"])] - - source_copy_args = ["--no-video"] - if audio_tracks_to_remux: - source_copy_args += ["--audio-tracks", ",".join(audio_tracks_to_remux)] - else: - source_copy_args += ["--no-audio"] - mkvmerge_args += source_copy_args + [str(input_file_abs)] - run_cmd(mkvmerge_args) - - # Move files - print("Moving files to final destinations...") - shutil.move(str(file_path), DIR_ORIGINAL / file_path.name) - shutil.move(str(intermediate_output_file), DIR_COMPLETED / file_path.name) - - print("Cleaning up persistent video temporary files (after successful processing)...") - video_temp_files_on_success = [ - current_dir / f"{file_path.stem}.vpy", - current_dir / f"{file_path.stem}.ut.mkv", - current_dir / f"temp-{file_path.stem}.mkv", # This is encoded_video_file - current_dir / f"{file_path.stem}.ut.mkv.lwi", - current_dir / f"{file_path.stem}.ut.mkv.ffindex", - ] - if handbrake_intermediate_for_cleanup and handbrake_intermediate_for_cleanup.exists(): - video_temp_files_on_success.append(handbrake_intermediate_for_cleanup) - - for temp_vid_file in video_temp_files_on_success: - if temp_vid_file.exists(): - print(f" Deleting: {temp_vid_file}") - temp_vid_file.unlink(missing_ok=True) - else: - print(f" Skipping (not found): {temp_vid_file}") - - except Exception as e: - print(f"ERROR: An error occurred while processing '{file_path.name}': {e}", file=sys.stderr) # Goes to log - original_stderr_console.write(f"ERROR during processing of '{file_path.name}': {e}\nSee log '{log_file_path}' for details.\n") - processing_error_occurred = True - finally: - # This is the original 'finally' block. Its prints go to the log file. - print("--- Starting Universal Cleanup (for this file) ---") - print(" - Cleaning up disposable audio temporary directory...") - if audio_temp_dir and Path(audio_temp_dir).exists(): - shutil.rmtree(audio_temp_dir, ignore_errors=True) - print(f" - Deleted audio temp dir: {audio_temp_dir}") - elif audio_temp_dir: # Was created but now not found - print(f" - Audio temp dir not found or already cleaned: {audio_temp_dir}") - else: # Was never created - print(f" - Audio temp dir was not created.") - - print(" - Cleaning up intermediate output file (if it wasn't moved on success)...") - if intermediate_output_file.exists(): # Check if it still exists (e.g. error before move) - if processing_error_occurred: - print(f" - WARNING: Processing error occurred. Intermediate output file '{intermediate_output_file}' is being preserved at its original path for inspection.") - else: - # No processing error, so it should have been moved. - # If it's still here, it's unexpected but we'll clean it up. - print(f" - INFO: Intermediate output file '{intermediate_output_file}' found at original path despite no errors (expected to be moved). Cleaning up.") - intermediate_output_file.unlink(missing_ok=True) # Only unlink if no error and it exists - print(f" - Deleted intermediate output file from original path: {intermediate_output_file}") - else: - # File does not exist at original path - if not processing_error_occurred: - print(f" - Intermediate output file successfully moved (not found at original path, as expected): {intermediate_output_file}") - else: - print(f" - Processing error occurred, and intermediate output file '{intermediate_output_file}' not found at original path (likely not created or cleaned by another step).") - # --- End of original per-file processing block --- - - print(f"FINISHED LOG FOR: {file_path.name}") - # --- End of log-specific messages --- - - finally: # Outer finally for restoring stdout/stderr and closing log file - runtime = datetime.now() - date_for_runtime_calc - runtime_str = str(runtime).split('.')[0] - - # This print goes to the log file, as stdout is not yet restored. - print(f"\nTotal runtime for this file: {runtime_str}") - - if sys.stdout != original_stdout_console: - sys.stdout = original_stdout_console - if sys.stderr != original_stderr_console: - sys.stderr = original_stderr_console - if log_file_handle: - log_file_handle.close() - - # Announce to console (original stdout/stderr) that this file is done - if processing_error_occurred: - original_stderr_console.write(f"File: {file_path.name}\n") - original_stderr_console.write(f"Log: {log_file_path}\n") - original_stderr_console.write(f"Runtime: {runtime_str}\n") - else: - original_stdout_console.write(f"File: {file_path.name}\n") - original_stdout_console.write(f"Log: {log_file_path}\n") - original_stdout_console.write(f"Runtime: {runtime_str}\n") - -if __name__ == "__main__": - import argparse - parser = argparse.ArgumentParser(description="Batch-process MKV files with resumable video encoding, audio downmixing, per-file logging, and optional autocrop.") - parser.add_argument("--no-downmix", action="store_true", help="Preserve original audio channel layout.") - parser.add_argument("--autocrop", action="store_true", help="Automatically detect and crop black bars from video using cropdetect.") - parser.add_argument("--speed", type=str, help="Set the encoding speed. Possible values: slower, slow, medium, fast, faster.") - parser.add_argument("--quality", type=str, help="Set the encoding quality. Possible values: lowest, low, medium, high, higher.") - parser.add_argument("--grain", type=int, help="Set the film-grain value (number). Adjusts the film grain synthesis level.") - args = parser.parse_args() - main(no_downmix=args.no_downmix, autocrop=args.autocrop, speed=args.speed, quality=args.quality, grain=args.grain) +#!/usr/bin/env python3 + +# Note: This script is configured to use a custom version of SVT-AV1 +# called "SVT-AV1-Essential" from https://github.com/nekotrix/SVT-AV1-Essential + +import os +import sys +import subprocess +import shutil +import tempfile +import json +import re # Added for VFR frame rate parsing +from datetime import datetime +from pathlib import Path + +REQUIRED_TOOLS = [ + "ffmpeg", "ffprobe", "mkvmerge", "mkvpropedit", + "opusenc", "mediainfo", "av1an", "HandBrakeCLI", "ffmsindex" # Added HandBrakeCLI and ffmsindex +] +DIR_COMPLETED = Path("completed") +DIR_ORIGINAL = Path("original") +DIR_CONV_LOGS = Path("conv_logs") # Directory for conversion logs + +REMUX_CODECS = {"aac", "opus"} # Using a set for efficient lookups + +SVT_AV1_PARAMS = { + "preset": 2, # Speed preset. Lower is slower and yields better compression efficiency. + "crf": 30, # Constant Rate Factor (CRF). Lower is better quality. + "film-grain": 6, # Film grain synthesis level. Adds artificial grain to preserve detail and prevent banding. + "color-primaries": 1, # BT.709 color primaries (Standard SDR). + "transfer-characteristics": 1, # BT.709 transfer characteristics (Standard SDR). + "matrix-coefficients": 1, # BT.709 matrix coefficients (Standard SDR). + "scd": 0, # Scene change detection OFF (av1an handles scene cuts). + "keyint": 0, # Keyframe interval OFF (av1an inserts keyframes). + "lp": 2, # Logical Processors to use per av1an worker. + "auto-tiling": 1, # Automatically determine the number of tiles based on resolution. + "tune": 1, # 0 = VQ, 1 = PSNR, 2 = SSIM (SVT-AV1-Essential default recommended). + "progress": 2, # Detailed progress output. +} + +def check_tools(): + for tool in REQUIRED_TOOLS: + if shutil.which(tool) is None: + print(f"Required tool '{tool}' not found in PATH.") + sys.exit(1) + +def run_cmd(cmd, capture_output=False, check=True): + if capture_output: + result = subprocess.run(cmd, stdout=subprocess.PIPE, stderr=subprocess.PIPE, check=check, text=True) + return result.stdout + else: + subprocess.run(cmd, check=check) + +def convert_audio_track(index, ch, lang, audio_temp_dir, source_file, should_downmix): + audio_temp_path = Path(audio_temp_dir) + temp_extracted = audio_temp_path / f"track_{index}_extracted.flac" + temp_normalized = audio_temp_path / f"track_{index}_normalized.flac" + final_opus = audio_temp_path / f"track_{index}_final.opus" + + print(f" - Extracting Audio Track #{index} to FLAC...") + ffmpeg_args = [ + "ffmpeg", "-v", "quiet", "-stats", "-y", "-i", str(source_file), "-map", f"0:{index}", "-map_metadata", "-1" + ] + if should_downmix and ch >= 6: + if ch == 6: + ffmpeg_args += ["-af", "pan=stereo|c0=c2+0.30*c0+0.30*c4|c1=c2+0.30*c1+0.30*c5"] + elif ch == 8: + ffmpeg_args += ["-af", "pan=stereo|c0=c2+0.30*c0+0.30*c4+0.30*c6|c1=c2+0.30*c1+0.30*c5+0.30*c7"] + else: # Other multi-channel (e.g. 7ch, 10ch) + ffmpeg_args += ["-ac", "2"] + ffmpeg_args += ["-c:a", "flac", str(temp_extracted)] + run_cmd(ffmpeg_args) + + print(f" - Normalizing Audio Track #{index} with ffmpeg (loudnorm 2-pass)...") + # First pass: Analyze the audio to get loudnorm stats + # The stats are printed to stderr, so we must use subprocess.run directly to capture it. + print(" - Pass 1: Analyzing...") + result = subprocess.run( + ["ffmpeg", "-v", "info", "-i", str(temp_extracted), "-af", "loudnorm=I=-23:LRA=7:tp=-1:print_format=json", "-f", "null", "-"], + capture_output=True, text=True, check=True) + + # Find the start of the JSON block in stderr and parse it. + # This is more robust than slicing the last N lines. + # We find the start and end of the JSON block to avoid parsing extra data. + stderr_output = result.stderr + json_start_index = stderr_output.find('{') + if json_start_index == -1: + raise ValueError("Could not find start of JSON block in ffmpeg output for loudnorm analysis.") + + brace_level = 0 + json_end_index = -1 + for i, char in enumerate(stderr_output[json_start_index:]): + if char == '{': + brace_level += 1 + elif char == '}': + brace_level -= 1 + if brace_level == 0: + json_end_index = json_start_index + i + 1 + break + + stats = json.loads(stderr_output[json_start_index:json_end_index]) + + # Second pass: Apply the normalization using the stats from the first pass + print(" - Pass 2: Applying normalization...") + run_cmd([ + "ffmpeg", "-v", "quiet", "-stats", "-y", "-i", str(temp_extracted), "-af", + f"loudnorm=I=-23:LRA=7:tp=-1:measured_i={stats['input_i']}:measured_lra={stats['input_lra']}:measured_tp={stats['input_tp']}:measured_thresh={stats['input_thresh']}:offset={stats['target_offset']}", + "-c:a", "flac", str(temp_normalized) + ]) + + # Set bitrate based on the final channel count of the Opus file. + # If we are downmixing, the result is stereo. + # If not, the result has the original channel count. + is_being_downmixed = should_downmix and ch >= 6 + + if is_being_downmixed: + # Downmixing from 5.1 or 7.1 results in a stereo track. + bitrate = "128k" + else: + # Not downmixing (or source is already stereo or less). + # Base bitrate on the source channel count. + if ch == 1: # Mono + bitrate = "64k" + elif ch == 2: # Stereo + bitrate = "128k" + elif ch == 6: # 5.1 Surround + bitrate = "256k" + elif ch == 8: # 7.1 Surround + bitrate = "384k" + else: # Other layouts + bitrate = "192k" # A sensible default for other/uncommon layouts. + + print(f" - Encoding Audio Track #{index} to Opus at {bitrate}...") + run_cmd([ + "opusenc", "--vbr", "--bitrate", bitrate, str(temp_normalized), str(final_opus) + ]) + return final_opus + +def convert_video(source_file_base, source_file_full, is_vfr, target_cfr_fps_for_handbrake, autocrop_filter=None): + print(" --- Starting Video Processing ---") + # source_file_base is file_path.stem (e.g., "my.anime.episode.01") + vpy_file = Path(f"{source_file_base}.vpy") + ut_video_file = Path(f"{source_file_base}.ut.mkv") + encoded_video_file = Path(f"temp-{source_file_base}.mkv") + handbrake_cfr_intermediate_file = None # To store path of HandBrake output if created + + current_input_for_utvideo = Path(source_file_full) + + if is_vfr and target_cfr_fps_for_handbrake: + print(f" - Source is VFR. Converting to CFR ({target_cfr_fps_for_handbrake}) with HandBrakeCLI...") + handbrake_cfr_intermediate_file = Path(f"{source_file_base}.cfr_temp.mkv") + handbrake_args = [ + "HandBrakeCLI", + "--input", str(source_file_full), + "--output", str(handbrake_cfr_intermediate_file), + "--cfr", + "--rate", str(target_cfr_fps_for_handbrake), + "--encoder", "x264_10bit", # Changed to x264_10bit for 10-bit CFR intermediate + "--quality", "0", # CRF 0 for x264 is often considered visually lossless, or near-lossless + "--encoder-preset", "superfast", # Use a fast preset for quicker processing + "--encoder-tune", "fastdecode", # Added tune for faster decoding + "--audio", "none", + "--subtitle", "none", + "--crop-mode", "none" # Disable auto-cropping + ] + print(f" - Running HandBrakeCLI: {' '.join(handbrake_args)}") + try: + run_cmd(handbrake_args) + if handbrake_cfr_intermediate_file.exists() and handbrake_cfr_intermediate_file.stat().st_size > 0: + print(f" - HandBrake VFR to CFR conversion successful: {handbrake_cfr_intermediate_file}") + current_input_for_utvideo = handbrake_cfr_intermediate_file + else: + print(f" - Warning: HandBrakeCLI VFR-to-CFR conversion failed or produced an empty file. Proceeding with original source for UTVideo.") + handbrake_cfr_intermediate_file = None # Ensure it's None if failed + except subprocess.CalledProcessError as e: + print(f" - Error during HandBrakeCLI execution: {e}") + print(f" - Proceeding with original source for UTVideo.") + handbrake_cfr_intermediate_file = None # Ensure it's None if failed + + + print(" - Creating UTVideo intermediate file (overwriting if exists)...") + # Check if source is already UTVideo + ffprobe_cmd = [ + "ffprobe", "-v", "error", "-select_streams", "v:0", + "-show_entries", "stream=codec_name", "-of", "default=noprint_wrappers=1:nokey=1", + str(current_input_for_utvideo) # Use current input, which might be HandBrake output + ] + source_codec = run_cmd(ffprobe_cmd, capture_output=True, check=True).strip() + + video_codec_args = ["-c:v", "utvideo"] + if source_codec == "utvideo" and current_input_for_utvideo == Path(source_file_full): # Only copy if original was UTVideo + print(" - Source is already UTVideo. Copying video stream...") + video_codec_args = ["-c:v", "copy"] + + ffmpeg_args = [ + "ffmpeg", "-hide_banner", "-v", "quiet", "-stats", "-y", "-i", str(current_input_for_utvideo), + "-map", "0:v:0", "-map_metadata", "-1", "-map_chapters", "-1", "-an", "-sn", "-dn", + ] + if autocrop_filter: + ffmpeg_args += ["-vf", autocrop_filter] + ffmpeg_args += video_codec_args + [str(ut_video_file)] + run_cmd(ffmpeg_args) + + print(" - Indexing UTVideo file with ffmsindex for VapourSynth...") + ffmsindex_args = ["ffmsindex", "-f", str(ut_video_file)] + run_cmd(ffmsindex_args) + + ut_video_full_path = os.path.abspath(ut_video_file) + vpy_script_content = f"""import vapoursynth as vs +core = vs.core +core.num_threads = 4 +clip = core.ffms2.Source(source=r'''{ut_video_full_path}''') +clip = core.resize.Point(clip, format=vs.YUV420P10, matrix_in_s="709") # type: ignore +clip.set_output() +""" + with vpy_file.open("w", encoding="utf-8") as f: + f.write(vpy_script_content) + + print(" - Starting AV1 encode with av1an (this will take a long time)...") + total_cores = os.cpu_count() or 4 # Fallback if cpu_count is None + workers = max(1, (total_cores // 2) - 1) # Half the cores minus one, with a minimum of 1 worker. + print(f" - Using {workers} workers for av1an (Total Cores: {total_cores}, Logic: (Cores/2)-1).") + + # Create the parameter string for av1an's -v option, which expects a single string. + av1an_video_params_str = " ".join([f"--{key} {value}" for key, value in SVT_AV1_PARAMS.items()]) + print(f" - Using SVT-AV1 parameters: {av1an_video_params_str}") + + av1an_enc_args = [ + "av1an", "-i", str(vpy_file), "-o", str(encoded_video_file), "-n", + "-e", "svt-av1", "--resume", "--sc-pix-format", "yuv420p", "-c", "mkvmerge", + "--set-thread-affinity", "2", "--pix-format", "yuv420p10le", "--force", "--no-defaults", + "-w", str(workers), + "-v", av1an_video_params_str + ] + run_cmd(av1an_enc_args) + print(" --- Finished Video Processing ---") + return encoded_video_file, handbrake_cfr_intermediate_file + +def is_ffmpeg_decodable(file_path): + """Quickly check if ffmpeg can decode the input file.""" + try: + # Try to decode a short segment of the first audio stream + subprocess.run([ + "ffmpeg", "-v", "error", "-i", str(file_path), "-map", "0:a:0", "-t", "1", "-f", "null", "-" + ], check=True) + return True + except subprocess.CalledProcessError: + return False + +# --- CROPDETECT LOGIC FROM cropdetect.py --- +import argparse as _argparse_cropdetect +import multiprocessing as _multiprocessing_cropdetect +from collections import Counter as _Counter_cropdetect + +COLOR_GREEN = "\033[92m" +COLOR_RED = "\033[91m" +COLOR_YELLOW = "\033[93m" +COLOR_RESET = "\033[0m" + +KNOWN_ASPECT_RATIOS = [ + {"name": "HDTV (16:9)", "ratio": 16/9}, + {"name": "Widescreen (Scope)", "ratio": 2.39}, + {"name": "Widescreen (Flat)", "ratio": 1.85}, + {"name": "IMAX Digital (1.90:1)", "ratio": 1.90}, + {"name": "Fullscreen (4:3)", "ratio": 4/3}, + {"name": "IMAX 70mm (1.43:1)", "ratio": 1.43}, +] + +def _check_prerequisites_cropdetect(): + for tool in ['ffmpeg', 'ffprobe']: + if not shutil.which(tool): + print(f"Error: '{tool}' command not found. Is it installed and in your PATH?") + return False + return True + +def _analyze_segment_cropdetect(task_args): + seek_time, input_file, width, height = task_args + ffmpeg_args = [ + 'ffmpeg', '-hide_banner', + '-ss', str(seek_time), + '-i', input_file, '-t', '1', '-vf', 'cropdetect', + '-f', 'null', '-' + ] + result = subprocess.run(ffmpeg_args, capture_output=True, text=True, encoding='utf-8') + if result.returncode != 0: + return [] + crop_detections = re.findall(r'crop=(\d+):(\d+):(\d+):(\d+)', result.stderr) + significant_crops = [] + for w_str, h_str, x_str, y_str in crop_detections: + w, h, x, y = map(int, [w_str, h_str, x_str, y_str]) + significant_crops.append((f"crop={w}:{h}:{x}:{y}", seek_time)) + return significant_crops + +def _snap_to_known_ar_cropdetect(w, h, x, y, video_w, video_h, tolerance=0.03): + if h == 0: return f"crop={w}:{h}:{x}:{y}", None + detected_ratio = w / h + best_match = None + smallest_diff = float('inf') + for ar in KNOWN_ASPECT_RATIOS: + diff = abs(detected_ratio - ar['ratio']) + if diff < smallest_diff: + smallest_diff = diff + best_match = ar + if not best_match or (smallest_diff / best_match['ratio']) >= tolerance: + return f"crop={w}:{h}:{x}:{y}", None + if abs(w - video_w) < 16: + new_h = round(video_w / best_match['ratio']) + if new_h % 8 != 0: + new_h = new_h + (8 - (new_h % 8)) + new_h = min(new_h, video_h) + new_y = round((video_h - new_h) / 2) + if new_y % 2 != 0: + new_y -= 1 + new_y = max(0, new_y) + return f"crop={video_w}:{new_h}:0:{new_y}", best_match['name'] + if abs(h - video_h) < 16: + new_w = round(video_h * best_match['ratio']) + if new_w % 8 != 0: + new_w = new_w + (8 - (new_w % 8)) + new_w = min(new_w, video_w) + new_x = round((video_w - new_w) / 2) + if new_x % 2 != 0: + new_x -= 1 + new_x = max(0, new_x) + return f"crop={new_w}:{video_h}:{new_x}:0", best_match['name'] + return f"crop={w}:{h}:{x}:{y}", None + +def _cluster_crop_values_cropdetect(crop_counts, tolerance=8): + clusters = [] + temp_counts = crop_counts.copy() + while temp_counts: + center_str, _ = temp_counts.most_common(1)[0] + try: + _, values = center_str.split('='); + cw, ch, cx, cy = map(int, values.split(':')) + except (ValueError, IndexError): + del temp_counts[center_str] + continue + cluster_total_count = 0 + crops_to_remove = [] + for crop_str, count in temp_counts.items(): + try: + _, values = crop_str.split('='); + w, h, x, y = map(int, values.split(':')) + if abs(x - cx) <= tolerance and abs(y - cy) <= tolerance: + cluster_total_count += count + crops_to_remove.append(crop_str) + except (ValueError, IndexError): + continue + if cluster_total_count > 0: + clusters.append({'center': center_str, 'count': cluster_total_count}) + for crop_str in crops_to_remove: + del temp_counts[crop_str] + clusters.sort(key=lambda c: c['count'], reverse=True) + return clusters + +def _parse_crop_string_cropdetect(crop_str): + try: + _, values = crop_str.split('='); + w, h, x, y = map(int, values.split(':')) + return {'w': w, 'h': h, 'x': x, 'y': y} + except (ValueError, IndexError): + return None + +def _calculate_bounding_box_cropdetect(crop_keys): + min_x = min_w = min_y = min_h = float('inf') + max_x = max_w = max_y = max_h = float('-inf') + for key in crop_keys: + parsed = _parse_crop_string_cropdetect(key) + if not parsed: + continue + w, h, x, y = parsed['w'], parsed['h'], parsed['x'], parsed['y'] + min_x = min(min_x, x) + min_y = min(min_y, y) + max_x = max(max_x, x + w) + max_y = max(max_y, y + h) + min_w = min(min_w, w) + min_h = min(min_h, h) + max_w = max(max_w, w) + max_h = max(max_h, h) + if (max_x - min_x) <= 2 and (max_y - min_y) <= 2: + return None + bounding_crop = f"crop={max_x - min_x}:{max_y - min_y}:{min_x}:{min_y}" + return bounding_crop + +def _analyze_video_cropdetect(input_file, duration, width, height, num_workers, significant_crop_threshold, min_crop, debug=False): + num_tasks = num_workers * 4 + segment_duration = max(1, duration // num_tasks) + tasks = [(i * segment_duration, input_file, width, height) for i in range(num_tasks)] + crop_results = [] + with _multiprocessing_cropdetect.Pool(processes=num_workers) as pool: + results_iterator = pool.imap_unordered(_analyze_segment_cropdetect, tasks) + for result in results_iterator: + crop_results.append(result) + all_crops_with_ts = [crop for sublist in crop_results for crop in sublist] + all_crop_strings = [item[0] for item in all_crops_with_ts] + if not all_crop_strings: + return None + crop_counts = _Counter_cropdetect(all_crop_strings) + clusters = _cluster_crop_values_cropdetect(crop_counts) + total_detections = sum(c['count'] for c in clusters) + significant_clusters = [] + for cluster in clusters: + percentage = (cluster['count'] / total_detections) * 100 + if percentage >= significant_crop_threshold: + significant_clusters.append(cluster) + for cluster in significant_clusters: + parsed_crop = _parse_crop_string_cropdetect(cluster['center']) + if parsed_crop: + _, ar_label = _snap_to_known_ar_cropdetect( + parsed_crop['w'], parsed_crop['h'], parsed_crop['x'], parsed_crop['y'], width, height + ) + cluster['ar_label'] = ar_label + else: + cluster['ar_label'] = None + if not significant_clusters: + return None + elif len(significant_clusters) == 1: + dominant_cluster = significant_clusters[0] + parsed_crop = _parse_crop_string_cropdetect(dominant_cluster['center']) + snapped_crop, ar_label = _snap_to_known_ar_cropdetect( + parsed_crop['w'], parsed_crop['h'], parsed_crop['x'], parsed_crop['y'], width, height + ) + parsed_snapped = _parse_crop_string_cropdetect(snapped_crop) + if parsed_snapped and parsed_snapped['w'] == width and parsed_snapped['h'] == height: + return None + else: + return snapped_crop + else: + crop_keys = [c['center'] for c in significant_clusters] + bounding_box_crop = _calculate_bounding_box_cropdetect(crop_keys) + if bounding_box_crop: + parsed_bb = _parse_crop_string_cropdetect(bounding_box_crop) + snapped_crop, ar_label = _snap_to_known_ar_cropdetect( + parsed_bb['w'], parsed_bb['h'], parsed_bb['x'], parsed_bb['y'], width, height + ) + parsed_snapped = _parse_crop_string_cropdetect(snapped_crop) + if parsed_snapped and parsed_snapped['w'] == width and parsed_snapped['h'] == height: + return None + else: + return snapped_crop + else: + return None + +def detect_autocrop_filter(input_file, significant_crop_threshold=5.0, min_crop=10, debug=False): + if not _check_prerequisites_cropdetect(): + return None + try: + probe_duration_args = [ + 'ffprobe', '-v', 'error', '-show_entries', 'format=duration', '-of', 'default=noprint_wrappers=1:nokey=1', + input_file + ] + duration_str = subprocess.check_output(probe_duration_args, stderr=subprocess.STDOUT, text=True) + duration = int(float(duration_str)) + probe_res_args = [ + 'ffprobe', '-v', 'error', + '-select_streams', 'v', + '-show_entries', 'stream=width,height,disposition', + '-of', 'json', + input_file + ] + probe_output = subprocess.check_output(probe_res_args, stderr=subprocess.STDOUT, text=True) + streams_data = json.loads(probe_output) + video_stream = None + for stream in streams_data.get('streams', []): + if stream.get('disposition', {}).get('attached_pic', 0) == 0: + video_stream = stream + break + if not video_stream or 'width' not in video_stream or 'height' not in video_stream: + return None + width = int(video_stream['width']) + height = int(video_stream['height']) + except Exception: + return None + return _analyze_video_cropdetect(input_file, duration, width, height, max(1, os.cpu_count() // 2), significant_crop_threshold, min_crop, debug) + +def main(no_downmix=False, autocrop=False, preset=None, crf=None, grain=None): + check_tools() + + # Override default SVT-AV1 params if provided via command line + if preset is not None: + SVT_AV1_PARAMS["preset"] = preset + if crf is not None: + SVT_AV1_PARAMS["crf"] = crf + if grain is not None: + SVT_AV1_PARAMS["film-grain"] = grain + + current_dir = Path(".") + files_to_process = sorted( + f for f in current_dir.glob("*.mkv") + if not (f.name.endswith(".ut.mkv") or f.name.startswith("temp-") or f.name.startswith("output-") or f.name.endswith(".cfr_temp.mkv")) + ) + if not files_to_process: + print("No MKV files found to process. Exiting.") + return + DIR_COMPLETED.mkdir(exist_ok=True, parents=True) + DIR_ORIGINAL.mkdir(exist_ok=True, parents=True) + DIR_CONV_LOGS.mkdir(exist_ok=True, parents=True) + while True: + files_to_process = sorted( + f for f in current_dir.glob("*.mkv") + if not (f.name.endswith(".ut.mkv") or f.name.startswith("temp-") or f.name.startswith("output-") or f.name.endswith(".cfr_temp.mkv")) + ) + if not files_to_process: + print("No more .mkv files found to process in the current directory. The script will now exit.") + break + file_path = files_to_process[0] + if not is_ffmpeg_decodable(file_path): + print(f"ERROR: ffmpeg cannot decode '{file_path.name}'. Skipping this file.", file=sys.stderr) + shutil.move(str(file_path), DIR_ORIGINAL / file_path.name) + continue + print("-" * shutil.get_terminal_size(fallback=(80, 24)).columns) + log_file_name = f"{file_path.stem}.log" + log_file_path = DIR_CONV_LOGS / log_file_name + original_stdout_console = sys.stdout + original_stderr_console = sys.stderr + print(f"Processing: {file_path.name}", file=original_stdout_console) + print(f"Logging output to: {log_file_path}", file=original_stdout_console) + log_file_handle = None + processing_error_occurred = False + date_for_runtime_calc = datetime.now() + try: + log_file_handle = open(log_file_path, 'w', encoding='utf-8') + sys.stdout = log_file_handle + sys.stderr = log_file_handle + print(f"STARTING LOG FOR: {file_path.name}") + print(f"Processing started at: {date_for_runtime_calc}") + print(f"Full input file path: {file_path.resolve()}") + print("-" * shutil.get_terminal_size(fallback=(80, 24)).columns) + input_file_abs = file_path.resolve() + intermediate_output_file = current_dir / f"output-{file_path.name}" + audio_temp_dir = None + handbrake_intermediate_for_cleanup = None + try: + audio_temp_dir = tempfile.mkdtemp(prefix="anime_audio_") + print(f"Audio temporary directory created at: {audio_temp_dir}") + print(f"Analyzing file: {input_file_abs}") + ffprobe_info_json = run_cmd([ + "ffprobe", "-v", "quiet", "-print_format", "json", "-show_streams", "-show_format", str(input_file_abs) + ], capture_output=True) + ffprobe_info = json.loads(ffprobe_info_json) + mkvmerge_info_json = run_cmd([ + "mkvmerge", "-J", str(input_file_abs) + ], capture_output=True) + mkv_info = json.loads(mkvmerge_info_json) + mediainfo_json = run_cmd([ + "mediainfo", "--Output=JSON", "-f", str(input_file_abs) + ], capture_output=True) + media_info = json.loads(mediainfo_json) + is_vfr = False + target_cfr_fps_for_handbrake = None + video_track_info = None + if media_info.get("media") and media_info["media"].get("track"): + for track in media_info["media"]["track"]: + if track.get("@type") == "Video": + video_track_info = track + break + if video_track_info: + frame_rate_mode = video_track_info.get("FrameRate_Mode") + if frame_rate_mode and frame_rate_mode.upper() in ["VFR", "VARIABLE"]: + is_vfr = True + print(f" - Detected VFR based on MediaInfo FrameRate_Mode: {frame_rate_mode}") + original_fps_str = video_track_info.get("FrameRate_Original_String") + if original_fps_str: + match = re.search(r'\((\d+/\d+)\)', original_fps_str) + if match: + target_cfr_fps_for_handbrake = match.group(1) + else: + target_cfr_fps_for_handbrake = video_track_info.get("FrameRate_Original") + if not target_cfr_fps_for_handbrake: + target_cfr_fps_for_handbrake = video_track_info.get("FrameRate_Original") + if not target_cfr_fps_for_handbrake: + target_cfr_fps_for_handbrake = video_track_info.get("FrameRate") + if target_cfr_fps_for_handbrake: + print(f" - Using MediaInfo FrameRate ({target_cfr_fps_for_handbrake}) as fallback for HandBrake target FPS.") + if target_cfr_fps_for_handbrake: + print(f" - Target CFR for HandBrake: {target_cfr_fps_for_handbrake}") + if isinstance(target_cfr_fps_for_handbrake, str) and "/" in target_cfr_fps_for_handbrake: + try: + num, den = map(float, target_cfr_fps_for_handbrake.split('/')) + target_cfr_fps_for_handbrake = f"{num / den:.3f}" + print(f" - Converted fractional FPS to decimal for HandBrake: {target_cfr_fps_for_handbrake}") + except ValueError: + print(f" - Warning: Could not parse fractional FPS '{target_cfr_fps_for_handbrake}'. HandBrakeCLI might fail.") + is_vfr = False + else: + print(" - Warning: VFR detected, but could not determine target CFR from MediaInfo. Will attempt standard UTVideo conversion without HandBrake.") + is_vfr = False + else: + print(f" - Video appears to be CFR or FrameRate_Mode not specified as VFR/Variable by MediaInfo.") + autocrop_filter = None + if autocrop: + print("--- Running autocrop detection ---") + autocrop_filter = detect_autocrop_filter(str(input_file_abs)) + if autocrop_filter: + print(f" - Autocrop filter detected: {autocrop_filter}") + else: + print(" - No crop needed or detected.") + encoded_video_file, handbrake_intermediate_for_cleanup = convert_video( + file_path.stem, str(input_file_abs), is_vfr, target_cfr_fps_for_handbrake, autocrop_filter=autocrop_filter + ) + + print("--- Starting Audio Processing ---") + processed_audio_files = [] + audio_tracks_to_remux = [] + audio_streams = [s for s in ffprobe_info.get("streams", []) if s.get("codec_type") == "audio"] + + # Build mkvmerge track mapping by track ID + mkv_audio_tracks = {t["id"]: t for t in mkv_info.get("tracks", []) if t.get("type") == "audio"} + + # Build mediainfo track mapping by StreamOrder + media_tracks_data = media_info.get("media", {}).get("track", []) + mediainfo_audio_tracks = {int(t.get("StreamOrder", -1)): t for t in media_tracks_data if t.get("@type") == "Audio"} + + for stream in audio_streams: + stream_index = stream["index"] + codec = stream.get("codec_name") + channels = stream.get("channels", 2) + language = stream.get("tags", {}).get("language", "und") + + # Find mkvmerge track by matching ffprobe stream index to mkvmerge track's 'properties'->'stream_id' + mkv_track = None + for t in mkv_info.get("tracks", []): + if t.get("type") == "audio" and t.get("properties", {}).get("stream_id") == stream_index: + mkv_track = t + break + if not mkv_track: + # Fallback: try by position + mkv_track = mkv_info.get("tracks", [])[stream_index] if stream_index < len(mkv_info.get("tracks", [])) else {} + + track_id = mkv_track.get("id", -1) + track_title = mkv_track.get("properties", {}).get("track_name", "") + + # Find mediainfo track by StreamOrder + audio_track_info = mediainfo_audio_tracks.get(stream_index) + track_delay = 0 + delay_raw = audio_track_info.get("Video_Delay") if audio_track_info else None + if delay_raw is not None: + try: + delay_val = float(delay_raw) + # If the value is a float < 1, it's seconds, so convert to ms. + if delay_val < 1: + track_delay = int(round(delay_val * 1000)) + else: + track_delay = int(round(delay_val)) + except Exception: + track_delay = 0 + + print(f"Processing Audio Stream #{stream_index} (TID: {track_id}, Codec: {codec}, Channels: {channels})") + if codec in REMUX_CODECS: + audio_tracks_to_remux.append(str(track_id)) + else: + # Convert any codec that is not in REMUX_CODECS + opus_file = convert_audio_track( + stream_index, channels, language, audio_temp_dir, str(input_file_abs), not no_downmix + ) + processed_audio_files.append({ + "Path": opus_file, + "Language": language, + "Title": track_title, + "Delay": track_delay + }) + + print("--- Finished Audio Processing ---") + + # Final mux + print("Assembling final file with mkvmerge...") + mkvmerge_args = ["mkvmerge", "-o", str(intermediate_output_file), str(encoded_video_file)] + for file_info in processed_audio_files: + sync_switch = ["--sync", f"0:{file_info['Delay']}"] if file_info["Delay"] else [] + mkvmerge_args += [ + "--language", f"0:{file_info['Language']}", + "--track-name", f"0:{file_info['Title']}" + ] + sync_switch + [str(file_info["Path"])] + + source_copy_args = ["--no-video"] + if audio_tracks_to_remux: + source_copy_args += ["--audio-tracks", ",".join(audio_tracks_to_remux)] + else: + source_copy_args += ["--no-audio"] + mkvmerge_args += source_copy_args + [str(input_file_abs)] + run_cmd(mkvmerge_args) + + # Move files + print("Moving files to final destinations...") + shutil.move(str(file_path), DIR_ORIGINAL / file_path.name) + shutil.move(str(intermediate_output_file), DIR_COMPLETED / file_path.name) + + print("Cleaning up persistent video temporary files (after successful processing)...") + video_temp_files_on_success = [ + current_dir / f"{file_path.stem}.vpy", + current_dir / f"{file_path.stem}.ut.mkv", + current_dir / f"temp-{file_path.stem}.mkv", # This is encoded_video_file + current_dir / f"{file_path.stem}.ut.mkv.lwi", + current_dir / f"{file_path.stem}.ut.mkv.ffindex", + ] + if handbrake_intermediate_for_cleanup and handbrake_intermediate_for_cleanup.exists(): + video_temp_files_on_success.append(handbrake_intermediate_for_cleanup) + + for temp_vid_file in video_temp_files_on_success: + if temp_vid_file.exists(): + print(f" Deleting: {temp_vid_file}") + temp_vid_file.unlink(missing_ok=True) + else: + print(f" Skipping (not found): {temp_vid_file}") + + except Exception as e: + print(f"ERROR: An error occurred while processing '{file_path.name}': {e}", file=sys.stderr) # Goes to log + original_stderr_console.write(f"ERROR during processing of '{file_path.name}': {e}\nSee log '{log_file_path}' for details.\n") + processing_error_occurred = True + finally: + # This is the original 'finally' block. Its prints go to the log file. + print("--- Starting Universal Cleanup (for this file) ---") + print(" - Cleaning up disposable audio temporary directory...") + if audio_temp_dir and Path(audio_temp_dir).exists(): + shutil.rmtree(audio_temp_dir, ignore_errors=True) + print(f" - Deleted audio temp dir: {audio_temp_dir}") + elif audio_temp_dir: # Was created but now not found + print(f" - Audio temp dir not found or already cleaned: {audio_temp_dir}") + else: # Was never created + print(f" - Audio temp dir was not created.") + + print(" - Cleaning up intermediate output file (if it wasn't moved on success)...") + if intermediate_output_file.exists(): # Check if it still exists (e.g. error before move) + if processing_error_occurred: + print(f" - WARNING: Processing error occurred. Intermediate output file '{intermediate_output_file}' is being preserved at its original path for inspection.") + else: + # No processing error, so it should have been moved. + # If it's still here, it's unexpected but we'll clean it up. + print(f" - INFO: Intermediate output file '{intermediate_output_file}' found at original path despite no errors (expected to be moved). Cleaning up.") + intermediate_output_file.unlink(missing_ok=True) # Only unlink if no error and it exists + print(f" - Deleted intermediate output file from original path: {intermediate_output_file}") + else: + # File does not exist at original path + if not processing_error_occurred: + print(f" - Intermediate output file successfully moved (not found at original path, as expected): {intermediate_output_file}") + else: + print(f" - Processing error occurred, and intermediate output file '{intermediate_output_file}' not found at original path (likely not created or cleaned by another step).") + # --- End of original per-file processing block --- + + print(f"FINISHED LOG FOR: {file_path.name}") + # --- End of log-specific messages --- + + finally: # Outer finally for restoring stdout/stderr and closing log file + runtime = datetime.now() - date_for_runtime_calc + runtime_str = str(runtime).split('.')[0] + + # This print goes to the log file, as stdout is not yet restored. + print(f"\nTotal runtime for this file: {runtime_str}") + + if sys.stdout != original_stdout_console: + sys.stdout = original_stdout_console + if sys.stderr != original_stderr_console: + sys.stderr = original_stderr_console + if log_file_handle: + log_file_handle.close() + + # Announce to console (original stdout/stderr) that this file is done + if processing_error_occurred: + original_stderr_console.write(f"File: {file_path.name}\n") + original_stderr_console.write(f"Log: {log_file_path}\n") + original_stderr_console.write(f"Runtime: {runtime_str}\n") + else: + original_stdout_console.write(f"File: {file_path.name}\n") + original_stdout_console.write(f"Log: {log_file_path}\n") + original_stdout_console.write(f"Runtime: {runtime_str}\n") + +if __name__ == "__main__": + import argparse + parser = argparse.ArgumentParser(description="Batch-process MKV files with resumable video encoding, audio downmixing, per-file logging, and optional autocrop.") + parser.add_argument("--no-downmix", action="store_true", help="Preserve original audio channel layout.") + parser.add_argument("--autocrop", action="store_true", help="Automatically detect and crop black bars from video using cropdetect.") + parser.add_argument("--preset", type=int, help=f"Set the encoding preset. Lower is slower/better compression. (default: {SVT_AV1_PARAMS['preset']})") + parser.add_argument("--crf", type=int, help=f"Set the Constant Rate Factor (CRF). Lower is better quality. (default: {SVT_AV1_PARAMS['crf']})") + parser.add_argument("--grain", type=int, help=f"Set the film-grain value (number). Adjusts the film grain synthesis level. (default: {SVT_AV1_PARAMS['film-grain']})") + args = parser.parse_args() + main(no_downmix=args.no_downmix, autocrop=args.autocrop, preset=args.preset, crf=args.crf, grain=args.grain)