Internet-Draft Matroska Format September 2024
Lhomme, et al. Expires 16 March 2025 [Page]
Workgroup:
cellar
Internet-Draft:
draft-ietf-cellar-matroska-22
Published:
Intended Status:
Standards Track
Expires:
Authors:
S. Lhomme
M. Bunkus
D. Rice

Matroska Media Container Format Specification

Abstract

This document defines the Matroska audiovisual data container structure, including definitions of its structural elements, terminology, vocabulary, and application.

This document updates RFC 8794 to permit the use of a previously reserved Extensible Binary Meta Language (EBML) Element ID.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."

This Internet-Draft will expire on 16 March 2025.

Table of Contents

1. Introduction

Matroska is an audiovisual data container format. It was derived from a project called [MCF] but diverges from it significantly because it is based on EBML (Extensible Binary Meta Language) [RFC8794], a binary derivative of XML. EBML provides significant advantages in terms of future format extensibility, without breaking file support in parsers reading the previous versions.

To avoid any misunderstandings, it is essential to clarify exactly what an audio/video container is:

Matroska is designed with the future in mind. It incorporates features such as:

2. Status of This Document

This document covers Matroska versions 1, 2, 3, and 4. Matroska version 4 is the current version. Matroska versions 1 to 3 are no longer maintained. No new elements are expected in files with version numbers 1, 2, or 3.

3. Notation and Conventions

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.

This document defines the following terms in order to define the format and application of Matroska:

Matroska:

A multimedia container format based on EBML (Extensible Binary Meta Language).

Matroska Reader:

A data parser that interprets the semantics of a Matroska document and creates a way for programs to use Matroska.

Matroska Player:

A Matroska Reader with the primary purpose of playing audiovisual files, including Matroska documents.

Matroska Writer:

A data writer that creates Matroska documents.

4. Matroska Overview

4.1. Principles

Matroska is a Document Type of EBML. This specification is dependent on the EBML specification [RFC8794]. For an understanding of Matroska's EBML Schema, see in particular the sections of the EBML specification that cover EBML Element Types (Section 7), EBML Schema (Section 11.1), and EBML Structure (Section 3).

4.2. Updates to RFC 8794

Because of an oversight, [RFC8794] reserved EBML ID 0x80, which is used by deployed Matroska implementations. For this reason, this specification updates [RFC8794] to make 0x80 a legal EBML ID. Additionally, this specification makes the following updates:

OLD:

One-octet Element IDs MUST be between 0x81 and 0xFE. These items are valuable because they are short, and they need to be used for commonly repeated elements. Element IDs are to be allocated within this range according to the "RFC Required" policy [RFC8126].

The following one-octet Element IDs are RESERVED: 0xFF and 0x80.

NEW:

One-octet Element IDs MUST be between 0x80 and 0xFE. These items are valuable because they are short, and they need to be used for commonly repeated elements. Element IDs are to be allocated within this range according to the "RFC Required" policy [RFC8126].

The following one-octet Element ID is RESERVED: 0xFF.

OLD:

  +=========================+================+=================+
  | Element ID Octet Length | Range of Valid | Number of Valid |
  |                         |  Element IDs   |     Element IDs |
  +=========================+================+=================+
  |            1            |  0x81 - 0xFE   |             126 |
  +-------------------------+----------------+-----------------+

NEW:

  +=========================+================+=================+
  | Element ID Octet Length | Range of Valid | Number of Valid |
  |                         |  Element IDs   |     Element IDs |
  +=========================+================+=================+
  |            1            |  0x80 - 0xFE   |             127 |
  +-------------------------+----------------+-----------------+

4.3. Added EBML Constraints

As an EBML Document Type, Matroska adds the following constraints to the EBML specification [RFC8794]:

  • The docType of the EBML Header MUST be "matroska".

  • The EBMLMaxIDLength of the EBML Header MUST be 4.

  • The EBMLMaxSizeLength of the EBML Header MUST be between 1 and 8, inclusive.

4.4. Design Rules

The Root Element and all Top-Level Elements MUST use 4 octets for their EBML Element ID -- i.e., Segment and direct children of Segment.

Legacy EBML/Matroska parsers did not handle Empty Elements properly; elements were present in the file but had a length of 0. They always assumed the value was 0 for integers/dates or 0x0p+0, the textual expression of floats using the format in [ISO9899], no matter the default value of the element that should have been used instead. Therefore, Matroska Writers MUST NOT use EBML Empty Elements if the element has a default value that is not 0 for integers/dates and 0x0p+0 for floats.

When adding new elements to Matroska, these rules apply:

  • A non-mandatory integer/date Element MUST NOT have a default value other than 0.

  • A non-mandatory float Element MUST NOT have a default value other than 0x0p+0.

  • A non-mandatory string Element MUST NOT have a default value, as empty strings cannot be defined in the XML Schema.

4.5. Data Layout

A Matroska file MUST be composed of at least one EBML Document using the Matroska Document Type. Each EBML Document MUST start with an EBML Header and MUST be followed by the EBML Root Element, defined as Segment in Matroska. Matroska defines several Top-Level Elements that may occur within the Segment.

As an example, a simple Matroska file consisting of a single EBML Document could be represented like this:

  • EBML Header
  • Segment

A more complex Matroska file consisting of an EBML Stream (consisting of two EBML Documents) could be represented like this:

  • EBML Header
  • Segment
  • EBML Header
  • Segment

The following diagram represents a simple Matroska file, comprised of an EBML Document with an EBML Header, a Segment element (the Root Element), and all eight Matroska Top-Level Elements. In the diagrams in this section, horizontal spacing expresses a parent-child relationship between Matroska elements (e.g., the Info element is contained within the Segment element), whereas vertical alignment represents the storage order within the file.

+-------------+
| EBML Header |
+---------------------------+
| Segment     | SeekHead    |
|             |-------------|
|             | Info        |
|             |-------------|
|             | Tracks      |
|             |-------------|
|             | Chapters    |
|             |-------------|
|             | Cluster     |
|             |-------------|
|             | Cues        |
|             |-------------|
|             | Attachments |
|             |-------------|
|             | Tags        |
+---------------------------+
Figure 1: Basic Layout of a Matroska File

The Matroska EBML Schema defines eight Top-Level Elements:

The SeekHead element (also known as MetaSeek) contains an index of Top-Level Elements locations within the Segment. Use of the SeekHead element is RECOMMENDED. Without a SeekHead element, a Matroska parser would have to search the entire file to find all of the other Top-Level Elements. This is due to Matroska's flexible ordering requirements; for instance, it is acceptable for the Chapters element to be stored after the Cluster element(s).

+--------------------------------+
| SeekHead | Seek | SeekID       |
|          |      |--------------|
|          |      | SeekPosition |
+--------------------------------+
Figure 2: Representation of a SeekHead Element

The Info element contains vital information for identifying the whole Segment. This includes the title for the Segment, a randomly generated unique identifier (UID), and the UID(s) of any linked Segment elements.

+-------------------------+
| Info | SegmentUUID      |
|      |------------------|
|      | SegmentFilename  |
|      |------------------|
|      | PrevUUID         |
|      |------------------|
|      | PrevFilename     |
|      |------------------|
|      | NextUUID         |
|      |------------------|
|      | NextFilename     |
|      |------------------|
|      | SegmentFamily    |
|      |------------------|
|      | ChapterTranslate |
|      |------------------|
|      | TimestampScale   |
|      |------------------|
|      | Duration         |
|      |------------------|
|      | DateUTC          |
|      |------------------|
|      | Title            |
|      |------------------|
|      | MuxingApp        |
|      |------------------|
|      | WritingApp       |
|-------------------------|
Figure 3: Representation of an Info Element and Its Child Elements

The Tracks element defines the technical details for each track and can store the name, number, UID, language, and type (audio, video, subtitles, etc.) of each track. For example, the Tracks element MAY store information about the resolution of a video track or sample rate of an audio track.

The Tracks element MUST identify all the data needed by the codec to decode the data of the specified track. However, the data required is contingent on the codec used for the track. For example, a Track element for uncompressed audio only requires the audio bit rate to be present. A codec such as AC-3 would require that the CodecID element be present for all tracks, as it is the primary way to identify which codec to use to decode the track.

+------------------------------------+
| Tracks | TrackEntry | TrackNumber  |
|        |            |--------------|
|        |            | TrackUID     |
|        |            |--------------|
|        |            | TrackType    |
|        |            |--------------|
|        |            | Name         |
|        |            |--------------|
|        |            | Language     |
|        |            |--------------|
|        |            | CodecID      |
|        |            |--------------|
|        |            | CodecPrivate |
|        |            |--------------|
|        |            | CodecName    |
|        |            |----------------------------------+
|        |            | Video        | FlagInterlaced    |
|        |            |              |-------------------|
|        |            |              | FieldOrder        |
|        |            |              |-------------------|
|        |            |              | StereoMode        |
|        |            |              |-------------------|
|        |            |              | AlphaMode         |
|        |            |              |-------------------|
|        |            |              | PixelWidth        |
|        |            |              |-------------------|
|        |            |              | PixelHeight       |
|        |            |              |-------------------|
|        |            |              | DisplayWidth      |
|        |            |              |-------------------|
|        |            |              | DisplayHeight     |
|        |            |              |-------------------|
|        |            |              | AspectRatioType   |
|        |            |              |-------------------|
|        |            |              | Colour            |
|        |            |----------------------------------|
|        |            | Audio        | SamplingFrequency |
|        |            |              |-------------------|
|        |            |              | Channels          |
|        |            |              |-------------------|
|        |            |              | BitDepth          |
|--------------------------------------------------------|

Figure 4: Representation of the Tracks Element and a Selection of Its Descendant Elements

The Chapters element lists all of the chapters. Chapters are a way to set predefined points to jump to in video or audio.

+-----------------------------------------+
| Chapters | Edition | EditionUID         |
|          | Entry   |--------------------|
|          |         | EditionFlagDefault |
|          |         |--------------------|
|          |         | EditionFlagOrdered |
|          |         |---------------------------------+
|          |         | ChapterAtom | ChapterUID        |
|          |         |             |-------------------|
|          |         |             | ChapterStringUID  |
|          |         |             |-------------------|
|          |         |             | ChapterTimeStart  |
|          |         |             |-------------------|
|          |         |             | ChapterTimeEnd    |
|          |         |             |-------------------|
|          |         |             | ChapterFlagHidden |
|          |         |             |-------------------------------+
|          |         |             | ChapterDisplay | ChapString   |
|          |         |             |                |--------------|
|          |         |             |                | ChapLanguage |
+------------------------------------------------------------------+
Figure 5: Representation of the Chapters Element and a Selection of Its Descendant Elements

Cluster elements contain the content for each track, e.g., video frames. A Matroska file SHOULD contain at least one Cluster element. In the rare case it doesn't, there should be a method for Segments to link together, possibly using Chapters; see Section 17.

The Cluster element helps to break up SimpleBlock or BlockGroup elements and helps with seeking and error protection. Every Cluster element MUST contain a Timestamp element. This SHOULD be the Timestamp element used to play the first Block in the Cluster element, unless a different value is needed to accommodate for more Blocks; see Section 11.2.

Cluster elements contain one or more Block element, such as BlockGroup or SimpleBlock elements. In some situations, a Cluster element MAY contain no Block element, for example, in a live recording when no data has been collected.

A BlockGroup element MAY contain a Block of data and any information relating directly to that Block.

+--------------------------+
| Cluster | Timestamp      |
|         |----------------|
|         | Position       |
|         |----------------|
|         | PrevSize       |
|         |----------------|
|         | SimpleBlock    |
|         |----------------|
|         | BlockGroup     |
+--------------------------+
Figure 6: Representation of a Cluster Element and Its Immediate Child Elements
+----------------------------------+
| Block | Portion of | Data Type   |
|       | a Block    |  - Bit Flag |
|       |--------------------------+
|       | Header     | TrackNumber |
|       |            |-------------|
|       |            | Timestamp   |
|       |            |-------------|
|       |            | Flags       |
|       |            |  - Gap      |
|       |            |  - Lacing   |
|       |            |  - Reserved |
|       |--------------------------|
|       | Optional   | FrameSize   |
|       |--------------------------|
|       | Data       | Frame       |
+----------------------------------+
Figure 7: Representation of the Block Element Structure

Each Cluster MUST contain exactly one Timestamp element. The Timestamp element value MUST be stored once per Cluster. The Timestamp element in the Cluster is relative to the entire Segment. The Timestamp element SHOULD be the first element in the Cluster it belongs to or the second element if that Cluster contains a CRC-32 element (Section 6.2).

Additionally, the Block contains an offset that, when added to the Cluster's Timestamp element value, yields the Block's effective timestamp. Therefore, the timestamp in the Block itself is relative to the Timestamp element in the Cluster. For example, if the Timestamp element in the Cluster is set to 10 seconds and a Block in that Cluster is supposed to be played 12 seconds into the clip, the timestamp in the Block would be set to 2 seconds.

The ReferenceBlock in the BlockGroup is used instead of the basic "P-frame"/"B-frame" description. Instead of simply saying that this Block depends on the Block directly before or directly after, the Timestamp of the necessary Block is used. Because there can be as many ReferenceBlock elements as necessary for a Block, it allows for some extremely complex referencing.

The Cues element is used to seek when playing back a file by providing a temporal index for some of the Tracks. It is similar to the SeekHead element but is used for seeking to a specific time when playing back the file. It is possible to seek without this element, but it is much more difficult because a Matroska Reader would have to "hunt and peck" through the file to look for the correct timestamp.

The Cues element SHOULD contain at least one CuePoint element. Each CuePoint element stores the position of the Cluster that contains the BlockGroup or SimpleBlock element. The timestamp is stored in the CueTime element, and the location is stored in the CueTrackPositions element.

The Cues element is flexible. For instance, the Cues element can be used to index every single timestamp of every Block or they can be indexed selectively.

+-------------------------------------+
| Cues | CuePoint | CueTime           |
|      |          |-------------------|
|      |          | CueTrackPositions |
|      |------------------------------|
|      | CuePoint | CueTime           |
|      |          |-------------------|
|      |          | CueTrackPositions |
+-------------------------------------+
Figure 8: Representation of a Cues Element and Two Levels of Its Descendant Elements

The Attachments element is for attaching files to a Matroska file, such as pictures, fonts, web pages, etc.

+------------------------------------------------+
| Attachments | AttachedFile | FileDescription   |
|             |              |-------------------|
|             |              | FileName          |
|             |              |-------------------|
|             |              | FileMediaType     |
|             |              |-------------------|
|             |              | FileData          |
|             |              |-------------------|
|             |              | FileUID           |
+------------------------------------------------+
Figure 9: Representation of an Attachments Element

The Tags element contains metadata that describes the Segment and potentially its Tracks, Chapters, and Attachments. Each Track or Chapter that those tags applies to has its UID listed in the Tags. The Tags contain all extra information about the file: scriptwriters, singers, actors, directors, titles, edition, price, dates, genre, comments, etc. Tags can contain their values in multiple languages. For example, a movie's "TITLE" tag value might contain both the original English title as well as the German title.

+-------------------------------------------+
| Tags | Tag | Targets   | TargetTypeValue  |
|      |     |           |------------------|
|      |     |           | TargetType       |
|      |     |           |------------------|
|      |     |           | TagTrackUID      |
|      |     |           |------------------|
|      |     |           | TagEditionUID    |
|      |     |           |------------------|
|      |     |           | TagChapterUID    |
|      |     |           |------------------|
|      |     |           | TagAttachmentUID |
|      |     |------------------------------|
|      |     | SimpleTag | TagName          |
|      |     |           |------------------|
|      |     |           | TagLanguage      |
|      |     |           |------------------|
|      |     |           | TagDefault       |
|      |     |           |------------------|
|      |     |           | TagString        |
|      |     |           |------------------|
|      |     |           | TagBinary        |
|      |     |           |------------------|
|      |     |           | SimpleTag        |
+-------------------------------------------+
Figure 10: Representation of a Tags Element and Three Levels of Its Children Elements

5. Matroska Schema

This specification includes an EBML Schema that defines the elements and structure of Matroska using the EBML Schema elements and attributes defined in Section 11.1 of [RFC8794].

Attributes using their default value (like minOccurs, minver, etc.) or attributes with undefined values (like length, maxver, etc.) are omitted.

The definitions for each Matroska element are provided below.

5.1. Segment Element

id / type:
0x18538067 / master
unknownsizeallowed:
True
path:
\Segment
minOccurs / maxOccurs:
1 / 1
definition:
The Root Element that contains all other Top-Level Elements; see Section 4.5.

5.1.1. SeekHead Element

id / type:
0x114D9B74 / master
path:
\Segment\SeekHead
maxOccurs:
2
definition:
Contains seeking information of Top-Level Elements; see Section 4.5.
5.1.1.1. Seek Element
id / type:
0x4DBB / master
path:
\Segment\SeekHead\Seek
minOccurs:
1
definition:
Contains a single seek entry to an EBML Element.
5.1.1.1.1. SeekID Element
id / type:
0x53AB / binary
length:
4
path:
\Segment\SeekHead\Seek\SeekID
minOccurs / maxOccurs:
1 / 1
definition:
The binary EBML ID of a Top-Level Element.
5.1.1.1.2. SeekPosition Element
id / type:
0x53AC / uinteger
path:
\Segment\SeekHead\Seek\SeekPosition
minOccurs / maxOccurs:
1 / 1
definition:
The Segment Position (Section 16) of a Top-Level Element.

5.1.2. Info Element

id / type:
0x1549A966 / master
path:
\Segment\Info
minOccurs / maxOccurs:
1 / 1
recurring:
True
definition:
Contains general information about the Segment.
5.1.2.1. SegmentUUID Element
id / type:
0x73A4 / binary
length:
16
path:
\Segment\Info\SegmentUUID
maxOccurs:
1
definition:
A randomly generated UID that identifies the Segment amongst many others (128 bits). It is equivalent to a Universally Unique Identifier (UUID) v4 [RFC4122] with all bits randomly (or pseudorandomly) chosen. An actual UUID v4 value, where some bits are not random, MAY also be used.
usage notes:
If the Segment is a part of a Linked Segment, then this element is REQUIRED. The value of the UID MUST contain at least one bit set to 1.
5.1.2.2. SegmentFilename Element
id / type:
0x7384 / utf-8
path:
\Segment\Info\SegmentFilename
maxOccurs:
1
definition:
A filename corresponding to this Segment.
5.1.2.3. PrevUUID Element
id / type:
0x3CB923 / binary
length:
16
path:
\Segment\Info\PrevUUID
maxOccurs:
1
definition:
An ID that identifies the previous Segment of a Linked Segment.
usage notes:
If the Segment is a part of a Linked Segment that uses Hard Linking (Section 17.1), then either the PrevUUID or the NextUUID element is REQUIRED. If a Segment contains a PrevUUID but not a NextUUID, then it MAY be considered as the last Segment of the Linked Segment. The PrevUUID MUST NOT be equal to the SegmentUUID.
5.1.2.4. PrevFilename Element
id / type:
0x3C83AB / utf-8
path:
\Segment\Info\PrevFilename
maxOccurs:
1
definition:
A filename corresponding to the file of the previous Linked Segment.
usage notes:
Provision of the previous filename is for display convenience, but PrevUUID SHOULD be considered authoritative for identifying the previous Segment in a Linked Segment.
5.1.2.5. NextUUID Element
id / type:
0x3EB923 / binary
length:
16
path:
\Segment\Info\NextUUID
maxOccurs:
1
definition:
An ID that identifies the next Segment of a Linked Segment.
usage notes:
If the Segment is a part of a Linked Segment that uses Hard Linking (Section 17.1), then either the PrevUUID or the NextUUID element is REQUIRED. If a Segment contains a NextUUID but not a PrevUUID, then it MAY be considered as the first Segment of the Linked Segment. The NextUUID MUST NOT be equal to the SegmentUUID.
5.1.2.6. NextFilename Element
id / type:
0x3E83BB / utf-8
path:
\Segment\Info\NextFilename
maxOccurs:
1
definition:
A filename corresponding to the file of the next Linked Segment.
usage notes:
Provision of the next filename is for display convenience, but NextUUID SHOULD be considered authoritative for identifying the Next Segment.
5.1.2.7. SegmentFamily Element
id / type:
0x4444 / binary
length:
16
path:
\Segment\Info\SegmentFamily
definition:
A UID that all Segments of a Linked Segment MUST share (128 bits). It is equivalent to a UUID v4 [RFC4122] with all bits randomly (or pseudorandomly) chosen. An actual UUID v4 value, where some bits are not random, MAY also be used.
usage notes:
If the Segment Info contains a ChapterTranslate element, this element is REQUIRED.
5.1.2.8. ChapterTranslate Element
id / type:
0x6924 / master
path:
\Segment\Info\ChapterTranslate
definition:
The mapping between this Segment and a segment value in the given Chapter Codec.
rationale:
Chapter Codecs may need to address different segments, but they may not know of the way to identify such segments when stored in Matroska. This element and its child elements add a way to map the internal segments known to the Chapter Codec to the SegmentUUIDs in Matroska. This allows remuxing a file with Chapter Codec without changing the content of the codec data, just the Segment mapping.
5.1.2.8.1. ChapterTranslateID Element
id / type:
0x69A5 / binary
path:
\Segment\Info\ChapterTranslate\ChapterTranslateID
minOccurs / maxOccurs:
1 / 1
definition:
The binary value used to represent this Segment in the chapter codec data. The format depends on the ChapProcessCodecID used; see Section 5.1.7.1.4.15.
5.1.2.8.2. ChapterTranslateCodec Element
id / type:
0x69BF / uinteger
path:
\Segment\Info\ChapterTranslate\ChapterTranslateCodec
minOccurs / maxOccurs:
1 / 1
definition:
Applies to the chapter codec of the given chapter edition(s); see Section 5.1.7.1.4.15.
defined values:
See Table 31. Additional values can be registered in the "Matroska Chapter Codec IDs" registry defined in Section 27.14.
5.1.2.8.3. ChapterTranslateEditionUID Element
id / type:
0x69FC / uinteger
path:
\Segment\Info\ChapterTranslate\ChapterTranslateEditionUID
definition:
Specifies a chapter edition UID to which this ChapterTranslate applies.
usage notes:
When no ChapterTranslateEditionUID is specified in the ChapterTranslate, the ChapterTranslate applies to all chapter editions found in the Segment using the given ChapterTranslateCodec.
5.1.2.9. TimestampScale Element
id / type / default:
0x2AD7B1 / uinteger / 1000000
range:
not 0
path:
\Segment\Info\TimestampScale
minOccurs / maxOccurs:
1 / 1
definition:
Base unit for Segment Ticks and Track Ticks, in nanoseconds. A TimestampScale value of 1000000 means scaled timestamps in the Segment are expressed in milliseconds; see Section 11 on how to interpret timestamps.
5.1.2.10. Duration Element
id / type:
0x4489 / float
range:
> 0x0p+0
path:
\Segment\Info\Duration
maxOccurs:
1
definition:
Duration of the Segment, expressed in Segment Ticks, which are based on TimestampScale; see Section 11.1.
5.1.2.11. DateUTC Element
id / type:
0x4461 / date
path:
\Segment\Info\DateUTC
maxOccurs:
1
definition:
The date and time that the Segment was created by the muxing application or library.
5.1.2.12. Title Element
id / type:
0x7BA9 / utf-8
path:
\Segment\Info\Title
maxOccurs:
1
definition:
General name of the Segment.
5.1.2.13. MuxingApp Element
id / type:
0x4D80 / utf-8
path:
\Segment\Info\MuxingApp
minOccurs / maxOccurs:
1 / 1
definition:
Muxing application or library (example: "libmatroska-0.4.3").
usage notes:
Include the full name of the application or library followed by the version number.
5.1.2.14. WritingApp Element
id / type:
0x5741 / utf-8
path:
\Segment\Info\WritingApp
minOccurs / maxOccurs:
1 / 1
definition:
Writing application (example: "mkvmerge-0.3.3").
usage notes:
Include the full name of the application followed by the version number.

5.1.3. Cluster Element

id / type:
0x1F43B675 / master
unknownsizeallowed:
True
path:
\Segment\Cluster
definition:
The Top-Level Element containing the (monolithic) Block structure.
5.1.3.1. Timestamp Element
id / type:
0xE7 / uinteger
path:
\Segment\Cluster\Timestamp
minOccurs / maxOccurs:
1 / 1
definition:
Absolute timestamp of the cluster, expressed in Segment Ticks, which are based on TimestampScale; see Section 11.1.
usage notes:
This element SHOULD be the first child element of the Cluster it belongs to or the second if that Cluster contains a CRC-32 element (Section 6.2).
5.1.3.2. Position Element
id / type:
0xA7 / uinteger
path:
\Segment\Cluster\Position
maxOccurs:
1
maxver:
4
definition:
The Segment Position of the Cluster in the Segment (0 in live streams). It might help to resynchronize the offset on damaged streams.
5.1.3.3. PrevSize Element
id / type:
0xAB / uinteger
path:
\Segment\Cluster\PrevSize
maxOccurs:
1
definition:
Size of the previous Cluster, in octets. Can be useful for backward playing.
5.1.3.4. SimpleBlock Element
id / type:
0xA3 / binary
path:
\Segment\Cluster\SimpleBlock
minver:
2
definition:
Similar to Block (see Section 10.1) but without all the extra information. Mostly used to reduce overhead when no extra feature is needed; see Section 10.2 on SimpleBlock Structure.
5.1.3.5. BlockGroup Element
id / type:
0xA0 / master
path:
\Segment\Cluster\BlockGroup
definition:
Basic container of information containing a single Block and information specific to that Block.
5.1.3.5.1. Block Element
id / type:
0xA1 / binary
path:
\Segment\Cluster\BlockGroup\Block
minOccurs / maxOccurs:
1 / 1
definition:
Block containing the actual data to be rendered and a timestamp relative to the Cluster Timestamp; see Section 10.1 on Block Structure.
5.1.3.5.2. BlockAdditions Element
id / type:
0x75A1 / master
path:
\Segment\Cluster\BlockGroup\BlockAdditions
maxOccurs:
1
definition:
Contains additional binary data to complete the Block element; see Section 4.1.5 of [I-D.ietf-cellar-codec] for more information. An EBML parser that has no knowledge of the Block structure could still see and use/skip these data.
5.1.3.5.2.1. BlockMore Element
id / type:
0xA6 / master
path:
\Segment\Cluster\BlockGroup\BlockAdditions\BlockMore
minOccurs:
1
definition:
Contains the BlockAdditional and some parameters.
5.1.3.5.2.2. BlockAdditional Element
id / type:
0xA5 / binary
path:
\Segment\Cluster\BlockGroup\BlockAdditions\BlockMore\BlockAdditional
minOccurs / maxOccurs:
1 / 1
definition:
Interpreted by the codec as it wishes (using the BlockAddID).
5.1.3.5.2.3. BlockAddID Element
id / type / default:
0xEE / uinteger / 1
range:
not 0
path:
\Segment\Cluster\BlockGroup\BlockAdditions\BlockMore\BlockAddID
minOccurs / maxOccurs:
1 / 1
definition:
An ID that identifies how to interpret the BlockAdditional data; see Section 4.1.5 of [I-D.ietf-cellar-codec] for more information. A value of 1 indicates that the BlockAdditional data is defined by the codec. Any other value indicates that the BlockAdditional data should be handled according to the BlockAddIDType that is located in the TrackEntry.
usage notes:
Each BlockAddID value MUST be unique between all BlockMore elements found in a BlockAdditions element. To keep MaxBlockAdditionID as low as possible, small values SHOULD be used.
5.1.3.5.3. BlockDuration Element
id / type:
0x9B / uinteger
path:
\Segment\Cluster\BlockGroup\BlockDuration
minOccurs / maxOccurs:
See Table 1 / 1
definition:
The duration of the Block, expressed in Track Ticks; see Section 11.1. The BlockDuration element can be useful at the end of a Track to define the duration of the last frame (as there is no subsequent Block available) or when there is a break in a track like for subtitle tracks.
notes:
See Table 1.
Table 1: BlockDuration Implementation Notes
attribute note
minOccurs BlockDuration MUST be set (minOccurs=1) if the associated TrackEntry stores a DefaultDuration value.
default If a value is not present and no DefaultDuration is defined, the value is assumed to be the difference between the timestamp of this Block and the timestamp of the next Block in "display" order (not coding order).
5.1.3.5.4. ReferencePriority Element
id / type / default:
0xFA / uinteger / 0
path:
\Segment\Cluster\BlockGroup\ReferencePriority
minOccurs / maxOccurs:
1 / 1
definition:
This frame is referenced and has the specified cache priority. In the cache, only a frame of the same or higher priority can replace this frame. A value of 0 means the frame is not referenced.
5.1.3.5.5. ReferenceBlock Element
id / type:
0xFB / integer
path:
\Segment\Cluster\BlockGroup\ReferenceBlock
definition:
A timestamp value, relative to the timestamp of the Block in this BlockGroup, expressed in Track Ticks; see Section 11.1. This is used to reference other frames necessary to decode this frame. The relative value SHOULD correspond to a valid Block that this Block depends on. Historically, Matroska Writers didn't write the actual Block(s) that this Block depends on, but they did write some Block(s) in the past.

The value "0" MAY also be used to signify that this Block cannot be decoded on its own, but the necessary reference Block(s) is unknown. In this case, other ReferenceBlock elements MUST NOT be found in the same BlockGroup.

If the BlockGroup doesn't have a ReferenceBlock element, then the Block it contains can be decoded without using any other Block data.

5.1.3.5.6. CodecState Element
id / type:
0xA4 / binary
path:
\Segment\Cluster\BlockGroup\CodecState
maxOccurs:
1
minver:
2
definition:
The new codec state to use. Data interpretation is private to the codec. This information SHOULD always be referenced by a seek entry.
5.1.3.5.7. DiscardPadding Element
id / type:
0x75A2 / integer
path:
\Segment\Cluster\BlockGroup\DiscardPadding
maxOccurs:
1
minver:
4
definition:
Duration of the silent data added to the Block, expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1 (padding at the end of the Block for positive values and at the beginning of the Block for negative values). The duration of DiscardPadding is not calculated in the duration of the TrackEntry and SHOULD be discarded during playback.

5.1.4. Tracks Element

id / type:
0x1654AE6B / master
path:
\Segment\Tracks
maxOccurs:
1
recurring:
True
definition:
A Top-Level Element of information with many tracks described.
5.1.4.1. TrackEntry Element
id / type:
0xAE / master
path:
\Segment\Tracks\TrackEntry
minOccurs:
1
definition:
Describes a track with all elements.
5.1.4.1.1. TrackNumber Element
id / type:
0xD7 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\TrackNumber
minOccurs / maxOccurs:
1 / 1
definition:
The track number as used in the Block Header.
5.1.4.1.2. TrackUID Element
id / type:
0x73C5 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\TrackUID
minOccurs / maxOccurs:
1 / 1
definition:
A UID that identifies the Track.
stream copy:
True (Section 8)
5.1.4.1.3. TrackType Element
id / type:
0x83 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\TrackType
minOccurs / maxOccurs:
1 / 1
definition:
The TrackType defines the type of each frame found in the Track. The value SHOULD be stored on 1 octet.
defined values:
See Table 2. Additional values can be registered in the "Matroska Track Types" registry defined in Section 27.16.
stream copy:
True (Section 8)
Table 2: TrackType Values
value label contents of each frame
1 video An image.
2 audio Audio samples.
3 complex A mix of different other TrackType. The codec needs to define how the Matroska Player should interpret such data.
16 logo An image to be rendered over the video track(s).
17 subtitle Subtitle or closed caption data to be rendered over the video track(s).
18 buttons Interactive button(s) to be rendered over the video track(s).
32 control Metadata used to control the player of the Matroska Player.
33 metadata Timed metadata that can be passed on to the Matroska Player.
5.1.4.1.4. FlagEnabled Element
id / type / default:
0xB9 / uinteger / 1
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagEnabled
minOccurs / maxOccurs:
1 / 1
minver:
2
definition:
Set to 1 if the track is usable. It is possible to turn a track that is not usable into a usable track using chapter codecs or control tracks.
5.1.4.1.5. FlagDefault Element
id / type / default:
0x88 / uinteger / 1
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagDefault
minOccurs / maxOccurs:
1 / 1
definition:
Set to 1 if the track (audio, video, or subtitles) is eligible for automatic selection by the player; see Section 19 for more details.
5.1.4.1.6. FlagForced Element
id / type / default:
0x55AA / uinteger / 0
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagForced
minOccurs / maxOccurs:
1 / 1
definition:
Applies only to subtitles. Set to 1 if the track is eligible for automatic selection by the player if it matches the user's language preference, even if the user's preferences would not normally enable subtitles with the selected audio track; this can be used for tracks containing only translations of audio in foreign languages or on-screen text. See Section 19 for more details.
5.1.4.1.7. FlagHearingImpaired Element
id / type:
0x55AB / uinteger
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagHearingImpaired
maxOccurs:
1
minver:
4
definition:
Set to 1 if and only if the track is suitable for users with hearing impairments.
5.1.4.1.8. FlagVisualImpaired Element
id / type:
0x55AC / uinteger
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagVisualImpaired
maxOccurs:
1
minver:
4
definition:
Set to 1 if and only if the track is suitable for users with visual impairments.
5.1.4.1.9. FlagTextDescriptions Element
id / type:
0x55AD / uinteger
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagTextDescriptions
maxOccurs:
1
minver:
4
definition:
Set to 1 if and only if the track contains textual descriptions of video content.
5.1.4.1.10. FlagOriginal Element
id / type:
0x55AE / uinteger
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagOriginal
maxOccurs:
1
minver:
4
definition:
Set to 1 if and only if the track is in the content's original language.
5.1.4.1.11. FlagCommentary Element
id / type:
0x55AF / uinteger
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagCommentary
maxOccurs:
1
minver:
4
definition:
Set to 1 if and only if the track contains commentary.
5.1.4.1.12. FlagLacing Element
id / type / default:
0x9C / uinteger / 1
range:
0-1
path:
\Segment\Tracks\TrackEntry\FlagLacing
minOccurs / maxOccurs:
1 / 1
definition:
Set to 1 if the track MAY contain blocks that use lacing. When set to 0, all blocks MUST have their lacing flags set to "no lacing"; see Section 10.3 on 'Block' Lacing.
5.1.4.1.13. DefaultDuration Element
id / type:
0x23E383 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\DefaultDuration
maxOccurs:
1
definition:
Number of nanoseconds per frame, expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1 ("frame" in the Matroska sense -- one element put into a (Simple)Block).
stream copy:
True (Section 8)
5.1.4.1.14. DefaultDecodedFieldDuration Element
id / type:
0x234E7A / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\DefaultDecodedFieldDuration
maxOccurs:
1
minver:
4
definition:
The period between two successive fields at the output of the decoding process, expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1. See Section 9 for more information.
stream copy:
True (Section 8)
5.1.4.1.15. TrackTimestampScale Element
id / type / default:
0x23314F / float / 0x1p+0
range:
> 0x0p+0
path:
\Segment\Tracks\TrackEntry\TrackTimestampScale
minOccurs / maxOccurs:
1 / 1
maxver:
3
definition:
The scale to apply on this track to work at normal speed in relation with other tracks (mostly used to adjust video speed when the audio length differs).
stream copy:
True (Section 8)
5.1.4.1.16. MaxBlockAdditionID Element
id / type / default:
0x55EE / uinteger / 0
path:
\Segment\Tracks\TrackEntry\MaxBlockAdditionID
minOccurs / maxOccurs:
1 / 1
definition:
The maximum value of BlockAddID (Section 5.1.3.5.2.3). A value of 0 means there is no BlockAdditions (Section 5.1.3.5.2) for this track.
5.1.4.1.17. BlockAdditionMapping Element
id / type:
0x41E4 / master
path:
\Segment\Tracks\TrackEntry\BlockAdditionMapping
minver:
4
definition:
Contains elements that extend the track format by adding content either to each frame, with BlockAddID (Section 5.1.3.5.2.3), or to the track as a whole with BlockAddIDExtraData.
5.1.4.1.17.1. BlockAddIDValue Element
id / type:
0x41F0 / uinteger
range:
>=2
path:
\Segment\Tracks\TrackEntry\BlockAdditionMapping\BlockAddIDValue
maxOccurs:
1
minver:
4
definition:
If the track format extension needs content beside frames, the value refers to the BlockAddID (Section 5.1.3.5.2.3) value being described.
usage notes:
To keep MaxBlockAdditionID as low as possible, small values SHOULD be used.
5.1.4.1.17.2. BlockAddIDName Element
id / type:
0x41A4 / string
path:
\Segment\Tracks\TrackEntry\BlockAdditionMapping\BlockAddIDName
maxOccurs:
1
minver:
4
definition:
A human-friendly name describing the type of BlockAdditional data, as defined by the associated Block Additional Mapping.
5.1.4.1.17.3. BlockAddIDType Element
id / type / default:
0x41E7 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\BlockAdditionMapping\BlockAddIDType
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Stores the registered identifier of the Block Additional Mapping to define how the BlockAdditional data should be handled.
usage notes:
If BlockAddIDType is 0, the BlockAddIDValue and corresponding BlockAddID values MUST be 1.
5.1.4.1.17.4. BlockAddIDExtraData Element
id / type:
0x41ED / binary
path:
\Segment\Tracks\TrackEntry\BlockAdditionMapping\BlockAddIDExtraData
maxOccurs:
1
minver:
4
definition:
Extra binary data that the BlockAddIDType can use to interpret the BlockAdditional data. The interpretation of the binary data depends on the BlockAddIDType value and the corresponding Block Additional Mapping.
5.1.4.1.18. Name Element
id / type:
0x536E / utf-8
path:
\Segment\Tracks\TrackEntry\Name
maxOccurs:
1
definition:
A human-readable track name.
5.1.4.1.19. Language Element
id / type / default:
0x22B59C / string / eng
path:
\Segment\Tracks\TrackEntry\Language
minOccurs / maxOccurs:
1 / 1
definition:
The language of the track, in the Matroska languages form; see Section 12 on language codes. This element MUST be ignored if the LanguageBCP47 element is used in the same TrackEntry.
5.1.4.1.20. LanguageBCP47 Element
id / type:
0x22B59D / string
path:
\Segment\Tracks\TrackEntry\LanguageBCP47
maxOccurs:
1
minver:
4
definition:
The language of the track, in the form defined in [RFC5646]; see Section 12 on language codes. If this element is used, then any Language elements used in the same TrackEntry MUST be ignored.
5.1.4.1.21. CodecID Element
id / type:
0x86 / string
path:
\Segment\Tracks\TrackEntry\CodecID
minOccurs / maxOccurs:
1 / 1
definition:
An ID corresponding to the codec; see [I-D.ietf-cellar-codec] for more info.
stream copy:
True (Section 8)
5.1.4.1.22. CodecPrivate Element
id / type:
0x63A2 / binary
path:
\Segment\Tracks\TrackEntry\CodecPrivate
maxOccurs:
1
definition:
Private data only known to the codec.
stream copy:
True (Section 8)
5.1.4.1.23. CodecName Element
id / type:
0x258688 / utf-8
path:
\Segment\Tracks\TrackEntry\CodecName
maxOccurs:
1
definition:
A human-readable string specifying the codec.
5.1.4.1.25. CodecDelay Element
id / type / default:
0x56AA / uinteger / 0
path:
\Segment\Tracks\TrackEntry\CodecDelay
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
The built-in delay for the codec, expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1. It represents the number of codec samples that will be discarded by the decoder during playback. This timestamp value MUST be subtracted from each frame timestamp in order to get the timestamp that will be actually played. The value SHOULD be small so the muxing of tracks with the same actual timestamp are in the same Cluster.
stream copy:
True (Section 8)
5.1.4.1.26. SeekPreRoll Element
id / type / default:
0x56BB / uinteger / 0
path:
\Segment\Tracks\TrackEntry\SeekPreRoll
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
After a discontinuity, the duration of the data that the decoder MUST decode before the decoded data is valid, expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1.
stream copy:
True (Section 8)
5.1.4.1.27. TrackTranslate Element
id / type:
0x6624 / master
path:
\Segment\Tracks\TrackEntry\TrackTranslate
definition:
The mapping between this TrackEntry and a track value in the given Chapter Codec.
rationale:
Chapter Codecs may need to address content in a specific track, but they may not know of the way to identify tracks in Matroska. This element and its child elements add a way to map the internal tracks known to the Chapter Codec to the track IDs in Matroska. This allows remuxing a file with Chapter Codec without changing the content of the codec data, just the track mapping.
5.1.4.1.27.1. TrackTranslateTrackID Element
id / type:
0x66A5 / binary
path:
\Segment\Tracks\TrackEntry\TrackTranslate\TrackTranslateTrackID
minOccurs / maxOccurs:
1 / 1
definition:
The binary value used to represent this TrackEntry in the chapter codec data. The format depends on the ChapProcessCodecID used; see Section 5.1.7.1.4.15.
5.1.4.1.27.2. TrackTranslateCodec Element
id / type:
0x66BF / uinteger
path:
\Segment\Tracks\TrackEntry\TrackTranslate\TrackTranslateCodec
minOccurs / maxOccurs:
1 / 1
definition:
Applies to the chapter codec of the given chapter edition(s); see Section 5.1.7.1.4.15.
defined values:
See Table 31. Additional values can be registered in the "Matroska Chapter Codec IDs" registry defined in Section 27.14.
5.1.4.1.27.3. TrackTranslateEditionUID Element
id / type:
0x66FC / uinteger
path:
\Segment\Tracks\TrackEntry\TrackTranslate\TrackTranslateEditionUID
definition:
Specifies a chapter edition UID to which this TrackTranslate applies.
usage notes:
When no TrackTranslateEditionUID is specified in the TrackTranslate, the TrackTranslate applies to all chapter editions found in the Segment using the given TrackTranslateCodec.
5.1.4.1.28. Video Element
id / type:
0xE0 / master
path:
\Segment\Tracks\TrackEntry\Video
maxOccurs:
1
definition:
Video settings.
5.1.4.1.28.1. FlagInterlaced Element
id / type / default:
0x9A / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\FlagInterlaced
minOccurs / maxOccurs:
1 / 1
minver:
2
definition:
Specifies whether the video frames in this track are interlaced.
restrictions:
See Table 3.
stream copy:
True (Section 8)
Table 3: FlagInterlaced Values
value label definition
0 undetermined Unknown status. This value SHOULD be avoided.
1 interlaced Interlaced frames.
2 progressive No interlacing.
5.1.4.1.28.2. FieldOrder Element
id / type / default:
0x9D / uinteger / 2
path:
\Segment\Tracks\TrackEntry\Video\FieldOrder
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Specifies the field ordering of video frames in this track.
restrictions:
See Table 4.
usage notes:
If FlagInterlaced is not set to 1, this element MUST be ignored.
stream copy:
True (Section 8)
Table 4: FieldOrder Values
value label definition
0 progressive Interlaced frames. This value SHOULD be avoided; setting FlagInterlaced to 2 is sufficient.
1 tff Top field displayed first. Top field stored first.
2 undetermined Unknown field order. This value SHOULD be avoided.
6 bff Bottom field displayed first. Bottom field stored first.
9 tff (interleaved) Top field displayed first. Fields are interleaved in storage with the top line of the top field stored first.
14 bff (interleaved) Bottom field displayed first. Fields are interleaved in storage with the top line of the top field stored first.
5.1.4.1.28.3. StereoMode Element
id / type / default:
0x53B8 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\StereoMode
minOccurs / maxOccurs:
1 / 1
minver:
3
definition:
Stereo-3D video mode. See Section 18.10 for more details.
defined values:
See Table 5. Additional values can be registered in the "Matroska Stereo Modes" registry defined in Section 27.7.
stream copy:
True (Section 8)
Table 5: StereoMode Values
value label
0 mono
1 side by side (left eye first)
2 top - bottom (right eye is first)
3 top - bottom (left eye is first)
4 checkboard (right eye is first)
5 checkboard (left eye is first)
6 row interleaved (right eye is first)
7 row interleaved (left eye is first)
8 column interleaved (right eye is first)
9 column interleaved (left eye is first)
10 anaglyph (cyan/red)
11 side by side (right eye first)
12 anaglyph (green/magenta)
13 both eyes laced in one Block (left eye is first)
14 both eyes laced in one Block (right eye is first)
5.1.4.1.28.4. AlphaMode Element
id / type / default:
0x53C0 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\AlphaMode
minOccurs / maxOccurs:
1 / 1
minver:
3
definition:
Indicates whether the BlockAdditional element with BlockAddID of "1" contains Alpha data as defined by the Codec Mapping for the CodecID. Undefined values (i.e., values other than 0 or 1) SHOULD NOT be used, as the behavior of known implementations is different.
defined values:
See Table 6. Additional values can be registered in the "Matroska Alpha Modes" registry defined in Section 27.8.
stream copy:
True (Section 8)
Table 6: AlphaMode Values
value label definition
0 none The BlockAdditional element with BlockAddID of "1" does not exist or SHOULD NOT be considered as containing such data.
1 present The BlockAdditional element with BlockAddID of "1" contains alpha channel data.
5.1.4.1.28.5. OldStereoMode Element
id / type:
0x53B9 / uinteger
path:
\Segment\Tracks\TrackEntry\Video\OldStereoMode
maxOccurs:
1
maxver:
2
definition:
Bogus StereoMode value used in old versions of [libmatroska].
restrictions:
See Table 7.
usage notes:
This element MUST NOT be used. It was an incorrect value used in libmatroska up to 0.9.0.
Table 7: OldStereoMode Values
value label
0 mono
1 right eye
2 left eye
3 both eyes
5.1.4.1.28.6. PixelWidth Element
id / type:
0xB0 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\Video\PixelWidth
minOccurs / maxOccurs:
1 / 1
definition:
Width of the encoded video frames in pixels.
stream copy:
True (Section 8)
5.1.4.1.28.7. PixelHeight Element
id / type:
0xBA / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\Video\PixelHeight
minOccurs / maxOccurs:
1 / 1
definition:
Height of the encoded video frames in pixels.
stream copy:
True (Section 8)
5.1.4.1.28.8. PixelCropBottom Element
id / type / default:
0x54AA / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\PixelCropBottom
minOccurs / maxOccurs:
1 / 1
definition:
The number of video pixels to remove at the bottom of the image.
stream copy:
True (Section 8)
5.1.4.1.28.9. PixelCropTop Element
id / type / default:
0x54BB / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\PixelCropTop
minOccurs / maxOccurs:
1 / 1
definition:
The number of video pixels to remove at the top of the image.
stream copy:
True (Section 8)
5.1.4.1.28.10. PixelCropLeft Element
id / type / default:
0x54CC / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\PixelCropLeft
minOccurs / maxOccurs:
1 / 1
definition:
The number of video pixels to remove on the left of the image.
stream copy:
True (Section 8)
5.1.4.1.28.11. PixelCropRight Element
id / type / default:
0x54DD / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\PixelCropRight
minOccurs / maxOccurs:
1 / 1
definition:
The number of video pixels to remove on the right of the image.
stream copy:
True (Section 8)
5.1.4.1.28.12. DisplayWidth Element
id / type:
0x54B0 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\Video\DisplayWidth
maxOccurs:
1
definition:
Width of the video frames to display. Applies to the video frame after cropping (PixelCrop* Elements).
notes:
See Table 8.
stream copy:
True (Section 8)
Table 8: DisplayWidth Implementation Notes
attribute note
default If the DisplayUnit of the same TrackEntry is 0, then the default value for DisplayWidth is equal to PixelWidth - PixelCropLeft - PixelCropRight; else, there is no default value.
5.1.4.1.28.13. DisplayHeight Element
id / type:
0x54BA / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\Video\DisplayHeight
maxOccurs:
1
definition:
Height of the video frames to display. Applies to the video frame after cropping (PixelCrop* Elements).
notes:
See Table 9.
stream copy:
True (Section 8)
Table 9: DisplayHeight Implementation Notes
attribute note
default If the DisplayUnit of the same TrackEntry is 0, then the default value for DisplayHeight is equal to PixelHeight - PixelCropTop - PixelCropBottom; else, there is no default value.
5.1.4.1.28.14. DisplayUnit Element
id / type / default:
0x54B2 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\DisplayUnit
minOccurs / maxOccurs:
1 / 1
definition:
How DisplayWidth and DisplayHeight are interpreted.
defined values:
See Table 10. Additional values can be registered in the "Matroska Display Units" registry defined in Section 27.9.
Table 10: DisplayUnit Values
value label
0 pixels
1 centimeters
2 inches
3 display aspect ratio
4 unknown
5.1.4.1.28.15. UncompressedFourCC Element
id / type:
0x2EB524 / binary
length:
4
path:
\Segment\Tracks\TrackEntry\Video\UncompressedFourCC
minOccurs / maxOccurs:
See Table 11 / 1
definition:
Specifies the uncompressed pixel format used for the Track's data as a FourCC. This value is similar in scope to the biCompression value of AVI's BITMAPINFO [AVIFormat]. There is neither a definitive list of FourCC values nor an official registry. Some common values for YUV pixel formats can be found at [MSYUV8], [MSYUV16], and [FourCC-YUV]. Some common values for uncompressed RGB pixel formats can be found at [MSRGB] and [FourCC-RGB].
notes:
See Table 11.
stream copy:
True (Section 8)
Table 11: UncompressedFourCC Implementation Notes
attribute note
minOccurs UncompressedFourCC MUST be set (minOccurs=1) in TrackEntry when the CodecID element of the TrackEntry is set to "V_UNCOMPRESSED".
5.1.4.1.28.16. Colour Element
id / type:
0x55B0 / master
path:
\Segment\Tracks\TrackEntry\Video\Colour
maxOccurs:
1
minver:
4
definition:
Settings describing the color format.
stream copy:
True (Section 8)
5.1.4.1.28.17. MatrixCoefficients Element
id / type / default:
0x55B1 / uinteger / 2
path:
\Segment\Tracks\TrackEntry\Video\Colour\MatrixCoefficients
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
The Matrix Coefficients of the video used to derive luma and chroma values from red, green, and blue color primaries. For clarity, the value and meanings for MatrixCoefficients are adopted from Table 4 of [ITU-H.273].
restrictions:
See Table 12.
stream copy:
True (Section 8)
Table 12: MatrixCoefficients Values
value label
0 Identity
1 ITU-R BT.709
2 unspecified
3 reserved
4 US FCC 73.682
5 ITU-R BT.470BG
6 SMPTE 170M
7 SMPTE 240M
8 YCoCg
9 BT2020 Non-constant Luminance
10 BT2020 Constant Luminance
11 SMPTE ST 2085
12 Chroma-derived Non-constant Luminance
13 Chroma-derived Constant Luminance
14 ITU-R BT.2100-0
5.1.4.1.28.18. BitsPerChannel Element
id / type / default:
0x55B2 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\Colour\BitsPerChannel
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Number of decoded bits per channel. A value of 0 indicates that the BitsPerChannel is unspecified.
stream copy:
True (Section 8)
5.1.4.1.28.19. ChromaSubsamplingHorz Element
id / type:
0x55B3 / uinteger
path:
\Segment\Tracks\TrackEntry\Video\Colour\ChromaSubsamplingHorz
maxOccurs:
1
minver:
4
definition:
The number of pixels to remove in the Cr and Cb channels for every pixel not removed horizontally. Example: For video with 4:2:0 chroma subsampling, the ChromaSubsamplingHorz SHOULD be set to 1.
stream copy:
True (Section 8)
5.1.4.1.28.20. ChromaSubsamplingVert Element
id / type:
0x55B4 / uinteger
path:
\Segment\Tracks\TrackEntry\Video\Colour\ChromaSubsamplingVert
maxOccurs:
1
minver:
4
definition:
The number of pixels to remove in the Cr and Cb channels for every pixel not removed vertically. Example: For video with 4:2:0 chroma subsampling, the ChromaSubsamplingVert SHOULD be set to 1.
stream copy:
True (Section 8)
5.1.4.1.28.21. CbSubsamplingHorz Element
id / type:
0x55B5 / uinteger
path:
\Segment\Tracks\TrackEntry\Video\Colour\CbSubsamplingHorz
maxOccurs:
1
minver:
4
definition:
The number of pixels to remove in the Cb channel for every pixel not removed horizontally. This is additive with ChromaSubsamplingHorz. Example: For video with 4:2:1 chroma subsampling, the ChromaSubsamplingHorz SHOULD be set to 1, and CbSubsamplingHorz SHOULD be set to 1.
stream copy:
True (Section 8)
5.1.4.1.28.22. CbSubsamplingVert Element
id / type:
0x55B6 / uinteger
path:
\Segment\Tracks\TrackEntry\Video\Colour\CbSubsamplingVert
maxOccurs:
1
minver:
4
definition:
The number of pixels to remove in the Cb channel for every pixel not removed vertically. This is additive with ChromaSubsamplingVert.
stream copy:
True (Section 8)
5.1.4.1.28.23. ChromaSitingHorz Element
id / type / default:
0x55B7 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\Colour\ChromaSitingHorz
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
How chroma is subsampled horizontally.
defined values:
See Table 13. Additional values can be registered in the "Matroska Horizontal Chroma Sitings" registry defined in Section 27.10.
stream copy:
True (Section 8)
Table 13: ChromaSitingHorz Values
value label
0 unspecified
1 left collocated
2 half
5.1.4.1.28.24. ChromaSitingVert Element
id / type / default:
0x55B8 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\Colour\ChromaSitingVert
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
How chroma is subsampled vertically.
defined values:
See Table 14. Additional values can be registered in the "Matroska Vertical Chroma Sitings" registry defined in Section 27.11.
stream copy:
True (Section 8)
Table 14: ChromaSitingVert Values
value label
0 unspecified
1 top collocated
2 half
5.1.4.1.28.25. Color Range Element
id / type / default:
0x55B9 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\Colour\Range
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Clipping of the color ranges.
defined values:
See Table 15. Additional values can be registered in the "Matroska Color Ranges" registry defined in Section 27.12.
stream copy:
True (Section 8)
Table 15: Range Values
value label
0 unspecified
1 broadcast range
2 full range (no clipping)
3 defined by MatrixCoefficients / TransferCharacteristics
5.1.4.1.28.26. TransferCharacteristics Element
id / type / default:
0x55BA / uinteger / 2
path:
\Segment\Tracks\TrackEntry\Video\Colour\TransferCharacteristics
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
The transfer characteristics of the video. For clarity, the value and meanings for TransferCharacteristics are adopted from Table 3 of [ITU-H.273].
restrictions:
See Table 16.
stream copy:
True (Section 8)
Table 16: TransferCharacteristics Values
value label
0 reserved
1 ITU-R BT.709
2 unspecified
3 reserved2
4 Gamma 2.2 curve - BT.470M
5 Gamma 2.8 curve - BT.470BG
6 SMPTE 170M
7 SMPTE 240M
8 Linear
9 Log
10 Log Sqrt
11 IEC 61966-2-4
12 ITU-R BT.1361 Extended Colour Gamut
13 IEC 61966-2-1
14 ITU-R BT.2020 10 bit
15 ITU-R BT.2020 12 bit
16 ITU-R BT.2100 Perceptual Quantization
17 SMPTE ST 428-1
18 ARIB STD-B67 (HLG)
5.1.4.1.28.27. Primaries Element
id / type / default:
0x55BB / uinteger / 2
path:
\Segment\Tracks\TrackEntry\Video\Colour\Primaries
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
The color primaries of the video. For clarity, the value and meanings for Primaries are adopted from Table 2 of [ITU-H.273].
restrictions:
See Table 17.
stream copy:
True (Section 8)
Table 17: Primaries Values
value label
0 reserved
1 ITU-R BT.709
2 unspecified
3 reserved2
4 ITU-R BT.470M
5 ITU-R BT.470BG - BT.601 625
6 ITU-R BT.601 525 - SMPTE 170M
7 SMPTE 240M
8 FILM
9 ITU-R BT.2020
10 SMPTE ST 428-1
11 SMPTE RP 432-2
12 SMPTE EG 432-2
22 EBU Tech. 3213-E - JEDEC P22 phosphors
5.1.4.1.28.28. MaxCLL Element
id / type:
0x55BC / uinteger
path:
\Segment\Tracks\TrackEntry\Video\Colour\MaxCLL
maxOccurs:
1
minver:
4
definition:
Maximum brightness of a single pixel (Maximum Content Light Level) in candelas per square meter (cd/m2).
stream copy:
True (Section 8)
5.1.4.1.28.29. MaxFALL Element
id / type:
0x55BD / uinteger
path:
\Segment\Tracks\TrackEntry\Video\Colour\MaxFALL
maxOccurs:
1
minver:
4
definition:
Maximum brightness of a single full frame (Maximum Frame-Average Light Level) in candelas per square meter (cd/m2).
stream copy:
True (Section 8)
5.1.4.1.28.30. MasteringMetadata Element
id / type:
0x55D0 / master
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata
maxOccurs:
1
minver:
4
definition:
SMPTE 2086 mastering data.
stream copy:
True (Section 8)
5.1.4.1.28.31. PrimaryRChromaticityX Element
id / type:
0x55D1 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\PrimaryRChromaticityX
maxOccurs:
1
minver:
4
definition:
Red X chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.32. PrimaryRChromaticityY Element
id / type:
0x55D2 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\PrimaryRChromaticityY
maxOccurs:
1
minver:
4
definition:
Red Y chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.33. PrimaryGChromaticityX Element
id / type:
0x55D3 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\PrimaryGChromaticityX
maxOccurs:
1
minver:
4
definition:
Green X chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.34. PrimaryGChromaticityY Element
id / type:
0x55D4 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\PrimaryGChromaticityY
maxOccurs:
1
minver:
4
definition:
Green Y chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.35. PrimaryBChromaticityX Element
id / type:
0x55D5 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\PrimaryBChromaticityX
maxOccurs:
1
minver:
4
definition:
Blue X chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.36. PrimaryBChromaticityY Element
id / type:
0x55D6 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\PrimaryBChromaticityY
maxOccurs:
1
minver:
4
definition:
Blue Y chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.37. WhitePointChromaticityX Element
id / type:
0x55D7 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\WhitePointChromaticityX
maxOccurs:
1
minver:
4
definition:
White X chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.38. WhitePointChromaticityY Element
id / type:
0x55D8 / float
range:
0x0p+0-0x1p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\WhitePointChromaticityY
maxOccurs:
1
minver:
4
definition:
White Y chromaticity coordinate, as defined by [CIE-1931].
stream copy:
True (Section 8)
5.1.4.1.28.39. LuminanceMax Element
id / type:
0x55D9 / float
range:
>= 0x0p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\LuminanceMax
maxOccurs:
1
minver:
4
definition:
Maximum luminance. Represented in candelas per square meter (cd/m2).
stream copy:
True (Section 8)
5.1.4.1.28.40. LuminanceMin Element
id / type:
0x55DA / float
range:
>= 0x0p+0
path:
\Segment\Tracks\TrackEntry\Video\Colour\MasteringMetadata\LuminanceMin
maxOccurs:
1
minver:
4
definition:
Minimum luminance. Represented in candelas per square meter (cd/m2).
stream copy:
True (Section 8)
5.1.4.1.28.41. Projection Element
id / type:
0x7670 / master
path:
\Segment\Tracks\TrackEntry\Video\Projection
maxOccurs:
1
minver:
4
definition:
Describes the video projection details. Used to render spherical or VR videos or to flip videos horizontally or vertically.
stream copy:
True (Section 8)
5.1.4.1.28.42. ProjectionType Element
id / type / default:
0x7671 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\Video\Projection\ProjectionType
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Describes the projection used for this video track.
defined values:
See Table 18. Additional values can be registered in the "Matroska Projection Types" registry defined in Section 27.15.
stream copy:
True (Section 8)
Table 18: ProjectionType Values
value label
0 rectangular
1 equirectangular
2 cubemap
3 mesh
5.1.4.1.28.43. ProjectionPrivate Element
id / type:
0x7672 / binary
path:
\Segment\Tracks\TrackEntry\Video\Projection\ProjectionPrivate
maxOccurs:
1
minver:
4
definition:
Private data that only applies to a specific projection.
  • If ProjectionType equals 0 (rectangular), then this element MUST NOT be present.
  • If ProjectionType equals 1 (equirectangular), then this element MUST be present and contain the same binary data that would be stored inside an ISOBMFF Equirectangular Projection Box ("equi").
  • If ProjectionType equals 2 (cubemap), then this element MUST be present and contain the same binary data that would be stored inside an ISOBMFF Cubemap Projection Box ("cbmp").
  • If ProjectionType equals 3 (mesh), then this element MUST be present and contain the same binary data that would be stored inside an ISOBMFF Mesh Projection Box ("mshp").
usage notes:
ISOBMFF box size and FourCC fields are not included in the binary data, but the FullBox version and flag fields are. This is to avoid redundant framing information while preserving versioning and semantics between the two container formats.
stream copy:
True (Section 8)
5.1.4.1.28.44. ProjectionPoseYaw Element
id / type / default:
0x7673 / float / 0x0p+0
range:
>= -0xB4p+0, <= 0xB4p+0
path:
\Segment\Tracks\TrackEntry\Video\Projection\ProjectionPoseYaw
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Specifies a yaw rotation to the projection.

Value represents a clockwise rotation, in degrees, around the up vector. This rotation must be applied before any ProjectionPosePitch or ProjectionPoseRoll rotations. The value of this element MUST be in the -180 to 180 degree range, both inclusive.

Setting ProjectionPoseYaw to 180 or -180 degrees with ProjectionPoseRoll and ProjectionPosePitch set to 0 degrees flips the image horizontally.

stream copy:
True (Section 8)
5.1.4.1.28.45. ProjectionPosePitch Element
id / type / default:
0x7674 / float / 0x0p+0
range:
>= -0x5Ap+0, <= 0x5Ap+0
path:
\Segment\Tracks\TrackEntry\Video\Projection\ProjectionPosePitch
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Specifies a pitch rotation to the projection.

Value represents a counter-clockwise rotation, in degrees, around the right vector. This rotation must be applied after the ProjectionPoseYaw rotation and before the ProjectionPoseRoll rotation. The value of this element MUST be in the -90 to 90 degree range, both inclusive.

stream copy:
True (Section 8)
5.1.4.1.28.46. ProjectionPoseRoll Element
id / type / default:
0x7675 / float / 0x0p+0
range:
>= -0xB4p+0, <= 0xB4p+0
path:
\Segment\Tracks\TrackEntry\Video\Projection\ProjectionPoseRoll
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
Specifies a roll rotation to the projection.

Value represents a counter-clockwise rotation, in degrees, around the forward vector. This rotation must be applied after the ProjectionPoseYaw and ProjectionPosePitch rotations. The value of this element MUST be in the -180 to 180 degree range, both inclusive.

Setting ProjectionPoseRoll to 180 or -180 degrees and ProjectionPoseYaw to 180 or -180 degrees with ProjectionPosePitch set to 0 degrees flips the image vertically.

Setting ProjectionPoseRoll to 180 or -180 degrees with ProjectionPoseYaw and ProjectionPosePitch set to 0 degrees flips the image horizontally and vertically.

stream copy:
True (Section 8)
5.1.4.1.29. Audio Element
id / type:
0xE1 / master
path:
\Segment\Tracks\TrackEntry\Audio
maxOccurs:
1
definition:
Audio settings.
5.1.4.1.29.1. SamplingFrequency Element
id / type / default:
0xB5 / float / 0x1.f4p+12
range:
> 0x0p+0
path:
\Segment\Tracks\TrackEntry\Audio\SamplingFrequency
minOccurs / maxOccurs:
1 / 1
definition:
Sampling frequency in Hz.
stream copy:
True (Section 8)
5.1.4.1.29.2. OutputSamplingFrequency Element
id / type:
0x78B5 / float
range:
> 0x0p+0
path:
\Segment\Tracks\TrackEntry\Audio\OutputSamplingFrequency
maxOccurs:
1
definition:
Real output sampling frequency in Hz that is used for Spectral Band Replication (SBR) techniques.
notes:
See Table 19.
Table 19: OutputSamplingFrequency Implementation Notes
attribute note
default The default value for OutputSamplingFrequency of the same TrackEntry is equal to the SamplingFrequency.
5.1.4.1.29.3. Channels Element
id / type / default:
0x9F / uinteger / 1
range:
not 0
path:
\Segment\Tracks\TrackEntry\Audio\Channels
minOccurs / maxOccurs:
1 / 1
definition:
Numbers of channels in the track.
stream copy:
True (Section 8)
5.1.4.1.29.4. BitDepth Element
id / type:
0x6264 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\Audio\BitDepth
maxOccurs:
1
definition:
Bits per sample, mostly used for PCM.
stream copy:
True (Section 8)
5.1.4.1.30. TrackOperation Element
id / type:
0xE2 / master
path:
\Segment\Tracks\TrackEntry\TrackOperation
maxOccurs:
1
minver:
3
definition:
Operation that needs to be applied on tracks to create this virtual track. For more details, see Section 18.8.
stream copy:
True (Section 8)
5.1.4.1.30.1. TrackCombinePlanes Element
id / type:
0xE3 / master
path:
\Segment\Tracks\TrackEntry\TrackOperation\TrackCombinePlanes
maxOccurs:
1
minver:
3
definition:
Contains the list of all video plane tracks that need to be combined to create this 3D track.
stream copy:
True (Section 8)
5.1.4.1.30.2. TrackPlane Element
id / type:
0xE4 / master
path:
\Segment\Tracks\TrackEntry\TrackOperation\TrackCombinePlanes\TrackPlane
minOccurs:
1
minver:
3
definition:
Contains a video plane track that needs to be combined to create this 3D track.
stream copy:
True (Section 8)
5.1.4.1.30.3. TrackPlaneUID Element
id / type:
0xE5 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\TrackOperation\TrackCombinePlanes\TrackPlane\TrackPlaneUID
minOccurs / maxOccurs:
1 / 1
minver:
3
definition:
The TrackUID number of the track representing the plane.
stream copy:
True (Section 8)
5.1.4.1.30.4. TrackPlaneType Element
id / type:
0xE6 / uinteger
path:
\Segment\Tracks\TrackEntry\TrackOperation\TrackCombinePlanes\TrackPlane\TrackPlaneType
minOccurs / maxOccurs:
1 / 1
minver:
3
definition:
The kind of plane this track corresponds to.
defined values:
See Table 20. Additional values can be registered in the "Matroska Track Plane Types" registry defined in Section 27.17.
stream copy:
True (Section 8)
Table 20: TrackPlaneType Values
value label
0 left eye
1 right eye
2 background
5.1.4.1.30.5. TrackJoinBlocks Element
id / type:
0xE9 / master
path:
\Segment\Tracks\TrackEntry\TrackOperation\TrackJoinBlocks
maxOccurs:
1
minver:
3
definition:
Contains the list of all tracks whose Blocks need to be combined to create this virtual track.
stream copy:
True (Section 8)
5.1.4.1.30.6. TrackJoinUID Element
id / type:
0xED / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\TrackOperation\TrackJoinBlocks\TrackJoinUID
minOccurs:
1
minver:
3
definition:
The TrackUID number of a track whose blocks are used to create this virtual track.
stream copy:
True (Section 8)
5.1.4.1.31. ContentEncodings Element
id / type:
0x6D80 / master
path:
\Segment\Tracks\TrackEntry\ContentEncodings
maxOccurs:
1
definition:
Settings for several content encoding mechanisms like compression or encryption.
stream copy:
True (Section 8)
5.1.4.1.31.1. ContentEncoding Element
id / type:
0x6240 / master
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding
minOccurs:
1
definition:
Settings for one content encoding like compression or encryption.
stream copy:
True (Section 8)
5.1.4.1.31.2. ContentEncodingOrder Element
id / type / default:
0x5031 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncodingOrder
minOccurs / maxOccurs:
1 / 1
definition:
Defines the order to apply each ContentEncoding of the ContentEncodings. The decoder/demuxer MUST start with the ContentEncoding with the highest ContentEncodingOrder and work its way down to the ContentEncoding with the lowest ContentEncodingOrder. This value MUST be unique for each ContentEncoding found in the ContentEncodings of this TrackEntry.
stream copy:
True (Section 8)
5.1.4.1.31.3. ContentEncodingScope Element
id / type / default:
0x5032 / uinteger / 1
range:
not 0
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncodingScope
minOccurs / maxOccurs:
1 / 1
definition:
A bit field that describes which elements have been modified in this way. Values (big-endian) can be OR'ed.
defined values:
See Table 21. Additional values can be registered in the "Matroska Content Encoding Scopes" registry defined in Section 27.5.
stream copy:
True (Section 8)
Table 21: ContentEncodingScope Values
value label definition
0x1 Block All frame contents, excluding lacing data.
0x2 Private The track's CodecPrivate data.
0x4 Next The next ContentEncoding (next ContentEncodingOrder; the data inside ContentCompression and/or ContentEncryption). This value SHOULD NOT be used, as it's not supported by players.
5.1.4.1.31.4. ContentEncodingType Element
id / type / default:
0x5033 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncodingType
minOccurs / maxOccurs:
1 / 1
definition:
A value describing the kind of transformation that is applied.
defined values:
See Table 22. Additional values can be registered in the "Matroska Content Encoding Types" registry defined in Section 27.6.
stream copy:
True (Section 8)
Table 22: ContentEncodingType Values
value label
0 Compression
1 Encryption
5.1.4.1.31.5. ContentCompression Element
id / type:
0x5034 / master
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentCompression
maxOccurs:
1
definition:
Settings describing the compression used. This element MUST be present if the value of ContentEncodingType is 0 and absent otherwise. Each block MUST be decompressable, even if no previous block is available in order to not prevent seeking.
stream copy:
True (Section 8)
5.1.4.1.31.6. ContentCompAlgo Element
id / type / default:
0x4254 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentCompression\ContentCompAlgo
minOccurs / maxOccurs:
1 / 1
definition:
The compression algorithm used.
defined values:
See Table 23. Additional values can be registered in the "Matroska Compression Algorithms" registry defined in Section 27.2.
usage notes:
Compression method "1" (bzlib) and "2" (lzo1x) lack proper documentation on the format, which limits implementation possibilities. Due to licensing conflicts on commonly available libraries' compression methods, "2" (lzo1x) does not offer widespread interoperability. A Matroska Writer SHOULD NOT use these compression methods by default. A Matroska Reader MAY support methods "1" and "2" and SHOULD support other methods.
stream copy:
True (Section 8)
Table 23: ContentCompAlgo Values
value label definition
0 zlib zlib compression [RFC1950].
1 bzlib bzip2 compression [BZIP2] SHOULD NOT be used; see usage notes.
2 lzo1x Lempel-Ziv-Oberhumer compression [LZO] SHOULD NOT be used; see usage notes.
3 Header Stripping Octets in ContentCompSettings (Section 5.1.4.1.31.7) have been stripped from each frame.
5.1.4.1.31.7. ContentCompSettings Element
id / type:
0x4255 / binary
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentCompression\ContentCompSettings
maxOccurs:
1
definition:
Settings that might be needed by the decompressor. For Header Stripping (ContentCompAlgo=3), the bytes that were removed from the beginning of each frame of the track.
stream copy:
True (Section 8)
5.1.4.1.31.8. ContentEncryption Element
id / type:
0x5035 / master
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption
maxOccurs:
1
definition:
Settings describing the encryption used. This element MUST be present if the value of ContentEncodingType is 1 (encryption) and MUST be ignored otherwise. A Matroska Player MAY support encryption.
stream copy:
True (Section 8)
5.1.4.1.31.9. ContentEncAlgo Element
id / type / default:
0x47E1 / uinteger / 0
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentEncAlgo
minOccurs / maxOccurs:
1 / 1
definition:
The encryption algorithm used.
defined values:
See Table 24. Additional values can be registered in the "Matroska Encryption Algorithms" registry defined in Section 27.3.
stream copy:
True (Section 8)
Table 24: ContentEncAlgo Values
value label definition
0 Not encrypted The data are not encrypted.
1 DES Data Encryption Standard (DES) [FIPS46-3]. This value SHOULD be avoided.
2 3DES Triple Data Encryption Algorithm [SP800-67]. This value SHOULD be avoided.
3 Twofish Twofish Encryption Algorithm [Twofish].
4 Blowfish Blowfish Encryption Algorithm [Blowfish]. This value SHOULD be avoided.
5 AES Advanced Encryption Standard (AES) [FIPS197].
5.1.4.1.31.10. ContentEncKeyID Element
id / type:
0x47E2 / binary
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentEncKeyID
maxOccurs:
1
definition:
For public key algorithms, the ID of the public key that the data was encrypted with.
stream copy:
True (Section 8)
5.1.4.1.31.11. ContentEncAESSettings Element
id / type:
0x47E7 / master
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentEncAESSettings
maxOccurs:
1
minver:
4
definition:
Settings describing the encryption algorithm used.
notes:
See Table 25.
stream copy:
True (Section 8)
Table 25: ContentEncAESSettings Implementation Notes
attribute note
maxOccurs ContentEncAESSettings MUST NOT be set (maxOccurs=0) if ContentEncAlgo is not AES (5).
5.1.4.1.31.12. AESSettingsCipherMode Element
id / type:
0x47E8 / uinteger
range:
not 0
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentEncAESSettings\AESSettingsCipherMode
minOccurs / maxOccurs:
1 / 1
minver:
4
definition:
The AES cipher mode used in the encryption.
defined values:
See Table 26. Additional values can be registered in the "Matroska AES Cipher Modes" registry defined in Section 27.4.
notes:
See Table 27.
stream copy:
True (Section 8)
Table 26: AESSettingsCipherMode Values
value label definition
1 AES-CTR Counter [SP800-38A]
2 AES-CBC Cipher Block Chaining [SP800-38A]
Table 27: AESSettingsCipherMode Implementation Notes
attribute note
maxOccurs AESSettingsCipherMode MUST NOT be set (maxOccurs=0) if ContentEncAlgo is not AES (5).

5.1.5. Cues Element

id / type:
0x1C53BB6B / master
path:
\Segment\Cues
minOccurs / maxOccurs:
See Table 28 / 1
definition:
A Top-Level Element to speed seeking access. All entries are local to the Segment.
notes:
See Table 28.
Table 28: Cues Implementation Notes
attribute note
minOccurs This element SHOULD be set when the Segment is not transmitted as a live stream; see Section 23.2.
5.1.5.1. CuePoint Element
id / type:
0xBB / master
path:
\Segment\Cues\CuePoint
minOccurs:
1
definition:
Contains all information relative to a seek point in the Segment.
5.1.5.1.1. CueTime Element
id / type:
0xB3 / uinteger
path:
\Segment\Cues\CuePoint\CueTime
minOccurs / maxOccurs:
1 / 1
definition:
Absolute timestamp of the seek point, expressed in Segment Ticks, which are based on TimestampScale; see Section 11.1.
5.1.5.1.2. CueTrackPositions Element
id / type:
0xB7 / master
path:
\Segment\Cues\CuePoint\CueTrackPositions
minOccurs:
1
definition:
Contains positions for different tracks corresponding to the timestamp.
5.1.5.1.2.1. CueTrack Element
id / type:
0xF7 / uinteger
range:
not 0
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueTrack
minOccurs / maxOccurs:
1 / 1
definition:
The track for which a position is given.
5.1.5.1.2.2. CueClusterPosition Element
id / type:
0xF1 / uinteger
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueClusterPosition
minOccurs / maxOccurs:
1 / 1
definition:
The Segment Position (Section 16) of the Cluster containing the associated Block.
5.1.5.1.2.3. CueRelativePosition Element
id / type:
0xF0 / uinteger
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueRelativePosition
maxOccurs:
1
minver:
4
definition:
The relative position inside the Cluster of the referenced SimpleBlock or BlockGroup with 0 being the first possible position for an element inside that Cluster.
5.1.5.1.2.4. CueDuration Element
id / type:
0xB2 / uinteger
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueDuration
maxOccurs:
1
minver:
4
definition:
The duration of the block, expressed in Segment Ticks, which are based on TimestampScale; see Section 11.1. If missing, the track's DefaultDuration does not apply and no duration information is available in terms of the cues.
5.1.5.1.2.5. CueBlockNumber Element
id / type:
0x5378 / uinteger
range:
not 0
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueBlockNumber
maxOccurs:
1
definition:
Number of the Block in the specified Cluster.
5.1.5.1.2.6. CueCodecState Element
id / type / default:
0xEA / uinteger / 0
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueCodecState
minOccurs / maxOccurs:
1 / 1
minver:
2
definition:
The Segment Position (Section 16) of the Codec State corresponding to this Cues element. 0 means that the data is taken from the initial TrackEntry.
5.1.5.1.2.7. CueReference Element
id / type:
0xDB / master
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueReference
minver:
2
definition:
The Clusters containing the referenced Blocks.
5.1.5.1.2.8. CueRefTime Element
id / type:
0x96 / uinteger
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueReference\CueRefTime
minOccurs / maxOccurs:
1 / 1
minver:
2
definition:
Timestamp of the referenced Block, expressed in Segment Ticks which is based on TimestampScale; see Section 11.1.

5.1.6. Attachments Element

id / type:
0x1941A469 / master
path:
\Segment\Attachments
maxOccurs:
1
definition:
Contains attached files.
5.1.6.1. AttachedFile Element
id / type:
0x61A7 / master
path:
\Segment\Attachments\AttachedFile
minOccurs:
1
definition:
An attached file.
5.1.6.1.1. FileDescription Element
id / type:
0x467E / utf-8
path:
\Segment\Attachments\AttachedFile\FileDescription
maxOccurs:
1
definition:
A human-friendly name for the attached file.
5.1.6.1.2. FileName Element
id / type:
0x466E / utf-8
path:
\Segment\Attachments\AttachedFile\FileName
minOccurs / maxOccurs:
1 / 1
definition:
Filename of the attached file.
5.1.6.1.3. FileMediaType Element
id / type:
0x4660 / string
path:
\Segment\Attachments\AttachedFile\FileMediaType
minOccurs / maxOccurs:
1 / 1
definition:
Media type of the file following the format described in [RFC6838].
stream copy:
True (Section 8)
5.1.6.1.4. FileData Element
id / type:
0x465C / binary
path:
\Segment\Attachments\AttachedFile\FileData
minOccurs / maxOccurs:
1 / 1
definition:
The data of the file.
stream copy:
True (Section 8)
5.1.6.1.5. FileUID Element
id / type:
0x46AE / uinteger
range:
not 0
path:
\Segment\Attachments\AttachedFile\FileUID
minOccurs / maxOccurs:
1 / 1
definition:
UID representing the file, as random as possible.
stream copy:
True (Section 8)

5.1.7. Chapters Element

id / type:
0x1043A770 / master
path:
\Segment\Chapters
maxOccurs:
1
recurring:
True
definition:
A system to define basic menus and partition data. For more detailed information, see Section 20.
5.1.7.1. EditionEntry Element
id / type:
0x45B9 / master
path:
\Segment\Chapters\EditionEntry
minOccurs:
1
definition:
Contains all information about a Segment edition.
5.1.7.1.1. EditionUID Element
id / type:
0x45BC / uinteger
range:
not 0
path:
\Segment\Chapters\EditionEntry\EditionUID
maxOccurs:
1
definition:
A UID that identifies the edition. It's useful for tagging an edition.
stream copy:
True (Section 8)
5.1.7.1.2. EditionFlagDefault Element
id / type / default:
0x45DB / uinteger / 0
range:
0-1
path:
\Segment\Chapters\EditionEntry\EditionFlagDefault
minOccurs / maxOccurs:
1 / 1
definition:
Set to 1 if the edition SHOULD be used as the default one.
5.1.7.1.3. EditionFlagOrdered Element
id / type / default:
0x45DD / uinteger / 0
range:
0-1
path:
\Segment\Chapters\EditionEntry\EditionFlagOrdered
minOccurs / maxOccurs:
1 / 1
definition:
Set to 1 if the chapters can be defined multiple times and the order to play them is enforced; see Section 20.1.3.
5.1.7.1.4. ChapterAtom Element
id / type:
0xB6 / master
path:
\Segment\Chapters\EditionEntry\+ChapterAtom
minOccurs:
1
recursive:
True
definition:
Contains the atom information to use as the chapter atom (applies to all tracks).
5.1.7.1.4.1. ChapterUID Element
id / type:
0x73C4 / uinteger
range:
not 0
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterUID
minOccurs / maxOccurs:
1 / 1
definition:
A UID that identifies the Chapter.
stream copy:
True (Section 8)
5.1.7.1.4.2. ChapterStringUID Element
id / type:
0x5654 / utf-8
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterStringUID
maxOccurs:
1
minver:
3
definition:
A unique string ID that identifies the Chapter. For example, it is used as the storage for cue identifier values [WebVTT].
5.1.7.1.4.3. ChapterTimeStart Element
id / type:
0x91 / uinteger
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterTimeStart
minOccurs / maxOccurs:
1 / 1
definition:
Timestamp of the start of Chapter, expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1.
5.1.7.1.4.4. ChapterTimeEnd Element
id / type:
0x92 / uinteger
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterTimeEnd
minOccurs / maxOccurs:
See Table 29 / 1
definition:
Timestamp of the end of Chapter (timestamp excluded), expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1. The value MUST be greater than or equal to the ChapterTimeStart of the same ChapterAtom.
usage notes:
With the ChapterTimeEnd timestamp value being excluded, it MUST take into account the duration of the last frame it includes, especially for the ChapterAtom using the last frames of the Segment.
notes:
See Table 29.
Table 29: ChapterTimeEnd Implementation Notes
attribute note
minOccurs ChapterTimeEnd MUST be set (minOccurs=1) if the Edition is an ordered edition; see Section 20.1.3. If it's a Parent Chapter, see Section 20.2.3.
5.1.7.1.4.5. ChapterFlagHidden Element
id / type / default:
0x98 / uinteger / 0
range:
0-1
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterFlagHidden
minOccurs / maxOccurs:
1 / 1
definition:
Set to 1 if a chapter is hidden. Hidden chapters SHOULD NOT be available to the user interface (but still be available to Control Tracks; see Section 20.2.5 on Chapter flags).
5.1.7.1.4.6. ChapterSegmentUUID Element
id / type:
0x6E67 / binary
length:
16
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterSegmentUUID
minOccurs / maxOccurs:
See Table 30 / 1
definition:
The SegmentUUID of another Segment to play during this chapter.
usage notes:
The value MUST NOT be the SegmentUUID value of the Segment it belongs to.
notes:
See Table 30.
Table 30: ChapterSegmentUUID Implementation Notes
attribute note
minOccurs ChapterSegmentUUID MUST be set (minOccurs=1) if ChapterSegmentEditionUID is used; see Section 17.2 on Medium-Linking Segments.
5.1.7.1.4.7. ChapterSegmentEditionUID Element
id / type:
0x6EBC / uinteger
range:
not 0
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterSegmentEditionUID
maxOccurs:
1
definition:
The EditionUID to play from the Segment linked in ChapterSegmentUUID. If ChapterSegmentEditionUID is undeclared, then no Edition of the Linked Segment is used; see Section 17.2 on Medium-Linking Segments.
5.1.7.1.4.8. ChapterPhysicalEquiv Element
id / type:
0x63C3 / uinteger
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterPhysicalEquiv
maxOccurs:
1
definition:
Specifies the physical equivalent of this ChapterAtom, e.g., "DVD" (60) or "SIDE" (50); see Section 20.4 for a complete list of values.
5.1.7.1.4.9. ChapterDisplay Element
id / type:
0x80 / master
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterDisplay
definition:
Contains all possible strings to use for the chapter display.
5.1.7.1.4.10. ChapString Element
id / type:
0x85 / utf-8
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterDisplay\ChapString
minOccurs / maxOccurs:
1 / 1
definition:
Contains the string to use as the chapter atom.
5.1.7.1.4.11. ChapLanguage Element
id / type / default:
0x437C / string / eng
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterDisplay\ChapLanguage
minOccurs:
1
definition:
A language corresponding to the string, in the Matroska languages form; see Section 12 on language codes. This element MUST be ignored if a ChapLanguageBCP47 element is used within the same ChapterDisplay element.
5.1.7.1.4.12. ChapLanguageBCP47 Element
id / type:
0x437D / string
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterDisplay\ChapLanguageBCP47
minver:
4
definition:
A language corresponding to the ChapString, in the form defined in [RFC5646]; see Section 12 on language codes. If a ChapLanguageBCP47 element is used, then any ChapLanguage and ChapCountry elements used in the same ChapterDisplay MUST be ignored.
5.1.7.1.4.13. ChapCountry Element
id / type:
0x437E / string
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapterDisplay\ChapCountry
definition:
A country corresponding to the string, in the Matroska countries form; see Section 13 on country codes. This element MUST be ignored if a ChapLanguageBCP47 element is used within the same ChapterDisplay element.
5.1.7.1.4.14. ChapProcess Element
id / type:
0x6944 / master
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapProcess
definition:
Contains all the commands associated with the Atom.
5.1.7.1.4.15. ChapProcessCodecID Element
id / type / default:
0x6955 / uinteger / 0
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapProcess\ChapProcessCodecID
minOccurs / maxOccurs:
1 / 1
definition:
Contains the type of the codec used for processing.
defined values:
See Table 31. Additional values can be registered in the "Matroska Chapter Codec IDs" registry defined in Section 27.14.
Table 31: ChapProcessCodecID Values
value label definition
0 Matroska Script Chapter commands using the Matroska Script codec.
1 DVD-menu Chapter commands using the DVD-like codec.
5.1.7.1.4.16. ChapProcessPrivate Element
id / type:
0x450D / binary
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapProcess\ChapProcessPrivate
maxOccurs:
1
definition:
Optional data attached to the ChapProcessCodecID information. For ChapProcessCodecID = 1, it is the "DVD level" equivalent; see Section 20.3 on DVD menus.
5.1.7.1.4.17. ChapProcessCommand Element
id / type:
0x6911 / master
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapProcess\ChapProcessCommand
definition:
Contains all the commands associated with the Atom.
5.1.7.1.4.18. ChapProcessTime Element
id / type:
0x6922 / uinteger
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapProcess\ChapProcessCommand\ChapProcessTime
minOccurs / maxOccurs:
1 / 1
definition:
Defines when the process command SHOULD be handled.
restrictions:
See Table 32.
Table 32: ChapProcessTime Values
value label
0 during the whole chapter
1 before starting playback
2 after playback of the chapter
5.1.7.1.4.19. ChapProcessData Element
id / type:
0x6933 / binary
path:
\Segment\Chapters\EditionEntry\+ChapterAtom\ChapProcess\ChapProcessCommand\ChapProcessData
minOccurs / maxOccurs:
1 / 1
definition:
Contains the command information. The data SHOULD be interpreted depending on the ChapProcessCodecID value. For ChapProcessCodecID = 1, the data correspond to the binary DVD cell pre/post commands; see Section 20.3 on DVD menus.

5.1.8. Tags Element

id / type:
0x1254C367 / master
path:
\Segment\Tags
definition:
Element containing metadata describing Tracks, Editions, Chapters, Attachments, or the Segment as a whole. A list of valid tags can be found in [I-D.ietf-cellar-tags].
5.1.8.1. Tag Element
id / type:
0x7373 / master
path:
\Segment\Tags\Tag
minOccurs:
1
definition:
A single metadata descriptor.
5.1.8.1.1. Targets Element
id / type:
0x63C0 / master
path:
\Segment\Tags\Tag\Targets
minOccurs / maxOccurs:
1 / 1
definition:
Specifies which other elements the metadata represented by the tag value applies to. If empty or omitted, then the tag value describes everything in the Segment.
5.1.8.1.1.1. TargetTypeValue Element
id / type / default:
0x68CA / uinteger / 50
range:
not 0
path:
\Segment\Tags\Tag\Targets\TargetTypeValue
minOccurs / maxOccurs:
1 / 1
definition:
A number to indicate the logical level of the target.
defined values:
See Table 33. Additional values can be registered in the "Matroska Tags Target Types" registry defined in Section 27.13.
usage notes:
The TargetTypeValue values are meant to be compared. Higher values MUST correspond to a logical level that contains the lower logical level TargetTypeValue values.
Table 33: TargetTypeValue Values
value label definition
70 COLLECTION The highest hierarchical level that tags can describe.
60 EDITION / ISSUE / VOLUME / OPUS / SEASON / SEQUEL A list of lower levels grouped together.
50 ALBUM / OPERA / CONCERT / MOVIE / EPISODE The most common grouping level of music and video (e.g., an episode for TV series).
40 PART / SESSION When an album or episode has different logical parts.
30 TRACK / SONG / CHAPTER The common parts of an album or movie.
20 SUBTRACK / MOVEMENT / SCENE Corresponds to parts of a track for audio, such as a movement or scene in a movie.
10 SHOT The lowest hierarchy found in music or movies.
5.1.8.1.1.2. TargetType Element
id / type:
0x63CA / string
path:
\Segment\Tags\Tag\Targets\TargetType
maxOccurs:
1
definition:
An informational string that can be used to display the logical level of the target, such as "ALBUM", "TRACK", "MOVIE", "CHAPTER", etc.
restrictions:
See Table 34.
Table 34: TargetType Values
value label
COLLECTION TargetTypeValue 70
EDITION TargetTypeValue 60
ISSUE TargetTypeValue 60
VOLUME TargetTypeValue 60
OPUS TargetTypeValue 60
SEASON TargetTypeValue 60
SEQUEL TargetTypeValue 60
ALBUM TargetTypeValue 50
OPERA TargetTypeValue 50
CONCERT TargetTypeValue 50
MOVIE TargetTypeValue 50
EPISODE TargetTypeValue 50
PART TargetTypeValue 40
SESSION TargetTypeValue 40
TRACK TargetTypeValue 30
SONG TargetTypeValue 30
CHAPTER TargetTypeValue 30
SUBTRACK TargetTypeValue 20
MOVEMENT TargetTypeValue 20
SCENE TargetTypeValue 20
SHOT TargetTypeValue 10
5.1.8.1.1.3. TagTrackUID Element
id / type / default:
0x63C5 / uinteger / 0
path:
\Segment\Tags\Tag\Targets\TagTrackUID
definition:
A UID that identifies the Track(s) that the tags belong to.
usage notes:
If the value is 0 at this level, the tags apply to all tracks in the Segment. If set to any other value, it MUST match the TrackUID value of a track found in this Segment.
5.1.8.1.1.4. TagEditionUID Element
id / type / default:
0x63C9 / uinteger / 0
path:
\Segment\Tags\Tag\Targets\TagEditionUID
definition:
A UID that identifies the EditionEntry(s) that the tags belong to.
usage notes:
If the value is 0 at this level, the tags apply to all editions in the Segment. If set to any other value, it MUST match the EditionUID value of an edition found in this Segment.
5.1.8.1.1.5. TagChapterUID Element
id / type / default:
0x63C4 / uinteger / 0
path:
\Segment\Tags\Tag\Targets\TagChapterUID
definition:
A UID that identifies the Chapter(s) that the tags belong to.
usage notes:
If the value is 0 at this level, the tags apply to all chapters in the Segment. If set to any other value, it MUST match the ChapterUID value of a chapter found in this Segment.
5.1.8.1.1.6. TagAttachmentUID Element
id / type / default:
0x63C6 / uinteger / 0
path:
\Segment\Tags\Tag\Targets\TagAttachmentUID
definition:
A UID that identifies the Attachment(s) that the tags belong to.
usage notes:
If the value is 0 at this level, the tags apply to all the attachments in the Segment. If set to any other value, it MUST match the FileUID value of an attachment found in this Segment.
5.1.8.1.2. SimpleTag Element
id / type:
0x67C8 / master
path:
\Segment\Tags\Tag\+SimpleTag
minOccurs:
1
recursive:
True
definition:
Contains general information about the target.
5.1.8.1.2.1. TagName Element
id / type:
0x45A3 / utf-8
path:
\Segment\Tags\Tag\+SimpleTag\TagName
minOccurs / maxOccurs:
1 / 1
definition:
The name of the tag value that is going to be stored.
5.1.8.1.2.2. TagLanguage Element
id / type / default:
0x447A / string / und
path:
\Segment\Tags\Tag\+SimpleTag\TagLanguage
minOccurs / maxOccurs:
1 / 1
definition:
Specifies the language of the specified tag in the Matroska languages form; see Section 12 on language codes. This element MUST be ignored if the TagLanguageBCP47 element is used within the same SimpleTag element.
5.1.8.1.2.3. TagLanguageBCP47 Element
id / type:
0x447B / string
path:
\Segment\Tags\Tag\+SimpleTag\TagLanguageBCP47
maxOccurs:
1
minver:
4
definition:
The language used in the TagString, in the form defined in [RFC5646]; see Section 12 on language codes. If this element is used, then any TagLanguage elements used in the same SimpleTag MUST be ignored.
5.1.8.1.2.4. TagDefault Element
id / type / default:
0x4484 / uinteger / 1
range:
0-1
path:
\Segment\Tags\Tag\+SimpleTag\TagDefault
minOccurs / maxOccurs:
1 / 1
definition:
A boolean value to indicate if this is the default/original language to use for the given tag.
5.1.8.1.2.5. TagString Element
id / type:
0x4487 / utf-8
path:
\Segment\Tags\Tag\+SimpleTag\TagString
maxOccurs:
1
definition:
The tag value.
5.1.8.1.2.6. TagBinary Element
id / type:
0x4485 / binary
path:
\Segment\Tags\Tag\+SimpleTag\TagBinary
maxOccurs:
1
definition:
The tag value if it is binary. Note that this cannot be used in the same SimpleTag as TagString.

6. Matroska Element Ordering

With the exceptions of the EBML Header and the CRC-32 element, the EBML specification [RFC8794] does not require any particular storage order for elements. However, this specification defines mandates and recommendations for ordering certain elements to facilitate better playback, seeking, and editing efficiency. This section describes and offers rationale for ordering requirements and recommendations for Matroska.

6.1. Top-Level Elements

The Info element is the only REQUIRED Top-Level Element in a Matroska file. To be playable, Matroska MUST also contain at least one Tracks element and Cluster element. The first Info element and the first Tracks element either MUST be stored before the first Cluster element or SHALL both be referenced by a SeekHead element occurring before the first Cluster element.

All Top-Level Elements MUST use a 4-octet EBML Element ID.

When using Medium Linking, chapters are used to reference other Segments to play in a given order (see Section 17.2). A Segment containing these Linked Chapters does not require a Track element or a Cluster element.

It is possible to edit a Matroska file after it has been created. For example, chapters, tags, or attachments can be added. When new Top-Level Elements are added to a Matroska file, the SeekHead element(s) MUST be updated so that the SeekHead element(s) itemizes the identity and position of all Top-Level Elements.

Editing, removing, or adding elements to a Matroska file often requires that some existing elements be voided or extended. Transforming the existing elements into Void elements as padding can be used as a method to avoid moving large amounts of data around.

6.2. CRC-32

As noted by the EBML specification [RFC8794], if a CRC-32 element is used, then the CRC-32 element MUST be the first ordered element within its Parent Element.

In Matroska, all Top-Level Elements of an EBML Document SHOULD include a CRC-32 element as their first Child Element. The Segment element, which is the Root Element, SHOULD NOT have a CRC-32 element.

6.3. SeekHead

If used, the first SeekHead element MUST be the first non-CRC-32 Child element of the Segment element. If a second SeekHead element is used, then the first SeekHead element MUST reference the identity and position of the second SeekHead element.

Additionally, the second SeekHead element MUST only reference Cluster elements and not any other Top-Level Element already contained within the first SeekHead element.

The second SeekHead element MAY be stored in any order relative to the other Top-Level Elements. Whether one or two SeekHead elements are used, the SeekHead element(s) MUST collectively reference the identity and position of all Top-Level Elements except for the first SeekHead element.

6.4. Cues (Index)

The Cues element is RECOMMENDED to optimize seeking access in Matroska. It is programmatically simpler to add the Cues element after all Cluster elements have been written because this does not require a prediction of how much space to reserve before writing the Cluster elements. However, storing the Cues element before the Cluster elements can provide some seeking advantages. If the Cues element is present, then it SHOULD either be stored before the first Cluster element or be referenced by a SeekHead element.

6.5. Info

The first Info element SHOULD occur before the first Tracks element and first Cluster element except when referenced by a SeekHead element.

6.6. Chapters Element

The Chapters element SHOULD be placed before the Cluster element(s). The Chapters element can be used during playback even if the user does not need to seek. It immediately gives the user information about what section is being read and what other sections are available.

In the case of Ordered Chapters, it is RECOMMENDED to evaluate the logical linking before playing. The Chapters element SHOULD be placed before the first Tracks element and after the first Info element.

6.7. Attachments

The Attachments element is not intended to be used by default when playing the file but could contain information relevant to the content, such as cover art or fonts. Cover art is useful even before the file is played, and fonts could be needed before playback starts for the initialization of subtitles. The Attachments element MAY be placed before the first Cluster element; however, if the Attachments element is likely to be edited, then it SHOULD be placed after the last Cluster element.

6.8. Tags

The Tags element is most subject to changes after the file was originally created. For easier editing, the Tags element can be placed at the end of the Segment element, even after the Attachments element. On the other hand, it is inconvenient to have to seek in the Segment for tags, especially for network streams; thus, it's better if the Tags element is found early in the stream. When editing the Tags element, the original Tags element at the beginning can be overwritten with a Void element and a new Tags element written at the end of the Segment element. The file and Segment sizes will only marginally change.

7. Matroska Versioning

Matroska is based on the principle that a reading application does not have to support 100% of the specifications in order to be able to play the file. Therefore, a Matroska file contains version indicators that tell a reading application what to expect.

It is possible and valid to have the version fields indicate that the file contains Matroska elements from a higher specification version number while signaling that a reading application MUST only support a lower version number properly in order to play it back (possibly with a reduced feature set).

The EBML Header of each Matroska document informs the reading application on what version of Matroska to expect. The elements within the EBML Header with jurisdiction over this information are DocTypeVersion and DocTypeReadVersion.

DocTypeVersion MUST be equal to or greater than the highest Matroska version number of any element present in the Matroska file. For example, a file using the SimpleBlock element (Section 5.1.3.4) MUST have a DocTypeVersion equal to or greater than 2. A file containing CueRelativePosition elements (Section 5.1.5.1.2.3) MUST have a DocTypeVersion equal to or greater than 4.

The DocTypeReadVersion MUST contain the minimum version number that a reading application can minimally support in order to play the file back -- optionally with a reduced feature set. For example, if a file contains only elements of version 2 or lower except for CueRelativePosition (which is a version 4 Matroska element), then DocTypeReadVersion SHOULD still be set to 2 and not 4 because evaluating CueRelativePosition is not necessary for standard playback -- it makes seeking more precise if used.

A reading application supporting Matroska version V MUST NOT refuse to read a file with DocReadTypeVersion equal to or lower than V, even if DocTypeVersion is greater than V.

A reading application supporting at least Matroska version V and reading a file whose DocTypeReadVersion field is equal to or lower than V MUST skip Matroska/EBML elements it encounters but does not know about if that unknown element fits into the size constraints set by the current Parent Element.

8. Stream Copy

It is sometimes necessary to create a Matroska file from another Matroska file, for example, to add subtitles in a language or to edit out a portion of the content. Some values from the original Matroska file need to be kept the same in the destination file. For example, the SamplingFrequency of an audio track wouldn't change between the two files. Some other values may change between the two files, for example, the TrackNumber of an audio track when another track has been added.

An element is marked with a property "stream copy: True" when the values of that element need to be kept identical between the source and destination files. If that property is not set, elements may or may not keep the same value between the source and destination files.

9. DefaultDecodedFieldDuration

The DefaultDecodedFieldDuration element can signal to the displaying application how often fields of a video sequence will be available for displaying. It can be used for both interlaced and progressive content.

If the video sequence is signaled as interlaced (Section 5.1.4.1.28.1), then DefaultDecodedFieldDuration equals the period between two successive fields at the output of the decoding process. For video sequences signaled as progressive, DefaultDecodedFieldDuration is half of the period between two successive frames at the output of the decoding process.

These values are valid at the end of the decoding process before post-processing (such as deinterlacing or inverse telecine) is applied.

Examples:

10. Cluster Blocks

Frames using references SHOULD be stored in "coding order" (i.e., the references first and then the frames referencing them). A consequence is that timestamps might not be consecutive. However, a frame with a past timestamp MUST reference a frame already known; otherwise, it is considered bad/void.

Matroska has two similar ways to store frames in a block:

The SimpleBlock is usually preferred unless some extra elements of the BlockGroup need to be used. A Matroska Reader MUST support both types of blocks.

Each block contains the same parts in the following order:

The block header starts with the number of the Track it corresponds to. The value MUST correspond to the TrackNumber (Section 5.1.4.1.1) of a TrackEntry of the Segment.

The TrackNumber is coded using the Variable-Size Integer (VINT) mechanism described in Section 4 of [RFC8794]. To save space, the shortest VINT form SHOULD be used. The value can be coded using up to 8 octets. This is the only element with a variable size in the block header.

The timestamp is expressed in Track Ticks; see Section 11.1. The value is stored as a signed value on 16 bits.

10.1. Block Structure

This section describes the binary data contained in the Block element (Section 5.1.3.5.1). Bit 0 is the most significant bit.

As the TrackNumber size can vary between 1 and 8 octets, there are 8 different sizes for the Block header. The definitions for TrackNumber sizes of 1 and 2 are provided; the other variants can be deduced by extending the size of the TrackNumber by multiples of 8 bits.

  0                   1                   2                   3
  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |               |                               |       |I|LAC|U|
 |  Track Number |         Timestamp             | Rsvrd |N|ING|N|
 |               |                               |       |V|   |U|
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 11: Block Header with 1-Octet TrackNumber
  0                   1                   2                   3
  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |          Track Number         |         Timestamp             |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |       |I|LAC|U|
 | Rsvrd |N|ING|N|                     ...
 |       |V|   |U|
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 12: Block Header with 2-Octet TrackNumber

where:

Track Number:
8, 16, 24, 32, 40, 48, or 56 bits. An EBML VINT-coded track number.
Timestamp:
16 bits. Signed timestamp in Track Ticks.
Rsvrd:
4 bits. Reserved bits MUST be set to 0.
INV:
1 bit. Invisible; The codec SHOULD decode this frame but not display it.
LACING:

2 bits. Uses lacing mode.

00b:
no lacing (Section 10.3.1)

01b: : Xiph lacing (Section 10.3.2)

11b: : EBML lacing (Section 10.3.3)

10b: : fixed-size lacing (Section 10.3.4)

UNU:
1 bit. Unused bit.

The remaining data in the Block corresponds to the lacing data and frames usage as described in each respective lacing mode (see Section 10.3).

10.2. SimpleBlock Structure

This section describes the binary data contained in the SimpleBlock element (Section 5.1.3.4). Bit 0 is the most significant bit.

The SimpleBlock structure is inspired by the Block structure; see Section 10.1. The main differences are the added Keyframe flag and Discardable flag. Otherwise, everything is the same.

As the TrackNumber size can vary between 1 and 8 octets, there are 8 different sizes for the SimpleBlock header. The definitions for TrackNumber sizes of 1 and 2 are provided; the other variants can be deduced by extending the size of the TrackNumber by multiples of 8 bits.

  0                   1                   2                   3
  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |               |                               |K|     |I|LAC|D|
 |  Track Number |         Timestamp             |E|Rsvrd|N|ING|I|
 |               |                               |Y|     |V|   |S|
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 13: SimpleBlock Header with 1-Octet TrackNumber
  0                   1                   2                   3
  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |          Track Number         |         Timestamp             |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |K|     |I|LAC|D|
 |E|Rsvrd|N|ING|I|                     ...
 |Y|     |V|   |S|
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 14: SimpleBlock Header with 2-Octet TrackNumber

where:

Track Number:
8, 16, 24, 32, 40, 48, or 56 bits. An EBML VINT-coded track number.
Timestamp:
16 bits. Signed timestamp in Track Ticks.
KEY:
1 bit. Keyframe; Set when the Block contains only keyframes.
Rsvrd:
3 bits. Reserved bits MUST be set to 0.
INV:
1 bit. Invisible; the codec SHOULD decode this frame but not display it.
LACING:

2 bits. Uses lacing mode.

00b:
no lacing (Section 10.3.1)

01b: : Xiph lacing (Section 10.3.2)

11b: : EBML lacing (Section 10.3.3)

10b: : fixed-size lacing (Section 10.3.4)

DIS:
1 bit. Discardable; The frames of the Block can be discarded during playing if needed.

The remaining data in the SimpleBlock corresponds to the lacing data and frames usage as described in each respective lacing mode (see Section 10.3).

10.3. Block Lacing

Lacing is a mechanism to save space when storing data. It is typically used for small blocks of data (referred to as frames in Matroska). It packs multiple frames into a single Block or SimpleBlock.

Lacing MUST NOT be used to store a single frame in a Block or SimpleBlock.

There are three types of lacing:

  • Xiph, which is inspired by what is found in the Ogg container [RFC3533]

  • EBML, which is the same with sizes coded differently

  • Fixed-size, where the size is not coded

When lacing is not used, i.e., to store a single frame, the lacing bits (bits 5 and 6) of the Block or SimpleBlock MUST be set to zero.

For example, a user wants to store three frames of the same track. The first frame is 800 octets long, the second is 500 octets long, and the third is 1000 octets long. Because these frames are small, they can be stored in a lace to save space.

It is possible to not use lacing at all and just store a single frame without any extra data. When the FlagLacing (Section 5.1.4.1.12) is set to 0, all blocks of that track MUST NOT use lacing.

10.3.1. No Lacing

When no lacing is used, the number of frames in the lace is omitted, and only one frame can be stored in the Block. The LACING bits of the Block Header flags are set to 00b.

The Block for an 800-octet frame is as follows:

Table 35: No Lacing
Block Octet Value Description
4-803 <frame> Single frame data

When a Block contains a single frame, it MUST use this "no lacing" mode.

10.3.2. Xiph Lacing

The Xiph lacing uses the same coding of size as found in the Ogg container [RFC3533]. The LACING bits of the Block Header flags are set to 01b.

The Block data with laced frames is stored as follows:

  • Lacing Head on 1 Octet: Number of frames in the lace minus 1.

  • Lacing size of each frame except the last one.

  • Binary data of each frame consecutively.

The lacing size is split into 255 values, stored as unsigned octets -- for example, 500 is coded 255;245 or [0xFF 0xF5]. A frame with a size multiple of 255 is coded with a 0 at the end of the size -- for example, 765 is coded 255;255;255;0 or [0xFF 0xFF 0xFF 0x00].

The size of the last frame is deduced from the size remaining in the Block after the other frames.

Because large sizes result in large coding of the sizes, it is RECOMMENDED to use Xiph lacing only with small frames.

In our example, the 800-, 500-, and 1000-octet frames are stored with Xiph lacing in a Block as follows:

Table 36: Xiph Lacing Example
Block Octets Value Description
4 0x02 Number of frames minus 1
5-8 0xFF 0xFF 0xFF 0x23 Size of the first frame (255;255;255;35)
9-10 0xFF 0xF5 Size of the second frame (255;245)
11-810 First frame data
811-1310 Second frame data
1311-2310 Third frame data

The Block is 2311 octets, and the last frame starts at 1311, so we can deduce that the size of the last frame is 2311 - 1311 = 1000.

10.3.3. EBML Lacing

The EBML lacing encodes the frame size with an EBML-like encoding [RFC8794]. The LACING bits of the Block Header flags are set to 11b.

The Block data with laced frames is stored as follows:

  • Lacing Head on 1 Octet: Number of frames in the lace minus 1.

  • Lacing size of each frame except the last one.

  • Binary data of each frame consecutively.

The first frame size is encoded as an EBML VINT value. The remaining frame sizes are encoded as signed values using the difference between the frame size and the previous frame size. These signed values are encoded as VINT, with a mapping from signed to unsigned numbers. Decoding the unsigned number stored in the VINT to a signed number is done by subtracting 2((7*n)-1)-1, where n is the octet size of the VINT.

Table 37: EBML Lacing Signed VINT Bits Usage
Bit Representation of Signed VINT Possible Value Range
1xxx xxxx 2^7 values from -(26-1) to 26
01xx xxxx xxxx xxxx 2^14 values from -(213-1) to 213
001x xxxx xxxx xxxx xxxx xxxx 2^21 values from -(220-1) to 220
0001 xxxx xxxx xxxx xxxx xxxx xxxx xxxx 2^28 values from -(227-1) to 227
0000 1xxx xxxx xxxx xxxx xxxx xxxx xxxx xxxx xxxx 2^35 values from -(234-1) to 234

In our example, the 800-, 500-, and 1000-octet frames are stored with EBML lacing in a Block as follows:

Table 38: EBML Lacing Example
Block Octets Value Description
4 0x02 Number of frames minus 1
5-6 0x43 0x20 Size of the first frame (800 = 0x320 + 0x4000)
7-8 0x5E 0xD3 Size of the second frame (500 - 800 = -300 = - 0x12C + 0x1FFF + 0x4000)
8-807 <frame1> First frame data
808-1307 <frame2> Second frame data
1308-2307 <frame3> Third frame data

The Block is 2308 octets, and the last frame starts at 1308, so we can deduce that the size of the last frame is 2308 - 1308 = 1000.

10.3.4. Fixed-size Lacing

Fixed-size lacing doesn't store the frame size; rather, it only stores the number of frames in the lace. Each frame MUST have the same size. The frame size of each frame is deduced from the total size of the Block. The LACING bits of the Block Header flags are set to 10b.

The Block data with laced frames is stored as follows:

  • Lacing Head on 1 Octet: Number of frames in the lace minus 1.

  • Binary data of each frame consecutively.

For example, for three frames that are 800 octets each:

Table 39: Fixed-Size Lacing Example
Block Octets Value Description
4 0x02 Number of frames minus 1
5-804 <frame1> First frame data
805-1604 <frame2> Second frame data
1605-2404 <frame3> Third frame data

This gives a Block of 2405 octets. When reading the Block, we find that there are three frames (Octet 4). The data start at Octet 5, so the size of each frame is (2405 - 5) / 3 = 800.

10.3.5. Laced Frames Timestamp

A Block only contains a single timestamp value. But when lacing is used, it contains more than one frame. Each frame originally has its own timestamp, or Presentation Timestamp (PTS). That timestamp applies to the first frame in the lace.

In the lace, each frame after the first one has an underdetermined timestamp. However, each of these frames MUST be contiguous -- i.e., the decoded data MUST NOT contain any gap between them. If there is a gap in the stream, the frames around the gap MUST NOT be in the same Block.

Lacing is only useful for small contiguous data to save space. This is usually the case for audio tracks and not the case for video (which use a lot of data) or subtitle tracks (which have long gaps). For audio, there is usually a fixed output sampling frequency for the whole track, so the decoder should be able to recover the timestamp of each sample, knowing each output sample is contiguous with a fixed frequency. For subtitles, this is usually not the case, so lacing SHOULD NOT be used.

10.4. Random Access Points

Random Access Points (RAPs) are positions where the parser can seek to and start playback without decoding what was before. In Matroska, BlockGroups and SimpleBlocks can be RAPs. To seek to these elements, it is still necessary to seek to the Cluster containing them, read the Cluster Timestamp, and start playback from the BlockGroup or SimpleBlock that is a RAP.

Because a Matroska File is usually composed of multiple tracks playing at the same time -- video, audio, and subtitles -- to seek properly to a RAP, each selected track must be taken into account. Usually, all audio and subtitle BlockGroups or SimpleBlocks are RAPs. They are independent of each other and can be played randomly.

On the other hand, video tracks often use references to previous and future frames for better coding efficiency. Frames with such references MUST either contain one or more ReferenceBlock elements in their BlockGroup or MUST be marked as non-keyframe in a SimpleBlock; see Section 10.2.

&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;BlockGroup&gt;
    &lt;!-- References a Block 40 Track Ticks before this one --&gt;
    &lt;ReferenceBlock&gt;-40&lt;/ReferenceBlock&gt;
    &lt;Block/&gt;
  &lt;/BlockGroup&gt;
  ...
&lt;/Cluster&gt;
Figure 15: BlockGroup with a Frame That References Another Frame, with the EBML Tree Shown as XML
&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;SimpleBlock/&gt; (octet 3 bit 0 not set)
  ...
&lt;/Cluster&gt;
Figure 16: SimpleBlock with a Frame That References Another Frame, with the EBML Tree Shown as XML

Frames that are RAPs (i.e., frames that don't depend on other frames) MUST set the keyframe flag if they are in a SimpleBlock or their parent BlockGroup MUST NOT contain a ReferenceBlock.

&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;BlockGroup&gt;
    &lt;!-- No ReferenceBlock allowed in this BlockGroup --&gt;
    &lt;Block/&gt;
  &lt;/BlockGroup&gt;
  ...
&lt;/Cluster&gt;
Figure 17: BlockGroup with a Frame That References No Other Frame, with the EBML Tree Shown as XML
&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;SimpleBlock/&gt; (octet 3 bit 0 set)
  ...
&lt;/Cluster&gt;
Figure 18: SimpleBlock with a Frame That References No Other Frame, with the EBML Tree Shown as XML

There may be cases where the use of BlockGroup is necessary, as the frame may need a BlockDuration, BlockAdditions, CodecState, or DiscardPadding element. For those cases, a SimpleBlock MUST NOT be used; the reference information SHOULD be recovered for non-RAP frames.

&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;SimpleBlock/&gt; (octet 3 bit 0 not set)
  ...
&lt;/Cluster&gt;
Figure 19: SimpleBlock with a Frame That References Another Frame, with the EBML Tree Shown as XML
&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;BlockGroup&gt;
    &lt;!-- ReferenceBlock value recovered based on the codec --&gt;
    &lt;ReferenceBlock&gt;-40&lt;/ReferenceBlock&gt;
    &lt;BlockDuration&gt;20&lt;/BlockDuration&gt;
    &lt;Block/&gt;
  &lt;/BlockGroup&gt;
  ...
&lt;/Cluster&gt;
Figure 20: Same Frame That References Another Frame Put inside a BlockGroup to Add BlockDuration, with the EBML Tree Shown as XML

When a frame in a BlockGroup is not a RAP, the BlockGroup MUST contain at least a ReferenceBlock. The ReferenceBlocks MUST be used in one of the following ways:

  • each reference frame listed as a ReferenceBlock,

  • some referenced frames listed as a ReferenceBlock, even if the timestamp value is accurate, or

  • one ReferenceBlock with the timestamp value "0" corresponding to a self or unknown reference.

The lack of ReferenceBlock would mean such a frame is a RAP, and seeking on that frame that actually depends on other frames may create a bogus output or even crash.

&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;BlockGroup&gt;
    &lt;!-- ReferenceBlock value not recovered from the codec --&gt;
    &lt;ReferenceBlock&gt;0&lt;/ReferenceBlock&gt;
    &lt;BlockDuration&gt;20&lt;/BlockDuration&gt;
    &lt;Block/&gt;
  &lt;/BlockGroup&gt;
  ...
&lt;/Cluster&gt;
Figure 21: Same Frame That References Another Frame Put inside a BlockGroup, but the Reference Could Not Be Recovered, with the EBML Tree Shown as XML
&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;BlockGroup&gt;
    &lt;!-- References a Block 80 Track Ticks before this one --&gt;
    &lt;ReferenceBlock&gt;-80&lt;/ReferenceBlock&gt;
    &lt;!-- References a Block 40 Track Ticks after this one --&gt;
    &lt;ReferenceBlock&gt;40&lt;/ReferenceBlock&gt;
    &lt;Block/&gt;
  &lt;/BlockGroup&gt;
  ...
&lt;/Cluster&gt;
Figure 22: BlockGroup with a Frame That References Two Other Frames, with the EBML Tree Shown as XML

Intra-only video frames, such as the ones found in AV1 or VP9, can be decoded without any other frame, but they don't reset the codec state. Thus, seeking to these frames is not possible, as the next frames may need frames that are not known from this seeking point. Such intra-only frames MUST NOT be considered as keyframes, so the keyframe flag MUST NOT be set in the SimpleBlock or a ReferenceBlock MUST be used to signify the frame is not a RAP. The timestamp value of the ReferenceBlock MUST be "0", meaning it's referencing itself.

&lt;Cluster&gt;
  &lt;Timestamp&gt;123456&lt;/Timestamp&gt;
  &lt;BlockGroup&gt;
    &lt;!-- References itself to mark it should not be used as RAP --&gt;
    &lt;ReferenceBlock&gt;0&lt;/ReferenceBlock&gt;
    &lt;Block/&gt;
  &lt;/BlockGroup&gt;
  ...
&lt;/Cluster&gt;
Figure 23: Intra-Only Frame (Not a RAP), with the EBML Tree Shown as XML

Because a video SimpleBlock has less information on references than a video BlockGroup, it is possible to remux a video track using BlockGroup into a SimpleBlock, as long as it doesn't use any other BlockGroup features than ReferenceBlock.

11. Timestamps

Historically, timestamps in Matroska were mistakenly called timecodes. The Timestamp element was called Timecode, the TimestampScale element was called TimecodeScale, the TrackTimestampScale element was called TrackTimecodeScale, and the ReferenceTimestamp element was called ReferenceTimeCode.

11.1. Timestamp Ticks

All timestamp values in Matroska are expressed in multiples of a tick. They are usually stored as integers. There are three types of ticks possible: Matroska Ticks, Segment Ticks, and Track Ticks.

11.1.1. Matroska Ticks

The timestamp value is stored directly in nanoseconds.

The elements storing values in Matroska Ticks/nanoseconds are:

11.1.2. Segment Ticks

Elements in Segment Ticks involve the use of the TimestampScale element of the Segment to get the timestamp in nanoseconds of the element, with the following formula:

timestamp in nanosecond = element value * TimestampScale

This allows for storage of smaller integer values in the elements.

When using the default value of "1,000,000" for TimestampScale, one Segment Tick represents one millisecond.

The elements storing values in Segment Ticks are:

11.1.3. Track Ticks

Elements in Track Ticks involve the use of the TimestampScale element of the Segment and the TrackTimestampScale element of the Track to get the timestamp in nanoseconds of the element, with the following formula:

timestamp in nanoseconds =
    element value * TrackTimestampScale * TimestampScale

This allows for storage of smaller integer values in the elements. The resulting floating-point values of the timestamps are still expressed in nanoseconds.

When using the default values of "1,000,000" for TimestampScale and "1.0" for TrackTimestampScale, one Track Tick represents one millisecond.

The elements storing values in Track Ticks are:

When the TrackTimestampScale is interpreted as "1.0", Track Ticks are equivalent to Segment Ticks and give an integer value in nanoseconds. This is the most common case as TrackTimestampScale is usually omitted.

A value of TrackTimestampScale other than "1.0" MAY be used to scale the timestamps more in tune with each Track sampling frequency. For historical reasons, a lot of Matroska Readers don't take the TrackTimestampScale value into account. Thus, using a value other than "1.0" might not work in many places.

11.2. Block Timestamps

A Block element and SimpleBlock element timestamp is the time when the decoded data of the first frame in the Block/SimpleBlock MUST be presented if the track of that Block/SimpleBlock is selected for playback. This is also known as the Presentation Timestamp (PTS).

The Block element and SimpleBlock element store their timestamps as signed integers, relative to the Cluster\Timestamp value of the Cluster they are stored in. To get the timestamp of a Block or SimpleBlock in nanoseconds, the following formula is used:

( Cluster\Timestamp + ( block timestamp * TrackTimestampScale ) ) *
TimestampScale

The Block element and SimpleBlock element store their timestamps as 16-bit signed integers, allowing a range from "-32768" to "+32767" Track Ticks. Although these values can be negative, when added to the Cluster\Timestamp, the resulting frame timestamp SHOULD NOT be negative.

When a CodecDelay element is set, its value MUST be subtracted from each Block timestamp of that track. To get the timestamp in nanoseconds of the first frame in a Block or SimpleBlock, the formula becomes:

( ( Cluster\Timestamp + ( block timestamp * TrackTimestampScale ) ) *
  TimestampScale ) - CodecDelay

The resulting frame timestamp SHOULD NOT be negative.

During playback, when a frame has a negative timestamp, the content MUST be decoded by the decoder but not played to the user.

11.3. TimestampScale Rounding

The default Track Tick duration is one millisecond.

The TimestampScale is a floating-point value that is usually "1.0". But when it's not, the multiplied Block Timestamp is a floating-point value in nanoseconds. The Matroska Reader SHOULD use the nearest rounding value in nanoseconds to get the proper nanosecond timestamp of a Block. This allows some clever TimestampScale values to have a more refined timestamp precision per frame.

12. Language Codes

Matroska versions 1 through 3 use language codes that can be either the three-letter bibliographic ISO 639-2 form [ISO639-2] (like "fre" for French) or such a language code followed by a dash and a country code for specialities in languages (like "fre-ca" for Canadian French). The ISO 639-2 Language elements are Language element, TagLanguage element, and ChapLanguage element.

Starting in Matroska version 4, the forms defined in either [ISO639-2] or [RFC5646] MAY be used, although the form in [RFC5646] is RECOMMENDED. The Language elements in the [RFC5646] form are LanguageBCP47 element, TagLanguageBCP47 element, and ChapLanguageBCP47 element. If both an [ISO639-2] Language element and an [RFC5646] Language element are used within the same Parent Element, then the Language element in the [ISO639-2] form MUST be ignored and precedence given to the Language element in the [RFC5646] form.

In this document, "BCP47" in element names refers specifically to [RFC5646], which is part of BCP 47.

13. Country Codes

Country codes are the [RFC5646] two-letter region subtags, without the UK exception.

14. Encryption

This Matroska specification provides no interoperable solution for securing the data container with any assurances of confidentiality, integrity, authenticity, or authorization. The ContentEncryption element (Section 5.1.4.1.31.8) and associated sub-fields (Section 5.1.4.1.31.9 to Section 5.1.4.1.31.12) are defined only for the benefit of implementers to construct their own proprietary solution or as the basis for further standardization activities. How to use these fields to secure a Matroska data container is out of scope, as are any related issues such as key management and distribution.

A Matroska Reader who encounters containers that use the fields defined in this section MUST rely on out-of-scope guidance to decode the associated content.

Because encryption occurs within the Block element, it is possible to manipulate encrypted streams without decrypting them. The streams could potentially be copied, deleted, cut, appended, or any number of other possible editing techniques without decryption. The data can be used without having to expose it or go through the decrypting process.

Encryption can also be layered within Matroska. This means that two completely different types of encryption can be used, requiring two separate keys to be able to decrypt a stream.

Encryption information is stored in the ContentEncodings element under the ContentEncryption element.

For encryption systems sharing public/private keys, the creation of the keys and the exchange of keys are not covered by this document. They have to be handled by the system using Matroska.

The algorithms described in Table 24 support different modes of operations and key sizes. The specification of these parameters is required for a complete solution but is out of scope of this document and left to the proprietary implementations using them or subsequent profiles of this document.

The ContentEncodingScope element gives an idea of which part of the track is encrypted, but each ContentEncAlgo element and its sub-elements (like AESSettingsCipherMode) define exactly how the encrypted track should be interpreted.

An example of an extension that builds upon these security-related fields in this specification is [WebM-Enc]. It uses AES-CTR, ContentEncAlgo = 5 (Section 5.1.4.1.31.9), and AESSettingsCipherMode = 1 (Section 5.1.4.1.31.12).

A Matroska Writer MUST NOT use insecure cryptographic algorithms to create new archives or streams, but a Matroska Reader MAY support these algorithms to read previously made archives or streams.

15. Image Presentation

15.1. Cropping

The PixelCrop elements (PixelCropTop, PixelCropBottom, PixelCropRight, and PixelCropLeft) indicate when, and by how much, encoded video frames SHOULD be cropped for display. These elements allow edges of the frame that are not intended for display (such as the sprockets of a full-frame film scan or the Video ANCillary (VANC) area of a digitized analog videotape) to be stored but hidden. PixelCropTop and PixelCropBottom store an integer of how many rows of pixels SHOULD be cropped from the top and bottom of the image, respectively. PixelCropLeft and PixelCropRight store an integer of how many columns of pixels SHOULD be cropped from the left and right of the image, respectively.

For example, a pillar-boxed video that stores a 1440x1080 visual image within the center of a padded 1920x1080 encoded image may set both PixelCropLeft and PixelCropRight to "240", so a Matroska Player should crop off 240 columns of pixels from the left and right of the encoded image to present the image with the pillar-boxes hidden.

Cropping has to be performed before resizing and the display dimensions given by DisplayWidth, DisplayHeight, and DisplayUnit apply to the already-cropped image.

15.2. Rotation

The ProjectionPoseRoll element (Section 5.1.4.1.28.46) can be used to indicate that the image from the associated video track SHOULD be rotated for presentation. For instance, the following example of the Projection element (Section 5.1.4.1.28.41) and the ProjectionPoseRoll element represents a video track where the image SHOULD be presented with a 90-degree counter-clockwise rotation, with the EBML tree shown as XML:

&lt;Projection&gt;
  &lt;ProjectionPoseRoll&gt;90&lt;/ProjectionPoseRoll&gt;
&lt;/Projection&gt;
Figure 24: Rotation Example

16. Segment Position

The Segment Position of an element refers to the position of the first octet of the Element ID of that element, measured in octets, from the beginning of the Element Data section of the containing Segment element. In other words, the Segment Position of an element is the distance in octets from the beginning of its containing Segment element minus the size of the Element ID and Element Data Size of that Segment element. The Segment Position of the first Child Element of the Segment element is 0. An element that is not stored within a Segment element, such as the elements of the EBML Header, do not have a Segment Position.

16.1. Segment Position Exception

Elements that are defined to store a Segment Position MAY define reserved values to indicate a special meaning.

16.2. Example of Segment Position

This table presents an example of Segment Position by showing a hexadecimal representation of a very small Matroska file with labels to show the offsets in octets. The file contains a Segment element with an Element ID of "0x18538067" and a MuxingApp element with an Element ID of "0x4D80".

     0                             1                             2
     0  1  2  3  4  5  6  7  8  9  0  1  2  3  4  5  6  7  8  9  0
     +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+
   0 |1A|45|DF|A3|8B|42|82|88|6D|61|74|72|6F|73|6B|61|
     ^ EBML Header
   0 |                                               |18|53|80|67|
                                                     ^ Segment ID
  20 |93|
     ^ Segment Data Size
  20 |  |15|49|A9|66|8E|4D|80|84|69|65|74|66|57|41|84|69|65|74|66|
        ^ Start of Segment data
  20 |                 |4D|80|84|69|65|74|66|57|41|84|69|65|74|66|
                       ^ MuxingApp start

In the above example, the Element ID of the Segment element is stored at offset 16, the Element Data Size of the Segment element is stored at offset 20, and the Element Data of the Segment element is stored at offset 21.

The MuxingApp element is stored at offset 26. Since the Segment Position of an element is calculated by subtracting the position of the Element Data of the containing Segment element from the position of that element, the Segment Position of the MuxingApp element in the above example is "26 - 21" or "5".

17. Linked Segments

Matroska provides several methods to link two or more Segment elements together to create a Linked Segment. A Linked Segment is a set of multiple Segments linked together into a single presentation by using Hard Linking or Medium Linking.

All Segments within a Linked Segment MUST have a SegmentUUID.

All Segments within a Linked Segment SHOULD be stored within the same directory or be quickly accessible based on their SegmentUUID in order to have a seamless transition between segments.

All Segments within a Linked Segment MAY set a SegmentFamily with a common value to make it easier for a Matroska Player to know which Segments are meant to be played together.

The SegmentFilename, PrevFilename, and NextFilename elements MAY also give hints on the original filenames that were used when the Segment links were created, in case some SegmentUUIDs are damaged.

17.1. Hard Linking

Hard Linking, also called "splitting", is the process of creating a Linked Segment by linking multiple Segment elements using the NextUUID and PrevUUID elements.

All Segments within a Hard Linked Segment MUST use the same Tracks list and TimestampScale.

Within a Linked Segment, the timestamps of Block and SimpleBlock MUST consecutively follow the timestamps of Block and SimpleBlock from the previous Segment in linking order.

With Hard Linking, the chapters of any Segment within the Linked Segment MUST only reference the current Segment. The NextUUID and PrevUUID reference the respective SegmentUUID values of the next and previous Segments.

The first Segment of a Linked Segment MUST NOT have a PrevUUID element. The last Segment of a Linked Segment MUST NOT have a NextUUID element.

For each node of the chain of Segments of a Linked Segment, at least one Segment MUST reference the other Segment within the chain.

In a chain of Segments of a Linked Segment, the NextUUID always takes precedence over the PrevUUID. Thus, if SegmentA has a NextUUID to SegmentB and SegmentB has a PrevUUID to SegmentC, the link to use is NextUUID between SegmentA and SegmentB, and SegmentC is not part of the Linked Segment.

If SegmentB has a PrevUUID to SegmentA, but SegmentA has no NextUUID, then the Matroska Player MAY consider these two Segments linked as SegmentA followed by SegmentB.

As an example, three Segments can be Hard Linked as a Linked Segment through cross-referencing each other with SegmentUUID, PrevUUID, and NextUUID as shown in this table:

Table 40: Usual Hard Linking UIDs
file name SegmentUUID PrevUUID NextUUID
start.mkv 71000c23cd310998 53fbc94dd984a5dd Invalid a77b3598941cb803 eac0fcdafe44fac9
middle.mkv a77b3598941cb803 eac0fcdafe44fac9 71000c23cd310998 53fbc94dd984a5dd 6c92285fa6d3e827 b198d120ea3ac674
end.mkv 6c92285fa6d3e827 b198d120ea3ac674 a77b3598941cb803 eac0fcdafe44fac9 Invalid

An example where only the NextUUID element is used:

Table 41: Hard Linking without PrevUUID
file name SegmentUUID PrevUUID NextUUID
start.mkv 71000c23cd310998 53fbc94dd984a5dd Invalid a77b3598941cb803 eac0fcdafe44fac9
middle.mkv a77b3598941cb803 eac0fcdafe44fac9 n/a 6c92285fa6d3e827 b198d120ea3ac674
end.mkv 6c92285fa6d3e827 b198d120ea3ac674 n/a Invalid

An example where only the PrevUUID element is used:

Table 42: Hard Linking without NextUUID
file name SegmentUUID PrevUUID NextUUID
start.mkv 71000c23cd310998 53fbc94dd984a5dd Invalid n/a
middle.mkv a77b3598941cb803 eac0fcdafe44fac9 71000c23cd310998 53fbc94dd984a5dd n/a
end.mkv 6c92285fa6d3e827 b198d120ea3ac674 a77b3598941cb803 eac0fcdafe44fac9 Invalid

An example where only the middle.mkv is using the PrevUUID and NextUUID elements:

Table 43: Hard Linking with Mixed UID Links
file name SegmentUUID PrevUUID NextUUID
start.mkv 71000c23cd310998 53fbc94dd984a5dd Invalid n/a
middle.mkv a77b3598941cb803 eac0fcdafe44fac9 71000c23cd310998 53fbc94dd984a5dd 6c92285fa6d3e827 b198d120ea3ac674
end.mkv 6c92285fa6d3e827 b198d120ea3ac674 n/a Invalid

17.2. Medium Linking

Medium Linking creates relationships between Segments using Ordered Chapters (Section 20.1.3) and the ChapterSegmentUUID element. A Chapter Edition with Ordered Chapters MAY contain Chapters elements that reference timestamp ranges from other Segments. The Segment referenced by the Ordered Chapter via the ChapterSegmentUUID element SHOULD be played as part of a Linked Segment.

The timestamps of Segment content referenced by Ordered Chapters MUST be adjusted according to the cumulative duration of the previous Ordered Chapters.

As an example, a file named intro.mkv could have a SegmentUUID of "0xb16a58609fc7e60653a60c984fc11ead". Another file called program.mkv could use a Chapter Edition that contains two Ordered Chapters. The first chapter references the Segment of intro.mkv with the use of a ChapterSegmentUUID, ChapterSegmentEditionUID, ChapterTimeStart, and an optional ChapterTimeEnd element. The second chapter references content within the Segment of program.mkv. A Matroska Player SHOULD recognize the Linked Segment created by the use of ChapterSegmentUUID in an enabled Edition and present the reference content of the two Segments as a single presentation.

The ChapterSegmentUUID represents the Segment that holds the content to play in place of the Linked Chapter. The ChapterSegmentUUID MUST NOT be the SegmentUUID of its own Segment.

There are two ways to use a chapter link:

  • Linked-Duration linking

  • Linked-Edition linking

17.2.1. Linked-Duration

A Matroska Player MUST play the content of the Linked Segment from the ChapterTimeStart until the ChapterTimeEnd timestamp in place of the Linked Chapter.

ChapterTimeStart and ChapterTimeEnd represent timestamps in the Linked Segment matching the value of ChapterSegmentUUID. Their values MUST be in the range of the Linked Segment duration.

The ChapterTimeEnd value MUST be set when using Linked-Duration chapter linking. ChapterSegmentEditionUID MUST NOT be set.

17.2.2. Linked-Edition

A Matroska Player MUST play the whole Linked Edition of the Linked Segment in place of the Linked Chapter.

ChapterSegmentEditionUID represents a valid Edition from the Linked Segment matching the value of ChapterSegmentUUID.

When using Linked-Edition chapter linking, ChapterTimeEnd is OPTIONAL.

18. Track Flags

18.1. Default Flag

The Default flag is a hint for a Matroska Player indicating that a given track SHOULD be eligible to be automatically selected as the default track for a given language. If no tracks in a given language have the Default flag set, then all tracks in that language are eligible for automatic selection. This can be used to indicate that a track provides "regular service" that is suitable for users with default settings, as opposed to specialized services, such as commentary, captions for users with hearing impairments, or descriptive audio.

The Matroska Player MAY override the Default flag for any reason, including user preferences to prefer tracks providing accessibility services.

18.2. Forced Flag

The Forced flag tells the Matroska Player that it SHOULD display this subtitle track, even if user preferences usually would not call for any subtitles to be displayed alongside the audio track that is currently selected. This can be used to indicate that a track contains translations of on-screen text or dialogue spoken in a different language than the track's primary language.

18.3. Hearing-Impaired Flag

The Hearing-Impaired flag tells the Matroska Player that it SHOULD prefer this track when selecting a default track for a user with a hearing impairment and that it MAY prefer to select a different track when selecting a default track for a user that is not hearing impaired.

18.4. Visual-Impaired Flag

The Visual-Impaired flag tells the Matroska Player that it SHOULD prefer this track when selecting a default track for a user with a visual impairment and that it MAY prefer to select a different track when selecting a default track for a user that is not visually impaired.

18.5. Descriptions Flag

The Descriptions flag tells the Matroska Player that this track is suitable to play via a text-to-speech system for a user with a visual impairment and that it SHOULD NOT automatically select this track when selecting a default track for a user that is not visually impaired.

18.6. Original Flag

The Original flag tells the Matroska Player that this track is in the original language and that it SHOULD prefer this track if configured to prefer original-language tracks of this track's type.

18.7. Commentary Flag

The Commentary flag tells the Matroska Player that this track contains commentary on the content.

18.8. Track Operation

TrackOperation allows for the combination of multiple tracks to make a virtual one. It uses two separate system to combine tracks. One to create a 3D "composition" (left/right/background planes) and one to simplify join two tracks together to make a single track.

A track created with TrackOperation is a proper track with a UID and all its flags. However, the codec ID is meaningless because each "sub" track needs to be decoded by its own decoder before the "operation" is applied. The Cues elements corresponding to such a virtual track SHOULD be the union of the Cues elements for each of the tracks it's composed of (when the Cues are defined per track).

In the case of TrackJoinBlocks, the Block elements (from BlockGroup and SimpleBlock) of all the tracks SHOULD be used as if they were defined for this new virtual Track. When two Block elements have overlapping start or end timestamps, it's up to the underlying system to either drop some of these frames or render them the way they overlap. This situation SHOULD be avoided when creating such tracks, as you can never be sure of the end result on different platforms.

18.9. Overlay Track

An overlay track SHOULD be rendered in the same channel as the track it's linked to. When content is found in such a track, it SHOULD be played on the rendering channel instead of the original track.

18.10. Multi-planar and 3D Videos

There are two different ways to compress 3D videos: have each eye track in a separate track and have one track have both eyes combined inside (which is more efficient compression-wise). Matroska supports both ways.

For the single-track variant, there is the StereoMode element, which defines how planes are assembled in the track (mono or left-right combined). Odd values of StereoMode means the left plane comes first for more convenient reading. The pixel count of the track (PixelWidth/PixelHeight) is the raw number of pixels (for example, 3840x1080 for full HD side by side), and the DisplayWidth/DisplayHeight in pixels is the number of pixels for one plane (1920x1080 for that full HD stream). Old stereo 3D movies were displayed using anaglyph (cyan and red colors separated). For compatibility with such movies, there is a value of the StereoMode that corresponds to anaglyph.

There is also a "packed" mode (values 13 and 14) that consists of packing two frames together in a Block that uses lacing. The first frame is the left eye and the other frame is the right eye (or vice versa). The frames SHOULD be decoded in that order and are possibly dependent on each other (P and B frames).

For separate tracks, Matroska needs to define exactly which track does what. TrackOperation with TrackCombinePlanes does that. For more details, see Section 18.8 on how TrackOperation works.

The 3D support is still in infancy and may evolve to support more features.

The StereoMode used to be part of Matroska v2, but it didn't meet the requirement for multiple tracks. There was also a bug in [libmatroska] prior to 0.9.0 that would save/read it as 0x53B9 instead of 0x53B8; see OldStereoMode (Section 5.1.4.1.28.5). Matroska Readers MAY support these legacy files by checking Matroska v2 or 0x53B9. The older values of StereoMode were 0 (mono), 1 (right eye), 2 (left eye), and 3 (both eyes); these are the only values that can be found in OldStereoMode. They are not compatible with the StereoMode values found in Matroska v3 and above.

19. Default Track Selection

This section provides some example sets of Tracks and hypothetical user settings, along with indications of which ones a similarly configured Matroska Player SHOULD automatically select for playback by default in such a situation. A player MAY provide additional settings with more detailed controls for more nuanced scenarios. These examples are provided as guidelines to illustrate the intended usages of the various supported Track flags and their expected behaviors.

Track names are shown in English for illustrative purposes; actual files may have titles in the language of each track or provide titles in multiple languages.

19.1. Audio Selection

Example track set:

Table 44: Audio Tracks for Default Selection
No. Type Lang Layout Original Default Other Flags Name
1 Video und N/A N/A N/A None
2 Audio eng 5.1 1 1 None
3 Audio eng 2.0 1 1 None
4 Audio eng 2.0 1 0 Visual-Impaired Descriptive audio
5 Audio esp 5.1 0 1 None
6 Audio esp 2.0 0 0 Visual-Impaired Descriptive audio
7 Audio eng 2.0 1 0 Commentary Director's Commentary
8 Audio eng 2.0 1 0 None Karaoke

The table above shows a file with seven audio tracks -- five in English and two in Spanish.

The English tracks all have the Original flag, indicating that English is the original content language.

Generally, the player will first consider the track languages. If the player has an option to prefer original-language audio and the user has enabled it, then it should prefer one of the tracks with the Original flag. If the user has configured to specifically prefer audio tracks in English or Spanish, the player should select one of the tracks in the corresponding language. The player may also wish to prefer a track with the Original flag if no tracks matching any of the user's explicitly preferred languages are available.

Two of the tracks have the Visual-Impaired flag. If the player has been configured to prefer such tracks, it should select one; otherwise, it should avoid them if possible.

If selecting an English track, when other settings have left multiple possible options, it may be useful to exclude the tracks that lack the Default flag. Here, one provides descriptive service for individuals with visual impairments (which has its own flag and may be automatically selected by user configuration but is unsuitable for users with default-configured players), one is a commentary track (which has its own flag and the player may or may not have specialized handling for), and the last contains karaoke versions of the music that plays during the film (which is an unusual specialized audio service that Matroska has no built-in support for indicating, so it's indicated in the track name instead). By not setting the Default flag on these specialized tracks, the file's author hints that they should not be automatically selected by a default-configured player.

Having narrowed its choices down, the example player now may have to select between tracks 2 and 3. The only difference between these tracks is their channel layouts: 2 is 5.1 surround, while 3 is stereo. If the player is aware that the output device is a pair of headphones or stereo speakers, it may wish to prefer the stereo mix automatically. On the other hand, if it knows that the device is a surround system, it may wish to prefer the surround mix.

If the player finishes analyzing all of the available audio tracks and finds that more than one seem equally and maximally preferable, it SHOULD default to the first of the group.

19.2. Subtitle Selection

Example track set:

Table 45: Subtitle Tracks for Default Selection
No. Type Lang Original Default Forced Other Flags Name
1 Video und N/A N/A N/A None
2 Audio fra 1 1 N/A None
3 Audio por 0 1 N/A None
4 Subtitles fra 1 1 0 None
5 Subtitles fra 1 0 0 Hearing-Impaired Captions for users with hearing impairments
6 Subtitles por 0 1 0 None
7 Subtitles por 0 0 1 None Signs
8 Subtitles por 0 0 0 Hearing-Impaired SDH

The table above shows two audio tracks and five subtitle tracks. As we can see, French is the original language.

We'll start by discussing the case where the user prefers French (or original-language) audio (or has explicitly selected the French audio track) and also prefers French subtitles.

In this case, if the player isn't configured to display captions when the audio matches their preferred subtitle languages, the player doesn't need to select a subtitle track at all.

If the user has indicated that they want captions to be displayed, the selection simply comes down to whether hearing-impaired subtitles are preferred.

The situation for a user who prefers Portuguese subtitles starts out somewhat analogous. If they select the original French audio (either by explicit audio language preference, preference for original-language tracks, or explicitly selecting that track), then the selection once again comes down to the hearing-impaired preference.

However, the case where the Portuguese audio track is selected has an important catch: a Forced track in Portuguese is present. This may contain translations of on-screen text from the video track or of portions of the audio that are not translated (music, for instance). This means that even if the user's preferences wouldn't normally call for captions here, the Forced track should be selected nonetheless, rather than selecting no track at all. On the other hand, if the user's preferences do call for captions, the non-Forced tracks should be preferred, as the Forced track will not contain captioning for the dialogue.

20. Chapters

The Matroska Chapters system can have multiple Editions, and each Edition can consist of Simple Chapters where a chapter start time is used as a marker in the timeline only. An Edition can be more complex with Ordered Chapters where a chapter end timestamp is additionally used or much more complex with Linked Chapters. The Matroska Chapters system can also have a menu structure borrowed from the DVD-menu system [DVD-Video] or have its own built-in Matroska menu structure.

20.1. EditionEntry

The EditionEntry is also called an Edition. An Edition contains a set of Edition flags and MUST contain at least one ChapterAtom element. Chapters are always inside an Edition (or a Chapter itself is part of an Edition). Multiple Editions are allowed. Some of these Editions MAY be ordered and others not.

20.1.1. EditionFlagDefault

Only one Edition SHOULD have an EditionFlagDefault flag set to true.

20.1.2. Default Edition

The Default Edition is the Edition that a Matroska Player SHOULD use for playback by default.

The first Edition with the EditionFlagDefault flag set to true is the Default Edition.

When all EditionFlagDefault flags are set to false, then the first Edition is the Default Edition.

Table 46: Default Edition, All Default
Edition FlagDefault Default Edition
Edition 1 true X
Edition 2 true
Edition 3 true
Table 47: Default Edition, No Default
Edition FlagDefault Default Edition
Edition 1 false X
Edition 2 false
Edition 3 false
Table 48: Default Edition, With Default
Edition FlagDefault Default Edition
Edition 1 false
Edition 2 true X
Edition 3 false

20.1.3. EditionFlagOrdered

The EditionFlagOrdered flag is a significant feature, as it enables an Edition of Ordered Chapters that defines and arranges a virtual timeline rather than simply labeling points within the timeline. For example, with Editions of Ordered Chapters, a single Matroska file can present multiple edits of a film without duplicating content. Alternatively, if a videotape is digitized in full, one Ordered Edition could present the full content (including colorbars, countdown, slate, a feature presentation, and black frames), while another Edition of Ordered Chapters can use Chapters that only mark the intended presentation with the colorbars and other ancillary visual information excluded. If an Edition of Ordered Chapters is enabled, then the Matroska Player MUST play those Chapters in their stored order from the timestamp marked in the ChapterTimeStart element to the timestamp marked in to ChapterTimeEnd element.

If the EditionFlagOrdered flag evaluates to "0", Simple Chapters are used and only the ChapterTimeStart of a Chapter is used as a chapter mark to jump to the predefined point in the timeline. With Simple Chapters, a Matroska Player MUST ignore certain elements inside a Chapters element. In that case, these elements are informational only.

The following list shows the different Chapters elements only found in Ordered Chapters.

  • ChapterAtom\ChapterSegmentUUID

  • ChapterAtom\ChapterSegmentEditionUID

  • ChapterAtom\ChapProcess

  • Info\ChapterTranslate

  • TrackEntry\TrackTranslate

Furthermore, there are other EBML elements that could be used if the EditionFlagOrdered evaluates to "1".

20.1.3.1. Ordered-Edition and Matroska Segment Linking
Hard Linking:

Ordered Chapters supersede the Hard Linking.

Medium Linking:

Ordered Chapters are used in a normal way and can be combined with the ChapterSegmentUUID element, which establishes a link to another Segment.

See Section 17 on Linked Segments for more information about Hard Linking and Medium Linking.

20.2. ChapterAtom

The ChapterAtom is also called a Chapter.

20.2.1. ChapterTimeStart

ChapterTimeStart is the timestamp of the start of Chapter with nanosecond accuracy and is not scaled by TimestampScale. For Simple Chapters, this is the position of the chapter markers in the timeline.

20.2.2. ChapterTimeEnd

ChapterTimeEnd is the timestamp of the end of Chapter with nanosecond accuracy and is not scaled by TimestampScale. The timestamp defined by the ChapterTimeEnd is not part of the Chapter. A Matroska Player calculates the duration of this Chapter using the difference between the ChapterTimeEnd and ChapterTimeStart. The end timestamp MUST be greater than or equal to the start timestamp.

When the ChapterTimeEnd timestamp is equal to the ChapterTimeStart timestamp, the timestamp is included in the Chapter. It can be useful to put markers in a file or add chapter commands with ordered chapter commands without having to play anything; see Section 5.1.7.1.4.14.

Table 49: ChapterTimeEnd Usage Possibilities
Chapter Start timestamp End timestamp Duration
Chapter 1 0 1000000000 1000000000
Chapter 2 1000000000 5000000000 4000000000
Chapter 3 6000000000 6000000000 0
Chapter 4 9000000000 8000000000 Invalid (-1000000000)

20.2.3. Nested Chapters

A ChapterAtom element can contain other ChapterAtom elements. That element is a Parent Chapter, and the ChapterAtom elements it contains are Nested Chapters.

Nested Chapters can be useful to tag small parts of a Segment that already have tags or add Chapter Codec commands on smaller parts of a Segment that already have Chapter Codec commands.

The ChapterTimeStart of a Nested Chapter MUST be greater than or equal to the ChapterTimeStart of its Parent Chapter.

If the Parent Chapter of a Nested Chapter has a ChapterTimeEnd, the ChapterTimeStart of that Nested Chapter MUST be smaller than or equal to the ChapterTimeEnd of the Parent Chapter.

20.2.4. Nested Chapters in Ordered Chapters

The ChapterTimeEnd of the lowest level of Nested Chapters MUST be set for Ordered Chapters.

When used with Ordered Chapters, the ChapterTimeEnd value of a Parent Chapter is useless for playback, as the proper playback sections are described in its Nested Chapters. The ChapterTimeEnd SHOULD NOT be set in Parent Chapters and MUST be ignored for playback.

20.2.5. ChapterFlagHidden

Each Chapter's ChapterFlagHidden flag works independently of Parent Chapters. A Nested Chapter with a ChapterFlagHidden flag that evaluates to "0" remains visible in the user interface even if the Parent Chapter's ChapterFlagHidden flag is set to "1".

Table 50: ChapterFlagHidden Nested Visibility
Chapter + Nested Chapter ChapterFlagHidden visible
Chapter 1 0 yes
Nested Chapter 1.1 0 yes
Nested Chapter 1.2 1 no
Chapter 2 1 no
Nested Chapter 2.1 0 yes
Nested Chapter 2.2 1 no

20.4. Physical Types

Each level can have different meanings for audio and video. The ORIGINAL_MEDIA_TYPE tag [I-D.ietf-cellar-tags] can be used to specify a string for ChapterPhysicalEquiv = 60. Here is the list of possible levels for both audio and video:

Table 51: ChapterPhysicalEquiv Meaning per Track Type
Value Audio Video Comment
70 SET / PACKAGE SET / PACKAGE the collection of different media
60 CD / 12" / 10" / 7" / TAPE / MINIDISC / DAT DVD / VHS / LASERDISC the physical medium like a CD or a DVD
50 SIDE SIDE when the original medium (LP/DVD) has different sides
40 - LAYER another physical level on DVDs
30 SESSION SESSION as found on CDs and DVDs
20 TRACK - as found on audio CDs
10 INDEX - the first logical level of the side/medium

20.5. Chapter Examples

20.5.1. Example 1: Basic Chaptering

In this example, a movie is split in different chapters. It could also just be an audio file (album) in which each track corresponds to a chapter.

  • 00000 ms - 05000 ms: Intro
  • 05000 ms - 25000 ms: Before the crime
  • 25000 ms - 27500 ms: The crime
  • 27500 ms - 38000 ms: After the crime
  • 38000 ms - 43000 ms: Credits

This translates to Matroska form, with the EBML tree shown as follows in XML:

&lt;Chapters&gt;
  &lt;EditionEntry&gt;
    &lt;EditionUID&gt;16603393396715046047&lt;/EditionUID&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;1193046&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;0&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;5000000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Intro&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;2311527&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;5000000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;25000000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Before the crime&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Avant le crime&lt;/ChapString&gt;
        &lt;ChapLanguage&gt;fra&lt;/ChapLanguage&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;3430008&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;25000000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;27500000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;The crime&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Le crime&lt;/ChapString&gt;
        &lt;ChapLanguage&gt;fra&lt;/ChapLanguage&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;4548489&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;27500000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;38000000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;After the crime&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Apres le crime&lt;/ChapString&gt;
        &lt;ChapLanguage&gt;fra&lt;/ChapLanguage&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;5666960&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;38000000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;43000000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Credits&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Generique&lt;/ChapString&gt;
        &lt;ChapLanguage&gt;fra&lt;/ChapLanguage&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
  &lt;/EditionEntry&gt;
&lt;/Chapters&gt;
Figure 25: Basic Chapters Example

20.5.2. Example 2: Nested Chapters

In this example, an (existing) album is split into different chapters, and one of them contains another splitting.

20.5.2.1. The Micronauts "Bleep To Bleep"
  • 00:00 - 12:28: Baby wants to Bleep/Rock

    • 00:00 - 04:38: Baby wants to bleep (pt.1)
    • 04:38 - 07:12: Baby wants to rock
    • 07:12 - 10:33: Baby wants to bleep (pt.2)
    • 10:33 - 12:28: Baby wants to bleep (pt.3)
  • 12:30 - 19:38: Bleeper_O+2
  • 19:40 - 22:20: Baby wants to bleep (pt.4)
  • 22:22 - 25:18: Bleep to bleep
  • 25:20 - 33:35: Baby wants to bleep (k)
  • 33:37 - 44:28: Bleeper

This translates to Matroska form, with the EBML tree shown as follows in XML:

&lt;Chapters&gt;
  &lt;EditionEntry&gt;
    &lt;EditionUID&gt;1281690858003401414&lt;/EditionUID&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;1&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;0&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;748000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Baby wants to Bleep/Rock&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
      &lt;ChapterAtom&gt;
        &lt;ChapterUID&gt;2&lt;/ChapterUID&gt;
        &lt;ChapterTimeStart&gt;0&lt;/ChapterTimeStart&gt;
        &lt;ChapterTimeEnd&gt;278000000&lt;/ChapterTimeEnd&gt;
        &lt;ChapterDisplay&gt;
          &lt;ChapString&gt;Baby wants to bleep (pt.1)&lt;/ChapString&gt;
        &lt;/ChapterDisplay&gt;
      &lt;/ChapterAtom&gt;
      &lt;ChapterAtom&gt;
        &lt;ChapterUID&gt;3&lt;/ChapterUID&gt;
        &lt;ChapterTimeStart&gt;278000000&lt;/ChapterTimeStart&gt;
        &lt;ChapterTimeEnd&gt;432000000&lt;/ChapterTimeEnd&gt;
        &lt;ChapterDisplay&gt;
          &lt;ChapString&gt;Baby wants to rock&lt;/ChapString&gt;
        &lt;/ChapterDisplay&gt;
      &lt;/ChapterAtom&gt;
      &lt;ChapterAtom&gt;
        &lt;ChapterUID&gt;4&lt;/ChapterUID&gt;
        &lt;ChapterTimeStart&gt;432000000&lt;/ChapterTimeStart&gt;
        &lt;ChapterTimeEnd&gt;633000000&lt;/ChapterTimeEnd&gt;
        &lt;ChapterDisplay&gt;
          &lt;ChapString&gt;Baby wants to bleep (pt.2)&lt;/ChapString&gt;
        &lt;/ChapterDisplay&gt;
      &lt;/ChapterAtom&gt;
      &lt;ChapterAtom&gt;
        &lt;ChapterUID&gt;5&lt;/ChapterUID&gt;
        &lt;ChapterTimeStart&gt;633000000&lt;/ChapterTimeStart&gt;
        &lt;ChapterTimeEnd&gt;748000000&lt;/ChapterTimeEnd&gt;
        &lt;ChapterDisplay&gt;
          &lt;ChapString&gt;Baby wants to bleep (pt.3)&lt;/ChapString&gt;
        &lt;/ChapterDisplay&gt;
      &lt;/ChapterAtom&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;6&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;750000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;1178500000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Bleeper_O+2&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;7&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;1180500000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;1340000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Baby wants to bleep (pt.4)&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;8&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;1342000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;1518000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Bleep to bleep&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;9&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;1520000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;2015000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Baby wants to bleep (k)&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
    &lt;ChapterAtom&gt;
      &lt;ChapterUID&gt;10&lt;/ChapterUID&gt;
      &lt;ChapterTimeStart&gt;2017000000&lt;/ChapterTimeStart&gt;
      &lt;ChapterTimeEnd&gt;2668000000&lt;/ChapterTimeEnd&gt;
      &lt;ChapterDisplay&gt;
        &lt;ChapString&gt;Bleeper&lt;/ChapString&gt;
      &lt;/ChapterDisplay&gt;
    &lt;/ChapterAtom&gt;
  &lt;/EditionEntry&gt;
&lt;/Chapters&gt;
Figure 26: Nested Chapters Example

21. Attachments

Matroska supports storage of related files and data in the Attachments element (a Top-Level Element). Attachments elements can be used to store related cover art, font files, transcripts, reports, error recovery files, pictures, text-based annotations, copies of specifications, or other ancillary files related to the Segment.

Matroska Readers MUST NOT execute files stored as Attachments elements.

21.1. Cover Art

This section defines a set of guidelines for the storage of cover art in Matroska files. A Matroska Reader MAY use embedded cover art to display a representational still-image depiction of the multimedia contents of the Matroska file.

Only [JPEG] and PNG [RFC2083] image formats SHOULD be used for cover art pictures.

There can be two different covers for a movie/album: a portrait style (e.g., a DVD case) and a landscape style (e.g., a wide banner ad).

There can be two versions of the same cover: the normal cover and the small cover. The dimension of the normal cover SHOULD be 600 pixels on the smallest side (e.g., 960x600 for landscape, 600x800 for portrait, or 600x600 for square). The dimension of the small cover SHOULD be 120 pixels on the smallest side (e.g., 192x120 or 120x160).

Versions of cover art can be differentiated by the filename, which is stored in the FileName element. The default filename of the normal cover in square or portrait mode is cover.(jpg|png). When stored, the normal cover SHOULD be the first Attachments element in storage order. The small cover SHOULD be prefixed with "small_", such as small_cover.(jpg|png). The landscape variant SHOULD be suffixed with "_land", such as cover_land.(jpg|png). The filenames are case-sensitive.

The following table provides examples of file names for cover art in Attachments.

Table 52: Cover Art Filenames
File Name Image Orientation Pixel Length of Smallest Side
cover.jpg Portrait or square 600
small_cover.png Portrait or square 120
cover_land.png Landscape 600
small_cover_land.jpg Landscape 120

21.2. Font Files

Font files MAY be added to a Matroska file as Attachments so that the font file may be used to display an associated subtitle track. This allows the presentation of a Matroska file to be consistent in various environments where the needed fonts might not be available on the local system.

Depending on the font format in question, each font file can contain multiple font variants. Each font variant has a name that will be referred to as Font Name from now on. This Font Name can be different from the Attachment's FileName, even when disregarding the extension. In order to select a font for display, a Matroska Player SHOULD consider both the Font Name and the base name of the Attachment's FileName, preferring the former when there are multiple matches.

Subtitle codecs, such as SubStation Alpha (SSA) and Advanced SubStation Alpha (ASS), usually refer to a font by its Font Name, not by its filename. If none of the Attachments are a match for the Font Name, the Matroska Player SHOULD attempt to find a system font whose Font Name matches the one used in the subtitle track.

Since loading fonts temporarily can take a while, a Matroska Player usually loads or installs all the fonts found in attachments so they are ready to be used during playback. Failure to use the font attachment might result in incorrect rendering of the subtitles.

If a selected subtitle track has some AttachmentLink elements, the player MAY restrict its font rendering to use only these fonts.

A Matroska Player SHOULD handle the official font media types from [RFC8081] when the system can handle the type:

  • font/sfnt: Generic SFNT Font Type

  • font/ttf: TrueType Font (TTF) Font Type

  • font/otf: OpenType Layout (OTF) Font Type

  • font/collection: Collection Font Type

  • font/woff: WOFF 1.0

  • font/woff2: WOFF 2.0

Fonts in Matroska existed long before [RFC8081]. A few unofficial media types for fonts were used in existing files. Therefore, it is RECOMMENDED for a Matroska Player to support the following legacy media types for font attachments:

  • application/x-truetype-font: TrueType fonts, equivalent to font/ttf and sometimes font/otf

  • application/x-font-ttf: TrueType fonts, equivalent to font/ttf

  • application/vnd.ms-opentype: OpenType Layout fonts, equivalent to font/otf

  • application/font-sfnt: Generic SFNT Font Type, equivalent to font/sfnt

  • application/font-woff: WOFF 1.0, equivalent to font/woff

There may also be some font attachments with the application/octet-stream media type. In that case, the Matroska Player MAY try to guess the font type by checking the file extension of the AttachedFile\FileName string. Common file extensions for fonts are:

  • .ttf for TrueType fonts, equivalent to font/ttf

  • .otf for OpenType Layout fonts, equivalent to font/otf

  • .ttc for Collection fonts, equivalent to font/collection

The file extension check MUST be case-insensitive.

Matroska Writers SHOULD use a valid font media type from [RFC8081] in the AttachedFile\FileMediaType of the font attachment. They MAY use the media types found in older files when compatibility with older players is necessary.

22. Cues

The Cues element provides an index of certain Cluster elements to allow for optimized seeking to absolute timestamps within the Segment. The Cues element contains one or many CuePoint elements, each of which MUST reference an absolute timestamp (via the CueTime element), a Track (via the CueTrack element), and a Segment Position (via the CueClusterPosition element). Additional non-mandated elements are part of the CuePoint element, such as CueDuration, CueRelativePosition, CueCodecState, and others that provide any Matroska Reader with additional information to use in the optimization of seeking performance.

22.1. Recommendations

The following recommendations are provided to optimize Matroska performance.

  • Unless Matroska is used as a live stream, it SHOULD contain a Cues element.

  • For each video track, each keyframe SHOULD be referenced by a CuePoint element.

  • It is RECOMMENDED to not reference non-keyframes of video tracks in Cues unless it references a Cluster element that contains a CodecState element but no keyframes.

  • For each subtitle track present, each subtitle frame SHOULD be referenced by a CuePoint element with a CueDuration element.

  • References to audio tracks MAY be skipped in CuePoint elements if a video track is present. When included, the CuePoint elements SHOULD reference audio keyframes once every 500 milliseconds at most.

  • If the referenced frame is not stored within the first SimpleBlock or first BlockGroup within its Cluster element, then the CueRelativePosition element SHOULD be written to reference where in the Cluster the reference frame is stored.

  • If a CuePoint element references a Cluster element that includes a CodecState element, then that CuePoint element MUST use a CueCodecState element.

  • CuePoint elements SHOULD be numerically sorted in storage order by the value of the CueTime element.

23. Matroska Streaming

In Matroska, there are two kinds of streaming: file access and livestreaming.

23.1. File Access

File access can simply be reading a file located on your computer, but it also includes accessing a file from an HTTP (web) server or Common Internet File System (CIFS) (Windows share) server. These protocols are usually safe from reading errors, and seeking in the stream is possible. However, when a file is stored far away or on a slow server, seeking can be an expensive operation and should be avoided. When followed, the guidelines in Section 25 help reduce the number of seeking operations for regular playback and also have the playback start quickly without needing to read lot of data first (like a Cues element, Attachments element, or SeekHead element).

Matroska, having a small overhead, is well suited for storing music/videos on file servers without a big impact on the bandwidth used. Matroska does not require the index to be loaded before playing, which allows playback to start very quickly. The index can be loaded only when seeking is requested the first time.

23.2. Livestreaming

Livestreaming is the equivalent of television broadcasting on the Internet. There are two families of servers for livestreaming: RTP / Real-Time Streaming Protocol (RTSP) and HTTP. Matroska is not meant to be used over RTP. RTP already has timing and channel mechanisms that would be wasted if doubled in Matroska. Additionally, having the same information at the RTP and Matroska level would be a source of confusion if they do not match. Livestreaming of Matroska over file-like protocols like HTTP, QUIC, etc., is possible.

A live Matroska stream is different from a file because it usually has no known end (only ending when the client disconnects). For this, all bits of the "size" portion of the Segment element MUST be set to 1. Another option is to concatenate Segment elements with known sizes, one after the other. This solution allows a change of codec/resolution between each segment. For example, this allows for a switch between 4:3 and 16:9 in a television program.

When Segment elements are continuous, certain elements (like SeekHead, Cues, Chapters, and Attachments) MUST NOT be used.

It is possible for a Matroska Player to detect that a stream is not seekable. If the stream has neither a SeekHead list nor a Cues list at the beginning of the stream, it SHOULD be considered non-seekable. Even though it is possible to seek forward in the stream, it is NOT RECOMMENDED.

In the context of live radio or web TV, it is possible to "tag" the content while it is playing. The Tags element can be placed between Clusters each time it is necessary. In that case, the new Tags element MUST reset the previously encountered Tags elements and use the new values instead.

24. Tags

24.1. Tags Precedence

Tags allow tagging all kinds of Matroska parts with very detailed metadata in multiple languages.

Some Matroska elements also contain their own string value, like the track Name element (Section 5.1.4.1.18) or the ChapString element (Section 5.1.7.1.4.10).

The following Matroska elements can also be defined with tags:

When both values exist in the file, the value found in Tags takes precedence over the value found in the original location of the element. For example, if you have a TrackEntry\Name element and a tag value TITLE for that track in a Matroska Segment, the tag value string SHOULD be used instead of the TrackEntry\Name string to identify the track.

As the Tag element is optional, a lot of Matroska Readers do not handle it and will not use the tags value when it's found. Thus, for maximum compatibility, it's usually better to put the strings in the TrackEntry, ChapterAtom, and Attachments elements and keep the tags matching these values if tags are also used.

24.2. Tag Levels

Tag elements allow tagging information on multiple levels, with each level having a TargetTypeValue Section 5.1.8.1.1.1. An element for a given TargetTypeValue also applies to the lower levels denoted by smaller TargetTypeValue values. If an upper value doesn't apply to a level but the actual value to use is not known, an empty TagString (Section 5.1.8.1.2.5) or an empty TagBinary (Section 5.1.8.1.2.6) MUST be used as the tag value for this level.

See [I-D.ietf-cellar-tags] for more details on common tag names, types, and descriptions.

25. Implementation Recommendations

25.1. Cluster

It is RECOMMENDED that each individual Cluster element contain no more than five seconds or five megabytes of content.

25.2. SeekHead

It is RECOMMENDED that the first SeekHead element be followed by a Void element to allow for the SeekHead element to be expanded to cover new Top-Level Elements that could be added to the Matroska file, such as Tags, Chapters, and Attachments elements.

The size of this Void element should be adjusted depending on the Tags, Chapters, and Attachments elements in the Matroska file.

25.3. Optimum Layouts

While there can be Top-Level Elements in any order, some orderings of elements are better than others. The following subsections detail optimum layouts for different use cases.

25.3.1. Optimum Layout for a Muxer

This is the basic layout muxers should be using for an efficient playback experience:

25.3.2. Optimum Layout after Editing Tags

When tags from the previous layout need to be extended, they are moved to the end with the extra information. The location where the old tags were located is voided.

25.3.3. Optimum Layout with Cues at the Front

Cues are usually a big chunk of data referencing a lot of locations in the file. Players that want to seek in the file need to seek to the end of the file to access these locations. It is often better if they are placed early in the file. On the other hand, that means players that don't intend to seek will have to read/skip these data no matter what.

Because the Cues reference locations further in the file, it's often complicated to allocate the proper space for that element before all the locations are known. Therefore, this layout is rarely used:

25.3.4. Optimum Layout for Livestreaming

In livestreaming (Section 23.2), only a few elements make sense. For example, SeekHead and Cues are useless. All elements other than the Clusters MUST be placed before the Clusters.

  • Info
  • Tracks
  • Attachments (rare)
  • Tags
  • Clusters

26. Security Considerations

Matroska inherits security considerations from EBML [RFC8794].

Attacks on a Matroska Reader could include:

The same error handling done for EBML applies to Matroska files. Particular error handling is not covered in this specification, as this is depends on the goal of the Matroska Readers. Matroska Readers decide how to handle the errors whether or not they are recoverable in their code. For example, if the checksum of the \Segment\Tracks is invalid, some could decide to try to read the data anyway, some will just reject the file, and most will not even check it.

Matroska Reader implementations need to be robust against malicious payloads. Those related to denial of service are outlined in Section 2.1 of [RFC4732].

Although rarer, the same may apply to a Matroska Writer. Malicious stream data must not cause the Matroska Writer to misbehave, as this might allow an attacker access to transcoding gateways.

As an audio/video container format, a Matroska file or stream will potentially encapsulate numerous byte streams created with a variety of codecs. Implementers will need to consider the security considerations of these encapsulated formats.

27. IANA Considerations

27.1. Matroska Element IDs Registry

IANA has created a new registry called the "Matroska Element IDs" registry.

To register a new Element ID in this registry, one needs an Element ID, an Element Name, a Change Controller, and an optional Reference to a document describing the Element ID.

Element IDs are encoded using the VINT mechanism described in Section 4 of [RFC8794] and can be between one and five octets long. Five-octet Element IDs are possible only if declared in the EBML Header.

Element IDs are described in Section 5 of [RFC8794], with the changes in [Err7189] and [Err7191].

One-octet Matroska Element IDs (range 0x80-0xFE) are to be allocated according to the "RFC Required" policy [RFC8126].

Two-octet Matroska Element IDs (range 0x407F-0x7FFE) are to be allocated according to the "Specification Required" policy [RFC8126].

Two-octet Matroska Element IDs between 0x0100 and 0x407E are not valid for use as an Element ID.

Three-octet (range 0x203FFF-0x3FFFFE) and four-octet Matroska Element IDs (range 0x101FFFFF-0x1FFFFFFE) are to be allocated according to the "First Come First Served" policy [RFC8126].

Three-octet Matroska Element IDs between 0x010000 and 0x203FFE are not valid for use as an Element ID.

Four-octet Matroska Element IDs between 0x01000000 and 0x101FFFFE are not valid for use as an Element ID.

The allowed values in the "Matroska Element IDs" registry are similar to the ones found in the "EBML Element IDs" registry defined in Section 17.1 of [RFC8794].

EBML Element IDs defined for the EBML Header -- as defined in Section 17.1 of [RFC8794] -- MUST NOT be used as Matroska Element IDs.

Given the scarcity of one-octet Element IDs, they should only be created to save space for elements found many times in a file (for example, BlockGroup or Chapters). The four-octet Element IDs are mostly for synchronization of large elements. They should only be used for such high-level elements. Elements that are not expected to be used often should use three-octet Element IDs.

Elements found in Appendix A have an assigned Matroska Element ID for historical reasons. These elements are not in use and SHOULD NOT be reused unless there are no other IDs available with the desired size. Such IDs are marked as "Reclaimed" in the "Matroska Element IDs" registry, as they could be used for other things in the future.

Table 53 shows the initial contents of the "Matroska Element IDs" registry. The Change Controller for the initial entries is the IETF.

Table 53: Initial Contents of "Matroska Element IDs" Registry
Element ID Element Name Reference
0x80 ChapterDisplay RFC 9559, Section 5.1.7.1.4.9
0x83 TrackType RFC 9559, Section 5.1.4.1.3
0x85 ChapString RFC 9559, Section 5.1.7.1.4.10
0x86 CodecID RFC 9559, Section 5.1.4.1.21
0x88 FlagDefault RFC 9559, Section 5.1.4.1.5
0x8E Slices Reclaimed (RFC 9559, Appendix A.5)
0x91 ChapterTimeStart RFC 9559, Section 5.1.7.1.4.3
0x92 ChapterTimeEnd RFC 9559, Section 5.1.7.1.4.4
0x96 CueRefTime RFC 9559, Section 5.1.5.1.2.8
0x97 CueRefCluster Reclaimed (RFC 9559, Appendix A.37)
0x98 ChapterFlagHidden RFC 9559, Section 5.1.7.1.4.5
0x9A FlagInterlaced RFC 9559, Section 5.1.4.1.28.1
0x9B BlockDuration RFC 9559, Section 5.1.3.5.3
0x9C FlagLacing RFC 9559, Section 5.1.4.1.12
0x9D FieldOrder RFC 9559, Section 5.1.4.1.28.2
0x9F Channels RFC 9559, Section 5.1.4.1.29.3
0xA0 BlockGroup RFC 9559, Section 5.1.3.5
0xA1 Block RFC 9559, Section 5.1.3.5.1
0xA2 BlockVirtual Reclaimed (RFC 9559, Appendix A.3)
0xA3 SimpleBlock RFC 9559, Section 5.1.3.4
0xA4 CodecState RFC 9559, Section 5.1.3.5.6
0xA5 BlockAdditional RFC 9559, Section 5.1.3.5.2.2
0xA6 BlockMore RFC 9559, Section 5.1.3.5.2.1
0xA7 Position RFC 9559, Section 5.1.3.2
0xAA CodecDecodeAll Reclaimed (RFC 9559, Appendix A.22)
0xAB PrevSize RFC 9559, Section 5.1.3.3
0xAE TrackEntry RFC 9559, Section 5.1.4.1
0xAF EncryptedBlock Reclaimed (RFC 9559, Appendix A.15)
0xB0 PixelWidth RFC 9559, Section 5.1.4.1.28.6
0xB2 CueDuration RFC 9559, Section 5.1.5.1.2.4
0xB3 CueTime RFC 9559, Section 5.1.5.1.1
0xB5 SamplingFrequency RFC 9559, Section 5.1.4.1.29.1
0xB6 ChapterAtom RFC 9559, Section 5.1.7.1.4
0xB7 CueTrackPositions RFC 9559, Section 5.1.5.1.2
0xB9 FlagEnabled RFC 9559, Section 5.1.4.1.4
0xBA PixelHeight RFC 9559, Section 5.1.4.1.28.7
0xBB CuePoint RFC 9559, Section 5.1.5.1
0xC0 TrickTrackUID Reclaimed (RFC 9559, Appendix A.28)
0xC1 TrickTrackSegmentUID Reclaimed (RFC 9559, Appendix A.29)
0xC4 TrickMasterTrackSegmentUID Reclaimed (RFC 9559, Appendix A.32)
0xC6 TrickTrackFlag Reclaimed (RFC 9559, Appendix A.30)
0xC7 TrickMasterTrackUID Reclaimed (RFC 9559, Appendix A.31)
0xC8 ReferenceFrame Reclaimed (RFC 9559, Appendix A.12)
0xC9 ReferenceOffset Reclaimed (RFC 9559, Appendix A.13)
0xCA ReferenceTimestamp Reclaimed (RFC 9559, Appendix A.14)
0xCB BlockAdditionID Reclaimed (RFC 9559, Appendix A.9)
0xCC LaceNumber Reclaimed (RFC 9559, Appendix A.7)
0xCD FrameNumber Reclaimed (RFC 9559, Appendix A.8)
0xCE Delay Reclaimed (RFC 9559, Appendix A.10)
0xCF SliceDuration Reclaimed (RFC 9559, Appendix A.11)
0xD7 TrackNumber RFC 9559, Section 5.1.4.1.1
0xDB CueReference RFC 9559, Section 5.1.5.1.2.7
0xE0 Video RFC 9559, Section 5.1.4.1.28
0xE1 Audio RFC 9559, Section 5.1.4.1.29
0xE2 TrackOperation RFC 9559, Section 5.1.4.1.30
0xE3 TrackCombinePlanes RFC 9559, Section 5.1.4.1.30.1
0xE4 TrackPlane RFC 9559, Section 5.1.4.1.30.2
0xE5 TrackPlaneUID RFC 9559, Section 5.1.4.1.30.3
0xE6 TrackPlaneType RFC 9559, Section 5.1.4.1.30.4
0xE7 Timestamp RFC 9559, Section 5.1.3.1
0xE8 TimeSlice Reclaimed (RFC 9559, Appendix A.6)
0xE9 TrackJoinBlocks RFC 9559, Section 5.1.4.1.30.5
0xEA CueCodecState RFC 9559, Section 5.1.5.1.2.6
0xEB CueRefCodecState Reclaimed (RFC 9559, Appendix A.39)
0xED TrackJoinUID RFC 9559, Section 5.1.4.1.30.6
0xEE BlockAddID RFC 9559, Section 5.1.3.5.2.3
0xF0 CueRelativePosition RFC 9559, Section 5.1.5.1.2.3
0xF1 CueClusterPosition RFC 9559, Section 5.1.5.1.2.2
0xF7 CueTrack RFC 9559, Section 5.1.5.1.2.1
0xFA ReferencePriority RFC 9559, Section 5.1.3.5.4
0xFB ReferenceBlock RFC 9559, Section 5.1.3.5.5
0xFD ReferenceVirtual Reclaimed (RFC 9559, Appendix A.4)
0xFF Reserved RFC 9559
0x41A4 BlockAddIDName RFC 9559, Section 5.1.4.1.17.2
0x41E4 BlockAdditionMapping RFC 9559, Section 5.1.4.1.17
0x41E7 BlockAddIDType RFC 9559, Section 5.1.4.1.17.3
0x41ED BlockAddIDExtraData RFC 9559, Section 5.1.4.1.17.4
0x41F0 BlockAddIDValue RFC 9559, Section 5.1.4.1.17.1
0x4254 ContentCompAlgo RFC 9559, Section 5.1.4.1.31.6
0x4255 ContentCompSettings RFC 9559, Section 5.1.4.1.31.7
0x437C ChapLanguage RFC 9559, Section 5.1.7.1.4.11
0x437D ChapLanguageBCP47 RFC 9559, Section 5.1.7.1.4.12
0x437E ChapCountry RFC 9559, Section 5.1.7.1.4.13
0x4444 SegmentFamily RFC 9559, Section 5.1.2.7
0x4461 DateUTC RFC 9559, Section 5.1.2.11
0x447A TagLanguage RFC 9559, Section 5.1.8.1.2.2
0x447B TagLanguageBCP47 RFC 9559, Section 5.1.8.1.2.3
0x4484 TagDefault RFC 9559, Section 5.1.8.1.2.4
0x4485 TagBinary RFC 9559, Section 5.1.8.1.2.6
0x4487 TagString RFC 9559, Section 5.1.8.1.2.5
0x4489 Duration RFC 9559, Section 5.1.2.10
0x44B4 TagDefaultBogus Reclaimed (RFC 9559, Appendix A.43)
0x450D ChapProcessPrivate RFC 9559, Section 5.1.7.1.4.16
0x45A3 TagName RFC 9559, Section 5.1.8.1.2.1
0x45B9 EditionEntry RFC 9559, Section 5.1.7.1
0x45BC EditionUID RFC 9559, Section 5.1.7.1.1
0x45DB EditionFlagDefault RFC 9559, Section 5.1.7.1.2
0x45DD EditionFlagOrdered RFC 9559, Section 5.1.7.1.3
0x465C FileData RFC 9559, Section 5.1.6.1.4
0x4660 FileMediaType RFC 9559, Section 5.1.6.1.3
0x4661 FileUsedStartTime Reclaimed (RFC 9559, Appendix A.41)
0x4662 FileUsedEndTime Reclaimed (RFC 9559, Appendix A.42)
0x466E FileName RFC 9559, Section 5.1.6.1.2
0x4675 FileReferral Reclaimed (RFC 9559, Appendix A.40)
0x467E FileDescription RFC 9559, Section 5.1.6.1.1
0x46AE FileUID RFC 9559, Section 5.1.6.1.5
0x47E1 ContentEncAlgo RFC 9559, Section 5.1.4.1.31.9
0x47E2 ContentEncKeyID RFC 9559, Section 5.1.4.1.31.10
0x47E3 ContentSignature Reclaimed (RFC 9559, Appendix A.33)
0x47E4 ContentSigKeyID Reclaimed (RFC 9559, Appendix A.34)
0x47E5 ContentSigAlgo Reclaimed (RFC 9559, Appendix A.35)
0x47E6 ContentSigHashAlgo Reclaimed (RFC 9559, Appendix A.36)
0x47E7 ContentEncAESSettings RFC 9559, Section 5.1.4.1.31.11
0x47E8 AESSettingsCipherMode RFC 9559, Section 5.1.4.1.31.12
0x4D80 MuxingApp RFC 9559, Section 5.1.2.13
0x4DBB Seek RFC 9559, Section 5.1.1.1
0x5031 ContentEncodingOrder RFC 9559, Section 5.1.4.1.31.2
0x5032 ContentEncodingScope RFC 9559, Section 5.1.4.1.31.3
0x5033 ContentEncodingType RFC 9559, Section 5.1.4.1.31.4
0x5034 ContentCompression RFC 9559, Section 5.1.4.1.31.5
0x5035 ContentEncryption RFC 9559, Section 5.1.4.1.31.8
0x535F CueRefNumber Reclaimed (RFC 9559, Appendix A.38)
0x536E Name RFC 9559, Section 5.1.4.1.18
0x5378 CueBlockNumber RFC 9559, Section 5.1.5.1.2.5
0x537F TrackOffset Reclaimed (RFC 9559, Appendix A.18)
0x53AB SeekID RFC 9559, Section 5.1.1.1.1
0x53AC SeekPosition RFC 9559, Section 5.1.1.1.2
0x53B8 StereoMode RFC 9559, Section 5.1.4.1.28.3
0x53B9 OldStereoMode RFC 9559, Section 5.1.4.1.28.5
0x53C0 AlphaMode RFC 9559, Section 5.1.4.1.28.4
0x54AA PixelCropBottom RFC 9559, Section 5.1.4.1.28.8
0x54B0 DisplayWidth RFC 9559, Section 5.1.4.1.28.12
0x54B2 DisplayUnit RFC 9559, Section 5.1.4.1.28.14
0x54B3 AspectRatioType Reclaimed (RFC 9559, Appendix A.24)
0x54BA DisplayHeight RFC 9559, Section 5.1.4.1.28.13
0x54BB PixelCropTop RFC 9559, Section 5.1.4.1.28.9
0x54CC PixelCropLeft RFC 9559, Section 5.1.4.1.28.10
0x54DD PixelCropRight RFC 9559, Section 5.1.4.1.28.11
0x55AA FlagForced RFC 9559, Section 5.1.4.1.6
0x55AB FlagHearingImpaired RFC 9559, Section 5.1.4.1.7
0x55AC FlagVisualImpaired RFC 9559, Section 5.1.4.1.8
0x55AD FlagTextDescriptions RFC 9559, Section 5.1.4.1.9
0x55AE FlagOriginal RFC 9559, Section 5.1.4.1.10
0x55AF FlagCommentary RFC 9559, Section 5.1.4.1.11
0x55B0 Colour RFC 9559, Section 5.1.4.1.28.16
0x55B1 MatrixCoefficients RFC 9559, Section 5.1.4.1.28.17
0x55B2 BitsPerChannel RFC 9559, Section 5.1.4.1.28.18
0x55B3 ChromaSubsamplingHorz RFC 9559, Section 5.1.4.1.28.19
0x55B4 ChromaSubsamplingVert RFC 9559, Section 5.1.4.1.28.20
0x55B5 CbSubsamplingHorz RFC 9559, Section 5.1.4.1.28.21
0x55B6 CbSubsamplingVert RFC 9559, Section 5.1.4.1.28.22
0x55B7 ChromaSitingHorz RFC 9559, Section 5.1.4.1.28.23
0x55B8 ChromaSitingVert RFC 9559, Section 5.1.4.1.28.24
0x55B9 Range RFC 9559, Section 5.1.4.1.28.25
0x55BA TransferCharacteristics RFC 9559, Section 5.1.4.1.28.26
0x55BB Primaries RFC 9559, Section 5.1.4.1.28.27
0x55BC MaxCLL RFC 9559, Section 5.1.4.1.28.28
0x55BD MaxFALL RFC 9559, Section 5.1.4.1.28.29
0x55D0 MasteringMetadata RFC 9559, Section 5.1.4.1.28.30
0x55D1 PrimaryRChromaticityX RFC 9559, Section 5.1.4.1.28.31
0x55D2 PrimaryRChromaticityY RFC 9559, Section 5.1.4.1.28.32
0x55D3 PrimaryGChromaticityX RFC 9559, Section 5.1.4.1.28.33
0x55D4 PrimaryGChromaticityY RFC 9559, Section 5.1.4.1.28.34
0x55D5 PrimaryBChromaticityX RFC 9559, Section 5.1.4.1.28.35
0x55D6 PrimaryBChromaticityY RFC 9559, Section 5.1.4.1.28.36
0x55D7 WhitePointChromaticityX RFC 9559, Section 5.1.4.1.28.37
0x55D8 WhitePointChromaticityY RFC 9559, Section 5.1.4.1.28.38
0x55D9 LuminanceMax RFC 9559, Section 5.1.4.1.28.39
0x55DA LuminanceMin RFC 9559, Section 5.1.4.1.28.40
0x55EE MaxBlockAdditionID RFC 9559, Section 5.1.4.1.16
0x5654 ChapterStringUID RFC 9559, Section 5.1.7.1.4.2
0x56AA CodecDelay RFC 9559, Section 5.1.4.1.25
0x56BB SeekPreRoll RFC 9559, Section 5.1.4.1.26
0x5741 WritingApp RFC 9559, Section 5.1.2.14
0x5854 SilentTracks Reclaimed (RFC 9559, Appendix A.1)
0x58D7 SilentTrackNumber Reclaimed (RFC 9559, Appendix A.2)
0x61A7 AttachedFile RFC 9559, Section 5.1.6.1
0x6240 ContentEncoding RFC 9559, Section 5.1.4.1.31.1
0x6264 BitDepth RFC 9559, Section 5.1.4.1.29.4
0x63A2 CodecPrivate RFC 9559, Section 5.1.4.1.22
0x63C0 Targets RFC 9559, Section 5.1.8.1.1
0x63C3 ChapterPhysicalEquiv RFC 9559, Section 5.1.7.1.4.8
0x63C4 TagChapterUID RFC 9559, Section 5.1.8.1.1.5
0x63C5 TagTrackUID RFC 9559, Section 5.1.8.1.1.3
0x63C6 TagAttachmentUID RFC 9559, Section 5.1.8.1.1.6
0x63C9 TagEditionUID RFC 9559, Section 5.1.8.1.1.4
0x63CA TargetType RFC 9559, Section 5.1.8.1.1.2
0x6624 TrackTranslate RFC 9559, Section 5.1.4.1.27
0x66A5 TrackTranslateTrackID RFC 9559, Section 5.1.4.1.27.1
0x66BF TrackTranslateCodec RFC 9559, Section 5.1.4.1.27.2
0x66FC TrackTranslateEditionUID RFC 9559, Section 5.1.4.1.27.3
0x67C8 SimpleTag RFC 9559, Section 5.1.8.1.2
0x68CA TargetTypeValue RFC 9559, Section 5.1.8.1.1.1
0x6911 ChapProcessCommand RFC 9559, Section 5.1.7.1.4.17
0x6922 ChapProcessTime RFC 9559, Section 5.1.7.1.4.18
0x6924 ChapterTranslate RFC 9559, Section 5.1.2.8
0x6933 ChapProcessData RFC 9559, Section 5.1.7.1.4.19
0x6944 ChapProcess RFC 9559, Section 5.1.7.1.4.14
0x6955 ChapProcessCodecID RFC 9559, Section 5.1.7.1.4.15
0x69A5 ChapterTranslateID RFC 9559, Section 5.1.2.8.1
0x69BF ChapterTranslateCodec RFC 9559, Section 5.1.2.8.2
0x69FC ChapterTranslateEditionUID RFC 9559, Section 5.1.2.8.3
0x6D80 ContentEncodings RFC 9559, Section 5.1.4.1.31
0x6DE7 MinCache Reclaimed (RFC 9559, Appendix A.16)
0x6DF8 MaxCache Reclaimed (RFC 9559, Appendix A.17)
0x6E67 ChapterSegmentUUID RFC 9559, Section 5.1.7.1.4.6
0x6EBC ChapterSegmentEditionUID RFC 9559, Section 5.1.7.1.4.7
0x6FAB TrackOverlay Reclaimed (RFC 9559, Appendix A.23)
0x7373 Tag RFC 9559, Section 5.1.8.1
0x7384 SegmentFilename RFC 9559, Section 5.1.2.2
0x73A4 SegmentUUID RFC 9559, Section 5.1.2.1
0x73C4 ChapterUID RFC 9559, Section 5.1.7.1.4.1
0x73C5 TrackUID RFC 9559, Section 5.1.4.1.2
0x7446 AttachmentLink RFC 9559, Section 5.1.4.1.24
0x75A1 BlockAdditions RFC 9559, Section 5.1.3.5.2
0x75A2 DiscardPadding RFC 9559, Section 5.1.3.5.7
0x7670 Projection RFC 9559, Section 5.1.4.1.28.41
0x7671 ProjectionType RFC 9559, Section 5.1.4.1.28.42
0x7672 ProjectionPrivate RFC 9559, Section 5.1.4.1.28.43
0x7673 ProjectionPoseYaw RFC 9559, Section 5.1.4.1.28.44
0x7674 ProjectionPosePitch RFC 9559, Section 5.1.4.1.28.45
0x7675 ProjectionPoseRoll RFC 9559, Section 5.1.4.1.28.46
0x78B5 OutputSamplingFrequency RFC 9559, Section 5.1.4.1.29.2
0x7BA9 Title RFC 9559, Section 5.1.2.12
0x7D7B ChannelPositions Reclaimed (RFC 9559, Appendix A.27)
0x7FFF Reserved RFC 9559
0x22B59C Language RFC 9559, Section 5.1.4.1.19
0x22B59D LanguageBCP47 RFC 9559, Section 5.1.4.1.20
0x23314F TrackTimestampScale RFC 9559, Section 5.1.4.1.15
0x234E7A DefaultDecodedFieldDuration RFC 9559, Section 5.1.4.1.14
0x2383E3 FrameRate Reclaimed (RFC 9559, Appendix A.26)
0x23E383 DefaultDuration RFC 9559, Section 5.1.4.1.13
0x258688 CodecName RFC 9559, Section 5.1.4.1.23
0x26B240 CodecDownloadURL Reclaimed (RFC 9559, Appendix A.21)
0x2AD7B1 TimestampScale RFC 9559, Section 5.1.2.9
0x2EB524 UncompressedFourCC RFC 9559, Section 5.1.4.1.28.15
0x2FB523 GammaValue Reclaimed (RFC 9559, Appendix A.25)
0x3A9697 CodecSettings Reclaimed (RFC 9559, Appendix A.19)
0x3B4040 CodecInfoURL Reclaimed (RFC 9559, Appendix A.20)
0x3C83AB PrevFilename RFC 9559, Section 5.1.2.4
0x3CB923 PrevUUID RFC 9559, Section 5.1.2.3
0x3E83BB NextFilename RFC 9559, Section 5.1.2.6
0x3EB923 NextUUID RFC 9559, Section 5.1.2.5
0x3FFFFF Reserved RFC 9559
0x1043A770 Chapters RFC 9559, Section 5.1.7
0x114D9B74 SeekHead RFC 9559, Section 5.1.1
0x1254C367 Tags RFC 9559, Section 5.1.8
0x1549A966 Info RFC 9559, Section 5.1.2
0x1654AE6B Tracks RFC 9559, Section 5.1.4
0x18538067 Segment RFC 9559, Section 5.1
0x1941A469 Attachments RFC 9559, Section 5.1.6
0x1C53BB6B Cues RFC 9559, Section 5.1.5
0x1F43B675 Cluster RFC 9559, Section 5.1.3
0x1FFFFFFF Reserved RFC 9559

27.2. Matroska Compression Algorithms Registry

IANA has created a new registry called the "Matroska Compression Algorithms" registry. The values correspond to the unsigned integer ContentCompAlgo value described in Section 5.1.4.1.31.6.

To register a new Compression Algorithm in this registry, one needs a Compression Algorithm value, a description, a Change Controller, and a Reference to a document describing the Compression Algorithm.

The Compression Algorithms are to be allocated according to the "Specification Required" policy [RFC8126].

Table 54 shows the initial contents of the "Matroska Compression Algorithms" registry. The Change Controller for the initial entries is the IETF.

Table 54: Initial Contents of "Matroska Compression Algorithms" Registry
Compression Algorithm Description Reference
0 zlib RFC 9559, Section 5.1.4.1.31.6
1 bzlib RFC 9559, Section 5.1.4.1.31.6
2 lzo1x RFC 9559, Section 5.1.4.1.31.6
3 Header Stripping RFC 9559, Section 5.1.4.1.31.6

27.3. Matroska Encryption Algorithms Registry

IANA has created a new registry called the "Matroska Encryption Algorithms" registry. The values correspond to the unsigned integer ContentEncAlgo value described in Section 5.1.4.1.31.9.

To register a new Encryption Algorithm in this registry, one needs an Encryption Algorithm value, a description, a Change Controller, and an optional Reference to a document describing the Encryption Algorithm.

The Encryption Algorithms are to be allocated according to the "First Come First Served" policy [RFC8126].

Table 55 shows the initial contents of the "Matroska Encryption Algorithms" registry. The Change Controller for the initial entries is the IETF.

Table 55: Initial Contents of "Matroska Encryption Algorithms" Registry
Encryption Algorithm Description Reference
0 Not encrypted RFC 9559, Section 5.1.4.1.31.9
1 DES RFC 9559, Section 5.1.4.1.31.9
2 3DES RFC 9559, Section 5.1.4.1.31.9
3 Twofish RFC 9559, Section 5.1.4.1.31.9
4 Blowfish RFC 9559, Section 5.1.4.1.31.9
5 AES RFC 9559, Section 5.1.4.1.31.9

27.4. Matroska AES Cipher Modes Registry

IANA has created a new registry called the "Matroska AES Cipher Modes" registry. The values correspond to the unsigned integer AESSettingsCipherMode value described in Section 5.1.4.1.31.12.

To register a new AES Cipher Mode in this registry, one needs an AES Cipher Mode value, a description, a Change Controller, and an optional Reference to a document describing the AES Cipher Mode.

The AES Cipher Modes are to be allocated according to the "First Come First Served" policy [RFC8126].

The value 0 is not valid for use as an AES Cipher Mode.

Table 56 shows the initial contents of the "Matroska AES Cipher Modes" registry. The Change Controller for the initial entries is the IETF.

Table 56: Initial Contents of "Matroska AES Cipher Modes" Registry
AES Cipher Mode Description Reference
1 AES-CTR RFC 9559, Section 5.1.4.1.31.12
2 AES-CBC RFC 9559, Section 5.1.4.1.31.12

27.5. Matroska Content Encoding Scopes Registry

IANA has created a new registry called the "Matroska Content Encoding Scopes" registry. The values correspond to the unsigned integer ContentEncodingScope value described in Section 5.1.4.1.31.3.

To register a new Content Encoding Scope in this registry, one needs a Content Encoding Scope value, a description, a Change Controller, and a Reference to a document describing the Content Encoding Scope.

The Content Encoding Scopes are to be allocated according to the "Specification Required" policy [RFC8126].

The Content Encoding Scope is a bit-field value so only power of 2 value can be registered.

The value 0 is not valid for use as a Content Encoding Scope.

Table 57 shows the initial contents of the "Matroska Content Encoding Scopes" registry. The Change Controller for the initial entries is the IETF.

Table 57: Initial Contents of "Matroska Content Encoding Scopes" Registry
Content Encoding Scope Description Reference
0x1 Block RFC 9559, Section 5.1.4.1.31.3
0x2 Private RFC 9559, Section 5.1.4.1.31.3
0x4 Next RFC 9559, Section 5.1.4.1.31.3

27.6. Matroska Content Encoding Types Registry

IANA has created a new registry called the "Matroska Content Encoding Types" registry. The values correspond to the unsigned integer ContentEncodingType value described in Section 5.1.4.1.31.4.

To register a new Content Encoding Type in this registry, one needs a Content Encoding Type value, a description, a Change Controller, and a Reference to a document describing the Content Encoding Type.

The Content Encoding Types are to be allocated according to the "Specification Required" policy [RFC8126].

Table 58 shows the initial contents of the "Matroska Content Encoding Types" registry. The Change Controller for the initial entries is the IETF.

Table 58: Initial Contents of "Matroska Content Encoding Types" Registry
Content Encoding Type Description Reference
0 Compression RFC 9559, Section 5.1.4.1.31.4
1 Encryption RFC 9559, Section 5.1.4.1.31.4

27.7. Matroska Stereo Modes Registry

IANA has created a new registry called the "Matroska Stereo Modes" registry. The values correspond to the unsigned integer StereoMode value described in Section 5.1.4.1.28.3.

To register a new Stereo Mode in this registry, one needs a Stereo Mode value, a description, a Change Controller, and a Reference to a document describing the Stereo Mode.

The Stereo Modes are to be allocated according to the "Specification Required" policy [RFC8126].

Table 59 shows the initial contents of the "Matroska Stereo Modes" registry. The Change Controller for the initial entries is the IETF.

Table 59: Initial Contents of "Matroska Stereo Modes" Registry
Stereo Mode Description Reference
0 mono RFC 9559, Section 5.1.4.1.28.3
1 side by side (left eye first) RFC 9559, Section 5.1.4.1.28.3
2 top - bottom (right eye is first) RFC 9559, Section 5.1.4.1.28.3
3 top - bottom (left eye is first) RFC 9559, Section 5.1.4.1.28.3
4 checkboard (right eye is first) RFC 9559, Section 5.1.4.1.28.3
5 checkboard (left eye is first) RFC 9559, Section 5.1.4.1.28.3
6 row interleaved (right eye is first) RFC 9559, Section 5.1.4.1.28.3
7 row interleaved (left eye is first) RFC 9559, Section 5.1.4.1.28.3
8 column interleaved (right eye is first) RFC 9559, Section 5.1.4.1.28.3
9 column interleaved (left eye is first) RFC 9559, Section 5.1.4.1.28.3
10 anaglyph (cyan/red) RFC 9559, Section 5.1.4.1.28.3
11 side by side (right eye first) RFC 9559, Section 5.1.4.1.28.3
12 anaglyph (green/magenta) RFC 9559, Section 5.1.4.1.28.3
13 both eyes laced in one Block (left eye is first) RFC 9559, Section 5.1.4.1.28.3
14 both eyes laced in one Block (right eye is first) RFC 9559, Section 5.1.4.1.28.3

27.8. Matroska Alpha Modes Registry

IANA has created a new registry called the "Matroska Alpha Modes" registry. The values correspond to the unsigned integer AlphaMode value described in Section 5.1.4.1.28.4.

To register a new Alpha Mode in this registry, one needs an Alpha Mode value, a description, a Change Controller, and an optional Reference to a document describing the Alpha Mode.

The Alpha Modes are to be allocated according to the "First Come First Served" policy [RFC8126].

Table 60 shows the initial contents of the "Matroska Alpha Modes" registry. The Change Controller for the initial entries is the IETF.

Table 60: Initial Contents of "Matroska Alpha Modes" Registry
Alpha Mode Description Reference
0 none RFC 9559, Section 5.1.4.1.28.4
1 present RFC 9559, Section 5.1.4.1.28.4

27.9. Matroska Display Units Registry

IANA has created a new registry called the "Matroska Display Units" registry. The values correspond to the unsigned integer DisplayUnit value described in Section 5.1.4.1.28.14.

To register a new Display Unit in this registry, one needs a Display Unit value, a description, a Change Controller, and a Reference to a document describing the Display Unit.

The Display Units are to be allocated according to the "Specification Required" policy [RFC8126].

Table 61 shows the initial contents of the "Matroska Display Units" registry. The Change Controller for the initial entries is the IETF.

Table 61: Initial Contents of "Matroska Display Units" Registry
Display Unit Description Reference
0 pixels RFC 9559, Section 5.1.4.1.28.14
1 centimeters RFC 9559, Section 5.1.4.1.28.14
2 inches RFC 9559, Section 5.1.4.1.28.14
3 display aspect ratio RFC 9559, Section 5.1.4.1.28.14
4 unknown RFC 9559, Section 5.1.4.1.28.14

27.10. Matroska Horizontal Chroma Sitings Registry

IANA has created a new registry called the "Matroska Horizontal Chroma Sitings" registry. The values correspond to the unsigned integer ChromaSitingHorz value described in Section 5.1.4.1.28.23.

To register a new Horizontal Chroma Siting in this registry, one needs a Horizontal Chroma Siting value, a description, a Change Controller, and an optional Reference to a document describing the Horizontal Chroma Siting.

The Horizontal Chroma Sitings are to be allocated according to the "First Come First Served" policy [RFC8126].

Table 62 shows the initial contents of the "Matroska Horizontal Chroma Sitings" registry. The Change Controller for the initial entries is the IETF.

Table 62: Initial Contents of "Matroska Horizontal Chroma Sitings" Registry
Horizontal Chroma Siting Description Reference
0 unspecified RFC 9559, Section 5.1.4.1.28.23
1 left collocated RFC 9559, Section 5.1.4.1.28.23
2 half RFC 9559, Section 5.1.4.1.28.23

27.11. Matroska Vertical Chroma Sitings Registry

IANA has created a new registry called the "Matroska Vertical Chroma Sitings" registry. The values correspond to the unsigned integer ChromaSitingVert value described in Section 5.1.4.1.28.24.

To register a new Vertical Chroma Siting in this registry, one needs a Vertical Chroma Siting value, a description, a Change Controller, and an optional Reference to a document describing the Vertical Chroma Siting.

The Vertical Chroma Sitings are to be allocated according to the "First Come First Served" policy [RFC8126].

Table 63 shows the initial contents of the "Matroska Vertical Chroma Sitings" registry. The Change Controller for the initial entries is the IETF.

Table 63: Initial Contents of "Matroska Vertical Chroma Sitings" Registry
Vertical Chroma Siting Description Reference
0 unspecified RFC 9559, Section 5.1.4.1.28.24
1 top collocated RFC 9559, Section 5.1.4.1.28.24
2 half RFC 9559, Section 5.1.4.1.28.24

27.12. Matroska Color Ranges Registry

IANA has created a new registry called the "Matroska Color Ranges" registry. The values correspond to the unsigned integer Range value described in Section 5.1.4.1.28.25.

To register a new Color Range in this registry, one needs a Color Range value, a description, a Change Controller, and a Reference to a document describing the Color Range.

The Color Ranges are to be allocated according to the "Specification Required" policy [RFC8126].

Table 64 shows the initial contents of the "Matroska Color Ranges" registry. The Change Controller for the initial entries is the IETF.

Table 64: Initial Contents of "Matroska Color Ranges" Registry
Color Range Description Reference
0 unspecified RFC 9559, Section 5.1.4.1.28.25
1 broadcast range RFC 9559, Section 5.1.4.1.28.25
2 full range (no clipping) RFC 9559, Section 5.1.4.1.28.25
3 defined by MatrixCoefficients / TransferCharacteristics RFC 9559, Section 5.1.4.1.28.25

27.13. Matroska Tags Target Types Registry

IANA has created a new registry called the "Matroska Tags Target Types" registry. The values correspond to the unsigned integer TargetTypeValue value described in Section 5.1.8.1.1.1.

To register a new Tags Target Type in this registry, one needs a Tags Target Type value, a description, a Change Controller, and a Reference to a document describing the Tags Target Type.

The Tags Target Types are to be allocated according to the "Specification Required" policy [RFC8126].

The value 0 is not valid for use as a Tags Target Type.

Table 65 shows the initial contents of the "Matroska Tags Target Types" registry. The Change Controller for the initial entries is the IETF.

Table 65: Initial Contents of "Matroska Tags Target Types" Registry
Tags Target Type Description Reference
70 COLLECTION RFC 9559, Section 5.1.8.1.1.1
60 EDITION / ISSUE / VOLUME / OPUS / SEASON / SEQUEL RFC 9559, Section 5.1.8.1.1.1
50 ALBUM / OPERA / CONCERT / MOVIE / EPISODE RFC 9559, Section 5.1.8.1.1.1
40 PART / SESSION RFC 9559, Section 5.1.8.1.1.1
30 TRACK / SONG / CHAPTER RFC 9559, Section 5.1.8.1.1.1
20 SUBTRACK / MOVEMENT / SCENE RFC 9559, Section 5.1.8.1.1.1
10 SHOT RFC 9559, Section 5.1.8.1.1.1

27.14. Matroska Chapter Codec IDs Registry

IANA has created a new registry called the "Matroska Chapter Codec IDs" registry. The values correspond to the unsigned integer ChapProcessCodecID, ChapterTranslateCodec, and TrackTranslateCodec values described in Section 5.1.7.1.4.15.

To register a new Chapter Codec ID in this registry, one needs a Chapter Codec ID value, a description, a Change Controller, and a Reference to a document describing the Chapter Codec ID.

The Chapter Codec IDs are to be allocated according to the "Specification Required" policy [RFC8126].

Table 66 shows the initial contents of the "Matroska Chapter Codec IDs" registry. The Change Controller for the initial entries is the IETF.

Table 66: Initial Contents of "Matroska Chapter Codec IDs" Registry
Chapter Codec ID Description Reference
0 Matroska Script RFC 9559, Section 5.1.7.1.4.15
1 DVD-menu RFC 9559, Section 5.1.7.1.4.15

27.15. Matroska Projection Types Registry

IANA has created a new registry called the "Matroska Projection Types" registry. The values correspond to the unsigned integer ProjectionType value described in Section 5.1.4.1.28.42.

To register a new Projection Type in this registry, one needs a Projection Type value, a description, a Change Controller, and an optional Reference to a document describing the Projection Type.

The Projection Types are to be allocated according to the "First Come First Served" policy [RFC8126].

Table 67 shows the initial contents of the "Matroska Projection Types" registry. The Change Controller for the initial entries is the IETF.

Table 67: Initial Contents of "Matroska Projection Types" Registry
Projection Type Description Reference
0 rectangular RFC 9559, Section 5.1.4.1.28.42
1 equirectangular RFC 9559, Section 5.1.4.1.28.42
2 cubemap RFC 9559, Section 5.1.4.1.28.42
3 mesh RFC 9559, Section 5.1.4.1.28.42

27.16. Matroska Track Types Registry

IANA has created a new registry called the "Matroska Track Types" registry. The values correspond to the unsigned integer TrackType value described in Section 5.1.4.1.3.

To register a new Track Type in this registry, one needs a Track Type value, a description, a Change Controller, and a Reference to a document describing the Track Type.

The Track Types are to be allocated according to the "Specification Required" policy [RFC8126].

The value 0 is not valid for use as a Track Type.

Table 68 shows the initial contents of the "Matroska Track Types" registry. The Change Controller for the initial entries is the IETF.

Table 68: Initial Contents of "Matroska Track Types" Registry
Track Type Description Reference
1 video RFC 9559, Section 5.1.4.1.3
2 audio RFC 9559, Section 5.1.4.1.3
3 complex RFC 9559, Section 5.1.4.1.3
16 logo RFC 9559, Section 5.1.4.1.3
17 subtitle RFC 9559, Section 5.1.4.1.3
18 buttons RFC 9559, Section 5.1.4.1.3
32 control RFC 9559, Section 5.1.4.1.3
33 metadata RFC 9559, Section 5.1.4.1.3

27.17. Matroska Track Plane Types Registry

IANA has created a new registry called the "Matroska Track Plane Types" registry. The values correspond to the unsigned integer TrackPlaneType value described in Section 5.1.4.1.30.4.

To register a new Track Plane Type in this registry, one needs a Track Plane Type value, a description, a Change Controller, and an optional Reference to a document describing the Track Plane Type.

The Track Plane Types are to be allocated according to the "First Come First Served" policy [RFC8126].

Table 69 shows the initial contents of the "Matroska Track Plane Types" registry. The Change Controller for the initial entries is the IETF.

Table 69: Initial Contents of "Matroska Track Plane Types" Registry
Track Plane Type Description Reference
0 left eye RFC 9559, Section 5.1.4.1.30.4
1 right eye RFC 9559, Section 5.1.4.1.30.4
2 background RFC 9559, Section 5.1.4.1.30.4

27.18. Media Types

Matroska files and streams are found in three main forms: audio-video, audio-only, and (occasionally) stereoscopic video.

Historically, Matroska files and streams have used the following media types with an "x-" prefix. For better compatibility, a system SHOULD be able to handle both formats. Newer systems SHOULD NOT use the historic format and use the format that follows the format in [RFC6838] instead.

IANA has registered three media types per the templates (see [RFC6838]) in the following subsections.

27.18.1. For Files Containing Video Tracks

Type name:
video
Subtype name:
matroska
Required parameters:
N/A
Optional parameters:
N/A
Encoding considerations:
As per RFCs 9559 and 8794
Security considerations:
See Section 26 of RFC 9559.
Interoperability considerations:
Due to the extensibility of Matroska, it is possible to encounter files with unknown but valid EBML Elements. Readers should be ready to handle this case. The fixed byte order, octet boundaries, and UTF-8 usage allow for broad interoperability.
Published specification:
RFC 9559
Applications that use this media type:
FFmpeg, VLC, etc.
Fragment identifier considerations:
N/A

Additional information:

Deprecated alias names for this type:
video/x-matroska
Magic number(s):
N/A
File extension(s):
mkv
Macintosh file type code(s):
N/A
Person & email address to contact for further information:
IETF CELLAR WG (cellar@ietf.org)
Intended usage:
COMMON
Restrictions on usage:
None
Author:
IETF CELLAR WG
Change controller:
IETF

27.18.2. For Files Containing Audio Tracks with No Video Tracks

Type name:
audio
Subtype name:
matroska
Required parameters:
N/A
Optional parameters:
N/A
Encoding considerations:
As per RFCs 9559 and 8794
Security considerations:
See Section 26 of RFC 9559.
Interoperability considerations:
Due to the extensibility of Matroska, it is possible to encounter files with unknown but valid EBML Elements. Readers should be ready to handle this case. The fixed byte order, octet boundaries, and UTF-8 usage allow for broad interoperability.
Published specification:
RFC 9559
Applications that use this media type:
FFmpeg, VLC, etc.
Fragment identifier considerations:
N/A

Additional information:

Deprecated alias names for this type:
audio/x-matroska
Magic number(s):
N/A
File extension(s):
mka
Macintosh file type code(s):
N/A
Person & email address to contact for further information:
IETF CELLAR WG (cellar@ietf.org)
Intended usage:
COMMON
Restrictions on usage:
None
Author:
IETF CELLAR WG
Change controller:
IETF

27.18.3. For Files Containing a Stereoscopic Video Track

Type name:
video
Subtype name:
matroska-3d
Required parameters:
N/A
Optional parameters:
N/A
Encoding considerations:
As per RFCs 9559 and 8794
Security considerations:
See Section 26 of RFC 9559.
Interoperability considerations:
Due to the extensibility of Matroska, it is possible to encounter files with unknown but valid EBML Elements. Readers should be ready to handle this case. The fixed byte order, octet boundaries, and UTF-8 usage allow for broad interoperability.
Published specification:
RFC 9559
Applications that use this media type:
FFmpeg, VLC, etc.
Fragment identifier considerations:
N/A

Additional information:

Deprecated alias names for this type:
video/x-matroska-3d
Magic number(s):
N/A
File extension(s):
mk3d
Macintosh file type code(s):
N/A
Person & email address to contact for further information:
IETF CELLAR WG (cellar@ietf.org)
Intended usage:
COMMON
Restrictions on usage:
None
Author:
IETF CELLAR WG
Change controller:
IETF

28. Normative References

[CIE-1931]
Wikipedia, "CIE 1931 color space", <https://en.wikipedia.org/wiki/CIE_1931_color_space>.
[ISO639-2]
International Organization for Standardization, "Codes for the Representation of Names of Languages", ISO 639-2, , <https://www.loc.gov/standards/iso639-2/php/code_list.php>.
[ISO9899]
International Organization for Standardization, "Information technology -- Programming languages -- C", ISO/IEC 9899:2018, , <https://www.iso.org/standard/74528.html>.
[ITU-H.273]
ITU-T, "Coding-independent code points for video signal type identification", ITU-T Recommendation H.273, , <https://www.itu.int/rec/T-REC-H.273-202309-P/en>.
[RFC1950]
Deutsch, P. and J. Gailly, "ZLIB Compressed Data Format Specification version 3.3", RFC 1950, DOI 10.17487/RFC1950, , <https://www.rfc-editor.org/info/rfc1950>.
[RFC2119]
Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, , <https://www.rfc-editor.org/info/rfc2119>.
[RFC4122]
Leach, P., Mealling, M., and R. Salz, "A Universally Unique IDentifier (UUID) URN Namespace", RFC 4122, DOI 10.17487/RFC4122, , <https://www.rfc-editor.org/info/rfc4122>.
[RFC5646]
Phillips, A., Ed. and M. Davis, Ed., "Tags for Identifying Languages", BCP 47, RFC 5646, DOI 10.17487/RFC5646, , <https://www.rfc-editor.org/info/rfc5646>.
[RFC6838]
Freed, N., Klensin, J., and T. Hansen, "Media Type Specifications and Registration Procedures", BCP 13, RFC 6838, DOI 10.17487/RFC6838, , <https://www.rfc-editor.org/info/rfc6838>.
[RFC8081]
Lilley, C., "The "font" Top-Level Media Type", RFC 8081, DOI 10.17487/RFC8081, , <https://www.rfc-editor.org/info/rfc8081>.
[RFC8126]
Cotton, M., Leiba, B., and T. Narten, "Guidelines for Writing an IANA Considerations Section in RFCs", BCP 26, RFC 8126, DOI 10.17487/RFC8126, , <https://www.rfc-editor.org/info/rfc8126>.
[RFC8174]
Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, , <https://www.rfc-editor.org/info/rfc8174>.
[RFC8794]
Lhomme, S., Rice, D., and M. Bunkus, "Extensible Binary Meta Language", RFC 8794, DOI 10.17487/RFC8794, , <https://www.rfc-editor.org/info/rfc8794>.

29. Informative References

[AVIFormat]
Microsoft Corporation, "AVI RIFF File Reference", , <https://docs.microsoft.com/en-us/windows/win32/directshow/avi-riff-file-reference>.
[Blowfish]
Schneier, B., "The Blowfish Encryption Algorithm", , <https://www.schneier.com/academic/blowfish/>.
[BZIP2]
Seward, J., "bzip2", , <https://sourceware.org/bzip2/>.
[DivXTrickTrack]
"Smooth FF/RW", , <https://web.archive.org/web/20101222001148/http://labs.divx.com/node/16601>.
[DivXWorldFonts]
"World Fonts", , <https://web.archive.org/web/20110214132246/http://labs.divx.com/node/16602>.
[DVD-Video]
DVD Forum, "DVD-Books: Part 3 DVD-Video Book", , <http://www.dvdforum.org/>.
[Err7189]
RFC Errata, "Erratum ID 7189", RFC 8794, <https://www.rfc-editor.org/errata/eid7189>.
[Err7191]
RFC Errata, "Erratum ID 7191", RFC 8794, <https://www.rfc-editor.org/errata/eid7191>.
[FIPS197]
National Institute of Standards and Technology (NIST), "Advanced Encryption Standard (AES)", FIPS PUB 197, DOI 10.6028/NIST.FIPS.197, , <https://csrc.nist.gov/publications/detail/fips/197/final>.
[FIPS46-3]
National Institute of Standards and Technology (NIST), "Data Encryption Standard (DES)", FIPS PUB 46, , <https://csrc.nist.gov/publications/detail/fips/46/3/archive/1999-10-25>.
[FourCC-RGB]
FOURCC, "RGB pixel formats", <https://web.archive.org/web/20160609214806/https://www.fourcc.org/rgb.php>.
[FourCC-YUV]
FOURCC, "YUV pixel formats", <https://web.archive.org/web/20160609214806/https://www.fourcc.org/yuv.php>.
[I-D.ietf-cellar-codec]
Lhomme, S., Bunkus, M., and D. Rice, "Matroska Media Container Codec Specifications", Work in Progress, Internet-Draft, draft-ietf-cellar-codec-13, , <https://datatracker.ietf.org/doc/html/draft-ietf-cellar-codec-13>.
[I-D.ietf-cellar-tags]
Lhomme, S., Bunkus, M., and D. Rice, "Matroska Media Container Tag Specifications", Work in Progress, Internet-Draft, draft-ietf-cellar-tags-13, , <https://datatracker.ietf.org/doc/html/draft-ietf-cellar-tags-13>.
[JPEG]
ITU-T, "INFORMATION TECHNOLOGY - DIGITAL COMPRESSION AND CODING OF CONTINUOUS-TONE STILL IMAGES - REQUIREMENTS AND GUIDELINES", ITU-T Recommendation T.81, , <https://www.w3.org/Graphics/JPEG/itu-t81.pdf>.
[libmatroska]
"libmatroska", , <https://github.com/Matroska-Org/libmatroska>.
[LZO]
Tarreau, W. and R. Rodgman, "LZO stream format as understood by Linux's LZO decompressor", , <https://www.kernel.org/doc/Documentation/lzo.txt>.
[MCF]
"MCF specification, introduction", <http://mukoli.free.fr/mcf/>.
[MSRGB]
Microsoft Corporation, "Compression Enumeration", , <https://learn.microsoft.com/en-us/openspecs/windows_protocols/ms-wmf/4e588f70-bd92-4a6f-b77f-35d0feaf7a57>.
[MSYUV16]
Microsoft Corporation, "10-bit and 16-bit YUV Video Formats", , <https://learn.microsoft.com/en-us/windows/win32/medfound/10-bit-and-16-bit-yuv-video-formats>.
[MSYUV8]
Microsoft Corporation, "Recommended 8-Bit YUV Formats for Video Rendering", , <https://learn.microsoft.com/en-us/windows/win32/medfound/recommended-8-bit-yuv-formats-for-video-rendering>.
[RFC0959]
Postel, J. and J. Reynolds, "File Transfer Protocol", STD 9, RFC 959, DOI 10.17487/RFC0959, , <https://www.rfc-editor.org/info/rfc959>.
[RFC2083]
Boutell, T., "PNG (Portable Network Graphics) Specification Version 1.0", RFC 2083, DOI 10.17487/RFC2083, , <https://www.rfc-editor.org/info/rfc2083>.
[RFC3533]
Pfeiffer, S., "The Ogg Encapsulation Format Version 0", RFC 3533, DOI 10.17487/RFC3533, , <https://www.rfc-editor.org/info/rfc3533>.
[RFC4732]
Handley, M., Ed., Rescorla, E., Ed., and IAB, "Internet Denial-of-Service Considerations", RFC 4732, DOI 10.17487/RFC4732, , <https://www.rfc-editor.org/info/rfc4732>.
[RFC9110]
Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, Ed., "HTTP Semantics", STD 97, RFC 9110, DOI 10.17487/RFC9110, , <https://www.rfc-editor.org/info/rfc9110>.
[SMB-CIFS]
Microsoft Corporation, "[MS-CIFS]: Common Internet File System (CIFS) Protocol", , <https://winprotocoldoc.blob.core.windows.net/productionwindowsarchives/MS-CIFS/%5bMS-CIFS%5d.pdf>.
[SP800-38A]
National Institute of Standards and Technology (NIST), "Recommendation for Block Cipher Modes of Operation: Methods and Techniques", DOI 10.6028/NIST.SP.800-38A, NIST Special Publication 800-38A, , <https://nvlpubs.nist.gov/nistpubs/Legacy/SP/nistspecialpublication800-38a.pdf>.
[SP800-67]
National Institute of Standards and Technology (NIST), "Recommendation for the Triple Data Encryption Algorithm (TDEA) Block Cipher", DOI 10.6028/NIST.SP.800-67r2, NIST Special Publication 800-67, , <https://nvlpubs.nist.gov/nistpubs/SpecialPublications/NIST.SP.800-67r2.pdf>.
[Twofish]
Schneier, B., Kelsey, J., Whiting, D., Wagner, D., Hall, C., and N. Ferguson, "Twofish: A 128-Bit Block Cipher", , <https://www.schneier.com/academic/archives/1998/06/twofish_a_128-bit_bl.html>.
[WebM-Enc]
Galligan, F., "WebM Encryption", , <https://www.webmproject.org/docs/webm-encryption/>.
[WebVTT]
Pieters, S., Pfeiffer, S., Ed., Jaegenstedt, P., and I. Hickson, "WebVTT: The Web Video Text Tracks Format", W3C Candidate Recommendation, , <https://www.w3.org/TR/2019/CR-webvtt1-20190404/>.

Appendix A. Historic Deprecated Elements

As Matroska has evolved since 2002, many parts that were considered for use in the format were never used and often incorrectly designed. Many of the elements that were defined then are not found in any known files but were part of public specs. DivX also had a few custom elements that were designed for custom features.

In this appendix, we list elements that have a known ID that SHOULD NOT be reused to avoid colliding with existing files. These might be reassigned by IANA in the future if there are no more IDs for a given size. A short description of what each ID was used for is included, but the text is not normative.

A.1. SilentTracks Element

type / id:
master / 0x5854
path:
\Segment\Cluster\SilentTracks
documentation:
The list of tracks that are not used in that part of the stream. It is useful when using overlay tracks for seeking or deciding what track to use.

A.2. SilentTrackNumber Element

type / id:
uinteger / 0x58D7
path:
\Segment\Cluster\SilentTracks\SilentTrackNumber
documentation:
One of the track numbers that is not used from now on in the stream. It could change later if not specified as silent in a further Cluster.

A.3. BlockVirtual Element

type / id:
binary / 0xA2
path:
\Segment\Cluster\BlockGroup\BlockVirtual
documentation:
A Block with no data. It must be stored in the stream at the place the real Block would be in display order.

A.4. ReferenceVirtual Element

type / id:
integer / 0xFD
path:
\Segment\Cluster\BlockGroup\ReferenceVirtual
documentation:
The Segment Position of the data that would otherwise be in position of the virtual block.

A.5. Slices Element

type / id:
master / 0x8E
path:
\Segment\Cluster\BlockGroup\Slices
documentation:
Contains slices description.

A.6. TimeSlice Element

type / id:
master / 0xE8
path:
\Segment\Cluster\BlockGroup\Slices\TimeSlice
documentation:
Contains extra time information about the data contained in the Block. Being able to interpret this element is not required for playback.

A.7. LaceNumber Element

type / id:
uinteger / 0xCC
path:
\Segment\Cluster\BlockGroup\Slices\TimeSlice\LaceNumber
documentation:
The reverse number of the frame in the lace (0 is the last frame, 1 is the next to last, etc.). Being able to interpret this element is not required for playback.

A.8. FrameNumber Element

type / id:
uinteger / 0xCD
path:
\Segment\Cluster\BlockGroup\Slices\TimeSlice\FrameNumber
documentation:
The number of the frame to generate from this lace with this delay (allows for the generation of many frames from the same Block/Frame).

A.9. BlockAdditionID Element

type / id:
uinteger / 0xCB
path:
\Segment\Cluster\BlockGroup\Slices\TimeSlice\BlockAdditionID
documentation:
The ID of the BlockAdditional element (0 is the main Block).

A.10. Delay Element

type / id:
uinteger / 0xCE
path:
\Segment\Cluster\BlockGroup\Slices\TimeSlice\Delay
documentation:
The delay to apply to the element, expressed in Track Ticks; see Section 11.1.

A.11. SliceDuration Element

type / id:
uinteger / 0xCF
path:
\Segment\Cluster\BlockGroup\Slices\TimeSlice\SliceDuration
documentation:
The duration to apply to the element, expressed in Track Ticks; see Section 11.1.

A.12. ReferenceFrame Element

type / id:
master / 0xC8
path:
\Segment\Cluster\BlockGroup\ReferenceFrame
documentation:
Contains information about the last reference frame. See [DivXTrickTrack].

A.13. ReferenceOffset Element

type / id:
uinteger / 0xC9
path:
\Segment\Cluster\BlockGroup\ReferenceFrame\ReferenceOffset
documentation:
The relative offset, in bytes, from the previous BlockGroup element for this Smooth FF/RW video track to the containing BlockGroup element. See [DivXTrickTrack].

A.14. ReferenceTimestamp Element

type / id:
uinteger / 0xCA
path:
\Segment\Cluster\BlockGroup\ReferenceFrame\ReferenceTimestamp
documentation:
The timestamp of the BlockGroup pointed to by ReferenceOffset, expressed in Track Ticks; see Section 11.1. See [DivXTrickTrack].

A.15. EncryptedBlock Element

type / id:
binary / 0xAF
path:
\Segment\Cluster\EncryptedBlock
documentation:
Similar to SimpleBlock (see Section 10.2), but the data inside the Block are Transformed (encrypted and/or signed).

A.16. MinCache Element

type / id:
uinteger / 0x6DE7
path:
\Segment\Tracks\TrackEntry\MinCache
documentation:
The minimum number of frames a player should be able to cache during playback. If set to 0, the reference pseudo-cache system is not used.

A.17. MaxCache Element

type / id:
uinteger / 0x6DF8
path:
\Segment\Tracks\TrackEntry\MaxCache
documentation:
The maximum cache size necessary to store referenced frames in and the current frame. 0 means no cache is needed.

A.18. TrackOffset Element

type / id:
integer / 0x537F
path:
\Segment\Tracks\TrackEntry\TrackOffset
documentation:
A value to add to the Block's Timestamp, expressed in Matroska Ticks -- i.e., in nanoseconds; see Section 11.1. This can be used to adjust the playback offset of a track.

A.19. CodecSettings Element

type / id:
utf-8 / 0x3A9697
path:
\Segment\Tracks\TrackEntry\CodecSettings
documentation:
A string describing the encoding setting used.

A.20. CodecInfoURL Element

type / id:
string / 0x3B4040
path:
\Segment\Tracks\TrackEntry\CodecInfoURL
documentation:
A URL to find information about the codec used.

A.21. CodecDownloadURL Element

type / id:
string / 0x26B240
path:
\Segment\Tracks\TrackEntry\CodecDownloadURL
documentation:
A URL to download information about the codec used.

A.22. CodecDecodeAll Element

type / id:
uinteger / 0xAA
path:
\Segment\Tracks\TrackEntry\CodecDecodeAll
documentation:
Set to 1 if the codec can decode potentially damaged data.

A.23. TrackOverlay Element

type / id:
uinteger / 0x6FAB
path:
\Segment\Tracks\TrackEntry\TrackOverlay
documentation:
Specify that this track is an overlay track for the Track specified (in the u-integer). This means that when this track has a gap on SilentTracks, the overlay track should be used instead. The order of multiple TrackOverlay matters; the first one is the one that should be used. If the first one is not found, it should be the second, etc.

A.24. AspectRatioType Element

type / id:
uinteger / 0x54B3
path:
\Segment\Tracks\TrackEntry\Video\AspectRatioType
documentation:
Specifies the possible modifications to the aspect ratio.

A.25. GammaValue Element

type / id:
float / 0x2FB523
path:
\Segment\Tracks\TrackEntry\Video\GammaValue
documentation:
Gamma value.

A.26. FrameRate Element

type / id:
float / 0x2383E3
path:
\Segment\Tracks\TrackEntry\Video\FrameRate
documentation:
Number of frames per second. This value is informational only. It is intended for constant frame rate streams and should not be used for a variable frame rate TrackEntry.

A.27. ChannelPositions Element

type / id:
binary / 0x7D7B
path:
\Segment\Tracks\TrackEntry\Audio\ChannelPositions
documentation:
Table of horizontal angles for each successive channel.

A.28. TrickTrackUID Element

type / id:
uinteger / 0xC0
path:
\Segment\Tracks\TrackEntry\TrickTrackUID
documentation:
The TrackUID of the Smooth FF/RW video in the paired EBML structure corresponding to this video track. See [DivXTrickTrack].

A.29. TrickTrackSegmentUID Element

type / id:
binary / 0xC1
path:
\Segment\Tracks\TrackEntry\TrickTrackSegmentUID
documentation:
The SegmentUUID of the Segment containing the track identified by TrickTrackUID. See [DivXTrickTrack].

A.30. TrickTrackFlag Element

type / id:
uinteger / 0xC6
path:
\Segment\Tracks\TrackEntry\TrickTrackFlag
documentation:
Set to 1 if this video track is a Smooth FF/RW track. If set to 1, MasterTrackUID and MasterTrackSegUID should be present, and BlockGroups for this track must contain ReferenceFrame structures. Otherwise, TrickTrackUID and TrickTrackSegUID must be present if this track has a corresponding Smooth FF/RW track. See [DivXTrickTrack].

A.31. TrickMasterTrackUID Element

type / id:
uinteger / 0xC7
path:
\Segment\Tracks\TrackEntry\TrickMasterTrackUID
documentation:
The TrackUID of the video track in the paired EBML structure that corresponds to this Smooth FF/RW track. See [DivXTrickTrack].

A.32. TrickMasterTrackSegmentUID Element

type / id:
binary / 0xC4
path:
\Segment\Tracks\TrackEntry\TrickMasterTrackSegmentUID
documentation:
The SegmentUUID of the Segment containing the track identified by MasterTrackUID. See [DivXTrickTrack].

A.33. ContentSignature Element

type / id:
binary / 0x47E3
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentSignature
documentation:
A cryptographic signature of the contents.

A.34. ContentSigKeyID Element

type / id:
binary / 0x47E4
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentSigKeyID
documentation:
This is the ID of the private key that the data was signed with.

A.35. ContentSigAlgo Element

type / id:
uinteger / 0x47E5
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentSigAlgo
documentation:
The algorithm used for the signature.

A.36. ContentSigHashAlgo Element

type / id:
uinteger / 0x47E6
path:
\Segment\Tracks\TrackEntry\ContentEncodings\ContentEncoding\ContentEncryption\ContentSigHashAlgo
documentation:
The hash algorithm used for the signature.

A.37. CueRefCluster Element

type / id:
uinteger / 0x97
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueReference\CueRefCluster
documentation:
The Segment Position of the Cluster containing the referenced Block.

A.38. CueRefNumber Element

type / id:
uinteger / 0x535F
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueReference\CueRefNumber
documentation:
Number of the referenced Block of Track X in the specified Cluster.

A.39. CueRefCodecState Element

type / id:
uinteger / 0xEB
path:
\Segment\Cues\CuePoint\CueTrackPositions\CueReference\CueRefCodecState
documentation:
The Segment Position of the Codec State corresponding to this referenced element. 0 means that the data is taken from the initial TrackEntry.

A.40. FileReferral Element

type / id:
binary / 0x4675
path:
\Segment\Attachments\AttachedFile\FileReferral
documentation:
A binary value that a track/codec can refer to when the attachment is needed.

A.41. FileUsedStartTime Element

type / id:
uinteger / 0x4661
path:
\Segment\Attachments\AttachedFile\FileUsedStartTime
documentation:
The timestamp at which this optimized font attachment comes into context, expressed in Segment Ticks, which are based on TimestampScale. See [DivXWorldFonts].

A.42. FileUsedEndTime Element

type / id:
uinteger / 0x4662
path:
\Segment\Attachments\AttachedFile\FileUsedEndTime
documentation:
The timestamp at which this optimized font attachment goes out of context, expressed in Segment Ticks, which are based on TimestampScale. See [DivXWorldFonts].

A.43. TagDefaultBogus Element

type / id:
uinteger / 0x44B4
path:
\Segment\Tags\Tag\+SimpleTag\TagDefaultBogus
documentation:
A variant of the TagDefault element with a bogus element ID; see Section 5.1.8.1.2.4.

Authors' Addresses

Steve Lhomme
Moritz Bunkus
Dave Rice