RFC 9043




Internet Engineering Task Force (IETF)                    M. Niedermayer
Request for Comments: 9043
Category: Informational                                          D. Rice
ISSN: 2070-1721                                                        
                                                             J. Martinez
                                                             August 2021


             FFV1 Video Coding Format Versions 0, 1, and 3

Abstract



   This document defines FFV1, a lossless, intra-frame video encoding
   format.  FFV1 is designed to efficiently compress video data in a
   variety of pixel formats.  Compared to uncompressed video, FFV1
   offers storage compression, frame fixity, and self-description, which
   makes FFV1 useful as a preservation or intermediate video format.

Status of This Memo



   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Not all documents
   approved by the IESG are candidates for any level of Internet
   Standard; see Section 2 of RFC 7841.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   https://www.rfc-editor.org/info/rfc9043.

Copyright Notice



   Copyright (c) 2021 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (https://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

Table of Contents



   1.  Introduction
   2.  Notation and Conventions
     2.1.  Definitions
     2.2.  Conventions
       2.2.1.  Pseudocode
       2.2.2.  Arithmetic Operators
       2.2.3.  Assignment Operators
       2.2.4.  Comparison Operators
       2.2.5.  Mathematical Functions
       2.2.6.  Order of Operation Precedence
       2.2.7.  Range
       2.2.8.  NumBytes
       2.2.9.  Bitstream Functions
   3.  Sample Coding
     3.1.  Border
     3.2.  Samples
     3.3.  Median Predictor
       3.3.1.  Exception
     3.4.  Quantization Table Sets
     3.5.  Context
     3.6.  Quantization Table Set Indexes
     3.7.  Color Spaces
       3.7.1.  YCbCr
       3.7.2.  RGB
     3.8.  Coding of the Sample Difference
       3.8.1.  Range Coding Mode
       3.8.2.  Golomb Rice Mode
   4.  Bitstream
     4.1.  Quantization Table Set
       4.1.1.  "quant_tables"
       4.1.2.  "context_count"
     4.2.  Parameters
       4.2.1.  "version"
       4.2.2.  "micro_version"
       4.2.3.  "coder_type"
       4.2.4.  "state_transition_delta"
       4.2.5.  "colorspace_type"
       4.2.6.  "chroma_planes"
       4.2.7.  "bits_per_raw_sample"
       4.2.8.  "log2_h_chroma_subsample"
       4.2.9.  "log2_v_chroma_subsample"
       4.2.10. "extra_plane"
       4.2.11. "num_h_slices"
       4.2.12. "num_v_slices"
       4.2.13. "quant_table_set_count"
       4.2.14. "states_coded"
       4.2.15. "initial_state_delta"
       4.2.16. "ec"
       4.2.17. "intra"
     4.3.  Configuration Record
       4.3.1.  "reserved_for_future_use"
       4.3.2.  "configuration_record_crc_parity"
       4.3.3.  Mapping FFV1 into Containers
     4.4.  Frame
     4.5.  Slice
     4.6.  Slice Header
       4.6.1.  "slice_x"
       4.6.2.  "slice_y"
       4.6.3.  "slice_width"
       4.6.4.  "slice_height"
       4.6.5.  "quant_table_set_index_count"
       4.6.6.  "quant_table_set_index"
       4.6.7.  "picture_structure"
       4.6.8.  "sar_num"
       4.6.9.  "sar_den"
     4.7.  Slice Content
       4.7.1.  "primary_color_count"
       4.7.2.  "plane_pixel_height"
       4.7.3.  "slice_pixel_height"
       4.7.4.  "slice_pixel_y"
     4.8.  Line
       4.8.1.  "plane_pixel_width"
       4.8.2.  "slice_pixel_width"
       4.8.3.  "slice_pixel_x"
       4.8.4.  "sample_difference"
     4.9.  Slice Footer
       4.9.1.  "slice_size"
       4.9.2.  "error_status"
       4.9.3.  "slice_crc_parity"
   5.  Restrictions
   6.  Security Considerations
   7.  IANA Considerations
     7.1.  Media Type Definition
   8.  References
     8.1.  Normative References
     8.2.  Informative References
   Appendix A.  Multithreaded Decoder Implementation Suggestions
   Appendix B.  Future Handling of Some Streams Created by
           Nonconforming Encoders
   Appendix C.  FFV1 Implementations
     C.1.  FFmpeg FFV1 Codec
     C.2.  FFV1 Decoder in Go
     C.3.  MediaConch

   Authors' Addresses



1.  Introduction



   This document describes FFV1, a lossless video encoding format.  The
   design of FFV1 considers the storage of image characteristics, data
   fixity, and the optimized use of encoding time and storage
   requirements.  FFV1 is designed to support a wide range of lossless
   video applications such as long-term audiovisual preservation,
   scientific imaging, screen recording, and other video encoding
   scenarios that seek to avoid the generational loss of lossy video
   encodings.

   This document defines versions 0, 1, and 3 of FFV1.  The distinctions
   of the versions are provided throughout the document, but in summary:

   *  Version 0 of FFV1 was the original implementation of FFV1 and was
      flagged as stable on April 14, 2006 [FFV1_V0].

   *  Version 1 of FFV1 adds support of more video bit depths and was
      flagged as stable on April 24, 2009 [FFV1_V1].

   *  Version 2 of FFV1 only existed in experimental form and is not
      described by this document, but it is available as a LyX file at
      <https://github.com/FFmpeg/FFV1/
      blob/8ad772b6d61c3dd8b0171979a2cd9f11924d5532/ffv1.lyx>.

   *  Version 3 of FFV1 adds several features such as increased
      description of the characteristics of the encoding images and
      embedded Cyclic Redundancy Check (CRC) data to support fixity
      verification of the encoding.  Version 3 was flagged as stable on
      August 17, 2013 [FFV1_V3].

   This document assumes familiarity with mathematical and coding
   concepts such as Range encoding [Range-Encoding] and YCbCr color
   spaces [YCbCr].

   This specification describes the valid bitstream and how to decode
   it.  Nonconformant bitstreams and the nonconformant handling of
   bitstreams are outside this specification.  A decoder can perform any
   action that it deems appropriate for an invalid bitstream: reject the
   bitstream, attempt to perform error concealment, or re-download or
   use a redundant copy of the invalid part.

2.  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.

2.1.  Definitions



   FFV1:  The chosen name of this video encoding format, which is the
      short version of "FF Video 1".  The letters "FF" come from
      "FFmpeg", which is the name of the reference decoder whose first
      letters originally meant "Fast Forward".

   Container:  A format that encapsulates Frames (see Section 4.4) and
      (when required) a "Configuration Record" into a bitstream.

   Sample:  The smallest addressable representation of a color component
      or a luma component in a Frame.  Examples of Sample are Luma (Y),
      Blue-difference Chroma (Cb), Red-difference Chroma (Cr),
      Transparency, Red, Green, and Blue.

   Symbol:  A value stored in the bitstream, which is defined and
      decoded through one of the methods described in Table 4.

   Line:  A discrete component of a static image composed of Samples
      that represent a specific quantification of Samples of that image.

   Plane:  A discrete component of a static image composed of Lines that
      represent a specific quantification of Lines of that image.

   Pixel:  The smallest addressable representation of a color in a
      Frame.  It is composed of one or more Samples.

   MSB:  Most Significant Bit, the bit that can cause the largest change
      in magnitude of the symbol.

   VLC:  Variable Length Code, a code that maps source symbols to a
      variable number of bits.

   RGB:  A reference to the method of storing the value of a pixel by
      using three numeric values that represent Red, Green, and Blue.

   YCbCr:  A reference to the method of storing the value of a pixel by
      using three numeric values that represent the luma of the pixel
      (Y) and the chroma of the pixel (Cb and Cr).  The term YCbCr is
      used for historical reasons and currently references any color
      space relying on one luma Sample and two chroma Samples, e.g.,
      YCbCr (luma, blue-difference chroma, red-difference chroma),
      YCgCo, or ICtCp (intensity, blue-yellow, red-green).

2.2.  Conventions



2.2.1.  Pseudocode



   The FFV1 bitstream is described in this document using pseudocode.
   Note that the pseudocode is used to illustrate the structure of FFV1
   and is not intended to specify any particular implementation.  The
   pseudocode used is based upon the C programming language
   [ISO.9899.2018] and uses its "if/else", "while", and "for" keywords
   as well as functions defined within this document.

   In some instances, pseudocode is presented in a two-column format
   such as shown in Figure 1.  In this form, the "type" column provides
   a symbol as defined in Table 4 that defines the storage of the data
   referenced in that same line of pseudocode.

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   ExamplePseudoCode( ) {                                        |
       value                                                     | ur
   }                                                             |

     Figure 1: A depiction of type-labeled pseudocode used within this
                                 document.

2.2.2.  Arithmetic Operators



   Note: the operators and the order of precedence are the same as used
   in the C programming language [ISO.9899.2018], with the exception of
   ">>" (removal of implementation-defined behavior) and "^" (power
   instead of XOR) operators, which are redefined within this section.

   "a + b" means a plus b.

   "a - b" means a minus b.

   "-a" means negation of a.

   "a * b" means a multiplied by b.

   "a / b" means a divided by b.

   "a ^ b" means a raised to the b-th power.

   "a & b" means bitwise "and" of a and b.

   "a | b" means bitwise "or" of a and b.

   "a >> b" means arithmetic right shift of the two's complement integer
   representation of a by b binary digits.  This is equivalent to
   dividing a by 2, b times, with rounding toward negative infinity.

   "a << b" means arithmetic left shift of the two's complement integer
   representation of a by b binary digits.

2.2.3.  Assignment Operators



   "a = b" means a is assigned b.

   "a++" is equivalent to a is assigned a + 1.

   "a--" is equivalent to a is assigned a - 1.

   "a += b" is equivalent to a is assigned a + b.

   "a -= b" is equivalent to a is assigned a - b.

   "a *= b" is equivalent to a is assigned a * b.

2.2.4.  Comparison Operators



   "a > b" is true when a is greater than b.

   "a >= b" is true when a is greater than or equal to b.

   "a < b" is true when a is less than b.

   "a <= b" is true when a is less than or equal b.

   "a == b" is true when a is equal to b.

   "a != b" is true when a is not equal to b.

   "a && b" is true when both a is true and b is true.

   "a || b" is true when either a is true or b is true.

   "!a" is true when a is not true.

   "a ? b : c" if a is true, then b, otherwise c.

2.2.5.  Mathematical Functions



   "floor(a)" means the largest integer less than or equal to a.

   "ceil(a)" means the smallest integer greater than or equal to a.

   "sign(a)" extracts the sign of a number, i.e., if a < 0 then -1, else
   if a > 0 then 1, else 0.

   "abs(a)" means the absolute value of a, i.e., "abs(a)" = "sign(a) *
   a".

   "log2(a)" means the base-two logarithm of a.

   "min(a,b)" means the smaller of two values a and b.

   "max(a,b)" means the larger of two values a and b.

   "median(a,b,c)" means the numerical middle value in a data set of a,
   b, and c, i.e., "a+b+c-min(a,b,c)-max(a,b,c)".

   "a ==> b" means a implies b.

   "a <==> b" means a ==> b, b ==> a.

   "a_b" means the b-th value of a sequence of a.

   "a_(b,c)" means the 'b,c'-th value of a sequence of a.

2.2.6.  Order of Operation Precedence



   When order of precedence is not indicated explicitly by use of
   parentheses, operations are evaluated in the following order (from
   top to bottom, operations of same precedence being evaluated from
   left to right).  This order of operations is based on the order of
   operations used in Standard C.

   a++, a--
   !a, -a
   a ^ b
   a * b, a / b
   a + b, a - b
   a << b, a >> b
   a < b, a <= b, a > b, a >= b
   a == b, a != b
   a & b
   a | b
   a && b
   a || b
   a ? b : c
   a = b, a += b, a -= b, a *= b

2.2.7.  Range



   "a...b" means any value from a to b, inclusive.

2.2.8.  NumBytes



   "NumBytes" is a nonnegative integer that expresses the size in 8-bit
   octets of a particular FFV1 "Configuration Record" or "Frame".  FFV1
   relies on its container to store the "NumBytes" values; see
   Section 4.3.3.

2.2.9.  Bitstream Functions



2.2.9.1.  remaining_bits_in_bitstream



   "remaining_bits_in_bitstream( NumBytes )" means the count of
   remaining bits after the pointer in that "Configuration Record" or
   "Frame".  It is computed from the "NumBytes" value multiplied by 8
   minus the count of bits of that "Configuration Record" or "Frame"
   already read by the bitstream parser.

2.2.9.2.  remaining_symbols_in_syntax



   "remaining_symbols_in_syntax( )" is true as long as the range coder
   has not consumed all the given input bytes.

2.2.9.3.  byte_aligned



   "byte_aligned( )" is true if "remaining_bits_in_bitstream( NumBytes
   )" is a multiple of 8, otherwise false.

2.2.9.4.  get_bits



   "get_bits( i )" is the action to read the next "i" bits in the
   bitstream, from most significant bit to least significant bit, and to
   return the corresponding value.  The pointer is increased by "i".

3.  Sample Coding



   For each "Slice" (as described in Section 4.5) of a Frame, the
   Planes, Lines, and Samples are coded in an order determined by the
   color space (see Section 3.7).  Each Sample is predicted by the
   median predictor as described in Section 3.3 from other Samples
   within the same Plane, and the difference is stored using the method
   described in Section 3.8.

3.1.  Border



   A border is assumed for each coded "Slice" for the purpose of the
   median predictor and context according to the following rules:

   *  One column of Samples to the left of the coded Slice is assumed as
      identical to the Samples of the leftmost column of the coded Slice
      shifted down by one row.  The value of the topmost Sample of the
      column of Samples to the left of the coded Slice is assumed to be
      "0".

   *  One column of Samples to the right of the coded Slice is assumed
      as identical to the Samples of the rightmost column of the coded
      Slice.

   *  An additional column of Samples to the left of the coded Slice and
      two rows of Samples above the coded Slice are assumed to be "0".

   Figure 2 depicts a Slice of nine Samples "a,b,c,d,e,f,g,h,i" in a
   three-by-three arrangement along with its assumed border.

   +---+---+---+---+---+---+---+---+
   | 0 | 0 |   | 0 | 0 | 0 |   | 0 |
   +---+---+---+---+---+---+---+---+
   | 0 | 0 |   | 0 | 0 | 0 |   | 0 |
   +---+---+---+---+---+---+---+---+
   |   |   |   |   |   |   |   |   |
   +---+---+---+---+---+---+---+---+
   | 0 | 0 |   | a | b | c |   | c |
   +---+---+---+---+---+---+---+---+
   | 0 | a |   | d | e | f |   | f |
   +---+---+---+---+---+---+---+---+
   | 0 | d |   | g | h | i |   | i |
   +---+---+---+---+---+---+---+---+

        Figure 2: A depiction of FFV1's assumed border for a set of
                              example Samples.

3.2.  Samples



   Relative to any Sample "X", six other relatively positioned Samples
   from the coded Samples and presumed border are identified according
   to the labels used in Figure 3.  The labels for these relatively
   positioned Samples are used within the median predictor and context.

   +---+---+---+---+
   |   |   | T |   |
   +---+---+---+---+
   |   |tl | t |tr |
   +---+---+---+---+
   | L | l | X |   |
   +---+---+---+---+

       Figure 3: A depiction of how relatively positioned Samples are
                      referenced within this document.

   The labels for these relative Samples are made of the first letters
   of the words Top, Left, and Right.

3.3.  Median Predictor



   The prediction for any Sample value at position "X" may be computed
   based upon the relative neighboring values of "l", "t", and "tl" via
   this equation:

   median(l, t, l + t - tl)

   Note that this prediction template is also used in [ISO.14495-1.1999]
   and [HuffYUV].

3.3.1.  Exception



   If "colorspace_type == 0 && bits_per_raw_sample == 16 && ( coder_type
   == 1 || coder_type == 2 )" (see Sections 4.2.5, 4.2.7, and 4.2.3),
   the following median predictor MUST be used:

   median(left16s, top16s, left16s + top16s - diag16s)

   where:

   left16s = l  >= 32768 ? ( l  - 65536 ) : l
   top16s  = t  >= 32768 ? ( t  - 65536 ) : t
   diag16s = tl >= 32768 ? ( tl - 65536 ) : tl

   Background: a two's complement 16-bit signed integer was used for
   storing Sample values in all known implementations of FFV1 bitstream
   (see Appendix C).  So in some circumstances, the most significant bit
   was wrongly interpreted (used as a sign bit instead of the 16th bit
   of an unsigned integer).  Note that when the issue was discovered,
   the only impacted configuration of all known implementations was the
   16-bit YCbCr with no pixel transformation and with the range coder
   coder type, as the other potentially impacted configurations (e.g.,
   the 15/16-bit JPEG 2000 Reversible Color Transform (RCT)
   [ISO.15444-1.2019] with range coder or the 16-bit content with the
   Golomb Rice coder type) were not implemented.  Meanwhile, the 16-bit
   JPEG 2000 RCT with range coder was deployed without this issue in one
   implementation and validated by one conformance checker.  It is
   expected (to be confirmed) that this exception for the median
   predictor will be removed in the next version of the FFV1 bitstream.

3.4.  Quantization Table Sets



   Quantization Tables are used on Sample Differences (see Section 3.8),
   so Quantized Sample Differences are stored in the bitstream.

   The FFV1 bitstream contains one or more Quantization Table Sets.
   Each Quantization Table Set contains exactly five Quantization Tables
   with each Quantization Table corresponding to one of the five
   Quantized Sample Differences.  For each Quantization Table, both the
   number of quantization steps and their distribution are stored in the
   FFV1 bitstream; each Quantization Table has exactly 256 entries, and
   the eight least significant bits of the Quantized Sample Difference
   are used as an index:

   Q_j[k] = quant_tables[i][j][k&255]

    Figure 4: Description of the mapping from sample differences to the
                corresponding Quantized Sample Differences.

   In this formula, "i" is the Quantization Table Set index, "j" is the
   Quantized Table index, and "k" is the Quantized Sample Difference
   (see Section 4.1.1).

3.5.  Context



   Relative to any Sample "X", the Quantized Sample Differences "L-l",
   "l-tl", "tl-t", "T-t", and "t-tr" are used as context:

   context = Q_0[l - tl] +
             Q_1[tl - t] +
             Q_2[t - tr] +
             Q_3[L - l]  +
             Q_4[T - t]

           Figure 5: Description of the computing of the Context.

   If "context >= 0" then "context" is used, and the difference between
   the Sample and its predicted value is encoded as is; else "-context"
   is used, and the difference between the Sample and its predicted
   value is encoded with a flipped sign.

3.6.  Quantization Table Set Indexes



   For each Plane of each Slice, a Quantization Table Set is selected
   from an index:

   *  For Y Plane, "quant_table_set_index[ 0 ]" index is used.

   *  For Cb and Cr Planes, "quant_table_set_index[ 1 ]" index is used.

   *  For extra Plane, "quant_table_set_index[ (version <= 3 ||
      chroma_planes) ? 2 : 1 ]" index is used.

   Background: in the first implementations of the FFV1 bitstream, the
   index for Cb and Cr Planes was stored even if it was not used
   ("chroma_planes" set to 0), this index is kept for "version <= 3" in
   order to keep compatibility with FFV1 bitstreams in the wild.

3.7.  Color Spaces



   FFV1 supports several color spaces.  The count of allowed coded
   Planes and the meaning of the extra Plane are determined by the
   selected color space.

   The FFV1 bitstream interleaves data in an order determined by the
   color space.  In YCbCr for each Plane, each Line is coded from top to
   bottom, and for each Line, each Sample is coded from left to right.
   In JPEG 2000 RCT for each Line from top to bottom, each Plane is
   coded, and for each Plane, each Sample is encoded from left to right.

3.7.1.  YCbCr



   This color space allows one to four Planes.

   The Cb and Cr Planes are optional, but if they are used, then they
   MUST be used together.  Omitting the Cb and Cr Planes codes the
   frames in gray scale without color data.

   An optional transparency Plane can be used to code transparency data.

   An FFV1 Frame using YCbCr MUST use one of the following arrangements:

   *  Y

   *  Y, Transparency

   *  Y, Cb, Cr

   *  Y, Cb, Cr, Transparency

   The Y Plane MUST be coded first.  If the Cb and Cr Planes are used,
   then they MUST be coded after the Y Plane.  If a transparency Plane
   is used, then it MUST be coded last.

3.7.2.  RGB



   This color space allows three or four Planes.

   An optional transparency Plane can be used to code transparency data.

   JPEG 2000 RCT is a Reversible Color Transform that codes RGB (Red,
   Green, Blue) Planes losslessly in a modified YCbCr color space
   [ISO.15444-1.2019].  Reversible pixel transformations between YCbCr
   and RGB use the following formulae:

   Cb = b - g
   Cr = r - g
   Y = g + (Cb + Cr) >> 2

       Figure 6: Description of the transformation of pixels from RGB
             color space to coded, modified YCbCr color space.

   g = Y - (Cb + Cr) >> 2
   r = Cr + g
   b = Cb + g

     Figure 7: Description of the transformation of pixels from coded,
               modified YCbCr color space to RGB color space.

   Cb and Cr are positively offset by "1 << bits_per_raw_sample" after
   the conversion from RGB to the modified YCbCr, and they are
   negatively offset by the same value before the conversion from the
   modified YCbCr to RGB in order to have only nonnegative values after
   the conversion.

   When FFV1 uses the JPEG 2000 RCT, the horizontal Lines are
   interleaved to improve caching efficiency since it is most likely
   that the JPEG 2000 RCT will immediately be converted to RGB during
   decoding.  The interleaved coding order is also Y, then Cb, then Cr,
   and then, if used, transparency.

   As an example, a Frame that is two pixels wide and two pixels high
   could comprise the following structure:

   +------------------------+------------------------+
   | Pixel(1,1)             | Pixel(2,1)             |
   | Y(1,1) Cb(1,1) Cr(1,1) | Y(2,1) Cb(2,1) Cr(2,1) |
   +------------------------+------------------------+
   | Pixel(1,2)             | Pixel(2,2)             |
   | Y(1,2) Cb(1,2) Cr(1,2) | Y(2,2) Cb(2,2) Cr(2,2) |
   +------------------------+------------------------+

   In JPEG 2000 RCT, the coding order is left to right and then top to
   bottom, with values interleaved by Lines and stored in this order:

   Y(1,1) Y(2,1) Cb(1,1) Cb(2,1) Cr(1,1) Cr(2,1) Y(1,2) Y(2,2) Cb(1,2)
   Cb(2,2) Cr(1,2) Cr(2,2)

3.7.2.1.  RGB Exception



   If "bits_per_raw_sample" is between 9 and 15 inclusive and
   "extra_plane" is 0, the following formulae for reversible conversions
   between YCbCr and RGB MUST be used instead of the ones above:

   Cb = g - b
   Cr = r - b
   Y = b + (Cb + Cr) >> 2

       Figure 8: Description of the transformation of pixels from RGB
        color space to coded, modified YCbCr color space (in case of
                                exception).

   b = Y - (Cb + Cr) >> 2
   r = Cr + b
   g = Cb + b

     Figure 9: Description of the transformation of pixels from coded,
         modified YCbCr color space to RGB color space (in case of
                                exception).

   Background: At the time of this writing, in all known implementations
   of the FFV1 bitstream, when "bits_per_raw_sample" was between 9 and
   15 inclusive and "extra_plane" was 0, Green Blue Red (GBR) Planes
   were used as Blue Green Red (BGR) Planes during both encoding and
   decoding.  Meanwhile, 16-bit JPEG 2000 RCT was implemented without
   this issue in one implementation and validated by one conformance
   checker.  Methods to address this exception for the transform are
   under consideration for the next version of the FFV1 bitstream.

3.8.  Coding of the Sample Difference



   Instead of coding the n+1 bits of the Sample Difference with Huffman
   or Range coding (or n+2 bits, in the case of JPEG 2000 RCT), only the
   n (or n+1, in the case of JPEG 2000 RCT) least significant bits are
   used, since this is sufficient to recover the original Sample.  In
   Figure 10, the term "bits" represents "bits_per_raw_sample + 1" for
   JPEG 2000 RCT or "bits_per_raw_sample" otherwise:

   coder_input = ((sample_difference + 2 ^ (bits - 1)) &
                 (2 ^ bits - 1)) - 2 ^ (bits - 1)

      Figure 10: Description of the coding of the Sample Difference in
                               the bitstream.

3.8.1.  Range Coding Mode



   Early experimental versions of FFV1 used the Context-Adaptive Binary
   Arithmetic Coding (CABAC) coder from H.264 as defined in
   [ISO.14496-10.2020], but due to the uncertain patent/royalty
   situation, as well as its slightly worse performance, CABAC was
   replaced by a range coder based on an algorithm defined by G. Nigel
   N. Martin in 1979 [Range-Encoding].

3.8.1.1.  Range Binary Values



   To encode binary digits efficiently, a range coder is used.  A range
   coder encodes a series of binary symbols by using a probability
   estimation within each context.  The sizes of each of the two
   subranges are proportional to their estimated probability.  The
   Quantization Table is used to choose the context used from the
   surrounding image sample values for the case of coding the Sample
   Differences.  The coding of integers is done by coding multiple
   binary values.  The range decoder will read bytes until it can
   determine into which subrange the input falls to return the next
   binary symbol.

   To describe Range coding for FFV1, the following values are used:

   C_i  the i-th context.

   B_i  the i-th byte of the bytestream.

   R_i  the Range at the i-th symbol.

   r_i  the boundary between two subranges of R_i: a subrange of r_i
      values and a subrange R_i - r_i values.

   L_i  the Low value of the Range at the i-th symbol.

   l_i  a temporary variable to carry over or adjust the Low value of
      the Range between range coding operations.

   t_i  a temporary variable to transmit subranges between range coding
      operations.

   b_i  the i-th range-coded binary value.

   S_(0, i)  the i-th initial state.

   j_n  the length of the bytestream encoding n binary symbols.

   The following range coder state variables are initialized to the
   following values.  The Range is initialized to a value of 65,280
   (expressed in base 16 as 0xFF00) as depicted in Figure 11.  The Low
   is initialized according to the value of the first two bytes as
   depicted in Figure 12. j_i tracks the length of the bytestream
   encoding while incrementing from an initial value of j_0 to a final
   value of j_n. j_0 is initialized to 2 as depicted in Figure 13.

   R_0 = 65280

                Figure 11: The initial value for the Range.

   L_0 = 2 ^ 8 * B_0 + B_1

        Figure 12: The initial value for Low is set according to the
                     first two bytes of the bytestream.

   j_0 = 2

          Figure 13: The initial value for "j", the length of the
                            bytestream encoding.

   The following equations define how the range coder variables evolve
   as it reads or writes symbols.

   r_i = floor( ( R_i * S_(i, C_i) ) / 2 ^ 8 )

        Figure 14: This formula shows the positioning of range split
                            based on the state.

              b_i =  0                        <==>
              L_i <  R_i - r_i                ==>
      S_(i+1,C_i) =  zero_state_(S_(i, C_i))  AND
              l_i =  L_i                      AND
              t_i =  R_i - r_i

              b_i =  1                        <==>
              L_i >= R_i - r_i                ==>
      S_(i+1,C_i) =  one_state_(S_(i, C_i))   AND
              l_i =  L_i - R_i + r_i          AND
              t_i =  r_i

      Figure 15: This formula shows the linking of the decoded symbol
          (represented as b_i), the updated state (represented as
      S_(i+1,C_i)), and the updated range (represented as a range from
                                l_i to t_i).

   C_i != k ==> S_(i + 1, k) = S_(i, k)

       Figure 16: If the value of "k" is unequal to the i-th value of
      context, in other words, if the state is unchanged from the last
     symbol coding, then the value of the state is carried over to the
                            next symbol coding.

   t_i       <  2 ^ 8                         ==>
   R_(i + 1) =  2 ^ 8 * t_i                   AND
   L_(i + 1) =  2 ^ 8 * l_i + B_(j_i)         AND
   j_(i + 1) =  j_i + 1

   t_i       >= 2 ^ 8                         ==>
   R_(i + 1) =  t_i                           AND
   L_(i + 1) =  l_i                           AND
   j_(i + 1) =  j_i

     Figure 17: This formula shows the linking of the range coder with
                 the reading or writing of the bytestream.

       range = 0xFF00;
       end   = 0;
       low   = get_bits(16);
       if (low >= range) {
           low = range;
           end = 1;
       }

        Figure 18: A pseudocode description of the initialization of
                range coder variables in Range binary mode.

   refill() {
       if (range < 256) {
           range = range * 256;
           low   = low * 256;
           if (!end) {
               c.low += get_bits(8);
               if (remaining_bits_in_bitstream( NumBytes ) == 0) {
                   end = 1;
               }
           }
       }
   }

     Figure 19: A pseudocode description of refilling the binary value
                         buffer of the range coder.

   get_rac(state) {
       rangeoff  = (range * state) / 256;
       range    -= rangeoff;
       if (low < range) {
           state = zero_state[state];
           refill();
           return 0;
       } else {
           low   -= range;
           state  = one_state[state];
           range  = rangeoff;
           refill();
           return 1;
       }
   }

     Figure 20: A pseudocode description of the read of a binary value
                           in Range binary mode.

3.8.1.1.1.  Termination


   The range coder can be used in three modes:

   *  In Open mode when decoding, every symbol the reader attempts to
      read is available.  In this mode, arbitrary data can have been
      appended without affecting the range coder output.  This mode is
      not used in FFV1.

   *  In Closed mode, the length in bytes of the bytestream is provided
      to the range decoder.  Bytes beyond the length are read as 0 by
      the range decoder.  This is generally one byte shorter than the
      Open mode.

   *  In Sentinel mode, the exact length in bytes is not known, and thus
      the range decoder MAY read into the data that follows the range-
      coded bytestream by one byte.  In Sentinel mode, the end of the
      range-coded bytestream is a binary symbol with state 129, which
      value SHALL be discarded.  After reading this symbol, the range
      decoder will have read one byte beyond the end of the range-coded
      bytestream.  This way the byte position of the end can be
      determined.  Bytestreams written in Sentinel mode can be read in
      Closed mode if the length can be determined.  In this case, the
      last (sentinel) symbol will be read uncorrupted and be of value 0.

   The above describes the range decoding.  Encoding is defined as any
   process that produces a decodable bytestream.

   There are three places where range coder termination is needed in
   FFV1.  The first is in the "Configuration Record", which in this case
   the size of the range-coded bytestream is known and handled as Closed
   mode.  The second is the switch from the "Slice Header", which is
   range coded to Golomb-coded Slices as Sentinel mode.  The third is
   the end of range-coded Slices, which need to terminate before the CRC
   at their end.  This can be handled as Sentinel mode or as Closed mode
   if the CRC position has been determined.

3.8.1.2.  Range Nonbinary Values



   To encode scalar integers, it would be possible to encode each bit
   separately and use the past bits as context.  However, that would
   mean 255 contexts per 8-bit symbol, which is not only a waste of
   memory but also requires more past data to reach a reasonably good
   estimate of the probabilities.  Alternatively, it would also be
   possible to assume a Laplacian distribution and only deal with its
   variance and mean (as in Huffman coding).  However, for maximum
   flexibility and simplicity, the chosen method uses a single symbol to
   encode if a number is 0, and if the number is nonzero, it encodes the
   number using its exponent, mantissa, and sign.  The exact contexts
   used are best described by Figure 21.

   int get_symbol(RangeCoder *c, uint8_t *state, int is_signed) {
       if (get_rac(c, state + 0) {
           return 0;
       }

       int e = 0;
       while (get_rac(c, state + 1 + min(e, 9)) { //1..10
           e++;
       }

       int a = 1;
       for (int i = e - 1; i >= 0; i--) {
           a = a * 2 + get_rac(c, state + 22 + min(i, 9));  // 22..31
       }

       if (!is_signed) {
           return a;
       }

       if (get_rac(c, state + 11 + min(e, 10))) { //11..21
           return -a;
       } else {
           return a;
       }
   }

        Figure 21: A pseudocode description of the contexts of Range
                             nonbinary values.

   "get_symbol" is used for the read out of "sample_difference"
   indicated in Figure 10.

   "get_rac" returns a boolean computed from the bytestream as described
   by the formula found in Figure 14 and by the pseudocode found in
   Figure 20.

3.8.1.3.  Initial Values for the Context Model



   When the "keyframe" value (see Section 4.4) is 1, all range coder
   state variables are set to their initial state.

3.8.1.4.  State Transition Table



   In Range Coding Mode, a state transition table is used, indicating to
   which state the decoder will move based on the current state and the
   value extracted from Figure 20.

   one_state_i =
          default_state_transition_i + state_transition_delta_i

        Figure 22: Description of the coding of the state transition
                 table for a "get_rac" readout value of 1.

   zero_state_i = 256 - one_state_(256-i)

        Figure 23: Description of the coding of the state transition
                 table for a "get_rac" readout value of 0.

3.8.1.5.  default_state_transition



   By default, the following state transition table is used:

     0,  0,  0,  0,  0,  0,  0,  0, 20, 21, 22, 23, 24, 25, 26, 27,

    28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 37, 38, 39, 40, 41, 42,

    43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 56, 57,

    58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73,

    74, 75, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88,

    89, 90, 91, 92, 93, 94, 94, 95, 96, 97, 98, 99,100,101,102,103,

   104,105,106,107,108,109,110,111,112,113,114,114,115,116,117,118,

   119,120,121,122,123,124,125,126,127,128,129,130,131,132,133,133,

   134,135,136,137,138,139,140,141,142,143,144,145,146,147,148,149,

   150,151,152,152,153,154,155,156,157,158,159,160,161,162,163,164,

   165,166,167,168,169,170,171,171,172,173,174,175,176,177,178,179,

   180,181,182,183,184,185,186,187,188,189,190,190,191,192,194,194,

   195,196,197,198,199,200,201,202,202,204,205,206,207,208,209,209,

   210,211,212,213,215,215,216,217,218,219,220,220,222,223,224,225,

   226,227,227,229,229,230,231,232,234,234,235,236,237,238,239,240,

   241,242,243,244,245,246,247,248,248,  0,  0,  0,  0,  0,  0,  0,

        Figure 24: Default state transition table for Range coding.

3.8.1.6.  Alternative State Transition Table



   The alternative state transition table has been built using iterative
   minimization of frame sizes and generally performs better than the
   default.  To use it, the "coder_type" (see Section 4.2.3) MUST be set
   to 2, and the difference to the default MUST be stored in the
   "Parameters", see Section 4.2.  At the time of this writing, the
   reference implementation of FFV1 in FFmpeg uses Figure 25 by default
   when Range coding is used.

     0, 10, 10, 10, 10, 16, 16, 16, 28, 16, 16, 29, 42, 49, 20, 49,

    59, 25, 26, 26, 27, 31, 33, 33, 33, 34, 34, 37, 67, 38, 39, 39,

    40, 40, 41, 79, 43, 44, 45, 45, 48, 48, 64, 50, 51, 52, 88, 52,

    53, 74, 55, 57, 58, 58, 74, 60,101, 61, 62, 84, 66, 66, 68, 69,

    87, 82, 71, 97, 73, 73, 82, 75,111, 77, 94, 78, 87, 81, 83, 97,

    85, 83, 94, 86, 99, 89, 90, 99,111, 92, 93,134, 95, 98,105, 98,

   105,110,102,108,102,118,103,106,106,113,109,112,114,112,116,125,

   115,116,117,117,126,119,125,121,121,123,145,124,126,131,127,129,

   165,130,132,138,133,135,145,136,137,139,146,141,143,142,144,148,

   147,155,151,149,151,150,152,157,153,154,156,168,158,162,161,160,

   172,163,169,164,166,184,167,170,177,174,171,173,182,176,180,178,

   175,189,179,181,186,183,192,185,200,187,191,188,190,197,193,196,

   197,194,195,196,198,202,199,201,210,203,207,204,205,206,208,214,

   209,211,221,212,213,215,224,216,217,218,219,220,222,228,223,225,

   226,224,227,229,240,230,231,232,233,234,235,236,238,239,237,242,

   241,243,242,244,245,246,247,248,249,250,251,252,252,253,254,255,

      Figure 25: Alternative state transition table for Range coding.

3.8.2.  Golomb Rice Mode



   The end of the bitstream of the Frame is padded with zeroes until the
   bitstream contains a multiple of eight bits.

3.8.2.1.  Signed Golomb Rice Codes



   This coding mode uses Golomb Rice codes.  The VLC is split into two
   parts: the prefix and suffix.  The prefix stores the most significant
   bits or indicates if the symbol is too large to be stored (this is
   known as the ESC case, see Section 3.8.2.1.1).  The suffix either
   stores the k least significant bits or stores the whole number in the
   ESC case.

   int get_ur_golomb(k) {
       for (prefix = 0; prefix < 12; prefix++) {
           if (get_bits(1)) {
               return get_bits(k) + (prefix << k);
           }
       }
       return get_bits(bits) + 11;
   }

       Figure 26: A pseudocode description of the read of an unsigned
                        integer in Golomb Rice mode.

   int get_sr_golomb(k) {
       v = get_ur_golomb(k);
       if (v & 1) return - (v >> 1) - 1;
       else       return   (v >> 1);
   }

        Figure 27: A pseudocode description of the read of a signed
                        integer in Golomb Rice mode.

3.8.2.1.1.  Prefix


                        +================+=======+
                        | bits           | value |
                        +================+=======+
                        | 1              | 0     |
                        +----------------+-------+
                        | 01             | 1     |
                        +----------------+-------+
                        | ...            | ...   |
                        +----------------+-------+
                        | 0000 0000 01   | 9     |
                        +----------------+-------+
                        | 0000 0000 001  | 10    |
                        +----------------+-------+
                        | 0000 0000 0001 | 11    |
                        +----------------+-------+
                        | 0000 0000 0000 | ESC   |
                        +----------------+-------+

                           Table 1: Description
                           of the coding of the
                             prefix of signed
                            Golomb Rice codes.

   ESC is an ESCape symbol to indicate that the symbol to be stored is
   too large for normal storage and that an alternate storage method is
   used.

3.8.2.1.2.  Suffix


           +---------+----------------------------------------+
           | non-ESC | the k least significant bits MSB first |
           +---------+----------------------------------------+
           | ESC     | the value - 11, in MSB first order     |
           +---------+----------------------------------------+

             Table 2: Description of the coding of the suffix
                       of signed Golomb Rice codes.

   ESC MUST NOT be used if the value can be coded as non-ESC.

3.8.2.1.3.  Examples


   Table 3 shows practical examples of how signed Golomb Rice codes are
   decoded based on the series of bits extracted from the bitstream as
   described by the method above:

                  +=====+=======================+=======+
                  |  k  | bits                  | value |
                  +=====+=======================+=======+
                  |  0  | 1                     |     0 |
                  +-----+-----------------------+-------+
                  |  0  | 001                   |     2 |
                  +-----+-----------------------+-------+
                  |  2  | 1 00                  |     0 |
                  +-----+-----------------------+-------+
                  |  2  | 1 10                  |     2 |
                  +-----+-----------------------+-------+
                  |  2  | 01 01                 |     5 |
                  +-----+-----------------------+-------+
                  | any | 000000000000 10000000 |   139 |
                  +-----+-----------------------+-------+

                       Table 3: Examples of decoded,
                         signed Golomb Rice codes.

3.8.2.2.  Run Mode



   Run mode is entered when the context is 0 and left as soon as a
   nonzero difference is found.  The Sample Difference is identical to
   the predicted one.  The run and the first different Sample Difference
   are coded as defined in Section 3.8.2.4.1.

3.8.2.2.1.  Run Length Coding


   The run value is encoded in two parts.  The prefix part stores the
   more significant part of the run as well as adjusting the "run_index"
   that determines the number of bits in the less significant part of
   the run.  The second part of the value stores the less significant
   part of the run as it is.  The "run_index" is reset to zero for each
   Plane and Slice.

   log2_run[41] = {
    0, 0, 0, 0, 1, 1, 1, 1,
    2, 2, 2, 2, 3, 3, 3, 3,
    4, 4, 5, 5, 6, 6, 7, 7,
    8, 9,10,11,12,13,14,15,
   16,17,18,19,20,21,22,23,
   24,
   };

   if (run_count == 0 && run_mode == 1) {
       if (get_bits(1)) {
           run_count = 1 << log2_run[run_index];
           if (x + run_count <= w) {
               run_index++;
           }
       } else {
           if (log2_run[run_index]) {
               run_count = get_bits(log2_run[run_index]);
           } else {
               run_count = 0;
           }
           if (run_index) {
               run_index--;
           }
           run_mode = 2;
       }
   }

   The "log2_run" array is also used within [ISO.14495-1.1999].

3.8.2.3.  Sign Extension



   "sign_extend" is the function of increasing the number of bits of an
   input binary number in two's complement signed number representation
   while preserving the input number's sign (positive/negative) and
   value, in order to fit in the output bit width.  It MAY be computed
   with the following:

   sign_extend(input_number, input_bits) {
       negative_bias = 1 << (input_bits - 1);
       bits_mask = negative_bias - 1;
       output_number = input_number & bits_mask; // Remove negative bit
       is_negative = input_number & negative_bias; // Test negative bit
       if (is_negative)
           output_number -= negative_bias;
       return output_number
   }

3.8.2.4.  Scalar Mode



   Each difference is coded with the per context mean prediction removed
   and a per context value for "k".

   get_vlc_symbol(state) {
       i = state->count;
       k = 0;
       while (i < state->error_sum) {
           k++;
           i += i;
       }

       v = get_sr_golomb(k);

       if (2 * state->drift < -state->count) {
           v = -1 - v;
       }

       ret = sign_extend(v + state->bias, bits);

       state->error_sum += abs(v);
       state->drift     += v;

       if (state->count == 128) {
           state->count     >>= 1;
           state->drift     >>= 1;
           state->error_sum >>= 1;
       }
       state->count++;
       if (state->drift <= -state->count) {
           state->bias = max(state->bias - 1, -128);

           state->drift = max(state->drift + state->count,
                              -state->count + 1);
       } else if (state->drift > 0) {
           state->bias = min(state->bias + 1, 127);

           state->drift = min(state->drift - state->count, 0);
       }

       return ret;
   }

3.8.2.4.1.  Golomb Rice Sample Difference Coding


   Level coding is identical to the normal difference coding with the
   exception that the 0 value is removed as it cannot occur:

       diff = get_vlc_symbol(context_state);
       if (diff >= 0) {
           diff++;
       }

   Note that this is different from JPEG-LS (lossless JPEG), which
   doesn't use prediction in run mode and uses a different encoding and
   context model for the last difference.  On a small set of test
   Samples, the use of prediction slightly improved the compression
   rate.

3.8.2.5.  Initial Values for the VLC Context State



   When "keyframe" (see Section 4.4) value is 1, all VLC coder state
   variables are set to their initial state.

       drift     = 0;
       error_sum = 4;
       bias      = 0;
       count     = 1;

4.  Bitstream



   An FFV1 bitstream is composed of a series of one or more Frames and
   (when required) a "Configuration Record".

   Within the following subsections, pseudocode as described in
   Section 2.2.1 is used to explain the structure of each FFV1 bitstream
   component.  Table 4 lists symbols used to annotate that pseudocode in
   order to define the storage of the data referenced in that line of
   pseudocode.

       +========+==================================================+
       | symbol | definition                                       |
       +========+==================================================+
       | u(n)   | Unsigned, big-endian integer symbol using n bits |
       +--------+--------------------------------------------------+
       | br     | Boolean (1-bit) symbol that is range coded with  |
       |        | the method described in Section 3.8.1.1          |
       +--------+--------------------------------------------------+
       | ur     | Unsigned scalar symbol that is range coded with  |
       |        | the method described in Section 3.8.1.2          |
       +--------+--------------------------------------------------+
       | sr     | Signed scalar symbol that is range coded with    |
       |        | the method described in Section 3.8.1.2          |
       +--------+--------------------------------------------------+
       | sd     | Sample Difference symbol that is coded with the  |
       |        | method described in Section 3.8                  |
       +--------+--------------------------------------------------+

        Table 4: Definition of pseudocode symbols for this document.

   The following MUST be provided by external means during the
   initialization of the decoder:

   "frame_pixel_width" is defined as Frame width in pixels.

   "frame_pixel_height" is defined as Frame height in pixels.

   Default values at the decoder initialization phase:

   "ConfigurationRecordIsPresent" is set to 0.

4.1.  Quantization Table Set



   The Quantization Table Sets store a sequence of values that are equal
   to one less than the count of equal concurrent entries for each set
   of equal concurrent entries within the first half of the table
   (represented as "len - 1" in the pseudocode below) using the method
   described in Section 3.8.1.2.  The second half doesn't need to be
   stored as it is identical to the first with flipped sign. "scale" and
   "len_count[ i ][ j ]" are temporary values used for the computing of
   "context_count[ i ]" and are not used outside Quantization Table Set
   pseudocode.

   Example:

   Table: 0 0 1 1 1 1 2 2 -2 -2 -2 -1 -1 -1 -1 0

   Stored values: 1, 3, 1

   "QuantizationTableSet" has its own initial states, all set to 128.

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   QuantizationTableSet( i ) {                                   |
       scale = 1                                                 |
       for (j = 0; j < MAX_CONTEXT_INPUTS; j++) {                |
           QuantizationTable( i, j, scale )                      |
           scale *= 2 * len_count[ i ][ j ] - 1                  |
       }                                                         |
       context_count[ i ] = ceil( scale / 2 )                    |
   }                                                             |

   "MAX_CONTEXT_INPUTS" is 5.

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   QuantizationTable(i, j, scale) {                              |
       v = 0                                                     |
       for (k = 0; k < 128;) {                                   |
           len - 1                                               | ur
           for (n = 0; n < len; n++) {                           |
               quant_tables[ i ][ j ][ k ] = scale * v           |
               k++                                               |
           }                                                     |
           v++                                                   |
       }                                                         |
       for (k = 1; k < 128; k++) {                               |
           quant_tables[ i ][ j ][ 256 - k ] = \                 |
           -quant_tables[ i ][ j ][ k ]                          |
       }                                                         |
       quant_tables[ i ][ j ][ 128 ] = \                         |
       -quant_tables[ i ][ j ][ 127 ]                            |
       len_count[ i ][ j ] = v                                   |
   }                                                             |

4.1.1.  "quant_tables"



   "quant_tables[ i ][ j ][ k ]" indicates the Quantization Table value
   of the Quantized Sample Difference "k" of the Quantization Table "j"
   of the Quantization Table Set "i".

4.1.2.  "context_count"



   "context_count[ i ]" indicates the count of contexts for Quantization
   Table Set "i". "context_count[ i ]" MUST be less than or equal to
   32768.

4.2.  Parameters



   The "Parameters" section, which could be in a global header of a
   container file that may or may not be considered to be part of the
   bitstream, contains significant characteristics about the decoding
   configuration used for all instances of Frame (in FFV1 versions 0 and
   1) or the whole FFV1 bitstream (other versions), including the stream
   version, color configuration, and Quantization Tables.  Figure 28
   describes the contents of the bitstream.

   "Parameters" has its own initial states, all set to 128.

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   Parameters( ) {                                               |
       version                                                   | ur
       if (version >= 3) {                                       |
           micro_version                                         | ur
       }                                                         |
       coder_type                                                | ur
       if (coder_type > 1) {                                     |
           for (i = 1; i < 256; i++) {                           |
               state_transition_delta[ i ]                       | sr
           }                                                     |
       }                                                         |
       colorspace_type                                           | ur
       if (version >= 1) {                                       |
           bits_per_raw_sample                                   | ur
       }                                                         |
       chroma_planes                                             | br
       log2_h_chroma_subsample                                   | ur
       log2_v_chroma_subsample                                   | ur
       extra_plane                                               | br
       if (version >= 3) {                                       |
           num_h_slices - 1                                      | ur
           num_v_slices - 1                                      | ur
           quant_table_set_count                                 | ur
       }                                                         |
       for (i = 0; i < quant_table_set_count; i++) {             |
           QuantizationTableSet( i )                             |
       }                                                         |
       if (version >= 3) {                                       |
           for (i = 0; i < quant_table_set_count; i++) {         |
               states_coded                                      | br
               if (states_coded) {                               |
                   for (j = 0; j < context_count[ i ]; j++) {    |
                       for (k = 0; k < CONTEXT_SIZE; k++) {      |
                           initial_state_delta[ i ][ j ][ k ]    | sr
                       }                                         |
                   }                                             |
               }                                                 |
           }                                                     |
           ec                                                    | ur
           intra                                                 | ur
       }                                                         |
   }                                                             |

       Figure 28: A pseudocode description of the bitstream contents.

   CONTEXT_SIZE is 32.

4.2.1.  "version"



   "version" specifies the version of the FFV1 bitstream.

   Each version is incompatible with other versions: decoders SHOULD
   reject FFV1 bitstreams due to an unknown version.

   Decoders SHOULD reject FFV1 bitstreams with "version <= 1 &&
   ConfigurationRecordIsPresent == 1".

   Decoders SHOULD reject FFV1 bitstreams with "version >= 3 &&
   ConfigurationRecordIsPresent == 0".

                    +=======+=========================+
                    | value | version                 |
                    +=======+=========================+
                    | 0     | FFV1 version 0          |
                    +-------+-------------------------+
                    | 1     | FFV1 version 1          |
                    +-------+-------------------------+
                    | 2     | reserved*               |
                    +-------+-------------------------+
                    | 3     | FFV1 version 3          |
                    +-------+-------------------------+
                    | Other | reserved for future use |
                    +-------+-------------------------+

                        Table 5: The definitions for
                             "version" values.

   * Version 2 was experimental and this document does not describe it.

4.2.2.  "micro_version"



   "micro_version" specifies the micro-version of the FFV1 bitstream.

   After a version is considered stable (a micro-version value is
   assigned to be the first stable variant of a specific version), each
   new micro-version after this first stable variant is compatible with
   the previous micro-version: decoders SHOULD NOT reject FFV1
   bitstreams due to an unknown micro-version equal or above the micro-
   version considered as stable.

   Meaning of "micro_version" for "version" 3:

                    +=======+=========================+
                    | value | micro_version           |
                    +=======+=========================+
                    | 0...3 | reserved*               |
                    +-------+-------------------------+
                    | 4     | first stable variant    |
                    +-------+-------------------------+
                    | Other | reserved for future use |
                    +-------+-------------------------+

                        Table 6: The definitions for
                      "micro_version" values for FFV1
                                 version 3.

   * Development versions may be incompatible with the stable variants.

4.2.3.  "coder_type"



   "coder_type" specifies the coder used.

        +=======+=================================================+
        | value | coder used                                      |
        +=======+=================================================+
        | 0     | Golomb Rice                                     |
        +-------+-------------------------------------------------+
        | 1     | Range coder with default state transition table |
        +-------+-------------------------------------------------+
        | 2     | Range coder with custom state transition table  |
        +-------+-------------------------------------------------+
        | Other | reserved for future use                         |
        +-------+-------------------------------------------------+

             Table 7: The definitions for "coder_type" values.

   Restrictions:

   If "coder_type" is 0, then "bits_per_raw_sample" SHOULD NOT be > 8.

   Background: At the time of this writing, there is no known
   implementation of FFV1 bitstream supporting the Golomb Rice algorithm
   with "bits_per_raw_sample" greater than eight, and range coder is
   preferred.

4.2.4.  "state_transition_delta"



   "state_transition_delta" specifies the range coder custom state
   transition table.

   If "state_transition_delta" is not present in the FFV1 bitstream, all
   range coder custom state transition table elements are assumed to be
   0.

4.2.5.  "colorspace_type"



   "colorspace_type" specifies the color space encoded, the pixel
   transformation used by the encoder, the extra Plane content, as well
   as interleave method.

   +=======+==============+================+==============+============+
   | value | color space  | pixel          | extra Plane  | interleave |
   |       | encoded      | transformation | content      | method     |
   +=======+==============+================+==============+============+
   | 0     | YCbCr        | None           | Transparency | Plane then |
   |       |              |                |              | Line       |
   +-------+--------------+----------------+--------------+------------+
   | 1     | RGB          | JPEG 2000 RCT  | Transparency | Line then  |
   |       |              |                |              | Plane      |
   +-------+--------------+----------------+--------------+------------+
   | Other | reserved     | reserved for   | reserved for | reserved   |
   |       | for future   | future use     | future use   | for future |
   |       | use          |                |              | use        |
   +-------+--------------+----------------+--------------+------------+

           Table 8: The definitions for "colorspace_type" values.

   FFV1 bitstreams with "colorspace_type == 1 && (chroma_planes != 1 ||
   log2_h_chroma_subsample != 0 || log2_v_chroma_subsample != 0)" are
   not part of this specification.

4.2.6.  "chroma_planes"



   "chroma_planes" indicates if chroma (color) Planes are present.

                 +=======+===============================+
                 | value | presence                      |
                 +=======+===============================+
                 | 0     | chroma Planes are not present |
                 +-------+-------------------------------+
                 | 1     | chroma Planes are present     |
                 +-------+-------------------------------+

                        Table 9: The definitions for
                          "chroma_planes" values.

4.2.7.  "bits_per_raw_sample"



   "bits_per_raw_sample" indicates the number of bits for each Sample.
   Inferred to be 8 if not present.

                +=======+=================================+
                | value | bits for each Sample            |
                +=======+=================================+
                | 0     | reserved*                       |
                +-------+---------------------------------+
                | Other | the actual bits for each Sample |
                +-------+---------------------------------+

                       Table 10: The definitions for
                       "bits_per_raw_sample" values.

   * Encoders MUST NOT store "bits_per_raw_sample = 0".  Decoders SHOULD
   accept and interpret "bits_per_raw_sample = 0" as 8.

4.2.8.  "log2_h_chroma_subsample"



   "log2_h_chroma_subsample" indicates the subsample factor, stored in
   powers to which the number 2 is raised, between luma and chroma width
   ("chroma_width = 2 ^ -log2_h_chroma_subsample * luma_width").

4.2.9.  "log2_v_chroma_subsample"



   "log2_v_chroma_subsample" indicates the subsample factor, stored in
   powers to which the number 2 is raised, between luma and chroma
   height ("chroma_height = 2 ^ -log2_v_chroma_subsample *
   luma_height").

4.2.10.  "extra_plane"



   "extra_plane" indicates if an extra Plane is present.

                  +=======+============================+
                  | value | presence                   |
                  +=======+============================+
                  | 0     | extra Plane is not present |
                  +-------+----------------------------+
                  | 1     | extra Plane is present     |
                  +-------+----------------------------+

                      Table 11: The definitions for
                          "extra_plane" values.

4.2.11.  "num_h_slices"



   "num_h_slices" indicates the number of horizontal elements of the
   Slice raster.

   Inferred to be 1 if not present.

4.2.12.  "num_v_slices"



   "num_v_slices" indicates the number of vertical elements of the Slice
   raster.

   Inferred to be 1 if not present.

4.2.13.  "quant_table_set_count"



   "quant_table_set_count" indicates the number of Quantization
   Table Sets. "quant_table_set_count" MUST be less than or equal to 8.

   Inferred to be 1 if not present.

   MUST NOT be 0.

4.2.14.  "states_coded"



   "states_coded" indicates if the respective Quantization Table Set has
   the initial states coded.

   Inferred to be 0 if not present.

                +=======+================================+
                | value | initial states                 |
                +=======+================================+
                | 0     | initial states are not present |
                |       | and are assumed to be all 128  |
                +-------+--------------------------------+
                | 1     | initial states are present     |
                +-------+--------------------------------+

                      Table 12: The definitions for
                          "states_coded" values.

4.2.15.  "initial_state_delta"



   "initial_state_delta[ i ][ j ][ k ]" indicates the initial range
   coder state, and it is encoded using "k" as context index for the
   range coder and the following pseudocode:

   pred = j ? initial_states[ i ][j - 1][ k ] : 128

                Figure 29: Predictor value for the coding of
                   "initial_state_delta[ i ][ j ][ k ]".

   initial_state[ i ][ j ][ k ] =
          ( pred + initial_state_delta[ i ][ j ][ k ] ) & 255

                  Figure 30: Description of the coding of
                   "initial_state_delta[ i ][ j ][ k ]".

4.2.16.  "ec"



   "ec" indicates the error detection/correction type.

        +=======+=================================================+
        | value | error detection/correction type                 |
        +=======+=================================================+
        | 0     | 32-bit CRC in "ConfigurationRecord"             |
        +-------+-------------------------------------------------+
        | 1     | 32-bit CRC in "Slice" and "ConfigurationRecord" |
        +-------+-------------------------------------------------+
        | Other | reserved for future use                         |
        +-------+-------------------------------------------------+

                 Table 13: The definitions for "ec" values.

4.2.17.  "intra"



   "intra" indicates the constraint on "keyframe" in each instance of
   Frame.

   Inferred to be 0 if not present.

     +=======+=======================================================+
     | value | relationship                                          |
     +=======+=======================================================+
     | 0     | "keyframe" can be 0 or 1 (non keyframes or keyframes) |
     +-------+-------------------------------------------------------+
     | 1     | "keyframe" MUST be 1 (keyframes only)                 |
     +-------+-------------------------------------------------------+
     | Other | reserved for future use                               |
     +-------+-------------------------------------------------------+

               Table 14: The definitions for "intra" values.

4.3.  Configuration Record



   In the case of a FFV1 bitstream with "version >= 3", a "Configuration
   Record" is stored in the underlying container as described in
   Section 4.3.3.  It contains the "Parameters" used for all instances
   of Frame.  The size of the "Configuration Record", "NumBytes", is
   supplied by the underlying container.

   pseudocode                                                 | type
   -----------------------------------------------------------|-----
   ConfigurationRecord( NumBytes ) {                          |
       ConfigurationRecordIsPresent = 1                       |
       Parameters( )                                          |
       while (remaining_symbols_in_syntax(NumBytes - 4)) {    |
           reserved_for_future_use                            | br/ur/sr
       }                                                      |
       configuration_record_crc_parity                        | u(32)
   }                                                          |

4.3.1.  "reserved_for_future_use"



   "reserved_for_future_use" is a placeholder for future updates of this
   specification.

   Encoders conforming to this version of this specification SHALL NOT
   write "reserved_for_future_use".

   Decoders conforming to this version of this specification SHALL
   ignore "reserved_for_future_use".

4.3.2.  "configuration_record_crc_parity"



   "configuration_record_crc_parity" is 32 bits that are chosen so that
   the "Configuration Record" as a whole has a CRC remainder of zero.

   This is equivalent to storing the CRC remainder in the 32-bit parity.

   The CRC generator polynomial used is described in Section 4.9.3.

4.3.3.  Mapping FFV1 into Containers



   This "Configuration Record" can be placed in any file format that
   supports "Configuration Records", fitting as much as possible with
   how the file format stores "Configuration Records".  The
   "Configuration Record" storage place and "NumBytes" are currently
   defined and supported for the following formats:

4.3.3.1.  Audio Video Interleave (AVI) File Format



   The "Configuration Record" extends the stream format chunk ("AVI ",
   "hdlr", "strl", "strf") with the "ConfigurationRecord" bitstream.

   See [AVI] for more information about chunks.

   "NumBytes" is defined as the size, in bytes, of the "strf" chunk
   indicated in the chunk header minus the size of the stream format
   structure.

4.3.3.2.  ISO Base Media File Format



   The "Configuration Record" extends the sample description box
   ("moov", "trak", "mdia", "minf", "stbl", "stsd") with a "glbl" box
   that contains the "ConfigurationRecord" bitstream.  See
   [ISO.14496-12.2020] for more information about boxes.

   "NumBytes" is defined as the size, in bytes, of the "glbl" box
   indicated in the box header minus the size of the box header.

4.3.3.3.  NUT File Format



   The "codec_specific_data" element (in "stream_header" packet)
   contains the "ConfigurationRecord" bitstream.  See [NUT] for more
   information about elements.

   "NumBytes" is defined as the size, in bytes, of the
   "codec_specific_data" element as indicated in the "length" field of
   "codec_specific_data".

4.3.3.4.  Matroska File Format



   FFV1 SHOULD use "V_FFV1" as the Matroska "Codec ID".  For FFV1
   versions 2 or less, the Matroska "CodecPrivate" Element SHOULD NOT be
   used.  For FFV1 versions 3 or greater, the Matroska "CodecPrivate"
   Element MUST contain the FFV1 "Configuration Record" structure and no
   other data.  See [Matroska] for more information about elements.

   "NumBytes" is defined as the "Element Data Size" of the
   "CodecPrivate" Element.

4.4.  Frame



   A "Frame" is an encoded representation of a complete static image.
   The whole "Frame" is provided by the underlying container.

   A "Frame" consists of the "keyframe" field, "Parameters" (if "version
   <= 1"), and a sequence of independent Slices.  The pseudocode below
   describes the contents of a "Frame".

   The "keyframe" field has its own initial state, set to 128.

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   Frame( NumBytes ) {                                           |
       keyframe                                                  | br
       if (keyframe && !ConfigurationRecordIsPresent {           |
           Parameters( )                                         |
       }                                                         |
       while (remaining_bits_in_bitstream( NumBytes )) {         |
           Slice( )                                              |
       }                                                         |
   }                                                             |

   The following is an architecture overview of Slices in a Frame:

    +-----------------------------------------------------------------+
    | first Slice header                                              |
    +-----------------------------------------------------------------+
    | first Slice content                                             |
    +-----------------------------------------------------------------+
    | first Slice footer                                              |
    +-----------------------------------------------------------------+
    | --------------------------------------------------------------- |
    +-----------------------------------------------------------------+
    | second Slice header                                             |
    +-----------------------------------------------------------------+
    | second Slice content                                            |
    +-----------------------------------------------------------------+
    | second Slice footer                                             |
    +-----------------------------------------------------------------+
    | --------------------------------------------------------------- |
    +-----------------------------------------------------------------+
    | ...                                                             |
    +-----------------------------------------------------------------+
    | --------------------------------------------------------------- |
    +-----------------------------------------------------------------+
    | last Slice header                                               |
    +-----------------------------------------------------------------+
    | last Slice content                                              |
    +-----------------------------------------------------------------+
    | last Slice footer                                               |
    +-----------------------------------------------------------------+

4.5.  Slice



   A "Slice" is an independent, spatial subsection of a Frame that is
   encoded separately from another region of the same Frame.  The use of
   more than one "Slice" per Frame provides opportunities for taking
   advantage of multithreaded encoding and decoding.

   A "Slice" consists of a "Slice Header" (when relevant), a "Slice
   Content", and a "Slice Footer" (when relevant).  The pseudocode below
   describes the contents of a "Slice".

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   Slice( ) {                                                    |
       if (version >= 3) {                                       |
           SliceHeader( )                                        |
       }                                                         |
       SliceContent( )                                           |
       if (coder_type == 0) {                                    |
           while (!byte_aligned()) {                             |
               padding                                           | u(1)
           }                                                     |
       }                                                         |
       if (version <= 1) {                                       |
           while (remaining_bits_in_bitstream( NumBytes ) != 0) {|
               reserved                                          | u(1)
           }                                                     |
       }                                                         |
       if (version >= 3) {                                       |
           SliceFooter( )                                        |
       }                                                         |
   }                                                             |

   "padding" specifies a bit without any significance and used only for
   byte alignment. "padding" MUST be 0.

   "reserved" specifies a bit without any significance in this
   specification but may have a significance in a later revision of this
   specification.

   Encoders SHOULD NOT fill "reserved".

   Decoders SHOULD ignore "reserved".

4.6.  Slice Header



   A "Slice Header" provides information about the decoding
   configuration of the "Slice", such as its spatial position, size, and
   aspect ratio.  The pseudocode below describes the contents of the
   "Slice Header".

   "Slice Header" has its own initial states, all set to 128.

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   SliceHeader( ) {                                              |
       slice_x                                                   | ur
       slice_y                                                   | ur
       slice_width - 1                                           | ur
       slice_height - 1                                          | ur
       for (i = 0; i < quant_table_set_index_count; i++) {       |
           quant_table_set_index[ i ]                            | ur
       }                                                         |
       picture_structure                                         | ur
       sar_num                                                   | ur
       sar_den                                                   | ur
   }                                                             |

4.6.1.  "slice_x"



   "slice_x" indicates the x position on the Slice raster formed by
   "num_h_slices".

   Inferred to be 0 if not present.

4.6.2.  "slice_y"



   "slice_y" indicates the y position on the Slice raster formed by
   "num_v_slices".

   Inferred to be 0 if not present.

4.6.3.  "slice_width"



   "slice_width" indicates the width on the Slice raster formed by
   "num_h_slices".

   Inferred to be 1 if not present.

4.6.4.  "slice_height"



   "slice_height" indicates the height on the Slice raster formed by
   "num_v_slices".

   Inferred to be 1 if not present.

4.6.5.  "quant_table_set_index_count"



   "quant_table_set_index_count" is defined as the following:

   1 + ( ( chroma_planes || version <= 3 ) ? 1 : 0 )
       + ( extra_plane ? 1 : 0 )

4.6.6.  "quant_table_set_index"



   "quant_table_set_index" indicates the Quantization Table Set index to
   select the Quantization Table Set and the initial states for the
   "Slice Content".

   Inferred to be 0 if not present.

4.6.7.  "picture_structure"



   "picture_structure" specifies the temporal and spatial relationship
   of each Line of the Frame.

   Inferred to be 0 if not present.

                    +=======+=========================+
                    | value | picture structure used  |
                    +=======+=========================+
                    | 0     | unknown                 |
                    +-------+-------------------------+
                    | 1     | top field first         |
                    +-------+-------------------------+
                    | 2     | bottom field first      |
                    +-------+-------------------------+
                    | 3     | progressive             |
                    +-------+-------------------------+
                    | Other | reserved for future use |
                    +-------+-------------------------+

                       Table 15: The definitions for
                        "picture_structure" values.

4.6.8.  "sar_num"



   "sar_num" specifies the Sample aspect ratio numerator.

   Inferred to be 0 if not present.

   A value of 0 means that aspect ratio is unknown.

   Encoders MUST write 0 if the Sample aspect ratio is unknown.

   If "sar_den" is 0, decoders SHOULD ignore the encoded value and
   consider that "sar_num" is 0.

4.6.9.  "sar_den"



   "sar_den" specifies the Sample aspect ratio denominator.

   Inferred to be 0 if not present.

   A value of 0 means that aspect ratio is unknown.

   Encoders MUST write 0 if the Sample aspect ratio is unknown.

   If "sar_num" is 0, decoders SHOULD ignore the encoded value and
   consider that "sar_den" is 0.

4.7.  Slice Content



   A "Slice Content" contains all Line elements part of the "Slice".

   Depending on the configuration, Line elements are ordered by Plane
   then by row (YCbCr) or by row then by Plane (RGB).

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   SliceContent( ) {                                             |
       if (colorspace_type == 0) {                               |
           for (p = 0; p < primary_color_count; p++) {           |
               for (y = 0; y < plane_pixel_height[ p ]; y++) {   |
                   Line( p, y )                                  |
               }                                                 |
           }                                                     |
       } else if (colorspace_type == 1) {                        |
           for (y = 0; y < slice_pixel_height; y++) {            |
               for (p = 0; p < primary_color_count; p++) {       |
                   Line( p, y )                                  |
               }                                                 |
           }                                                     |
       }                                                         |
   }                                                             |

4.7.1.  "primary_color_count"



   "primary_color_count" is defined as the following:

   1 + ( chroma_planes ? 2 : 0 ) + ( extra_plane ? 1 : 0 )

4.7.2.  "plane_pixel_height"



   "plane_pixel_height[ p ]" is the height in pixels of Plane p of the
   "Slice".  It is defined as the following:

   chroma_planes == 1 && (p == 1 || p == 2)
       ? ceil(slice_pixel_height / (1 << log2_v_chroma_subsample))
       : slice_pixel_height

4.7.3.  "slice_pixel_height"



   "slice_pixel_height" is the height in pixels of the Slice.  It is
   defined as the following:

   floor(
           ( slice_y + slice_height )
           * slice_pixel_height
           / num_v_slices
       ) - slice_pixel_y.

4.7.4.  "slice_pixel_y"



   "slice_pixel_y" is the Slice vertical position in pixels.  It is
   defined as the following:

   floor( slice_y * frame_pixel_height / num_v_slices )

4.8.  Line



   A "Line" is a list of the Sample Differences (relative to the
   predictor) of primary color components.  The pseudocode below
   describes the contents of the "Line".

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   Line( p, y ) {                                                |
       if (colorspace_type == 0) {                               |
           for (x = 0; x < plane_pixel_width[ p ]; x++) {        |
               sample_difference[ p ][ y ][ x ]                  | sd
           }                                                     |
       } else if (colorspace_type == 1) {                        |
           for (x = 0; x < slice_pixel_width; x++) {             |
               sample_difference[ p ][ y ][ x ]                  | sd
           }                                                     |
       }                                                         |
   }                                                             |

4.8.1.  "plane_pixel_width"



   "plane_pixel_width[ p ]" is the width in pixels of Plane p of the
   "Slice".  It is defined as the following:

   chroma_planes == 1 && (p == 1 || p == 2)
       ? ceil( slice_pixel_width / (1 << log2_h_chroma_subsample) )
       : slice_pixel_width.

4.8.2.  "slice_pixel_width"



   "slice_pixel_width" is the width in pixels of the Slice.  It is
   defined as the following:

   floor(
           ( slice_x + slice_width )
           * slice_pixel_width
           / num_h_slices
       ) - slice_pixel_x

4.8.3.  "slice_pixel_x"



   "slice_pixel_x" is the Slice horizontal position in pixels.  It is
   defined as the following:

   floor( slice_x * frame_pixel_width / num_h_slices )

4.8.4.  "sample_difference"



   "sample_difference[ p ][ y ][ x ]" is the Sample Difference for
   Sample at Plane "p", y position "y", and x position "x".  The Sample
   value is computed based on median predictor and context described in
   Section 3.2.

4.9.  Slice Footer



   A "Slice Footer" provides information about Slice size and
   (optionally) parity.  The pseudocode below describes the contents of
   the "Slice Footer".

   Note: "Slice Footer" is always byte aligned.

   pseudocode                                                    | type
   --------------------------------------------------------------|-----
   SliceFooter( ) {                                              |
       slice_size                                                | u(24)
       if (ec) {                                                 |
           error_status                                          | u(8)
           slice_crc_parity                                      | u(32)
       }                                                         |
   }                                                             |

4.9.1.  "slice_size"



   "slice_size" indicates the size of the Slice in bytes.

   Note: this allows finding the start of Slices before previous Slices
   have been fully decoded and allows parallel decoding as well as error
   resilience.

4.9.2.  "error_status"



   "error_status" specifies the error status.

             +=======+=======================================+
             | value | error status                          |
             +=======+=======================================+
             | 0     | no error                              |
             +-------+---------------------------------------+
             | 1     | Slice contains a correctable error    |
             +-------+---------------------------------------+
             | 2     | Slice contains an uncorrectable error |
             +-------+---------------------------------------+
             | Other | reserved for future use               |
             +-------+---------------------------------------+

                Table 16: The definitions for "error_status"
                                  values.

4.9.3.  "slice_crc_parity"



   "slice_crc_parity" is 32 bits that are chosen so that the Slice as a
   whole has a CRC remainder of 0.

   This is equivalent to storing the CRC remainder in the 32-bit parity.

   The CRC generator polynomial used is the standard IEEE CRC polynomial
   (0x104C11DB7) with initial value 0, without pre-inversion, and
   without post-inversion.

5.  Restrictions



   To ensure that fast multithreaded decoding is possible, starting with
   version 3 and if "frame_pixel_width * frame_pixel_height" is more
   than 101376, "slice_width * slice_height" MUST be less or equal to
   "num_h_slices * num_v_slices / 4".  Note: 101376 is the frame size in
   pixels of a 352x288 frame also known as CIF (Common Intermediate
   Format) frame size format.

   For each Frame, each position in the Slice raster MUST be filled by
   one and only one Slice of the Frame (no missing Slice position and no
   Slice overlapping).

   For each Frame with a "keyframe" value of 0, each Slice MUST have the
   same value of "slice_x", "slice_y", "slice_width", and "slice_height"
   as a Slice in the previous Frame.

6.  Security Considerations



   Like any other codec (such as [RFC6716]), FFV1 should not be used
   with insecure ciphers or cipher modes that are vulnerable to known
   plaintext attacks.  Some of the header bits as well as the padding
   are easily predictable.

   Implementations of the FFV1 codec need to take appropriate security
   considerations into account.  Those related to denial of service are
   outlined in Section 2.1 of [RFC4732].  It is extremely important for
   the decoder to be robust against malicious payloads.  Malicious
   payloads MUST NOT cause the decoder to overrun its allocated memory
   or to take an excessive amount of resources to decode.  An overrun in
   allocated memory could lead to arbitrary code execution by an
   attacker.  The same applies to the encoder, even though problems in
   encoders are typically rarer.  Malicious video streams MUST NOT cause
   the encoder to misbehave because this would allow an attacker to
   attack transcoding gateways.  A frequent security problem in image
   and video codecs is failure to check for integer overflows.  An
   example is allocating "frame_pixel_width * frame_pixel_height" in
   pixel count computations without considering that the multiplication
   result may have overflowed the range of the arithmetic type.  The
   range coder could, if implemented naively, read one byte over the
   end.  The implementation MUST ensure that no read outside allocated
   and initialized memory occurs.

   None of the content carried in FFV1 is intended to be executable.

7.  IANA Considerations



   IANA has registered the following values.

7.1.  Media Type Definition



   This registration is done using the template defined in [RFC6838] and
   following [RFC4855].

   Type name:  video

   Subtype name:  FFV1

   Required parameters:  None.

   Optional parameters:  These parameters are used to signal the
      capabilities of a receiver implementation.  These parameters MUST
      NOT
be used for any other purpose.

      "version":  The "version" of the FFV1 encoding as defined by
         Section 4.2.1.

      "micro_version":  The "micro_version" of the FFV1 encoding as
         defined by Section 4.2.2.

      "coder_type":  The "coder_type" of the FFV1 encoding as defined by
         Section 4.2.3.

      "colorspace_type":  The "colorspace_type" of the FFV1 encoding as
         defined by Section 4.2.5.

      "bits_per_raw_sample":  The "bits_per_raw_sample" of the FFV1
         encoding as defined by Section 4.2.7.

      "max_slices":  The value of "max_slices" is an integer indicating
         the maximum count of Slices within a Frame of the FFV1
         encoding.

   Encoding considerations:  This media type is defined for
      encapsulation in several audiovisual container formats and
      contains binary data; see Section 4.3.3.  This media type is
      framed binary data; see Section 4.8 of [RFC6838].

   Security considerations:  See Section 6 of this document.

   Interoperability considerations:  None.

   Published specification:  RFC 9043.

   Applications that use this media type:  Any application that requires
      the transport of lossless video can use this media type.  Some
      examples are, but not limited to, screen recording, scientific
      imaging, and digital video preservation.

   Fragment identifier considerations:  N/A.

   Additional information:  None.

   Person & email address to contact for further information:
      Michael Niedermayer (mailto:michael@niedermayer.cc)

   Intended usage:  COMMON

   Restrictions on usage:  None.

   Author:  Dave Rice (mailto:dave@dericed.com)

   Change controller:  IETF CELLAR Working Group delegated from the
      IESG.

8.  References



8.1.  Normative References



   [ISO.9899.2018]
              International Organization for Standardization,
              "Information technology - Programming languages - C", ISO/
              IEC 9899:2018, June 2018.

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119,
              DOI 10.17487/RFC2119, March 1997,
              <https://www.rfc-editor.org/info/rfc2119>.

   [RFC4732]  Handley, M., Ed., Rescorla, E., Ed., and IAB, "Internet
              Denial-of-Service Considerations", RFC 4732,
              DOI 10.17487/RFC4732, December 2006,
              <https://www.rfc-editor.org/info/rfc4732>.

   [RFC4855]  Casner, S., "Media Type Registration of RTP Payload
              Formats", RFC 4855, DOI 10.17487/RFC4855, February 2007,
              <https://www.rfc-editor.org/info/rfc4855>.

   [RFC6838]  Freed, N., Klensin, J., and T. Hansen, "Media Type
              Specifications and Registration Procedures", BCP 13,
              RFC 6838, DOI 10.17487/RFC6838, January 2013,
              <https://www.rfc-editor.org/info/rfc6838>.

   [RFC8174]  Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
              2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
              May 2017, <https://www.rfc-editor.org/info/rfc8174>.

8.2.  Informative References



   [AddressSanitizer]
              Clang Project, "AddressSanitizer", Clang 12 documentation,
              <https://clang.llvm.org/docs/AddressSanitizer.html>.

   [AVI]      Microsoft, "AVI RIFF File Reference",
              <https://docs.microsoft.com/en-
              us/windows/win32/directshow/avi-riff-file-reference>.

   [FFV1GO]   Buitenhuis, D., "FFV1 Decoder in Go", 2019,
              <https://github.com/dwbuiten/go-ffv1>.

   [FFV1_V0]  Niedermayer, M., "Commit to mark FFV1 version 0 as non-
              experimental", April 2006, <https://git.videolan.org/?p=ff
              mpeg.git;a=commit;h=b548f2b91b701e1235608ac882ea6df915167c
              7e>.

   [FFV1_V1]  Niedermayer, M., "Commit to release FFV1 version 1", April
              2009, <https://git.videolan.org/?p=ffmpeg.git;a=commit;h=6
              8f8d33becbd73b4d0aa277f472a6e8e72ea6849>.

   [FFV1_V3]  Niedermayer, M., "Commit to mark FFV1 version 3 as non-
              experimental", August 2013, <https://git.videolan.org/?p=f
              fmpeg.git;a=commit;h=abe76b851c05eea8743f6c899cbe5f7409b0f
              301>.

   [HuffYUV]  Rudiak-Gould, B., "HuffYUV revisited", December 2003,
              <https://web.archive.org/web/20040402121343/
              http://cultact-server.novi.dk/kpo/huffyuv/huffyuv.html>.

   [ISO.14495-1.1999]
              International Organization for Standardization,
              "Information technology -- Lossless and near-lossless
              compression of continuous-tone still images: Baseline",
              ISO/IEC 14495-1:1999, December 1999.

   [ISO.14496-10.2020]
              International Organization for Standardization,
              "Information technology -- Coding of audio-visual objects
              -- Part 10: Advanced Video Coding", ISO/IEC 14496-10:2020,
              December 2020.

   [ISO.14496-12.2020]
              International Organization for Standardization,
              "Information technology -- Coding of audio-visual objects
              -- Part 12: ISO base media file format", ISO/IEC
              14496-12:2020, December 2020.

   [ISO.15444-1.2019]
              International Organization for Standardization,
              "Information technology -- JPEG 2000 image coding system:
              Core coding system", ISO/IEC 15444-1:2019, October 2019.

   [Matroska] Lhomme, S., Bunkus, M., and D. Rice, "Matroska Media
              Container Format Specifications", Work in Progress,
              Internet-Draft, draft-ietf-cellar-matroska-07, 12 April
              2021, <https://datatracker.ietf.org/doc/html/draft-ietf-
              cellar-matroska-07>.

   [MediaConch]
              MediaArea.net, "MediaConch", 2018,
              <https://mediaarea.net/MediaConch>.

   [NUT]      Niedermayer, M., "NUT Open Container Format", December
              2013, <https://ffmpeg.org/~michael/nut.txt>.

   [Range-Encoding]
              Martin, G. N. N., "Range encoding: an algorithm for
              removing redundancy from a digitised message", Proceedings
              of the Conference on Video and Data Recording, Institution
              of Electronic and Radio Engineers, Hampshire, England,
              July 1979.

   [REFIMPL]  Niedermayer, M., "The reference FFV1 implementation / the
              FFV1 codec in FFmpeg",
              <https://ffmpeg.org/doxygen/trunk/ffv1_8h.html>.

   [RFC6716]  Valin, JM., Vos, K., and T. Terriberry, "Definition of the
              Opus Audio Codec", RFC 6716, DOI 10.17487/RFC6716,
              September 2012, <https://www.rfc-editor.org/info/rfc6716>.

   [Valgrind] Valgrind Developers, "Valgrind website",
              <https://valgrind.org/>.

   [YCbCr]    Wikipedia, "YCbCr", 25 May 2021,
              <https://en.wikipedia.org/w/
              index.php?title=YCbCr&oldid=1025097882>.

Appendix A.  Multithreaded Decoder Implementation Suggestions



   This appendix is informative.

   The FFV1 bitstream is parsable in two ways: in sequential order as
   described in this document or with the pre-analysis of the footer of
   each Slice.  Each Slice footer contains a "slice_size" field so the
   boundary of each Slice is computable without having to parse the
   Slice content.  That allows multithreading as well as independence of
   Slice content (a bitstream error in a Slice header or Slice content
   has no impact on the decoding of the other Slices).

   After having checked the "keyframe" field, a decoder should parse
   "slice_size" fields, from "slice_size" of the last Slice at the end
   of the "Frame" up to "slice_size" of the first Slice at the beginning
   of the "Frame" before parsing Slices, in order to have Slice
   boundaries.  A decoder may fall back on sequential order e.g., in
   case of a corrupted "Frame" (e.g., frame size unknown or "slice_size"
   of Slices not coherent) or if there is no possibility of seeking into
   the stream.

Appendix B.  Future Handling of Some Streams Created by Nonconforming
             Encoders



   This appendix is informative.

   Some bitstreams were found with 40 extra bits corresponding to
   "error_status" and "slice_crc_parity" in the "reserved" bits of
   "Slice".  Any revision of this specification should avoid adding 40
   bits of content after "SliceContent" if "version == 0" or "version ==
   1", otherwise a decoder conforming to the revised specification could
   not distinguish between a revised bitstream and such buggy bitstream
   in the wild.

Appendix C.  FFV1 Implementations



   This appendix provides references to a few notable implementations of
   FFV1.

C.1.  FFmpeg FFV1 Codec



   This reference implementation [REFIMPL] contains no known buffer
   overflow or cases where a specially crafted packet or video segment
   could cause a significant increase in CPU load.

   The reference implementation [REFIMPL] was validated in the following
   conditions:

   *  Sending the decoder valid packets generated by the reference
      encoder and verifying that the decoder's output matches the
      encoder's input.

   *  Sending the decoder packets generated by the reference encoder and
      then subjected to random corruption.

   *  Sending the decoder random packets that are not FFV1.

   In all of the conditions above, the decoder and encoder was run
   inside the Valgrind memory debugger [Valgrind] as well as the Clang
   AddressSanitizer [AddressSanitizer], which tracks reads and writes to
   invalid memory regions as well as the use of uninitialized memory.
   There were no errors reported on any of the tested conditions.

C.2.  FFV1 Decoder in Go



   An FFV1 decoder [FFV1GO] was written in Go by Derek Buitenhuis during
   the work to develop this document.

C.3.  MediaConch



   The developers of the MediaConch project [MediaConch] created an
   independent FFV1 decoder as part of that project to validate FFV1
   bitstreams.  This work led to the discovery of three conflicts
   between existing FFV1 implementations and draft versions of this
   document.  These issues are addressed by Section 3.3.1,
   Section 3.7.2.1, and Appendix B.

Authors' Addresses



   Michael Niedermayer

   Email: michael@niedermayer.cc


   Dave Rice

   Email: dave@dericed.com


   Jérôme Martinez

   Email: jerome@mediaarea.net