GENWiki

CompuServe G I F Programming Reference

  Cover Sheet for the GIF89a Specification

  DEFERRED CLEAR CODE IN LZW COMPRESSION

  There has been confusion about where clear codes can be found in the
  data stream.  As the specification says, they may appear at anytime.  There
  is not a requirement to send a clear code when the string table is full.

  It is the encoder's decision as to when the table should be cleared.  When
  the table is full, the encoder can chose to use the table as is, making no
  changes to it until the encoder chooses to clear it.  The encoder during
  this time sends out codes that are of the maximum Code Size.

  As we can see from the above, when the decoder's table is full, it must
  not change the table until a clear code is received.  The Code Size is that
  of the maximum Code Size.  Processing other than this is done normally.

  Because of a large base of decoders that do not handle the decompression in
  this manner, we ask developers of GIF encoding software to NOT implement
  this feature until at least January 1991 and later if they see that their
  particular market is not ready for it.  This will give developers of GIF
  decoding software time to implement this feature and to get it into the
  hands of their clients before the decoders start "breaking" on the new
  GIF's.  It is not required that encoders change their software to take
  advantage of the deferred clear code, but it is for decoders.

  APPLICATION EXTENSION BLOCK - APPLICATION IDENTIFIER

  There will be a Courtesy Directory file located on CompuServe in the PICS
  forum.  This directory will contain Application Identifiers for Application
  Extension Blocks that have been used by developers of GIF applications.
  This file is intended to help keep developers that wish to create
  Application Extension Blocks from using the same Application Identifiers.
  This is not an official directory; it is for voluntary participation only
  and does not guarantee that someone will not use the same identifier.

  E-Mail can be sent to Larry Wood (forum manager of PICS) indicating the
  request for inclusion in this file with an identifier.

                      GRAPHICS INTERCHANGE FORMAT(sm)

                                Version 89a

                          (c)1987,1988,1989,1990

                                 Copyright
                          CompuServe Incorporated
                              Columbus, Ohio

CompuServe Incorporated Graphics Interchange Format Document Date : 31 July 1990 Programming Reference

                             Table of Contents

Disclaimer……………………………………………………….. 1

Foreword…………………………………………………………. 1

Licensing………………………………………………………… 1

About the Document………………………………………………… 2

General Description……………………………………………….. 2

Version Numbers…………………………………………………… 2

The Encoder………………………………………………………. 3

The Decoder………………………………………………………. 3

Compliance……………………………………………………….. 3

About Recommendations……………………………………………… 4

About Color Tables………………………………………………… 4

Blocks, Extensions and Scope……………………………………….. 4

Block Sizes………………………………………………………. 5

Using GIF as an embedded protocol…………………………………… 5

Data Sub-blocks…………………………………………………… 5

Block Terminator………………………………………………….. 6

Header…………………………………………………………… 7

Logical Screen Descriptor………………………………………….. 8

Global Color Table………………………………………………… 10

Image Descriptor………………………………………………….. 11

Local Color Table…………………………………………………. 13

Table Based Image Data…………………………………………….. 14

Graphic Control Extension………………………………………….. 15

Comment Extension…………………………………………………. 17

Plain Text Extension………………………………………………. 18

Application Extension……………………………………………… 21

Trailer………………………………………………………….. 23

Quick Reference Table……………………………………………… 24

GIF Grammar………………………………………………………. 25

Glossary…………………………………………………………. 27

Conventions………………………………………………………. 28

Interlaced Images…………………………………………………. 29

Variable-Length-Code LZW Compression………………………………… 30

On-line Capabilities Dialogue………………………………………. 33

1. Disclaimer.

The information provided herein is subject to change without notice. In no event will CompuServe Incorporated be liable for damages, including any loss of revenue, loss of profits or other incidental or consequential damages arising out of the use or inability to use the information; CompuServe Incorporated makes no claim as to the suitability of the information.

2. Foreword.

This document defines the Graphics Interchange Format(sm). The specification given here defines version 89a, which is an extension of version 87a.

The Graphics Interchange Format(sm) as specified here should be considered complete; any deviation from it should be considered invalid, including but not limited to, the use of reserved or undefined fields within control or data blocks, the inclusion of extraneous data within or between blocks, the use of methods or algorithms not specifically listed as part of the format, etc. In general, any and all deviations, extensions or modifications not specified in this document should be considered to be in violation of the format and should be avoided.

3. Licensing.

The Graphics Interchange Format© is the copyright property of CompuServe Incorporated. Only CompuServe Incorporated is authorized to define, redefine, enhance, alter, modify or change in any way the definition of the format.

CompuServe Incorporated hereby grants a limited, non-exclusive, royalty-free license for the use of the Graphics Interchange Format(sm) in computer software; computer software utilizing GIF(sm) must acknowledge ownership of the Graphics Interchange Format and its Service Mark by CompuServe Incorporated, in User and Technical Documentation. Computer software utilizing GIF, which is distributed or may be distributed without User or Technical Documentation must display to the screen or printer a message acknowledging ownership of the Graphics Interchange Format and the Service Mark by CompuServe Incorporated; in this case, the acknowledgement may be displayed in an opening screen or leading banner, or a closing screen or trailing banner. A message such as the following may be used:

    "The Graphics Interchange Format(c) is the Copyright property of
    CompuServe Incorporated. GIF(sm) is a Service Mark property of
    CompuServe Incorporated."

For further information, please contact :

    CompuServe Incorporated
    Graphics Technology Department
    5000 Arlington Center Boulevard
    Columbus, Ohio  43220
    U. S. A.

CompuServe Incorporated maintains a mailing list with all those individuals and organizations who wish to receive copies of this document when it is corrected

or revised. This service is offered free of charge; please provide us with your mailing address.

4. About the Document.

This document describes in detail the definition of the Graphics Interchange Format. This document is intended as a programming reference; it is recommended that the entire document be read carefully before programming, because of the interdependence of the various parts. There is an individual section for each of the Format blocks. Within each section, the sub-section labeled Required Version refers to the version number that an encoder will have to use if the corresponding block is used in the Data Stream. Within each section, a diagram describes the individual fields in the block; the diagrams are drawn vertically; top bytes in the diagram appear first in the Data Stream. Bits within a byte are drawn most significant on the left end. Multi-byte numeric fields are ordered Least Significant Byte first. Numeric constants are represented as Hexadecimal numbers, preceded by "0x". Bit fields within a byte are described in order from most significant bits to least significant bits.

5. General Description.

The Graphics Interchange Format(sm) defines a protocol intended for the on-line transmission and interchange of raster graphic data in a way that is independent of the hardware used in their creation or display.

The Graphics Interchange Format is defined in terms of blocks and sub-blocks which contain relevant parameters and data used in the reproduction of a graphic. A GIF Data Stream is a sequence of protocol blocks and sub-blocks representing a collection of graphics. In general, the graphics in a Data Stream are assumed to be related to some degree, and to share some control information; it is recommended that encoders attempt to group together related graphics in order to minimize hardware changes during processing and to minimize control information overhead. For the same reason, unrelated graphics or graphics which require resetting hardware parameters should be encoded separately to the extent possible.

A Data Stream may originate locally, as when read from a file, or it may originate remotely, as when transmitted over a data communications line. The Format is defined with the assumption that an error-free Transport Level Protocol is used for communications; the Format makes no provisions for error-detection and error-correction.

The GIF Data Stream must be interpreted in context, that is, the application program must rely on information external to the Data Stream to invoke the decoder process.

6. Version Numbers.

The version number in the Header of a Data Stream is intended to identify the minimum set of capabilities required of a decoder in order to fully process the Data Stream. An encoder should use the earliest possible version number that includes all the blocks used in the Data Stream. Within each block section in this document, there is an entry labeled Required Version which specifies the

earliest version number that includes the corresponding block. The encoder should make every attempt to use the earliest version number covering all the blocks in the Data Stream; the unnecessary use of later version numbers will hinder processing by some decoders.

7. The Encoder.

The Encoder is the program used to create a GIF Data Stream. From raster data and other information, the encoder produces the necessary control and data blocks needed for reproducing the original graphics.

The encoder has the following primary responsibilities.

Include in the Data Stream all the necessary information to

reproduce the graphics.

Insure that a Data Stream is labeled with the earliest possible

Version Number that will cover the definition of all the blocks in

          it; this is to ensure that the largest number of decoders can
          process the Data Stream.

Ensure encoding of the graphics in such a way that the decoding

process is optimized. Avoid redundant information as much as

          possible.

To the extent possible, avoid grouping graphics which might

require resetting hardware parameters during the decoding process.

Set to zero (off) each of the bits of each and every field

designated as reserved. Note that some fields in the Logical Screen

          Descriptor and the Image Descriptor were reserved under Version
          87a, but are used under version 89a.

8. The Decoder.

The Decoder is the program used to process a GIF Data Stream. It processes the Data Stream sequentially, parsing the various blocks and sub-blocks, using the control information to set hardware and process parameters and interpreting the data to render the graphics.

The decoder has the following primary responsibilities.

Process each graphic in the Data Stream in sequence, without

delays other than those specified in the control information.

Set its hardware parameters to fit, as closely as possible, the

control information contained in the Data Stream.

9. Compliance.

An encoder or a decoder is said to comply with a given version of the Graphics Interchange Format if and only if it fully conforms with and correctly implements the definition of the standard associated with that version. An

encoder or a decoder may be compliant with a given version number and not compliant with some subsequent version.

10. About Recommendations.

Each block section in this document contains an entry labeled Recommendation; this section lists a set of recommendations intended to guide and organize the use of the particular blocks. Such recommendations are geared towards making the functions of encoders and decoders more efficient, as well as making optimal use of the communications bandwidth. It is advised that these recommendations be followed.

11. About Color Tables.

The GIF format utilizes color tables to render raster-based graphics. A color table can have one of two different scopes: global or local. A Global Color Table is used by all those graphics in the Data Stream which do not have a Local Color Table associated with them. The scope of the Global Color Table is the entire Data Stream. A Local Color Table is always associated with the graphic that immediately follows it; the scope of a Local Color Table is limited to that single graphic. A Local Color Table supersedes a Global Color Table, that is, if a Data Stream contains a Global Color Table, and an image has a Local Color Table associated with it, the decoder must save the Global Color Table, use the Local Color Table to render the image, and then restore the Global Color Table. Both types of color tables are optional, making it possible for a Data Stream to contain numerous graphics without a color table at all. For this reason, it is recommended that the decoder save the last Global Color Table used until another Global Color Table is encountered. In this way, a Data Stream which does not contain either a Global Color Table or a Local Color Table may be processed using the last Global Color Table saved. If a Global Color Table from a previous Stream is used, that table becomes the Global Color Table of the present Stream. This is intended to reduce the overhead incurred by color tables. In particular, it is recommended that an encoder use only one Global Color Table if all the images in related Data Streams can be rendered with the same table. If no color table is available at all, the decoder is free to use a system color table or a table of its own. In that case, the decoder may use a color table with as many colors as its hardware is able to support; it is recommended that such a table have black and white as its first two entries, so that monochrome images can be rendered adequately.

The Definition of the GIF Format allows for a Data Stream to contain only the Header, the Logical Screen Descriptor, a Global Color Table and the GIF Trailer. Such a Data Stream would be used to load a decoder with a Global Color Table, in preparation for subsequent Data Streams without a color table at all.

12. Blocks, Extensions and Scope.

Blocks can be classified into three groups : Control, Graphic-Rendering and Special Purpose. Control blocks, such as the Header, the Logical Screen Descriptor, the Graphic Control Extension and the Trailer, contain information used to control the process of the Data Stream or information used in setting hardware parameters. Graphic-Rendering blocks such as the Image Descriptor and

the Plain Text Extension contain information and data used to render a graphic on the display device. Special Purpose blocks such as the Comment Extension and the Application Extension are neither used to control the process of the Data Stream nor do they contain information or data used to render a graphic on the display device. With the exception of the Logical Screen Descriptor and the Global Color Table, whose scope is the entire Data Stream, all other Control blocks have a limited scope, restricted to the Graphic-Rendering block that follows them. Special Purpose blocks do not delimit the scope of any Control blocks; Special Purpose blocks are transparent to the decoding process. Graphic-Rendering blocks and extensions are used as scope delimiters for Control blocks and extensions. The labels used to identify labeled blocks fall into three ranges : 0x00-0x7F (0-127) are the Graphic Rendering blocks, excluding the Trailer (0x3B); 0x80-0xF9 (128-249) are the Control blocks; 0xFA-0xFF (250-255) are the Special Purpose blocks. These ranges are defined so that decoders can handle block scope by appropriately identifying block labels, even when the block itself cannot be processed.

13. Block Sizes.

The Block Size field in a block, counts the number of bytes remaining in the block, not counting the Block Size field itself, and not counting the Block Terminator, if one is to follow. Blocks other than Data Blocks are intended to be of fixed length; the Block Size field is provided in order to facilitate skipping them, not to allow their size to change in the future. Data blocks and sub-blocks are of variable length to accommodate the amount of data.

14. Using GIF as an embedded protocol.

As an embedded protocol, GIF may be part of larger application protocols, within which GIF is used to render graphics. In such a case, the application protocol could define a block within which the GIF Data Stream would be contained. The application program would then invoke a GIF decoder upon encountering a block of type GIF. This approach is recommended in favor of using Application Extensions, which become overhead for all other applications that do not process them. Because a GIF Data Stream must be processed in context, the application must rely on some means of identifying the GIF Data Stream outside of the Stream itself.

15. Data Sub-blocks.

    a. Description. Data Sub-blocks are units containing data. They do not
    have a label, these blocks are processed in the context of control
    blocks, wherever data blocks are specified in the format. The first byte
    of the Data sub-block indicates the number of data bytes to follow. A
    data sub-block may contain from 0 to 255 data bytes. The size of the
    block does not account for the size byte itself, therefore, the empty
    sub-block is one whose size field contains 0x00.

    b. Required Version.  87a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Block Size                    Byte
   +---------------+
1  |               |
   +-             -+
2  |               |
   +-             -+
3  |               |
   +-             -+
   |               |       Data Values                   Byte
   +-             -+

up | |

   +-   . . . .   -+

to | |

   +-             -+
   |               |
   +-             -+

255 | |

   +---------------+

          i) Block Size - Number of bytes in the Data Sub-block; the size
          must be within 0 and 255 bytes, inclusive.

          ii) Data Values - Any 8-bit value. There must be exactly as many
          Data Values as specified by the Block Size field.

    d. Extensions and Scope. This type of block always occurs as part of a
    larger unit. It does not have a scope of itself.

    e. Recommendation. None.

16. Block Terminator.

    a. Description. This zero-length Data Sub-block is used to terminate a
    sequence of Data Sub-blocks. It contains a single byte in the position of
    the Block Size field and does not contain data.

    b. Required Version.  87a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Block Size                    Byte
   +---------------+

          i) Block Size - Number of bytes in the Data Sub-block; this field
          contains the fixed value 0x00.

          ii) Data Values - This block does not contain any data.

    d. Extensions and Scope. This block terminates the immediately preceding
    sequence of Data Sub-blocks. This block cannot be modified by any
    extension.

    e. Recommendation. None.

17. Header.

    a. Description. The Header identifies the GIF Data Stream in context. The
    Signature field marks the beginning of the Data Stream, and the Version
    field identifies the set of capabilities required of a decoder to fully
    process the Data Stream.  This block is REQUIRED; exactly one Header must
    be present per Data Stream.

    b. Required Version.  Not applicable. This block is not subject to a
    version number. This block must appear at the beginning of every Data
    Stream.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
 0 |               |       Signature                     3 Bytes
   +-             -+
 1 |               |
   +-             -+
 2 |               |
   +---------------+
 3 |               |       Version                       3 Bytes
   +-             -+
 4 |               |
   +-             -+
 5 |               |
   +---------------+

          i) Signature - Identifies the GIF Data Stream. This field contains
          the fixed value 'GIF'.

          ii) Version - Version number used to format the data stream.
          Identifies the minimum set of capabilities necessary to a decoder
          to fully process the contents of the Data Stream.

          Version Numbers as of 10 July 1990 :       "87a" - May 1987
                                                     "89a" - July 1989

          Version numbers are ordered numerically increasing on the first two
          digits starting with 87 (87,88,...,99,00,...,85,86) and
          alphabetically increasing on the third character (a,...,z).

          iii) Extensions and Scope. The scope of this block is the entire
          Data Stream. This block cannot be modified by any extension.

    d. Recommendations.

          i) Signature - This field identifies the beginning of the GIF Data
          Stream; it is not intended to provide a unique signature for the
          identification of the data. It is recommended that the GIF Data
          Stream be identified externally by the application. (Refer to
          Appendix G for on-line identification of the GIF Data Stream.)

          ii) Version - ENCODER : An encoder should use the earliest possible
          version number that defines all the blocks used in the Data Stream.
          When two or more Data Streams are combined, the latest of the
          individual version numbers should be used for the resulting Data
          Stream. DECODER : A decoder should attempt to process the data
          stream to the best of its ability; if it encounters a version
          number which it is not capable of processing fully, it should
          nevertheless, attempt to process the data stream to the best of its
          ability, perhaps after warning the user that the data may be
          incomplete.

18. Logical Screen Descriptor.

    a. Description.  The Logical Screen Descriptor contains the parameters
    necessary to define the area of the display device within which the
    images will be rendered.  The coordinates in this block are given with
    respect to the top-left corner of the virtual screen; they do not
    necessarily refer to absolute coordinates on the display device.  This
    implies that they could refer to window coordinates in a window-based
    environment or printer coordinates when a printer is used.

    This block is REQUIRED; exactly one Logical Screen Descriptor must be
    present per Data Stream.

    b. Required Version.  Not applicable. This block is not subject to a
    version number. This block must appear immediately after the Header.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Logical Screen Width          Unsigned
   +-             -+
1  |               |
   +---------------+
2  |               |       Logical Screen Height         Unsigned
   +-             -+
3  |               |
   +---------------+
4  | |     | |     |       <Packed Fields>               See below
   +---------------+
5  |               |       Background Color Index        Byte
   +---------------+
6  |               |       Pixel Aspect Ratio            Byte
   +---------------+

   <Packed Fields>  =      Global Color Table Flag       1 Bit
                           Color Resolution              3 Bits
                           Sort Flag                     1 Bit
                           Size of Global Color Table    3 Bits

          i) Logical Screen Width - Width, in pixels, of the Logical Screen
          where the images will be rendered in the displaying device.

          ii) Logical Screen Height - Height, in pixels, of the Logical
          Screen where the images will be rendered in the displaying device.

          iii) Global Color Table Flag - Flag indicating the presence of a
          Global Color Table; if the flag is set, the Global Color Table will
          immediately follow the Logical Screen Descriptor. This flag also
          selects the interpretation of the Background Color Index; if the
          flag is set, the value of the Background Color Index field should
          be used as the table index of the background color. (This field is
          the most significant bit of the byte.)

          Values :    0 -   No Global Color Table follows, the Background
                            Color Index field is meaningless.
                      1 -   A Global Color Table will immediately follow, the
                            Background Color Index field is meaningful.

          iv) Color Resolution - Number of bits per primary color available
          to the original image, minus 1. This value represents the size of
          the entire palette from which the colors in the graphic were
          selected, not the number of colors actually used in the graphic.
          For example, if the value in this field is 3, then the palette of
          the original image had 4 bits per primary color available to create
          the image.  This value should be set to indicate the richness of
          the original palette, even if not every color from the whole
          palette is available on the source machine.

          v) Sort Flag - Indicates whether the Global Color Table is sorted.
          If the flag is set, the Global Color Table is sorted, in order of
          decreasing importance. Typically, the order would be decreasing
          frequency, with most frequent color first. This assists a decoder,
          with fewer available colors, in choosing the best subset of colors;
          the decoder may use an initial segment of the table to render the
          graphic.

          Values :    0 -   Not ordered.
                      1 -   Ordered by decreasing importance, most
                            important color first.

          vi) Size of Global Color Table - If the Global Color Table Flag is
          set to 1, the value in this field is used to calculate the number
          of bytes contained in the Global Color Table. To determine that
          actual size of the color table, raise 2 to [the value of the field
          + 1].  Even if there is no Global Color Table specified, set this
          field according to the above formula so that decoders can choose
          the best graphics mode to display the stream in.  (This field is
          made up of the 3 least significant bits of the byte.)

          vii) Background Color Index - Index into the Global Color Table for

          the Background Color. The Background Color is the color used for
          those pixels on the screen that are not covered by an image. If the
          Global Color Table Flag is set to (zero), this field should be zero
          and should be ignored.

          viii) Pixel Aspect Ratio - Factor used to compute an approximation
          of the aspect ratio of the pixel in the original image.  If the
          value of the field is not 0, this approximation of the aspect ratio
          is computed based on the formula:

          Aspect Ratio = (Pixel Aspect Ratio + 15) / 64

          The Pixel Aspect Ratio is defined to be the quotient of the pixel's
          width over its height.  The value range in this field allows
          specification of the widest pixel of 4:1 to the tallest pixel of
          1:4 in increments of 1/64th.

          Values :        0 -   No aspect ratio information is given.
                     1..255 -   Value used in the computation.

    d. Extensions and Scope. The scope of this block is the entire Data
    Stream. This block cannot be modified by any extension.

    e. Recommendations. None.

19. Global Color Table.

    a. Description. This block contains a color table, which is a sequence of
    bytes representing red-green-blue color triplets. The Global Color Table
    is used by images without a Local Color Table and by Plain Text
    Extensions. Its presence is marked by the Global Color Table Flag being
    set to 1 in the Logical Screen Descriptor; if present, it immediately
    follows the Logical Screen Descriptor and contains a number of bytes
    equal to
                  3 x 2^(Size of Global Color Table+1).

    This block is OPTIONAL; at most one Global Color Table may be present
    per Data Stream.

    b. Required Version.  87a

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +===============+
0  |               |       Red 0                         Byte
   +-             -+
1  |               |       Green 0                       Byte
   +-             -+
2  |               |       Blue 0                        Byte
   +-             -+
3  |               |       Red 1                         Byte
   +-             -+
   |               |       Green 1                       Byte
   +-             -+

up | |

   +-   . . . .   -+       ...

to | |

   +-             -+
   |               |       Green 255                     Byte
   +-             -+

767 | | Blue 255 Byte

   +===============+

    d. Extensions and Scope. The scope of this block is the entire Data
    Stream. This block cannot be modified by any extension.

    e. Recommendation. None.

20. Image Descriptor.

    a. Description. Each image in the Data Stream is composed of an Image
    Descriptor, an optional Local Color Table, and the image data.  Each
    image must fit within the boundaries of the Logical Screen, as defined
    in the Logical Screen Descriptor.

    The Image Descriptor contains the parameters necessary to process a table
    based image. The coordinates given in this block refer to coordinates
    within the Logical Screen, and are given in pixels. This block is a
    Graphic-Rendering Block, optionally preceded by one or more Control
    blocks such as the Graphic Control Extension, and may be optionally
    followed by a Local Color Table; the Image Descriptor is always followed
    by the image data.

    This block is REQUIRED for an image.  Exactly one Image Descriptor must
    be present per image in the Data Stream.  An unlimited number of images
    may be present per Data Stream.

    b. Required Version.  87a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Image Separator               Byte
   +---------------+
1  |               |       Image Left Position           Unsigned
   +-             -+
2  |               |
   +---------------+
3  |               |       Image Top Position            Unsigned
   +-             -+
4  |               |
   +---------------+
5  |               |       Image Width                   Unsigned
   +-             -+
6  |               |
   +---------------+
7  |               |       Image Height                  Unsigned
   +-             -+
8  |               |
   +---------------+
9  | | | |   |     |       <Packed Fields>               See below
   +---------------+

   <Packed Fields>  =      Local Color Table Flag        1 Bit
                           Interlace Flag                1 Bit
                           Sort Flag                     1 Bit
                           Reserved                      2 Bits
                           Size of Local Color Table     3 Bits

         i) Image Separator - Identifies the beginning of an Image
         Descriptor. This field contains the fixed value 0x2C.

         ii) Image Left Position - Column number, in pixels, of the left edge
         of the image, with respect to the left edge of the Logical Screen.
         Leftmost column of the Logical Screen is 0.

         iii) Image Top Position - Row number, in pixels, of the top edge of
         the image with respect to the top edge of the Logical Screen. Top
         row of the Logical Screen is 0.

         iv) Image Width - Width of the image in pixels.

         v) Image Height - Height of the image in pixels.

         vi) Local Color Table Flag - Indicates the presence of a Local Color
         Table immediately following this Image Descriptor. (This field is
         the most significant bit of the byte.)

         Values :    0 -   Local Color Table is not present. Use
                           Global Color Table if available.
                     1 -   Local Color Table present, and to follow
                           immediately after this Image Descriptor.

         vii) Interlace Flag - Indicates if the image is interlaced. An image
         is interlaced in a four-pass interlace pattern; see Appendix E for
         details.

         Values :    0 - Image is not interlaced.
                     1 - Image is interlaced.

          viii) Sort Flag - Indicates whether the Local Color Table is
          sorted.  If the flag is set, the Local Color Table is sorted, in
          order of decreasing importance. Typically, the order would be
          decreasing frequency, with most frequent color first. This assists
          a decoder, with fewer available colors, in choosing the best subset
          of colors; the decoder may use an initial segment of the table to
          render the graphic.

          Values :    0 -   Not ordered.
                      1 -   Ordered by decreasing importance, most
                            important color first.

          ix) Size of Local Color Table - If the Local Color Table Flag is
          set to 1, the value in this field is used to calculate the number
          of bytes contained in the Local Color Table. To determine that
          actual size of the color table, raise 2 to the value of the field
          + 1. This value should be 0 if there is no Local Color Table
          specified. (This field is made up of the 3 least significant bits
          of the byte.)

   d. Extensions and Scope. The scope of this block is the Table-based Image
   Data Block that follows it. This block may be modified by the Graphic
   Control Extension.

   e. Recommendation. None.

21. Local Color Table.

   a. Description. This block contains a color table, which is a sequence of
   bytes representing red-green-blue color triplets. The Local Color Table
   is used by the image that immediately follows. Its presence is marked by
   the Local Color Table Flag being set to 1 in the Image Descriptor; if
   present, the Local Color Table immediately follows the Image Descriptor
   and contains a number of bytes equal to
                        3x2^(Size of Local Color Table+1).
   If present, this color table temporarily becomes the active color table
   and the following image should be processed using it. This block is
   OPTIONAL; at most one Local Color Table may be present per Image
   Descriptor and its scope is the single image associated with the Image
   Descriptor that precedes it.

   b. Required Version.  87a.

   c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +===============+
0  |               |       Red 0                         Byte
   +-             -+
1  |               |       Green 0                       Byte
   +-             -+
2  |               |       Blue 0                        Byte
   +-             -+
3  |               |       Red 1                         Byte
   +-             -+
   |               |       Green 1                       Byte
   +-             -+

up | |

   +-   . . . .   -+       ...

to | |

   +-             -+
   |               |       Green 255                     Byte
   +-             -+

767 | | Blue 255 Byte

   +===============+

   d. Extensions and Scope. The scope of this block is the Table-based Image
   Data Block that immediately follows it. This block cannot be modified by
   any extension.

   e. Recommendations. None.

22. Table Based Image Data.

   a. Description. The image data for a table based image consists of a
   sequence of sub-blocks, of size at most 255 bytes each, containing an
   index into the active color table, for each pixel in the image.  Pixel
   indices are in order of left to right and from top to bottom.  Each index
   must be within the range of the size of the active color table, starting
   at 0. The sequence of indices is encoded using the LZW Algorithm with
   variable-length code, as described in Appendix F

   b. Required Version.  87a.

   c. Syntax. The image data format is as follows:

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
   |               |       LZW Minimum Code Size         Byte
   +---------------+

   +===============+
   |               |
   /               /       Image Data                    Data Sub-blocks
   |               |
   +===============+

          i) LZW Minimum Code Size.  This byte determines the initial number
          of bits used for LZW codes in the image data, as described in
          Appendix F.

   d. Extensions and Scope. This block has no scope, it contains raster
   data. Extensions intended to modify a Table-based image must appear
   before the corresponding Image Descriptor.

   e. Recommendations. None.

23. Graphic Control Extension.

    a. Description. The Graphic Control Extension contains parameters used
    when processing a graphic rendering block. The scope of this extension is
    the first graphic rendering block to follow. The extension contains only
    one data sub-block.

    This block is OPTIONAL; at most one Graphic Control Extension may precede
    a graphic rendering block. This is the only limit to the number of
    Graphic Control Extensions that may be contained in a Data Stream.

    b. Required Version.  89a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Extension Introducer          Byte
   +---------------+
1  |               |       Graphic Control Label         Byte
   +---------------+

   +---------------+
0  |               |       Block Size                    Byte
   +---------------+
1  |     |     | | |       <Packed Fields>               See below
   +---------------+
2  |               |       Delay Time                    Unsigned
   +-             -+
3  |               |
   +---------------+
4  |               |       Transparent Color Index       Byte
   +---------------+

   +---------------+
0  |               |       Block Terminator              Byte
   +---------------+

    <Packed Fields>  =     Reserved                      3 Bits
                           Disposal Method               3 Bits
                           User Input Flag               1 Bit
                           Transparent Color Flag        1 Bit

          i) Extension Introducer - Identifies the beginning of an extension

          block. This field contains the fixed value 0x21.

          ii) Graphic Control Label - Identifies the current block as a
          Graphic Control Extension. This field contains the fixed value
          0xF9.

          iii) Block Size - Number of bytes in the block, after the Block
          Size field and up to but not including the Block Terminator.  This
          field contains the fixed value 4.

          iv) Disposal Method - Indicates the way in which the graphic is to
          be treated after being displayed.

          Values :    0 -   No disposal specified. The decoder is
                            not required to take any action.
                      1 -   Do not dispose. The graphic is to be left
                            in place.
                      2 -   Restore to background color. The area used by the
                            graphic must be restored to the background color.
                      3 -   Restore to previous. The decoder is required to
                            restore the area overwritten by the graphic with
                            what was there prior to rendering the graphic.
                   4-7 -    To be defined.

          v) User Input Flag - Indicates whether or not user input is
          expected before continuing. If the flag is set, processing will
          continue when user input is entered. The nature of the User input
          is determined by the application (Carriage Return, Mouse Button
          Click, etc.).

          Values :    0 -   User input is not expected.
                      1 -   User input is expected.

          When a Delay Time is used and the User Input Flag is set,
          processing will continue when user input is received or when the
          delay time expires, whichever occurs first.

          vi) Transparency Flag - Indicates whether a transparency index is
          given in the Transparent Index field. (This field is the least
          significant bit of the byte.)

          Values :    0 -   Transparent Index is not given.
                      1 -   Transparent Index is given.

          vii) Delay Time - If not 0, this field specifies the number of
          hundredths (1/100) of a second to wait before continuing with the
          processing of the Data Stream. The clock starts ticking immediately
          after the graphic is rendered. This field may be used in
          conjunction with the User Input Flag field.

          viii) Transparency Index - The Transparency Index is such that when
          encountered, the corresponding pixel of the display device is not
          modified and processing goes on to the next pixel. The index is
          present if and only if the Transparency Flag is set to 1.

          ix) Block Terminator - This zero-length data block marks the end of

          the Graphic Control Extension.

    d. Extensions and Scope. The scope of this Extension is the graphic
    rendering block that follows it; it is possible for other extensions to
    be present between this block and its target. This block can modify the
    Image Descriptor Block and the Plain Text Extension.

    e. Recommendations.

          i) Disposal Method - The mode Restore To Previous is intended to be
          used in small sections of the graphic; the use of this mode imposes
          severe demands on the decoder to store the section of the graphic
          that needs to be saved. For this reason, this mode should be used
          sparingly.  This mode is not intended to save an entire graphic or
          large areas of a graphic; when this is the case, the encoder should
          make every attempt to make the sections of the graphic to be
          restored be separate graphics in the data stream. In the case where
          a decoder is not capable of saving an area of a graphic marked as
          Restore To Previous, it is recommended that a decoder restore to
          the background color.

          ii) User Input Flag - When the flag is set, indicating that user
          input is expected, the decoder may sound the bell (0x07) to alert
          the user that input is being expected.  In the absence of a
          specified Delay Time, the decoder should wait for user input
          indefinitely.  It is recommended that the encoder not set the User
          Input Flag without a Delay Time specified.

24. Comment Extension.

    a. Description. The Comment Extension contains textual information which
    is not part of the actual graphics in the GIF Data Stream. It is suitable
    for including comments about the graphics, credits, descriptions or any
    other type of non-control and non-graphic data.  The Comment Extension
    may be ignored by the decoder, or it may be saved for later processing;
    under no circumstances should a Comment Extension disrupt or interfere
    with the processing of the Data Stream.

    This block is OPTIONAL; any number of them may appear in the Data Stream.

    b. Required Version.  89a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Extension Introducer          Byte
   +---------------+
1  |               |       Comment Label                 Byte
   +---------------+

   +===============+
   |               |
N  |               |       Comment Data                  Data Sub-blocks
   |               |
   +===============+

   +---------------+
0  |               |       Block Terminator              Byte
   +---------------+

          i) Extension Introducer - Identifies the beginning of an extension
          block. This field contains the fixed value 0x21.

          ii) Comment Label - Identifies the block as a Comment Extension.
          This field contains the fixed value 0xFE.

          iii) Comment Data - Sequence of sub-blocks, each of size at most
          255 bytes and at least 1 byte, with the size in a byte preceding
          the data.  The end of the sequence is marked by the Block
          Terminator.

          iv) Block Terminator - This zero-length data block marks the end of
          the Comment Extension.

    d. Extensions and Scope. This block does not have scope. This block
    cannot be modified by any extension.

    e. Recommendations.

          i) Data - This block is intended for humans.  It should contain
          text using the 7-bit ASCII character set. This block should
          not be used to store control information for custom processing.

          ii) Position - This block may appear at any point in the Data
          Stream at which a block can begin; however, it is recommended that
          Comment Extensions do not interfere with Control or Data blocks;
          they should be located at the beginning or at the end of the Data
          Stream to the extent possible.

25. Plain Text Extension.

    a. Description. The Plain Text Extension contains textual data and the
    parameters necessary to render that data as a graphic, in a simple form.
    The textual data will be encoded with the 7-bit printable ASCII
    characters.  Text data are rendered using a grid of character cells

    defined by the parameters in the block fields. Each character is rendered
    in an individual cell. The textual data in this block is to be rendered
    as mono-spaced characters, one character per cell, with a best fitting
    font and size. For further information, see the section on
    Recommendations below. The data characters are taken sequentially from
    the data portion of the block and rendered within a cell, starting with
    the upper left cell in the grid and proceeding from left to right and
    from top to bottom. Text data is rendered until the end of data is
    reached or the character grid is filled.  The Character Grid contains an
    integral number of cells; in the case that the cell dimensions do not
    allow for an integral number, fractional cells must be discarded; an
    encoder must be careful to specify the grid dimensions accurately so that
    this does not happen. This block requires a Global Color Table to be
    available; the colors used by this block reference the Global Color Table
    in the Stream if there is one, or the Global Color Table from a previous
    Stream, if one was saved. This block is a graphic rendering block,
    therefore it may be modified by a Graphic Control Extension.  This block
    is OPTIONAL; any number of them may appear in the Data Stream.

    b. Required Version.  89a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Extension Introducer          Byte
   +---------------+
1  |               |       Plain Text Label              Byte
   +---------------+

   +---------------+
0  |               |       Block Size                    Byte
   +---------------+
1  |               |       Text Grid Left Position       Unsigned
   +-             -+
2  |               |
   +---------------+
3  |               |       Text Grid Top Position        Unsigned
   +-             -+
4  |               |
   +---------------+
5  |               |       Text Grid Width               Unsigned
   +-             -+
6  |               |
   +---------------+
7  |               |       Text Grid Height              Unsigned
   +-             -+
8  |               |
   +---------------+
9  |               |       Character Cell Width          Byte
   +---------------+

10 | | Character Cell Height Byte

   +---------------+

11 | | Text Foreground Color Index Byte

   +---------------+

12 | | Text Background Color Index Byte

   +---------------+

   +===============+
   |               |
N  |               |       Plain Text Data               Data Sub-blocks
   |               |
   +===============+

   +---------------+
0  |               |       Block Terminator              Byte
   +---------------+

          i) Extension Introducer - Identifies the beginning of an extension
          block. This field contains the fixed value 0x21.

          ii) Plain Text Label - Identifies the current block as a Plain Text
          Extension. This field contains the fixed value 0x01.

          iii) Block Size - Number of bytes in the extension, after the Block
          Size field and up to but not including the beginning of the data
          portion. This field contains the fixed value 12.

          iv) Text Grid Left Position - Column number, in pixels, of the left
          edge of the text grid, with respect to the left edge of the Logical
          Screen.

          v) Text Grid Top Position - Row number, in pixels, of the top edge
          of the text grid, with respect to the top edge of the Logical
          Screen.

          vi) Image Grid Width - Width of the text grid in pixels.

          vii) Image Grid Height - Height of the text grid in pixels.

          viii) Character Cell Width - Width, in pixels, of each cell in the
          grid.

          ix) Character Cell Height - Height, in pixels, of each cell in the
          grid.

          x) Text Foreground Color Index - Index into the Global Color Table
          to be used to render the text foreground.

          xi) Text Background Color Index - Index into the Global Color Table
          to be used to render the text background.

          xii) Plain Text Data - Sequence of sub-blocks, each of size at most
          255 bytes and at least 1 byte, with the size in a byte preceding
          the data.  The end of the sequence is marked by the Block
          Terminator.

          xiii) Block Terminator - This zero-length data block marks the end
          of the Plain Text Data Blocks.

    d. Extensions and Scope. The scope of this block is the Plain Text Data
    Block contained in it. This block may be modified by the Graphic Control
    Extension.

    e. Recommendations. The data in the Plain Text Extension is assumed to be
    preformatted. The selection of font and size is left to the discretion of
    the decoder.  If characters less than 0x20 or greater than 0xf7 are
    encountered, it is recommended that the decoder display a Space character
    (0x20). The encoder should use grid and cell dimensions such that an
    integral number of cells fit in the grid both horizontally as well as
    vertically.  For broadest compatibility, character cell dimensions should
    be around 8x8 or 8x16 (width x height); consider an image for unusual
    sized text.

26. Application Extension.

    a. Description. The Application Extension contains application-specific
    information; it conforms with the extension block syntax, as described
    below, and its block label is 0xFF.

    b. Required Version.  89a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       Extension Introducer          Byte
   +---------------+
1  |               |       Extension Label               Byte
   +---------------+

   +---------------+
0  |               |       Block Size                    Byte
   +---------------+
1  |               |
   +-             -+
2  |               |
   +-             -+
3  |               |       Application Identifier        8 Bytes
   +-             -+
4  |               |
   +-             -+
5  |               |
   +-             -+
6  |               |
   +-             -+
7  |               |
   +-             -+
8  |               |
   +---------------+
9  |               |
   +-             -+

10 | | Appl. Authentication Code 3 Bytes

   +-             -+

11 | |

   +---------------+

   +===============+
   |               |
   |               |       Application Data              Data Sub-blocks
   |               |
   |               |
   +===============+

   +---------------+
0  |               |       Block Terminator              Byte
   +---------------+

          i) Extension Introducer - Defines this block as an extension. This
          field contains the fixed value 0x21.

          ii) Application Extension Label - Identifies the block as an
          Application Extension. This field contains the fixed value 0xFF.

          iii) Block Size - Number of bytes in this extension block,
          following the Block Size field, up to but not including the
          beginning of the Application Data. This field contains the fixed
          value 11.

          iv) Application Identifier - Sequence of eight printable ASCII
          characters used to identify the application owning the Application
          Extension.

          v) Application Authentication Code - Sequence of three bytes used
          to authenticate the Application Identifier. An Application program
          may use an algorithm to compute a binary code that uniquely
          identifies it as the application owning the Application Extension.

    d. Extensions and Scope. This block does not have scope. This block
    cannot be modified by any extension.

    e. Recommendation. None.

27. Trailer.

    a. Description. This block is a single-field block indicating the end of
    the GIF Data Stream.  It contains the fixed value 0x3B.

    b. Required Version.  87a.

    c. Syntax.

    7 6 5 4 3 2 1 0        Field Name                    Type
   +---------------+
0  |               |       GIF Trailer                   Byte
   +---------------+

    d. Extensions and Scope. This block does not have scope, it terminates
    the GIF Data Stream. This block may not be modified by any extension.

    e. Recommendations. None.

Appendix A. Quick Reference Table.

Block Name Required Label Ext. Vers. Application Extension Opt. (*) 0xFF (255) yes 89a Comment Extension Opt. (*) 0xFE (254) yes 89a Global Color Table Opt. (1) none no 87a Graphic Control Extension Opt. (*) 0xF9 (249) yes 89a Header Req. (1) none no N/A Image Descriptor Opt. (*) 0x2C (044) no 87a (89a) Local Color Table Opt. (*) none no 87a Logical Screen Descriptor Req. (1) none no 87a (89a) Plain Text Extension Opt. (*) 0x01 (001) yes 89a Trailer Req. (1) 0x3B (059) no 87a

Unlabeled Blocks Header Req. (1) none no N/A Logical Screen Descriptor Req. (1) none no 87a (89a) Global Color Table Opt. (1) none no 87a Local Color Table Opt. (*) none no 87a

Graphic-Rendering Blocks Plain Text Extension Opt. (*) 0x01 (001) yes 89a Image Descriptor Opt. (*) 0x2C (044) no 87a (89a)

Control Blocks Graphic Control Extension Opt. (*) 0xF9 (249) yes 89a

Special Purpose Blocks Trailer Req. (1) 0x3B (059) no 87a Comment Extension Opt. (*) 0xFE (254) yes 89a Application Extension Opt. (*) 0xFF (255) yes 89a

legend: (1) if present, at most one occurrence

                (*)   zero or more occurrences
                (+)   one or more occurrences

Notes : The Header is not subject to Version Numbers. (89a) The Logical Screen Descriptor and the Image Descriptor retained their syntax from version 87a to version 89a, but some fields reserved under version 87a are used under version 89a.

Appendix B. GIF Grammar.

A Grammar is a form of notation to represent the sequence in which certain objects form larger objects. A grammar is also used to represent the number of objects that can occur at a given position. The grammar given here represents the sequence of blocks that form the GIF Data Stream. A grammar is given by listing its rules. Each rule consists of the left-hand side, followed by some form of equals sign, followed by the right-hand side. In a rule, the right-hand side describes how the left-hand side is defined. The right-hand side consists of a sequence of entities, with the possible presence of special symbols. The following legend defines the symbols used in this grammar for GIF.

Legend: <> grammar word

                ::=   defines symbol
                *     zero or more occurrences
                +     one or more occurrences
                |     alternate element
                []    optional element

Example:

<GIF Data Stream> ::= Header <Logical Screen> <Data>* Trailer

This rule defines the entity <GIF Data Stream> as follows. It must begin with a Header. The Header is followed by an entity called Logical Screen, which is defined below by another rule. The Logical Screen is followed by the entity Data, which is also defined below by another rule. Finally, the entity Data is followed by the Trailer. Since there is no rule defining the Header or the Trailer, this means that these blocks are defined in the document. The entity Data has a special symbol (*) following it which means that, at this position, the entity Data may be repeated any number of times, including 0 times. For further reading on this subject, refer to a standard text on Programming Languages.

The Grammar.

<GIF Data Stream> ::= Header <Logical Screen> <Data>* Trailer

<Logical Screen> ::= Logical Screen Descriptor [Global Color Table]

<Data> ::= <Graphic Block> |

                        <Special-Purpose Block>

<Graphic Block> ::= [Graphic Control Extension] <Graphic-Rendering Block>

<Graphic-Rendering Block> ::= <Table-Based Image> |

                             Plain Text Extension

<Table-Based Image> ::= Image Descriptor [Local Color Table] Image Data

<Special-Purpose Block> ::= Application Extension |

                             Comment Extension

NOTE : The grammar indicates that it is possible for a GIF Data Stream to contain the Header, the Logical Screen Descriptor, a Global Color Table and the GIF Trailer. This special case is used to load a GIF decoder with a Global Color Table, in preparation for subsequent Data Streams without color tables at all.

Appendix C. Glossary.

Active Color Table - Color table used to render the next graphic. If the next graphic is an image which has a Local Color Table associated with it, the active color table becomes the Local Color Table associated with that image. If the next graphic is an image without a Local Color Table, or a Plain Text Extension, the active color table is the Global Color Table associated with the Data Stream, if there is one; if there is no Global Color Table in the Data Stream, the active color table is a color table saved from a previous Data Stream, or one supplied by the decoder.

Block - Collection of bytes forming a protocol unit. In general, the term includes labeled and unlabeled blocks, as well as Extensions.

Data Stream - The GIF Data Stream is composed of blocks and sub-blocks representing images and graphics, together with control information to render them on a display device. All control and data blocks in the Data Stream must follow the Header and must precede the Trailer.

Decoder - A program capable of processing a GIF Data Stream to render the images and graphics contained in it.

Encoder - A program capable of capturing and formatting image and graphic raster data, following the definitions of the Graphics Interchange Format.

Extension - A protocol block labeled by the Extension Introducer 0x21.

Extension Introducer - Label (0x21) defining an Extension.

Graphic - Data which can be rendered on the screen by virtue of some algorithm. The term graphic is more general than the term image; in addition to images, the term graphic also includes data such as text, which is rendered using character bit-maps.

Image - Data representing a picture or a drawing; an image is represented by an array of pixels called the raster of the image.

Raster - Array of pixel values representing an image.

Appendix D. Conventions.

Animation - The Graphics Interchange Format is not intended as a platform for animation, even though it can be done in a limited way.

Byte Ordering - Unless otherwise stated, multi-byte numeric fields are ordered with the Least Significant Byte first.

Color Indices - Color indices always refer to the active color table, either the Global Color Table or the Local Color Table.

Color Order - Unless otherwise stated, all triple-component RGB color values are specified in Red-Green-Blue order.

Color Tables - Both color tables, the Global and the Local, are optional; if present, the Global Color Table is to be used with every image in the Data Stream for which a Local Color Table is not given; if present, a Local Color Table overrides the Global Color Table. However, if neither color table is present, the application program is free to use an arbitrary color table. If the graphics in several Data Streams are related and all use the same color table, an encoder could place the color table as the Global Color Table in the first Data Stream and leave subsequent Data Streams without a Global Color Table or any Local Color Tables; in this way, the overhead for the table is eliminated. It is recommended that the decoder save the previous Global Color Table to be used with the Data Stream that follows, in case it does not contain either a Global Color Table or any Local Color Tables. In general, this allows the application program to use past color tables, significantly reducing transmission overhead.

Extension Blocks - Extensions are defined using the Extension Introducer code to mark the beginning of the block, followed by a block label, identifying the type of extension. Extension Codes are numbers in the range from 0x00 to 0xFF, inclusive. Special purpose extensions are transparent to the decoder and may be omitted when transmitting the Data Stream on-line. The GIF capabilities dialogue makes the provision for the receiver to request the transmission of all blocks; the default state in this regard is no transmission of Special purpose blocks.

Reserved Fields - All Reserved Fields are expected to have each bit set to zero (off).

Appendix E. Interlaced Images.

The rows of an Interlaced images are arranged in the following order:

    Group 1 : Every 8th. row, starting with row 0.              (Pass 1)
    Group 2 : Every 8th. row, starting with row 4.              (Pass 2)
    Group 3 : Every 4th. row, starting with row 2.              (Pass 3)
    Group 4 : Every 2nd. row, starting with row 1.              (Pass 4)

The Following example illustrates how the rows of an interlaced image are ordered.

    Row Number                                        Interlace Pass

0 —————————————– 1 1 —————————————– 4 2 —————————————– 3 3 —————————————– 4 4 —————————————– 2 5 —————————————– 4 6 —————————————– 3 7 —————————————– 4 8 —————————————– 1 9 —————————————– 4 10 —————————————– 3 11 —————————————– 4 12 —————————————– 2 13 —————————————– 4 14 —————————————– 3 15 —————————————– 4 16 —————————————– 1 17 —————————————– 4 18 —————————————– 3 19 —————————————– 4

Appendix F. Variable-Length-Code LZW Compression.

The Variable-Length-Code LZW Compression is a variation of the Lempel-Ziv Compression algorithm in which variable-length codes are used to replace patterns detected in the original data. The algorithm uses a code or translation table constructed from the patterns encountered in the original data; each new pattern is entered into the table and its index is used to replace it in the compressed stream.

The compressor takes the data from the input stream and builds a code or translation table with the patterns as it encounters them; each new pattern is entered into the code table and its index is added to the output stream; when a pattern is encountered which had been detected since the last code table refresh, its index from the code table is put on the output stream, thus achieving the data compression. The expander takes input from the compressed data stream and builds the code or translation table from it; as the compressed data stream is processed, codes are used to index into the code table and the corresponding data is put on the decompressed output stream, thus achieving data decompression. The details of the algorithm are explained below. The Variable-Length-Code aspect of the algorithm is based on an initial code size (LZW-initial code size), which specifies the initial number of bits used for the compression codes. When the number of patterns detected by the compressor in the input stream exceeds the number of patterns encodable with the current number of bits, the number of bits per LZW code is increased by one.

The Raster Data stream that represents the actual output image can be represented as:

       7 6 5 4 3 2 1 0
      +---------------+
      | LZW code size |
      +---------------+

      +---------------+ ----+
      |  block size   |     |
      +---------------+     |
      |               |     +-- Repeated as many
      |  data bytes   |     |   times as necessary.
      |               |     |
      +---------------+ ----+

      . . .       . . . ------- The code that terminates the LZW
                                compressed data must appear before
                                Block Terminator.
      +---------------+
      |0 0 0 0 0 0 0 0|  Block Terminator
      +---------------+

The conversion of the image from a series of pixel values to a transmitted or stored character stream involves several steps. In brief these steps are:

1. Establish the Code Size - Define the number of bits needed to represent the actual data.

2. Compress the Data - Compress the series of image pixels to a series of

compression codes.

3. Build a Series of Bytes - Take the set of compression codes and convert to a string of 8-bit bytes.

4. Package the Bytes - Package sets of bytes into blocks preceded by character counts and output.

ESTABLISH CODE SIZE

The first byte of the Compressed Data stream is a value indicating the minimum number of bits required to represent the set of actual pixel values. Normally this will be the same as the number of color bits. Because of some algorithmic constraints however, black & white images which have one color bit must be indicated as having a code size of 2. This code size value also implies that the compression codes must start out one bit longer.

COMPRESSION

The LZW algorithm converts a series of data values into a series of codes which may be raw values or a code designating a series of values. Using text characters as an analogy, the output code consists of a character or a code representing a string of characters.

The LZW algorithm used in GIF matches algorithmically with the standard LZW algorithm with the following differences:

1. A special Clear code is defined which resets all compression/decompression parameters and tables to a start-up state. The value of this code is 2<code size>. For example if the code size indicated was 4 (image was 4 bits/pixel) the Clear code value would be 16 (10000 binary). The Clear code can appear at any point in the image data stream and therefore requires the LZW algorithm to process succeeding codes as if a new data stream was starting. Encoders should output a Clear code as the first code of each image data stream. 2. An End of Information code is defined that explicitly indicates the end of the image data stream. LZW processing terminates when this code is encountered. It must be the last code output by the encoder for an image. The value of this code is <Clear code>+1. 3. The first available compression code value is <Clear code>+2. 4. The output codes are of variable length, starting at <code size>+1 bits per code, up to 12 bits per code. This defines a maximum code value of 4095 (0xFFF). Whenever the LZW code value would exceed the current code length, the code length is increased by one. The packing/unpacking of these codes must then be altered to reflect the new code length. BUILD 8-BIT BYTES Because the LZW compression used for GIF creates a series of variable length codes, of between 3 and 12 bits each, these codes must be reformed into a series of 8-bit bytes that will be the characters actually stored or transmitted. This provides additional compression of the image. The codes are formed into a stream of bits as if they were packed right to left and then 32 picked off 8 bits at a time to be output. Assuming a character array of 8 bits per character and using 5 bit codes to be packed, an example layout would be similar to: +—————+ 0 | | bbbaaaaa +—————+ 1 | | dcccccbb +—————+ 2 | | eeeedddd +—————+ 3 | | ggfffffe +—————+ 4 | | hhhhhggg +—————+ . . . +—————+ N | | +—————+ Note that the physical packing arrangement will change as the number of bits per compression code change but the concept remains the same. PACKAGE THE BYTES Once the bytes have been created, they are grouped into blocks for output by preceding each block of 0 to 255 bytes with a character count byte. A block with a zero byte count terminates the Raster Data stream for a given image. These blocks are what are actually output for the GIF image. This block format has the side effect of allowing a decoding program the ability to read past the actual image data if necessary by reading block counts and then skipping over the data. FURTHER READING [1] Ziv, J. and Lempel, A. : "A Universal Algorithm for Sequential Data Compression", IEEE Transactions on Information Theory, May 1977. [2] Welch, T. : "A Technique for High-Performance Data Compression", Computer, June 1984. [3] Nelson, M.R. : "LZW Data Compression", Dr. Dobb's Journal, October 1989. 33 Appendix G. On-line Capabilities Dialogue. NOTE : This section is currently (10 July 1990) under revision; the information provided here should be used as general guidelines. Code written based on this information should be designed in a flexible way to accommodate any changes resulting from the revisions. The following sequences are defined for use in mediating control between a GIF sender and GIF receiver over an interactive communications line. These sequences do not apply to applications that involve downloading of static GIF files and are not considered part of a GIF file. GIF CAPABILITIES ENQUIRY The GIF Capabilities Enquiry sequence is issued from a host and requests an interactive GIF decoder to return a response message that defines the graphics parameters for the decoder. This involves returning information about available screen sizes, number of bits/color supported and the amount of color detail supported. The escape sequence for the GIF Capabilities Enquiry is defined as: ESC[>0g 0x1B 0x5B 0x3E 0x30 0x67 GIF CAPABILITIES RESPONSE The GIF Capabilities Response message is returned by an interactive GIF decoder and defines the decoder's display capabilities for all graphics modes that are supported by the software. Note that this can also include graphics printers as well as a monitor screen. The general format of this message is: #version;protocol{;dev, width, height, color-bits, color-res}…<CR> '#' GIF Capabilities Response identifier character. version GIF format version number; initially '87a'. protocol='0' No end-to-end protocol supported by decoder Transfer as direct 8-bit data stream. protocol='1' Can use CIS B+ error correction protocol to transfer GIF data interactively from the host directly to the display. dev = '0' Screen parameter set follows. dev = '1' Printer parameter set follows. width Maximum supported display width in pixels. height Maximum supported display height in pixels. color-bits Number of bits per pixel supported. The number of supported colors is therefore 2color-bits. color-res Number of bits per color component supported in the hardware

             color palette. If color-res is '0' then no hardware palette
             table is available.

Note that all values in the GIF Capabilities Response are returned as ASCII decimal numbers and the message is terminated by a Carriage Return character.

The following GIF Capabilities Response message describes three standard IBM PC Enhanced Graphics Adapter configurations with no printer; the GIF data stream

can be processed within an error correcting protocol:

#87a;1;0,320,200,4,0;0,640,200,2,2;0,640,350,4,2<CR>

ENTER GIF GRAPHICS MODE

Two sequences are currently defined to invoke an interactive GIF decoder into action. The only difference between them is that different output media are selected. These sequences are:

ESC[>1g Display GIF image on screen

                0x1B 0x5B 0x3E 0x31 0x67

ESC[>2g Display image directly to an attached graphics printer. The image may optionally be displayed on the screen as well.

                0x1B 0x5B 0x3E 0x32 0x67

Note that the 'g' character terminating each sequence is in lowercase.

INTERACTIVE ENVIRONMENT

The assumed environment for the transmission of GIF image data from an interactive application is a full 8-bit data stream from host to micro. All 256 character codes must be transferrable. The establishing of an 8-bit data path for communications will normally be taken care of by the host application programs. It is however up to the receiving communications programs supporting GIF to be able to receive and pass on all 256 8-bit codes to the GIF decoder software.