LZW and GIF explained


>From: john@cooper.cooper.EDU (John Barkaus)
Newsgroups: comp.graphics
Subject: GIF file format responses 5/5

Date: 21 Apr 89 20:58:01 GMT
Organization: The Cooper Union (NY, NY)



                   LZW and GIF explained----Steve Blackstock


      I hope this little document will help enlighten those of you out there
who want to know more about the Lempel-Ziv Welch compression algorithm, and,
specifically, the implementation that GIF uses.
     Before we start, here's a little terminology, for the purposes of this
document:

      "character": a fundamental data element. In normal text files, this is
just a single byte. In raster images, which is what we're interested in, it's
an index that specifies the color of a given pixel. I'll refer to an arbitray
character as "K".
      "charstream": a stream of characters, as in a data file.
      "string": a number of continuous characters, anywhere from one to very
many characters in length. I can specify an arbitrary string as "[...]K".
      "prefix": almost the same as a string, but with the implication that a
prefix immediately precedes a character, and a prefix can have a length of
zero. So, a prefix and a character make up a string. I will refer to an
arbitrary prefix as "[...]".
      "root": a single-character string. For most purposes, this is a
character, but we may occasionally make a distinction. It is [...]K, where
[...] is empty.
      "code": a number, specified by a known number of bits, which maps to a
string.
      "codestream": the output stream of codes, as in the "raster data"
      "entry": a code and its string.
      "string table": a list of entries; usually, but not necessarily, unique.
      That should be enough of that.

     LZW is a way of compressing data that takes advantage of repetition of
strings in the data. Since raster data usually contains a lot of this
repetition, LZW is a good way of compressing and decompressing it.
     For the moment, lets consider normal LZW encoding and decoding. GIF's
variation on the concept is just an extension from there.
     LZW manipulates three objects in both compression and decompression: the
charstream, the codestream, and the string table. In compression, the
charstream is the input and the codestream is the output. In decompression,
the codestream is the input and the charstream is the output. The string table
is a product of both compression and decompression, but is never passed from
one to the other.
     The first thing we do in LZW compression is initialize our string table.
To do this, we need to choose a code size (how many bits) and know how many
values our characters can possibly take. Let's say our code size is 12 bits,
meaning we can store 0->FFF, or 4096 entries in our string table. Lets also
say that we have 32 possible different characters. (This corresponds to, say,
a picture in which there are 32 different colors possible for each pixel.) To
initialize the table, we set code#0 to character#0, code #1 to character#1,
and so on, until code#31 to character#31. Actually, we are specifying that
each code from 0 to 31 maps to a root. There will be no more entries in the
table that have this property.
     Now we start compressing data. Let's first define something called the
"current prefix". It's just a prefix that we'll store things in and compare
things to now and then. I will refer to it as "[.c.]". Initially, the current
prefix has nothing in it. Let's also define a "current string", which will be
the current prefix plus the next character in the charstream. I will refer to
the current string as "[.c.]K", where K is some character. OK, look at the
first character in the charstream. Call it P. Make [.c.]P the current string.
(At this point, of course, it's just the root P.) Now search through the
string table to see if [.c.]P appears in it. Of course, it does now, because
our string table is initialized to have all roots. So we don't do anything.
Now make [.c.]P the current prefix. Look at the next character in the
charstream. Call it Q. Add it to the current prefix to form [.c.]Q, the
current string. Now search through the string table to see if [.c.]Q appears
in it. In this case, of course, it doesn't. Aha! Now we get to do something.
Add [.c.]Q (which is PQ in this case) to the string table for code#32, and
output the code for [.c.] to the codestream. Now start over again with the
current prefix being just the root P. Keep adding characters to [.c.] to form
[.c.]K, until you can't find [.c.]K in the string table. Then output the code
for [.c.] and add [.c.]K to the string table. In pseudo-code, the algorithm
goes something like this:

     [1] Initialize string table;
     [2] [.c.] <- empty;
     [3] K <- next character in charstream;
     [4] Is [.c.]K in string table?
      (yes: [.c.] <- [.c.]K;
            go to [3];
      )
      (no: add [.c.]K to the string table;
           output the code for [.c.] to the codestream;
           [.c.] <- K;
           go to [3];
      )

       It's as simple as that! Of course, when you get to step [3] and there
aren't any more characters left, you just output the code for [.c.] and throw
the table away. You're done.
      Wanna do an example? Let's pretend we have a four-character alphabet:
A,B,C,D. The charstream looks like ABACABA. Let's compress it. First, we
initialize our string table to: #0=A, #1=B, #2=C, #3=D. The first character is
A, which is in the string table, so [.c.] becomes A. Next we get AB, which is
not in the table, so we output code #0 (for [.c.]),
     and add AB to the string table as code #4. [.c.] becomes B. Next we get
[.c.]A = BA, which is not in the string table, so output code #1, and add BA
to the string table as code #5. [.c.] becomes A. Next we get AC, which is not
in the string table. Output code #0, and add AC to the string table as code
#6. Now [.c.] becomes C. Next we get [.c.]A = CA, which is not in the table.
Output #2 for C, and add CA to table as code#7. Now [.c.] becomes A. Next we
get AB, which IS in the string table, so [.c.] gets AB, and we look at ABA,
which is not in the string table, so output the code for AB, which is #4, and
add ABA to the string table as code #8. [.c.] becomes A. We can't get any more
characters, so we just output #0 for the code for A, and we're done. So, the
codestream is #0#1#0#2#4#0.
      A few words (four) should be said here about efficiency: use a hashing
strategy. The search through the string table can be computationally
intensive, and some hashing is well worth the effort. Also, note that
"straight LZW" compression runs the risk of overflowing the string table -
getting to a code which can't be represented in the number of bits you've set
aside for codes. There are several ways of dealing with this problem, and GIF
implements a very clever one, but we'll get to that.
      An important thing to notice is that, at any point during the
compression, if [...]K is in the string table, [...] is there also. This fact
suggests an efficient method for storing strings in the table. Rather than
store the entire string of K's in the table, realize that any string can be
expressed as a prefix plus a character: [...]K. If we're about to store [...]K
in the table, we know that [...] is already there, so we can just store the
code for [...] plus the final character K.
      Ok, that takes care of compression. Decompression is perhaps more
difficult conceptually, but it is really easier to program.
      Here's how it goes: We again have to start with an initialized string
table. This table comes from what knowledge we have about the charstream that
we will eventually get, like what possible values the characters can take. In
GIF files, this information is in the header as the number of possible pixel
values. The beauty of LZW, though, is that this is all we need to know. We
will build the rest of the string table as we decompress the codestream. The
compression is done in such a way that we will never encounter a code in the
codestream that we can't translate into a string.
      We need to define something called a "current code", which I will refer
to as "<code>", and an "old-code", which I will refer to as "<old>". To start
things off, look at the first code. This is now <code>. This code will be in
the intialized string table as the code for a root. Output the root to the
charstream. Make this code the old-code <old>. *Now look at the next code, and
make it <code>. It is possible that this code will not be in the string table,
but let's assume for now that it is. Output the string corresponding to <code>
to the codestream. Now find the first character in the string you just
translated. Call this K. Add this to the prefix [...] generated by <old> to
form a new string [...]K. Add this string [...]K to the string table, and set
the old-code <old> to the current code <code>. Repeat from where I typed the
asterisk, and you're all set. Read this paragraph again if you just skimmed
it!!!  Now let's consider the possibility that <code> is not in the string
table. Think back to compression, and try to understand what happens when you
have a string like P[...]P[...]PQ appear in the charstream. Suppose P[...] is
already in the string table, but P[...]P is not. The compressor will parse out
P[...], and find that P[...]P is not in the string table. It will output the
code for P[...], and add P[...]P to the string table. Then it will get up to
P[...]P for the next string, and find that P[...]P is in the table, as
     the code just added. So it will output the code for P[...]P if it finds
that P[...]PQ is not in the table. The decompressor is always "one step
behind" the compressor. When the decompressor sees the code for P[...]P, it
will not have added that code to it's string table yet because it needed the
beginning character of P[...]P to add to the string for the last code, P[...],
to form the code for P[...]P. However, when a decompressor finds a code that
it doesn't know yet, it will always be the very next one to be added to the
string table. So it can guess at what the string for the code should be, and,
in fact, it will always be correct. If I am a decompressor, and I see
code#124, and yet my string table has entries only up to code#123, I can
figure out what code#124 must be, add it to my string table, and output the
string. If code#123 generated the string, which I will refer to here as a
prefix, [...], then code#124, in this special case, will be [...] plus the
first character of [...]. So just add the first character of [...] to the end
of itself. Not too bad.  As an example (and a very common one) of this special
case, let's assume we have a raster image in which the first three pixels have
the same color value. That is, my charstream looks like: QQQ.... For the sake
of argument, let's say we have 32 colors, and Q is the color#12. The
compressor will generate the code sequence 12,32,.... (if you don't know why,
take a minute to understand it.) Remember that #32 is not in the initial
table, which goes from #0 to #31. The decompressor will see #12 and translate
it just fine as color Q. Then it will see #32 and not yet know what that
means. But if it thinks about it long enough, it can figure out that QQ should
be entry#32 in the table and QQ should be the next string output.  So the
decompression pseudo-code goes something like:

      [1] Initialize string table;
     [2] get first code: <code>;
     [3] output the string for <code> to the charstream;
     [4] <old> = <code>;
     [5] <code> <- next code in codestream;
     [6] does <code> exist in the string table?
      (yes: output the string for <code> to the charstream;
            [...] <- translation for <old>;
            K <- first character of translation for <code>;
            add [...]K to the string table;        <old> <- <code>;  )
      (no: [...] <- translation for <old>;
           K <- first character of [...];
           output [...]K to charstream and add it to string table;
           <old> <- <code>
      )
     [7] go to [5];

      Again, when you get to step [5] and there are no more codes, you're
finished.  Outputting of strings, and finding of initial characters in strings
are efficiency problems all to themselves, but I'm not going to suggest ways
to do them here. Half the fun of programming is figuring these things out!
      ---
      Now for the GIF variations on the theme. In part of the header of a GIF
file, there is a field, in the Raster Data stream, called "code size". This is
a very misleading name for the field, but we have to live with it. What it is
really is the "root size". The actual size, in bits, of the compression codes
actually changes during compression/decompression, and I will refer to that
size here as the "compression size". The initial table is just the codes for
all the roots, as usual, but two special codes are added on top of those.
Suppose you have a "code size", which is usually the number of bits per pixel
in the image, of N. If the number of bits/pixel is one, then N must be 2: the
roots take up slots #0 and #1 in the initial table, and the two special codes
will take up slots #4 and #5. In any other case, N is the number of bits per
pixel, and the roots take up slots #0 through #(2**N-1), and the special codes
are (2**N) and (2**N + 1). The initial compression size will be N+1 bits per
code. If you're encoding, you output the codes (N+1) bits at a time to start
with, and if you're decoding, you grab (N+1) bits from the codestream at a
time.  As for the special codes: <CC> or the clear code, is (2**N), and <EOI>,
or end-of-information, is (2**N + 1). <CC> tells the compressor to re-
initialize the string table, and to reset the compression size to (N+1). <EOI>
means there's no more in the codestream.  If you're encoding or decoding, you
should start adding things to the string table at <CC> + 2. If you're
encoding, you should output <CC> as the very first code, and then whenever
after that you reach code #4095 (hex FFF), because GIF does not allow
compression sizes to be greater than 12 bits. If you're decoding, you should
reinitialize your string table when you observe <CC>.  The variable
compression sizes are really no big deal. If you're encoding, you start with a
compression size of (N+1) bits, and, whenever you output the code
(2**(compression size)-1), you bump the compression size up one bit. So the
next code you output will be one bit longer. Remember that the largest
compression size is 12 bits, corresponding to a code of 4095. If you get that
far, you must output <CC> as the next code, and start over.  If you're
decoding, you must increase your compression size AS SOON AS YOU write entry
#(2**(compression size) - 1) to the string table. The next code you READ will
be one bit longer. Don't make the mistake of waiting until you need to add the
code (2**compression size) to the table. You'll have already missed a bit from
the last code.  The packaging of codes into a bitsream for the raster data is
also a potential stumbling block for the novice encoder or decoder. The lowest
order bit in the code should coincide with the lowest available bit in the
first available byte in the codestream. For example, if you're starting with
5-bit compression codes, and your first three codes are, say, <abcde>,
<fghij>, <klmno>, where e, j, and o are bit#0, then your codestream will start
off like:

       byte#0: hijabcde
       byte#1: .klmnofg

      So the differences between straight LZW and GIF LZW are: two additional
special codes and variable compression sizes. If you understand LZW, and you
understand those variations, you understand it all!
      Just as sort of a P.S., you may have noticed that a compressor has a
little bit of flexibility at compression time. I specified a "greedy" approach
to the compression, grabbing as many characters as possible before outputting
codes. This is, in fact, the standard LZW way of doing things, and it will
yield the best compression ratio. But there's no rule saying you can't stop
anywhere along the line and just output the code for the current prefix,
whether it's already in the table or not, and add that string plus the next
character to the string table. There are various reasons for wanting to do
this, especially if the strings get extremely long and make hashing difficult.
If you need to, do it.
      Hope this helps out.----steve blackstock

---------------------------------------------------------------------------
Article 5729 of comp.graphics:
Path: polya!shelby!labrea!agate!ucbvax!tut.cis.ohio-state.edu!rutgers!cmcl2!phri!cooper!john
>From: john@cooper.cooper.EDU (John Barkaus)
Newsgroups: comp.graphics
Subject: GIF file format responses 4/5
Keywords: GIF LZW
Message-ID: <1489@cooper.cooper.EDU>
Date: 21 Apr 89 20:56:35 GMT
Organization: The Cooper Union (NY, NY)
Lines: 1050


>From: cmcl2!neuron1.Jpl.Nasa.Gov!harry (Harry Langenbacher)

G I F (tm)

     Graphics Interchange Format (tm)

      A standard defining a mechanism

     for the storage and transmission

   of raster-based graphics information

       June 15, 1987

     (c) CompuServe Incorporated, 1987

    All rights reserved

    While this document is copyrighted, the information

  contained within is made available for use in computer

  software without royalties, or licensing restrictions.

  GIF and 'Graphics Interchange Format' are trademarks of

CompuServe, Incorporated.

   an H&R Block Company

5000 Arlington Centre Blvd.

   Columbus, Ohio 43220

      (614) 457-8600

     Page 2

      Graphics Interchange Format (GIF) Specification

     Table of Contents

INTRODUCTION . . . . . . . . . . . . . . . . . page 3

GENERAL FILE FORMAT  . . . . . . . . . . . . . page 3

GIF SIGNATURE  . . . . . . . . . . . . . . . . page 4

SCREEN DESCRIPTOR  . . . . . . . . . . . . . . page 4

GLOBAL COLOR MAP . . . . . . . . . . . . . . . page 5

IMAGE DESCRIPTOR . . . . . . . . . . . . . . . page 6

LOCAL COLOR MAP  . . . . . . . . . . . . . . . page 7

RASTER DATA  . . . . . . . . . . . . . . . . . page 7

GIF TERMINATOR . . . . . . . . . . . . . . . . page 8

GIF EXTENSION BLOCKS . . . . . . . . . . . . . page 8

APPENDIX A - GLOSSARY  . . . . . . . . . . . . page 9

APPENDIX B - INTERACTIVE SEQUENCES . . . . . . page 10

APPENDIX C - IMAGE PACKAGING & COMPRESSION . . page 12

APPENDIX D - MULTIPLE IMAGE PROCESSING . . . . page 15

Graphics Interchange Format (GIF)      Page 3

Specification

INTRODUCTION

'GIF' (tm) is CompuServe's standard for defining generalized  color

   raster   images.    This   'Graphics  Interchange  Format'  (tm)  allows

   high-quality, high-resolution graphics to be displayed on a variety  of

   graphics  hardware  and is intended as an exchange and display mechanism

   for graphics images.  The image format described  in  this  document  is

   designed  to  support  current  and future image technology and will in

   addition serve as a basis for future CompuServe graphics products.

The main focus of  this  document  is to  provide  the  technical

   information necessary  for a  programmer to implement GIF encoders and

   decoders.  As such, some assumptions are made as to terminology relavent

   to graphics and programming in general.

The first section of this document describes the  GIF  data  format

   and its components and applies to all GIF decoders, either as standalone

   programs or as part of  a  communications  package. Appendix  B  is  a

   section  relavent to decoders that are part of a communications software

   package and describes the protocol requirements for entering and exiting

   GIF mode, and responding to host interrogations.  A glossary in Appendix

   A defines some of the terminology used in  this  document. Appendix  C

   gives  a  detailed  explanation  of how  the  graphics  image itself is

   packaged as a series of data bytes.

Graphics Interchange Format Data Definition

 GENERAL FILE FORMAT

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

| +-------------------+ |

| |   GIF Signature   | |

| +-------------------+ |

| +-------------------+ |

| | Screen Descriptor | |

| +-------------------+ |

| +-------------------+ |

| | Global Color Map  | |

| +-------------------+ |

. . .     . . .

| +-------------------+ |    ---+

| |  Image Descriptor | | |

| +-------------------+ | |

| +-------------------+ | |

| |  Local Color Map  | | |-   Repeated 1 to n times

| +-------------------+ | |

| +-------------------+ | |

| |    Raster Data    | | |

| +-------------------+ |    ---+

. . .     . . .

|-    GIF Terminator   -|

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

Graphics Interchange Format (GIF)      Page 4

Specification

 GIF SIGNATURE

The following GIF Signature identifies the  data  following  as  a

   valid GIF image stream.  It consists of the following six characters:

     G I F 8 7 a

The last three characters '87a' may be viewed as a  version  number

   for this  particular  GIF  definition  and will be used in general as a

   reference  in  documents  regarding GIF  that   address   any   version

   dependencies.

 SCREEN DESCRIPTOR

The Screen Descriptor describes the overall parameters for all GIF

   images  following.  It defines the overall dimensions of the image space

   or logical screen required, the existance of color mapping  information,

   background  screen color, and color depth information.  This information

   is stored in a series of 8-bit bytes as described below.

      bits

7 6 5 4 3 2 1 0  Byte #

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

| |  1

+-Screen Width -+      Raster width in pixels (LSB first)

| |  2

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

| |  3

+-Screen Height-+      Raster height in pixels (LSB first)

| |  4

+-+-----+-+-----+      M = 1, Global color map follows Descriptor

|M|  cr |0|pixel|  5   cr+1 = # bits of color resolution

+-+-----+-+-----+      pixel+1 = # bits/pixel in image

|   background |  6   background=Color index of screen background

+---------------+    (color is defined from the Global color

|0 0 0 0 0 0 0 0|  7     map or default map if none specified)

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

The logical screen width and height can both  be  larger  than the

   physical  display. How  images  larger  than  the physical display are

   handled is implementation dependent and can take advantage  of  hardware

   characteristics  (e.g.   Macintosh scrolling windows).  Otherwise images

   can be clipped to the edges of the display.

The value of 'pixel' also defines  the maximum  number  of  colors

   within  an  image. The  range  of values for 'pixel' is 0 to 7 which

   represents 1 to 8 bits.  This translates to a range of 2 (B & W) to 256

   colors.   Bit  3 of word 5 is reserved for future definition and must be

   zero.

Graphics Interchange Format (GIF)      Page 5

Specification

 GLOBAL COLOR MAP

The Global Color Map is optional but recommended for  images  where

   accurate color rendition is desired.  The existence of this color map is

   indicated in the 'M' field of byte 5 of the Screen Descriptor.  A  color

   map can  also  be associated with each image in a GIF file as described

   later.  However this  global  map  will  normally  be  used because  of

   hardware  restrictions  in equipment available today.  In the individual

   Image Descriptors the 'M' flag will normally be  zero.   If the  Global

   Color  Map  is  present,  it's definition immediately follows the Screen

   Descriptor. The  number  of  color  map  entries  following  a  Screen

   Descriptor  is equal to 2**(# bits per pixel), where each entry consists

   of three byte values representing the relative intensities of red, green

   and blue respectively.  The structure of the Color Map block is:

      bits

7 6 5 4 3 2 1 0  Byte #

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

| red intensity |  1 Red value for color index 0

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

|green intensity|  2 Green value for color index 0

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

| blue intensity|  3 Blue value for color index 0

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

| red intensity |  4 Red value for color index 1

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

|green intensity|  5 Green value for color index 1

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

| blue intensity|  6 Blue value for color index 1

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

: : (Continues for remaining colors)

Each image pixel value received will be displayed according to its

   closest match with an available color of the display based on this color

   map.  The color components represent a fractional intensity value  from

   none  (0)  to  full (255).  White would be represented as (255,255,255),

   black as (0,0,0) and medium yellow as (180,180,0).  For display, if the

   device  supports fewer than 8 bits per color component, the higher order

   bits of each component are used.  In the creation of  a  GIF  color map

   entry  with hardware  supporting  fewer  than 8 bits per component, the

   component values for the hardware  should  be  converted  to  the  8-bit

   format with the following calculation:

<map_value> = <component_value>*255/(2**<nbits> -1)

This assures accurate translation of colors for all  displays. In

   the cases  of  creating  GIF images from hardware without color palette

   capability, a fixed palette should be created  based  on  the  available

   display  colors for that hardware.  If no Global Color Map is indicated,

   a default color map is generated internally which  maps  each  possible

   incoming  color  index to the same hardware color index modulo <n> where

   <n> is the number of available hardware colors.

Graphics Interchange Format (GIF)      Page 6

Specification

 IMAGE DESCRIPTOR

The Image Descriptor defines the actual placement  and extents  of

   the following  image within the space defined in the Screen Descriptor.

   Also defined are flags to indicate the presence of a local color  lookup

   map, and to define the pixel display sequence.  Each Image Descriptor is

   introduced by an image separator  character.   The  role  of  the  Image

   Separator  is simply to provide a synchronization character to introduce

   an Image Descriptor.  This is desirable if a GIF file happens to contain

   more  than  one  image.   This  character  is defined as 0x2C hex or ','

   (comma).  When this character is encountered between images,  the  Image

   Descriptor will follow immediately.

Any characters encountered between the end of a previous image and

   the image separator character are to be ignored.  This allows future GIF

   enhancements to be present in newer image formats and yet ignored safely

   by older software decoders.

      bits

7 6 5 4 3 2 1 0  Byte #

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

|0 0 1 0 1 1 0 0|  1 ',' - Image separator character

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

| |  2 Start of image in pixels from the

+-  Image Left -+ left side of the screen (LSB first)

| |  3

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

| |  4

+-  Image Top  -+ Start of image in pixels from the

| |  5 top of the screen (LSB first)

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

| |  6

+- Image Width -+ Width of the image in pixels (LSB first)

| |  7

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

| |  8

+- Image Height-+ Height of the image in pixels (LSB first)

| |  9

+-+-+-+-+-+-----+ M=0 - Use global color map, ignore 'pixel'

|M|I|0|0|0|pixel| 10 M=1 - Local color map follows, use 'pixel'

+-+-+-+-+-+-----+ I=0 - Image formatted in Sequential order

I=1 - Image formatted in Interlaced order

pixel+1 - # bits per pixel for this image

The specifications for the image position and size must be confined

   to  the  dimensions defined by the Screen Descriptor.  On the other hand

   it is not necessary that the image fill the entire screen defined.

 LOCAL COLOR MAP

Graphics Interchange Format (GIF)      Page 7

Specification

A Local Color Map is optional and defined here for future use. If

   the 'M' bit of byte 10 of the Image Descriptor is set, then a color map

   follows the Image Descriptor that applies only to the  following  image.

   At the end of the image, the color map will revert to that defined after

   the Screen Descriptor.  Note that the 'pixel' field of byte 10  of the

   Image  Descriptor  is used only if a Local Color Map is indicated.  This

   defines the parameters not only for the image pixel size, but determines

   the number of color map entries that follow.  The bits per pixel value

   will also revert to the value specified in the  Screen  Descriptor  when

   processing of the image is complete.

 RASTER DATA

The format of the actual image is defined as the  series  of  pixel

   color  index  values that make up the image.  The pixels are stored left

   to right sequentially for an image row.  By default each  image  row  is

   written  sequentially, top to bottom.  In the case that the Interlace or

   'I' bit is set in byte 10 of the Image Descriptor then the row order  of

   the image  display follows  a  four-pass process in which the image is

   filled in by widely spaced rows.  The first pass writes every  8th  row,

   starting  with  the top row of the image window.  The second pass writes

   every 8th row starting at the fifth row from the top.   The third  pass

   writes every 4th row starting at the third row from the top.  The fourth

   pass completes the image, writing  every  other  row,  starting  at the

   second row from the top.  A graphic description of this process follows:

   Image

   Row Pass 1 Pass 2 Pass 3 Pass 4 Result

   ---------------------------------------------------

     0 **1a** **1a**

     1 **4a** **4a**

     2 **3a** **3a**

     3 **4b** **4b**

     4 **2a** **2a**

     5 **4c** **4c**

     6 **3b** **3b**

     7 **4d** **4d**

     8 **1b** **1b**

     9 **4e** **4e**

    10 **3c** **3c**

    11 **4f** **4f**

    12 **2b** **2b**

   . . .

The image pixel values are processed as a series of  color  indices

   which  map  into the existing color map.  The resulting color value from

   the map is what is actually displayed.  This series of  pixel  indices,

   the number of  which  is equal to image-width*image-height pixels, are

   passed to the GIF image data stream one value per pixel, compressed and

   packaged  according to  a  version of the LZW compression algorithm as

   defined in Appendix C.

Graphics Interchange Format (GIF)      Page 8

Specification

 GIF TERMINATOR

In order to provide a synchronization for the termination of a GIF

   image  file,  a  GIF  decoder  will process the end of GIF mode when the

   character 0x3B hex or ';' is found after an image  has  been  processed.

   By  convention  the decoding software will pause and wait for an action

   indicating that the user is ready to continue.  This may be a  carriage

   return  entered  at the  keyboard  or  a  mouse click.  For interactive

   applications this user action must  be  passed  on  to  the host  as  a

   carriage  return  character so  that the host application can continue.

   The decoding software will then typically leave graphics mode and resume

   any previous process.

 GIF EXTENSION BLOCKS

To provide for orderly extension of the GIF definition, a mechanism

   for defining  the  packaging  of extensions within a GIF data stream is

   necessary.  Specific GIF extensions are to be defined and documented  by

   CompuServe in order to provide a controlled enhancement path.

GIF Extension Blocks are packaged in a manner similar to that  used

   by the raster data though not compressed.  The basic structure is:

7 6 5 4 3 2 1 0  Byte #

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

|0 0 1 0 0 0 0 1|  1    '!' - GIF Extension Block Introducer

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

| function code |  2    Extension function code (0 to 255)

+---------------+    ---+

|  byte count | |

+---------------+ |

: : +-- Repeated as many times as necessary

|func data bytes| |

: : |

+---------------+    ---+

. . .     . . .

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

|0 0 0 0 0 0 0 0| zero byte count (terminates block)

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

A GIF Extension Block may immediately preceed any Image  Descriptor

   or occur before the GIF Terminator.

All GIF decoders must be able to recognize  the  existence  of GIF

   Extension  Blocks  and  read past them if unable to process the function

   code.  This ensures that older decoders will be able to process extended

   GIF image files in  the  future,  though  without  the  additional

   functionality.

Graphics Interchange Format (GIF)      Page 9

Appendix A - Glossary

GLOSSARY

Pixel - The smallest picture element of a  graphics  image.   This  usually

   corresponds to  a single dot on a graphics screen. Image resolution is

   typically given in units of pixels.   For  example a  fairly  standard

   graphics  screen  format  is  one 320 pixels across and 200 pixels high.

   Each pixel can  appear  as  one  of several  colors  depending  on the

   capabilities of the graphics hardware.

Raster - A horizontal row of pixels representing one line of an  image.   A

   typical method of working with images since most hardware is oriented to

   work most efficiently in this manner.

LSB - Least Significant Byte.  Refers to a convention for two byte  numeric

   values in which the less significant byte of the value preceeds the more

   significant byte.  This convention is typical on many microcomputers.

Color Map - The list of definitions of each color  used  in  a GIF  image.

   These  desired  colors are converted to available colors through a table

   which is derived by assigning an incoming color index (from the  image)

   to  an  output  color  index  (of  the  hardware). While the color map

   definitons are specified in a GIF image, the output pixel  colors  will

   vary  based on  the  hardware used and its ability to match the defined

   color.

Interlace - The method of displaying a GIF image in which  multiple  passes

   are made,  outputting  raster  lines  spaced  apart to provide a way of

   visualizing the general content of an entire image  before  all  of the

   data has been processed.

B Protocol - A CompuServe-developed error-correcting file transfer protocol

   available  in  the  public  domain  and implemented in CompuServe VIDTEX

   products.  This error checking mechanism will be used  in  transfers  of

   GIF images for interactive applications.

LZW - A sophisticated data compression algorithm  based  on  work  done  by

   Lempel-Ziv  &  Welch  which has  the feature of very efficient one-pass

   encoding and decoding.  This allows the image  to  be  decompressed and

   displayed  at  the  same  time.   The  original  article from which this

   technique was adapted is:

  Terry  A.   Welch,  "A  Technique  for  High Performance   Data

  Compression", IEEE Computer, vol 17 no 6 (June 1984)

This basic algorithm is also used in the  public  domain  ARC  file

   compression utilities.   The  CompuServe  adaptation  of LZW for GIF is

   described in Appendix C.

Graphics Interchange Format (GIF)     Page 10

Appendix B - Interactive Sequences

   GIF Sequence Exchanges for an Interactive Environment

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 GCE 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 GCE is defined as:

ESC [ > 0 g (g is lower case, spaces inserted for clarity)

(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>

   '#' - GCR identifier character (Number Sign)

   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 an 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 2**color-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  GCR  are  returned  as  ASCII  decimal

   numbers and the message is terminated by a Carriage Return character.

Graphics Interchange Format (GIF)     Page 11

Appendix B - Interactive Sequences

The  following GCR   message describes   three   standard EGA

   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 [ > 1 g   Display GIF image on screen

   (0x1B 0x5B 0x3E 0x31 0x67)

     ESC [ > 2 g   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  lower

   case.

 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.

Graphics Interchange Format (GIF)     Page 12

Appendix C - Image Packaging & Compression

The Raster Data stream that represents the actual output image can

   be represented as:

7 6 5 4 3 2 1 0

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

|   code size |

+---------------+     ---+

|blok byte count| |

+---------------+ |

: : +-- Repeated as many times as necessary

|  data bytes | |

: : |

+---------------+     ---+

. . .     . . .

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

|0 0 0 0 0 0 0 0| zero byte count (terminates data stream)

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

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  preceeded  by

       character counts and output.

ESTABLISH CODE SIZE

The first byte of the GIF Raster 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.

Graphics Interchange Format (GIF)     Page 13

Appendix C - Image Packaging & Compression

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 (hex FFF).  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 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:

byte n       byte 5   byte 4 byte 3 byte 2   byte 1

+-.....-----+--------+--------+--------+--------+--------+

| and so on |hhhhhggg|ggfffffe|eeeedddd|dcccccbb|bbbaaaaa|

+-.....-----+--------+--------+--------+--------+--------+

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 preceeding 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

Graphics Interchange Format (GIF)     Page 14

Appendix C - Image Packaging & Compression

   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.

Graphics Interchange Format (GIF)     Page 15

Appendix D - Multiple Image Processing

Since a  GIF  data  stream  can  contain  multiple  images,  it  is

   necessary  to  describe  processing and display of such a file.  Because

   the image descriptor allows for  placement of  the  image within the

   logical  screen,  it is possible to define a sequence of images that may

   each be a partial screen, but in total  fill  the  entire  screen. The

   guidelines for handling the multiple image situation are:

   1.  There is no pause between images.  Each is processed immediately  as

       seen by the decoder.

   2.  Each image explicitly overwrites any image  already  on the  screen

       inside  of  its window. The only screen clears are at the beginning

       and end of the  GIF  image  process.   See  discussion  on  the GIF

       terminator.


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