README - platform/external/libjpeg-turbo - Gitiles

 The Independent JPEG Group's JPEG software
 ==========================================

 README for release of  7-Oct-91
 ===============================

 This distribution contains the first public release of the Independent JPEG
 Group's free JPEG software.  You are welcome to redistribute this software and
 to use it for any purpose, subject to the conditions under LEGAL ISSUES, below.

 This software is still undergoing revision.  Updated versions may be obtained
 by anonymous FTP to uunet.uu.net; look under directory /graphics/jpeg.  This
 particular version will be archived as jpegsrc.v1.tar.Z.  If you don't have
 access to Internet FTP, UUNET's archives are also available via UUCP; contact
 postmaster@uunet.uu.net for information on retrieving files that way.

 Please report any problems with this software to jpeg-info@uunet.uu.net.

 If you intend to become a serious user of this software, please contact
 jpeg-info@uunet to be added to our electronic mailing list.  Then you'll be
 notified of updates and have a chance to participate in discussions, etc.

 This software is the work of Tom Lane, Philip Gladstone, Luis Ortiz, and other
 members of the independent JPEG group.


 DISCLAIMER
 ==========

 THIS SOFTWARE IS NOT COMPLETE NOR FULLY DEBUGGED.  It is not guaranteed to be
 useful for anything, nor to be compatible with subsequent releases, nor to be
 an accurate implementation of the JPEG standard.  (See LEGAL ISSUES for even
 more disclaimers.)


 WHAT'S HERE
 ===========

 This distribution contains software to implement JPEG image compression and
 decompression.  JPEG is a standardized compression method for full-color and
 gray-scale images.  JPEG is intended for "real-world" scenes; cartoons and
 other non-realistic images are not its strong suit.  JPEG is lossy, meaning
 that the output image is not necessarily identical to the input image.  Hence
 you should not use JPEG if you have to have identical output bits.  However,
 on typical images of real-world scenes, very good compression levels can be
 obtained with hardly any visible change, and amazingly high compression levels
 can be obtained if you can tolerate a low-quality image.  For more details,
 see the references, or just experiment with various compression settings.

 The software implements JPEG baseline and extended-sequential compression
 processes.  Provision is made for supporting all variants of these processes,
 although some uncommon parameter settings aren't implemented yet.  For legal
 reasons, we are not distributing code for the arithmetic-coding process; see
 LEGAL ISSUES.  At present we have made no provision for supporting the
 progressive or lossless processes defined in the standard.

 The present software is still largely in the prototype stage.  It does not
 support all possible variants of the JPEG standard, and some functions have
 rather slow and/or crude implementations.  However, it is useful already.

 The emphasis in designing this software has been on achieving portability and
 flexibility, while also making it fast enough to be useful.  We have not yet
 undertaken serious performance measurement or tuning; we intend to do so in
 the future.


 This software can be used on several levels:

 * As canned software for JPEG compression and decompression.  Just edit the
   Makefile and configuration files as needed (see SETUP), compile and go.
   Members of the independent JPEG group will improve the out-of-the-box
   functionality as time goes on.

 * As the basis for other JPEG programs.  For example, you could incorporate
   the decompressor into a general image viewing package by replacing the
   output module with write-to-screen functions.  For an implementation on
   specific hardware, you might want to replace some of the inner loops with
   assembly code.  For a non-command-line-driven system, you might want a
   different user interface.  (Members of the group will be producing Macintosh
   and Amiga versions with appropriate user interfaces, for example.)

 * As a toolkit for experimentation with JPEG and JPEG-like algorithms.  Most
   of the individual decisions you might want to mess with are packaged up into
   separate modules.  For example, the details of color-space conversion and
   subsampling techniques are each localized in one compressor and one
   decompressor module.  You'd probably also want to extend the user interface
   to give you more detailed control over the JPEG compression parameters.

 In particular, we welcome the use of this software as the basis for commercial
 products; no royalty is required.


 SETUP
 =====

 The installation process is not very automatic; you will need at least some
 familiarity with C programming and program build procedures for your system.
 (Volunteers to work on improving this situation are welcome.  Also, we will
 probably start distributing pre-built binaries for popular systems at some
 point.)

 First, select a makefile and copy it to "Makefile".  "makefile.unix"
 is appropriate for most Unix and Unix-like systems.  Special makefiles are
 included for various PC compilers.  If you don't see a makefile for your
 system, we recommend starting from makefile.unix.

 Look over the Makefile and adjust options as needed.  In particular, you'll
 need to change the CC= and CFLAGS= definitions if you don't have gcc
 (makefile.unix only).  If you have a function-prototype-less compiler, be sure
 to uncomment the .c.o rule and say "make ansi2knr".  This will cause the
 source files to be preprocessed to change our ANSI-style function definitions
 to old-style definitions.  (Thanks to Peter Deutsch of Aladdin Enterprises for
 ansi2knr.)

 Also look over jconfig.h and adjust #defines as necessary.  If you have an
 ANSI-compliant C compiler (gcc for instance), no changes should be necessary
 except perhaps for RIGHT_SHIFT_IS_UNSIGNED and TWO_FILE_COMMANDLINE.  For
 older compilers other mods may be needed, depending on what ANSI features are
 supported.  If you prefer, you can usually leave jconfig.h unmodified and add
 -D switches to the Makefile's CFLAGS= definition.

 Then say "make".

 If you have trouble with missing system include files or inclusion of the
 wrong ones, you can fix it in jinclude.h.  In particular, if you are using
 gcc on a machine with non-ANSI system include files, you are likely to find
 that jinclude.h tries to include the wrong files (because gcc defines
 __STDC__).  There's no good automatic solution to this, so you'll just have
 to hand-edit jinclude.h.

 As a quick test of functionality we've included three sample files:
 	testorig.jpg	same as blkint.jpg from JPEG validation floppy.
 	testimg.ppm	output of djpeg testorig.jpg
 	testimg.jpg	output of cjpeg testimg.ppm
 The two .jpg files aren't identical due to different parameter choices (and
 wouldn't be anyway, since JPEG is lossy).  However, if you can generate
 duplicates of testimg.ppm and testimg.jpg then you probably have a working
 port.  "make test" will perform the necessary comparisons (by generating
 testout.ppm and testout.jpg and comparing these to testimg.*).  NOTE: this
 is far from an exhaustive test of the JPEG software; some modules, such as
 color quantization and GIF I/O, are not exercised at all.  It's just a quick
 test to give you some confidence that you haven't missed something major.

 If you need to make a smaller version of the JPEG software, some optional
 functions can be removed at compile time.  See the xxx_SUPPORTED #defines
 in jconfig.h.  (Not a lot is actually removed right now, but as more optional
 stuff gets added, this mechanism will start to make a difference.)

 If you want to incorporate the JPEG code as subroutines in a larger program,
 we recommend that you make libjpeg.a.  Then use the .h files and libjpeg.a as
 your interface to the JPEG functions.  Your surrounding program will have to
 provide functionality similar to what's in jcmain.c or jdmain.c, and you may
 want to replace jerror.c and possibly other modules depending on your needs.
 See the "architecture" file for more info.  If it seems to you that the system
 structure doesn't accommodate what you want to do, please contact the authors.

 Special notes for Macintosh Think C users: If you have version 5.0 you should
 be able to just turn on __STDC__ through the compiler switch that enables
 that.  With version 4.0 you must manually edit jconfig.h to define PROTO,
 HAVE_UNSIGNED_CHAR, HAVE_UNSIGNED_SHORT, and const.  (It seems to be safe to
 just define __STDC__ to take care of the first three.)  When setting up
 project files, use the COBJECTS and DOBJECTS lists in makefile.unix as a guide
 to which files need to be included, and add the ANSI and Unix C libraries in a
 separate segment.  You may need to divide the JPEG files into more than one
 segment; you can do this pretty much as you please.


 USAGE
 =====

 The user interface is pretty minimal at this point.  We haven't bothered to
 generate manual-page files since the switches badly need redesign.  At the
 moment, things work like this:

 There are two programs, cjpeg to compress an image file into JPEG format,
 and djpeg to decompress.

 On Unix systems, you say:
 	cjpeg [switches] [imagefile] >jpegfile
 	djpeg [switches] [jpegfile]  >imagefile
 The programs read the specified input file, or standard input if none is
 named.  They always write to standard output (with trace/error messages to
 standard error).  These conventions are handy for piping images between
 programs.

 On PC, Macintosh, and Amiga systems, you say:
 	cjpeg [switches] imagefile jpegfile
 	djpeg [switches] jpegfile  imagefile
 i.e., both input and output files are named on the command line.  This style
 is a little more foolproof, and it loses no functionality if you don't have
 pipes.  You can get this style on Unix too, if you prefer, by defining
 TWO_FILE_COMMANDLINE in jconfig.h or in the Makefile.  You MUST use this style
 on any system that doesn't cope well with binary data fed through
 stdin/stdout.

 Currently supported image file formats include raw-format PPM, raw-format PGM
 (for monochrome images), and GIF.  cjpeg recognizes the input image format
 automatically, but you have to tell djpeg which format to generate.

 The only JPEG file format currently supported is a raw JPEG data stream.
 Unless modified, the programs use the JFIF conventions for variables left
 unspecified by the JPEG standard.  (In particular, cjpeg generates a JFIF APP0
 marker.)  Support for the JPEG-in-TIFF format will probably be added at some
 future date.

 The command line switches for cjpeg are:

 	-I		Generate noninterleaved JPEG file (not yet supported).

 	-Q quality	Scale quantization tables to adjust quality.
 			Quality is 0 (worst) to 100 (best); default is 75.
 			(See below for more info.)

 	-a		Use arithmetic coding rather than Huffman coding.
 			(Not currently supported, see LEGAL ISSUES.)

 	-o		Perform optimization of entropy encoding parameters.
 			Without this, default Huffman or arithmetic
 			parameters are used.  -o makes the JPEG file a tad
 			smaller, but compression uses much more memory.
 			Image quality is unaffected by -o.

 	-d		Enable debug printout.  More -d's give more printout.

 Typically you'd use -Q settings of 50 or 75 or so.  -Q 100 will generate a
 quantization table of all 1's, meaning no quantization loss; then any
 differences between input and output images are due to subsampling or to
 roundoff error in the DCT or colorspace-conversion steps.  -Q values below 50
 may be useful for making real small, low-quality images.  Try -Q 2 (or so) for
 some amusing Cubist effects.  (Note that -Q values below about 25 generate
 2-byte quantization tables, which are not decodable by pure baseline JPEG
 decoders.  cjpeg emits a warning message when you give such a -Q value.)

 The command line switches for djpeg are:

 	-G		Select GIF output format (implies -q, with default
 			of 256 colors).

 	-b		Perform cross-block smoothing.  This is quite
 			memory-intensive and only seems to improve the image
 			at very low quality settings (-Q 10 to 20 or so).

 	-g		Force gray-scale output even if input is color.

 	-q N		Quantize to N colors.

 	-D		Use Floyd-Steinberg dithering in color quantization.

 	-2		Use two-pass color quantization (not yet supported).

 	-d		Enable debug printout.  More -d's give more printout.

 Color quantization currently uses a rather shoddy algorithm (although it's not
 so horrible when dithered).  Because of this, the GIF output mode is not
 recommended in the current release, except for gray-scale output.  You can get
 better results by applying ppmquant to the unquantized (PPM) output of djpeg,
 then converting to GIF with ppmtogif.  We expect to provide a considerably
 better quantization algorithm in a future release.

 Note that djpeg *can* read noninterleaved JPEG files even though cjpeg can't
 yet generate them.  For most applications this is a nonissue, since hardly
 anybody seems to be using noninterleaved format.

 On a non-virtual-memory machine, you may run out of memory if you use -I or -o
 in cjpeg, or -q ... -2 in djpeg, or try to read an interlaced GIF file.  This
 will be addressed eventually by replacing jvirtmem.c with something that uses
 temporary files for large images (see TO DO).


 REFERENCES
 ==========

 The best and most readily available introduction to the JPEG compression
 algorithm is Wallace's article in the April '91 CACM:
 	Wallace, Gregory K.  "The JPEG Still Picture Compression Standard",
 	Communications of the ACM, April 1991 (vol. 34 no. 4), pp. 30-44.
 (Adjacent articles in that issue discuss MPEG motion picture compression,
 applications of JPEG, and related topics.)  We highly recommend reading that
 article before looking at any of the JPEG software.

 For more detail about the JPEG standard you pretty much have to go to the
 draft standard, which is not nearly as intelligible as Wallace's article.
 The current version is ISO/IEC Committee Draft CD 10918-1 dated 1991-03-15.
 The standard is not presently available electronically; you must order a paper
 copy through ISO.

 The JPEG standard does not specify all details of an interchangeable file
 format.  For the omitted details we follow the "JFIF" conventions, revision
 1.01.  A copy of the JFIF spec is available from:
 	Literature Department
 	C-Cube Microsystems, Inc.
 	399A West Trimble Road
 	San Jose, CA  95131
 	(408) 944-6300
 Requests can also be e-mailed to info@c3.pla.ca.us (this address good after
 10/10/91).  The same source can supply copies of the draft JPEG-in-TIFF specs.

 If you want to understand this implementation, start by reading the
 "architecture" documentation file.  Please read "codingrules" if you want to
 contribute any code.


 SUPPORTING SOFTWARE
 ===================

 You will probably want Jef Poskanzer's PBMPLUS image software; this provides
 many useful operations on PPM-format image files.  In particular, it can
 convert PPM images to and from a wide range of other formats.  You can FTP
 this free software from export.lcs.mit.edu (contrib/pbmplus*.tar.Z) or
 ftp.ee.lbl.gov (pbmplus*.tar.Z).

 If you are using X Windows you might want to use the xv or xloadimage viewers
 to save yourself the trouble of converting PPM to some other format.
 Both of these can be found in the contrib directory at export.lcs.mit.edu.


 LEGAL ISSUES
 ============

 The authors make NO WARRANTY or representation, either express or implied,
 with respect to this software, its quality, accuracy, merchantability, or
 fitness for a particular purpose.  This software is provided "AS IS", and you,
 its user, assume the entire risk as to its quality and accuracy.

 This software is copyright (C) 1991, Thomas G. Lane.
 All Rights Reserved except as specified below.

 Permission is hereby granted to use, copy, modify, and distribute this
 software (or portions thereof) for any purpose, without fee, subject to these
 conditions:
 (1) If any part of the source code for this software is distributed, then this
 README file must be included, with this copyright and no-warranty notice
 unaltered; and any additions, deletions, or changes to the original files
 must be clearly indicated in accompanying documentation.
 (2) If only executable code is distributed, then the accompanying
 documentation must state that "this software is based in part on the work of
 the Independent JPEG Group".
 (3) Permission for use of this software is granted only if the user accepts
 full responsibility for any undesirable consequences; the authors accept
 NO LIABILITY for damages of any kind.

 Permission is NOT granted for the use of any author's name or author's company
 name in advertising or publicity relating to this software or products derived
 from it.  This software may be referred to only as "the Independent JPEG
 Group's software".

 We specifically permit and encourage the use of this software as the basis of
 commercial products, provided that all warranty or liability claims are
 assumed by the product vendor.


 ansi2knr.c is included in this distribution by permission of L. Peter Deutsch,
 sole proprietor of its copyright holder, Aladdin Enterprises of Menlo Park, CA.
 ansi2knr.c is NOT covered by the above copyright and conditions, but instead
 by the usual distribution terms of the Free Software Foundation; principally,
 that you must include source code if you redistribute it.  (See the file
 ansi2knr.c for full details.)  However, since ansi2knr.c is not needed as part
 of any product generated from the JPEG code, this does not limit you more than
 the foregoing paragraphs do.


 It appears that the arithmetic coding option of the JPEG spec is covered by
 patents held by IBM, and possibly also patents of AT&T and Mitsubishi.  Hence
 arithmetic coding cannot legally be used without obtaining one or more
 licenses.  For this reason, support for arithmetic coding has been removed
 from the free JPEG software.  (Since arithmetic coding provides only a
 marginal gain over the unpatented Huffman mode, it is unlikely that very many
 people will choose to use it.  If you do obtain such a license, contact
 jpeg-info@uunet.uu.net for a copy of our arithmetic coding modules.)  So far
 as we are aware, there are no patent restrictions on the remaining code.


 TO DO
 =====

 Many of the modules need fleshing out to provide more complete
 implementations, or to provide faster paths for common cases.  The greatest
 needs are for (a) decent color quantization, and (b) a memory manager
 implementation that can work in limited memory by swapping "big" images to
 temporary files.  I (Tom Lane) am going to work on color quantization next.
 Volunteers to write a PC memory manager, or to work on any other modules, are
 welcome.

 We'd appreciate it if people would compile and check out the code on as wide a
 variety of systems as possible, and report any portability problems
 encountered (with solutions, if possible).  Checks of file compatibility with
 other JPEG implementations would also be of interest.  Finally, we would
 appreciate code profiles showing where the most time is spent, especially on
 unusual systems.

 Please send bug reports, offers of help, etc. to jpeg-info@uunet.uu.net.
	The Independent JPEG Group's JPEG software
	==========================================

	README for release of 7-Oct-91
	===============================

	This distribution contains the first public release of the Independent JPEG
	Group's free JPEG software. You are welcome to redistribute this software and
	to use it for any purpose, subject to the conditions under LEGAL ISSUES, below.

	This software is still undergoing revision. Updated versions may be obtained
	by anonymous FTP to uunet.uu.net; look under directory /graphics/jpeg. This
	particular version will be archived as jpegsrc.v1.tar.Z. If you don't have
	access to Internet FTP, UUNET's archives are also available via UUCP; contact
	postmaster@uunet.uu.net for information on retrieving files that way.

	Please report any problems with this software to jpeg-info@uunet.uu.net.

	If you intend to become a serious user of this software, please contact
	jpeg-info@uunet to be added to our electronic mailing list. Then you'll be
	notified of updates and have a chance to participate in discussions, etc.

	This software is the work of Tom Lane, Philip Gladstone, Luis Ortiz, and other
	members of the independent JPEG group.


	DISCLAIMER
	==========

	THIS SOFTWARE IS NOT COMPLETE NOR FULLY DEBUGGED. It is not guaranteed to be
	useful for anything, nor to be compatible with subsequent releases, nor to be
	an accurate implementation of the JPEG standard. (See LEGAL ISSUES for even
	more disclaimers.)


	WHAT'S HERE
	===========

	This distribution contains software to implement JPEG image compression and
	decompression. JPEG is a standardized compression method for full-color and
	gray-scale images. JPEG is intended for "real-world" scenes; cartoons and
	other non-realistic images are not its strong suit. JPEG is lossy, meaning
	that the output image is not necessarily identical to the input image. Hence
	you should not use JPEG if you have to have identical output bits. However,
	on typical images of real-world scenes, very good compression levels can be
	obtained with hardly any visible change, and amazingly high compression levels
	can be obtained if you can tolerate a low-quality image. For more details,
	see the references, or just experiment with various compression settings.

	The software implements JPEG baseline and extended-sequential compression
	processes. Provision is made for supporting all variants of these processes,
	although some uncommon parameter settings aren't implemented yet. For legal
	reasons, we are not distributing code for the arithmetic-coding process; see
	LEGAL ISSUES. At present we have made no provision for supporting the
	progressive or lossless processes defined in the standard.

	The present software is still largely in the prototype stage. It does not
	support all possible variants of the JPEG standard, and some functions have
	rather slow and/or crude implementations. However, it is useful already.

	The emphasis in designing this software has been on achieving portability and
	flexibility, while also making it fast enough to be useful. We have not yet
	undertaken serious performance measurement or tuning; we intend to do so in
	the future.


	This software can be used on several levels:

	* As canned software for JPEG compression and decompression. Just edit the
	Makefile and configuration files as needed (see SETUP), compile and go.
	Members of the independent JPEG group will improve the out-of-the-box
	functionality as time goes on.

	* As the basis for other JPEG programs. For example, you could incorporate
	the decompressor into a general image viewing package by replacing the
	output module with write-to-screen functions. For an implementation on
	specific hardware, you might want to replace some of the inner loops with
	assembly code. For a non-command-line-driven system, you might want a
	different user interface. (Members of the group will be producing Macintosh
	and Amiga versions with appropriate user interfaces, for example.)

	* As a toolkit for experimentation with JPEG and JPEG-like algorithms. Most
	of the individual decisions you might want to mess with are packaged up into
	separate modules. For example, the details of color-space conversion and
	subsampling techniques are each localized in one compressor and one
	decompressor module. You'd probably also want to extend the user interface
	to give you more detailed control over the JPEG compression parameters.

	In particular, we welcome the use of this software as the basis for commercial
	products; no royalty is required.


	SETUP
	=====

	The installation process is not very automatic; you will need at least some
	familiarity with C programming and program build procedures for your system.
	(Volunteers to work on improving this situation are welcome. Also, we will
	probably start distributing pre-built binaries for popular systems at some
	point.)

	First, select a makefile and copy it to "Makefile". "makefile.unix"
	is appropriate for most Unix and Unix-like systems. Special makefiles are
	included for various PC compilers. If you don't see a makefile for your
	system, we recommend starting from makefile.unix.

	Look over the Makefile and adjust options as needed. In particular, you'll
	need to change the CC= and CFLAGS= definitions if you don't have gcc
	(makefile.unix only). If you have a function-prototype-less compiler, be sure
	to uncomment the .c.o rule and say "make ansi2knr". This will cause the
	source files to be preprocessed to change our ANSI-style function definitions
	to old-style definitions. (Thanks to Peter Deutsch of Aladdin Enterprises for
	ansi2knr.)

	Also look over jconfig.h and adjust #defines as necessary. If you have an
	ANSI-compliant C compiler (gcc for instance), no changes should be necessary
	except perhaps for RIGHT_SHIFT_IS_UNSIGNED and TWO_FILE_COMMANDLINE. For
	older compilers other mods may be needed, depending on what ANSI features are
	supported. If you prefer, you can usually leave jconfig.h unmodified and add
	-D switches to the Makefile's CFLAGS= definition.

	Then say "make".

	If you have trouble with missing system include files or inclusion of the
	wrong ones, you can fix it in jinclude.h. In particular, if you are using
	gcc on a machine with non-ANSI system include files, you are likely to find
	that jinclude.h tries to include the wrong files (because gcc defines
	__STDC__). There's no good automatic solution to this, so you'll just have
	to hand-edit jinclude.h.

	As a quick test of functionality we've included three sample files:
	testorig.jpg same as blkint.jpg from JPEG validation floppy.
	testimg.ppm output of djpeg testorig.jpg
	testimg.jpg output of cjpeg testimg.ppm
	The two .jpg files aren't identical due to different parameter choices (and
	wouldn't be anyway, since JPEG is lossy). However, if you can generate
	duplicates of testimg.ppm and testimg.jpg then you probably have a working
	port. "make test" will perform the necessary comparisons (by generating
	testout.ppm and testout.jpg and comparing these to testimg.*). NOTE: this
	is far from an exhaustive test of the JPEG software; some modules, such as
	color quantization and GIF I/O, are not exercised at all. It's just a quick
	test to give you some confidence that you haven't missed something major.

	If you need to make a smaller version of the JPEG software, some optional
	functions can be removed at compile time. See the xxx_SUPPORTED #defines
	in jconfig.h. (Not a lot is actually removed right now, but as more optional
	stuff gets added, this mechanism will start to make a difference.)

	If you want to incorporate the JPEG code as subroutines in a larger program,
	we recommend that you make libjpeg.a. Then use the .h files and libjpeg.a as
	your interface to the JPEG functions. Your surrounding program will have to
	provide functionality similar to what's in jcmain.c or jdmain.c, and you may
	want to replace jerror.c and possibly other modules depending on your needs.
	See the "architecture" file for more info. If it seems to you that the system
	structure doesn't accommodate what you want to do, please contact the authors.

	Special notes for Macintosh Think C users: If you have version 5.0 you should
	be able to just turn on __STDC__ through the compiler switch that enables
	that. With version 4.0 you must manually edit jconfig.h to define PROTO,
	HAVE_UNSIGNED_CHAR, HAVE_UNSIGNED_SHORT, and const. (It seems to be safe to
	just define __STDC__ to take care of the first three.) When setting up
	project files, use the COBJECTS and DOBJECTS lists in makefile.unix as a guide
	to which files need to be included, and add the ANSI and Unix C libraries in a
	separate segment. You may need to divide the JPEG files into more than one
	segment; you can do this pretty much as you please.


	USAGE
	=====

	The user interface is pretty minimal at this point. We haven't bothered to
	generate manual-page files since the switches badly need redesign. At the
	moment, things work like this:

	There are two programs, cjpeg to compress an image file into JPEG format,
	and djpeg to decompress.

	On Unix systems, you say:
	cjpeg [switches] [imagefile] >jpegfile
	djpeg [switches] [jpegfile] >imagefile
	The programs read the specified input file, or standard input if none is
	named. They always write to standard output (with trace/error messages to
	standard error). These conventions are handy for piping images between
	programs.

	On PC, Macintosh, and Amiga systems, you say:
	cjpeg [switches] imagefile jpegfile
	djpeg [switches] jpegfile imagefile
	i.e., both input and output files are named on the command line. This style
	is a little more foolproof, and it loses no functionality if you don't have
	pipes. You can get this style on Unix too, if you prefer, by defining
	TWO_FILE_COMMANDLINE in jconfig.h or in the Makefile. You MUST use this style
	on any system that doesn't cope well with binary data fed through
	stdin/stdout.

	Currently supported image file formats include raw-format PPM, raw-format PGM
	(for monochrome images), and GIF. cjpeg recognizes the input image format
	automatically, but you have to tell djpeg which format to generate.

	The only JPEG file format currently supported is a raw JPEG data stream.
	Unless modified, the programs use the JFIF conventions for variables left
	unspecified by the JPEG standard. (In particular, cjpeg generates a JFIF APP0
	marker.) Support for the JPEG-in-TIFF format will probably be added at some
	future date.

	The command line switches for cjpeg are:

	-I Generate noninterleaved JPEG file (not yet supported).

	-Q quality Scale quantization tables to adjust quality.
	Quality is 0 (worst) to 100 (best); default is 75.
	(See below for more info.)

	-a Use arithmetic coding rather than Huffman coding.
	(Not currently supported, see LEGAL ISSUES.)

	-o Perform optimization of entropy encoding parameters.
	Without this, default Huffman or arithmetic
	parameters are used. -o makes the JPEG file a tad
	smaller, but compression uses much more memory.
	Image quality is unaffected by -o.

	-d Enable debug printout. More -d's give more printout.

	Typically you'd use -Q settings of 50 or 75 or so. -Q 100 will generate a
	quantization table of all 1's, meaning no quantization loss; then any
	differences between input and output images are due to subsampling or to
	roundoff error in the DCT or colorspace-conversion steps. -Q values below 50
	may be useful for making real small, low-quality images. Try -Q 2 (or so) for
	some amusing Cubist effects. (Note that -Q values below about 25 generate
	2-byte quantization tables, which are not decodable by pure baseline JPEG
	decoders. cjpeg emits a warning message when you give such a -Q value.)

	The command line switches for djpeg are:

	-G Select GIF output format (implies -q, with default
	of 256 colors).

	-b Perform cross-block smoothing. This is quite
	memory-intensive and only seems to improve the image
	at very low quality settings (-Q 10 to 20 or so).

	-g Force gray-scale output even if input is color.

	-q N Quantize to N colors.

	-D Use Floyd-Steinberg dithering in color quantization.

	-2 Use two-pass color quantization (not yet supported).

	-d Enable debug printout. More -d's give more printout.

	Color quantization currently uses a rather shoddy algorithm (although it's not
	so horrible when dithered). Because of this, the GIF output mode is not
	recommended in the current release, except for gray-scale output. You can get
	better results by applying ppmquant to the unquantized (PPM) output of djpeg,
	then converting to GIF with ppmtogif. We expect to provide a considerably
	better quantization algorithm in a future release.

	Note that djpeg can read noninterleaved JPEG files even though cjpeg can't
	yet generate them. For most applications this is a nonissue, since hardly
	anybody seems to be using noninterleaved format.

	On a non-virtual-memory machine, you may run out of memory if you use -I or -o
	in cjpeg, or -q ... -2 in djpeg, or try to read an interlaced GIF file. This
	will be addressed eventually by replacing jvirtmem.c with something that uses
	temporary files for large images (see TO DO).


	REFERENCES
	==========

	The best and most readily available introduction to the JPEG compression
	algorithm is Wallace's article in the April '91 CACM:
	Wallace, Gregory K. "The JPEG Still Picture Compression Standard",
	Communications of the ACM, April 1991 (vol. 34 no. 4), pp. 30-44.
	(Adjacent articles in that issue discuss MPEG motion picture compression,
	applications of JPEG, and related topics.) We highly recommend reading that
	article before looking at any of the JPEG software.

	For more detail about the JPEG standard you pretty much have to go to the
	draft standard, which is not nearly as intelligible as Wallace's article.
	The current version is ISO/IEC Committee Draft CD 10918-1 dated 1991-03-15.
	The standard is not presently available electronically; you must order a paper
	copy through ISO.

	The JPEG standard does not specify all details of an interchangeable file
	format. For the omitted details we follow the "JFIF" conventions, revision
	1.01. A copy of the JFIF spec is available from:
	Literature Department
	C-Cube Microsystems, Inc.
	399A West Trimble Road
	San Jose, CA 95131
	(408) 944-6300
	Requests can also be e-mailed to info@c3.pla.ca.us (this address good after
	10/10/91). The same source can supply copies of the draft JPEG-in-TIFF specs.

	If you want to understand this implementation, start by reading the
	"architecture" documentation file. Please read "codingrules" if you want to
	contribute any code.


	SUPPORTING SOFTWARE
	===================

	You will probably want Jef Poskanzer's PBMPLUS image software; this provides
	many useful operations on PPM-format image files. In particular, it can
	convert PPM images to and from a wide range of other formats. You can FTP
	this free software from export.lcs.mit.edu (contrib/pbmplus*.tar.Z) or
	ftp.ee.lbl.gov (pbmplus*.tar.Z).

	If you are using X Windows you might want to use the xv or xloadimage viewers
	to save yourself the trouble of converting PPM to some other format.
	Both of these can be found in the contrib directory at export.lcs.mit.edu.


	LEGAL ISSUES
	============

	The authors make NO WARRANTY or representation, either express or implied,
	with respect to this software, its quality, accuracy, merchantability, or
	fitness for a particular purpose. This software is provided "AS IS", and you,
	its user, assume the entire risk as to its quality and accuracy.

	This software is copyright (C) 1991, Thomas G. Lane.
	All Rights Reserved except as specified below.

	Permission is hereby granted to use, copy, modify, and distribute this
	software (or portions thereof) for any purpose, without fee, subject to these
	conditions:
	(1) If any part of the source code for this software is distributed, then this
	README file must be included, with this copyright and no-warranty notice
	unaltered; and any additions, deletions, or changes to the original files
	must be clearly indicated in accompanying documentation.
	(2) If only executable code is distributed, then the accompanying
	documentation must state that "this software is based in part on the work of
	the Independent JPEG Group".
	(3) Permission for use of this software is granted only if the user accepts
	full responsibility for any undesirable consequences; the authors accept
	NO LIABILITY for damages of any kind.

	Permission is NOT granted for the use of any author's name or author's company
	name in advertising or publicity relating to this software or products derived
	from it. This software may be referred to only as "the Independent JPEG
	Group's software".

	We specifically permit and encourage the use of this software as the basis of
	commercial products, provided that all warranty or liability claims are
	assumed by the product vendor.


	ansi2knr.c is included in this distribution by permission of L. Peter Deutsch,
	sole proprietor of its copyright holder, Aladdin Enterprises of Menlo Park, CA.
	ansi2knr.c is NOT covered by the above copyright and conditions, but instead
	by the usual distribution terms of the Free Software Foundation; principally,
	that you must include source code if you redistribute it. (See the file
	ansi2knr.c for full details.) However, since ansi2knr.c is not needed as part
	of any product generated from the JPEG code, this does not limit you more than
	the foregoing paragraphs do.


	It appears that the arithmetic coding option of the JPEG spec is covered by
	patents held by IBM, and possibly also patents of AT&T and Mitsubishi. Hence
	arithmetic coding cannot legally be used without obtaining one or more
	licenses. For this reason, support for arithmetic coding has been removed
	from the free JPEG software. (Since arithmetic coding provides only a
	marginal gain over the unpatented Huffman mode, it is unlikely that very many
	people will choose to use it. If you do obtain such a license, contact
	jpeg-info@uunet.uu.net for a copy of our arithmetic coding modules.) So far
	as we are aware, there are no patent restrictions on the remaining code.


	TO DO
	=====

	Many of the modules need fleshing out to provide more complete
	implementations, or to provide faster paths for common cases. The greatest
	needs are for (a) decent color quantization, and (b) a memory manager
	implementation that can work in limited memory by swapping "big" images to
	temporary files. I (Tom Lane) am going to work on color quantization next.
	Volunteers to write a PC memory manager, or to work on any other modules, are
	welcome.

	We'd appreciate it if people would compile and check out the code on as wide a
	variety of systems as possible, and report any portability problems
	encountered (with solutions, if possible). Checks of file compatibility with
	other JPEG implementations would also be of interest. Finally, we would
	appreciate code profiles showing where the most time is spent, especially on
	unusual systems.

	Please send bug reports, offers of help, etc. to jpeg-info@uunet.uu.net.