Section 0 - Why doesn't this FAQ answer my question?
Section 1 - What does cxref do (and what it doesn't)
Q 1.2 Does cxref show which #includes that are not needed?
Q 1.3 Can cxref document automatic function variables?
Q 1.4 Does cxref run on systems other than UNIX?
Section 2 - When cxref does not work
Q 2.1a How do I find out what is causing the parse error?
Q 2.1b What does this parse error message mean?
Q 2.2 Where are files doc/cxref.html & FAQ.html referenced from README.html?
Q 2.3 Why are half of the cross references missing?
Q 2.4 Why can't cxref process my header file in isolation?
Q 2.5 Why can't LaTeX process the output files?
Q 2.6 Why does the include file name have the complete path name?
Section 3 - How to make cxref do what you want
Q 3.1 How do I use cxref to process source files in more than one directory?
Q 3.2 How can I add my own information to the output files?
Q 3.3 Can I get a subset of the cross-reference information?
Q 3.4 Is there an easy way to generate the comments in the correct format?
Q 3.5 How do I produce LaTeX output from a single source.c.tex output file?
Q 3.6 How can I pass extra arguments to the C pre-processor?
Q 3.7 Can I cross-reference my source code at the same time as compiling it?
Q 3.8 What use is the .cxref configuration file?
Section 4 - More information about cxref
Q 4.1 Who wrote cxref, When and Why?
Q 4.2 How do I report bugs in cxref?
No. The cxref program only works for C, More specifically: 1) ANSI standard C with some leniency for common non-ANSI syntax. For example, the construct 'switch(foo) { case 1: ... default: }' is not ANSI, there must be a ';' after the default label, but it is accepted by cxref. 2) Traditional (K&R) function declarations, with implicit 'int' and 'void'. For example 'foo(){}' is parsed as if 'int foo(void){}' was specified. 3) The ability to parse GCC extensions. The GCC '__attribute__' and '__extension__' keywords and most of the other GCC extensions. The 'inline' keyword is allowed.
No. The output of the cxref program cross-references all of the functions, variables, type definitions, included file etc. There is not a way of identifying files that are included in another source file that do not need to be.
No. The inclusion of automatic variables in the output is not included. This is because of the number of them in a typical function. In theory it could be made to do this.
For example DOS / Win3 / Win95 / WinNT / OS/2. UNIX = Yes This is the system that the program way designed and initially written for, it should work on many versions of UNIX. I know that it works on Linux, SunOS 4.1.x, Solaris 2.x, AIX & HP-UX 10. DOS/Win3 = No The program was not designed for DOS, the filenames used and the multi-process nature of the program do not allow this. Win95/WinNT = Maybe Since Windows 95 and Windows NT claim to be real 32-bit multi-tasking operating systems, and support the long filenames that are required, it should in theory be possible to get the program working on these. I have reports that it is possible, but I do not support cxref for these OSes. OS/2 = Maybe As for Windows 95 / Windows NT above. I have reports that it is possible with OS/2 Warp with emx, but I do not support cxref for this OS.
The following error message is generated by cxref when parsing a source file (with YYDEBUG set to 0 in parse-yy.h when cxref was compiled). test.c: 4: parse error, expecting `','' or `';'' ^^^^^^ ^^^ ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ file line type of error name number generated by yacc The error is on line 4 of the file test.c. In this case, the error message that the yacc parser is generating is of some help, more often the error message is just 'parse error'. If YYDEBUG was set to 1 in parse-yy.h, then a more detailed error message would be given (see Q 2.1b).
The following error message is generated by cxref when parsing a source file (with YYDEBUG set to 1 in parse-yy.h when cxref was compiled). test.c: 4: parse error, expecting `','' or `';'' The previous 10, current and next 10 symbols are: -8 | 296 : INT : int -7 | 258 : IDENTIFIER : foo -6 | 40 : : ( -5 | 292 : VOID : void -4 | 41 : : ) -3 | 123 : : { -2 | 296 : INT : int -1 | 258 : IDENTIFIER : a 0 | 296 : INT : int 1 | 258 : IDENTIFIER : b 2 | 59 : : ; 3 | 125 : : } END OF FILE ^^^ ^^^^^^^^^^ ^^^^^ symbol symbol symbol number type value From this we can reconstruct part of the file test.c, using the previous and next 10 symbol values from the lexer. int foo(void) { int a int b; } ^ This is where the parse error occured, after 'int a' and before 'int b;'. The cause of the error is now clear, there is a ';' missing after the declaration of the variable a. The cxref program is intended to be used on source files that are known to compile with a C compiler. In this case a parse error message should not be seen except for either non-standard C, (and compiler) or a bug in cxref.
The README.html file has a reference to the files doc/cxref.html and FAQ.html these files are only present when 'make docs' has been run to generate the cross references for the cxref program itself.
The way that cxref works is that it processes all of the source files for a program, one at a time and generates a cross reference database. A second pass of the program is required to generate all of the cross references from the database of cross reference information. For this reason, the Makefile for the doc directory of cxref uses 'cxref *.c -xref -Odoc' for the first pass and 'cxref *.c -xref -Odoc -html -latex' for the second pass. The first to build the database, the second to produce the outputs. The reason that the cross references are missing is that only one pass of the program has been done on all of the files. The later files to be be processed will have cross references for the earlier files processed.
The cxref program needs to process the header files to enable a cross reference for them to be generated. In many cases, the header file will not have been written with this in mind, and may rely on other header files being included before the one being processed. The only solution to this is to modify the header file so that it includes all of the header files that it needs.
There are two options for producing LaTeX output, '-latex' and '-latex2e'. These refer to two different versions of the LaTeX program. The first is for use with LaTeX version 2.0.9, the second for use with LaTeX version 2e. The file cxref.tex (or basename.tex if '-Nbasename' is used) is the file that must be processed by LaTeX.
This is because a standard C preprocessor is being used instead of cxref-cpp. One of the changes to the GNU cccp to make cxref-cpp is to make it output the names of the include files as they are in the original source code and not after the files have been translated into an absolute pathname.
The cxref program depends on a database of cross references, these must all be consistent. This requires that all of the files to be cross referenced are in the same directory tree. Example: directory files - - - - - - - - basedir : f0.c f0.h ... |- s1 : f1.c f1.h ... |- s2 : f2.c f2.h ... ... -- f2.c -- #include <...> #include "f2.h" #include "../s1/f1.h" #include "f0.h" ---------- In the base directory 'basedir' run 'cxref -xref -Odoc s2/f2.c -html -I.'. This will create the file 'doc/s2/f2.c.html' for the file 'f2.c' and this will contain references to the files 'doc/s2/f2.h.html', 'doc/s1/f1.h.html' and 'doc/f0.h.html'. The subdirectories 'doc/s1', 'doc/s2' will be automatically created within the 'doc' directory to put the files into (the 'doc' directory must already exist). directory files - - - - - - - - basedir |- doc : f0.c.html f0.h.html ... cxref.html |- s1 : f1.c.html f1.h.html ... |- s2 : f2.c.html f2.h.html ... ... An alternative method is to use the -R option to cxref. In the directory 's2', cxref can be run as 'cxref -R.. -xref -Odoc f2.c -html -I.'. This will change directory to '..' ('basedir') before cxref is run, and will modify the cxref arguments so that it is equivalent to running cxref from 'basedir' as detailed above.
The files cxref.html and cxref.tex (depending on whether using HTML or LaTeX format and the use of the '-Nbasename' option) are the ones to edit. These files contain the lines 'Begin-Of-Source-Files' and 'End-Of-Source-Files' as comments. The output files for each source file are automatically included between these lines if they do not already exist there. The order of these files and any other text between these lines is not important. Customisation of the files should be added here. The output files for each source file are automatically generated so any edits made to these will be lost when cxref is run.
At the moment, the only one way to limit the amount of cross referencing is to use the '-xref-*' command line option (see README). There are plans for a future version of cxref to have an options file that would allow different amounts of information to be generated in the output. For example, only to display called and not calls information for each function.
The only easy way to do this is to use the cxref.el macro file and Emacs. This is what is used to generate the comments in the cxref source code itself.
The file cxref.tex (or basename.tex if '-Nbasename' is used) is the file that must be processed by LaTeX. All of the individual LaTeX files for the source files are included into this file. If an individual file source.c.tex needs to be processed then a copy of the file cxref.tex should be modified to include only the required source.c.tex file.
The cxref program itself has three ways that you can specify the arguments that are passed to the C pre-processor. a) The -CPP option allows the name of the pre-processor program itself to be changed. e.g. 'cxref -CPP "/usr/foo/cpp -C" foo.c' will use the cpp from /usr/foo instead of the compiled in default and pass it the option -C. b) The most common C pre-processor commands are recognised by cxref automatically, these are -D*, -U* and -I*. c) Any amount of extra options can be passed to the preprocessor by appending them to the command line after the end-of-arguments marker '--'. e.g. 'cxref foo.c -- -traditional' will pass -traditional to the pre-processor. A useful argument that you may want to use is '-- -include filename.h' This will include the specified file into the source file that is being processed at the beginning, and can be used to help when processing header files that do not include all of the required definitons (See Q 2.4).
It is possible to cross-reference and document your source code at the same time as compiling it by using the cxref-cc script. This takes the same arguments as your usual C compiler and performs both functions. First it calls the C compiler and passes on all of the command line arguments. The real C compiler is specified by the CXREFCC environment variable, or the CC environment variable or it will use gcc if neither of these are set. Second the arguments that cxref needs to have are extracted from the arguments that the C compiler had and cxref is called. The arguments that are kept are the -D*, -U*, -I* arguments to specify #defines and #include paths, and the file name of the source file itself. Any other arguments are taken from the .cxref file (See Q 3.8). After doing this it will still be necessary to sort out the header files since these are not cross-referenced using this method.
The most obvious use is if you have a lot of command line options that you don't want to have to enter every time that you run the program. However the .cxref file is most useful when you have a multiple directory source tree (See Q 3.1), or when you are using an existing Makefile to build documentation. When there are various subdirectories containing source code, a .cxref file in each sub-directory can be used just containing the line '-R..' or whatever is appropriate to point cxref to the root of the source tree. This means that there is no need to keep track of which directory you are in, they all will use the correct directory to work from. If you already have a Makefile that goes through all of the source code then you may want to modify it so that it calls cxref instead of calling the C compiler. This means that there is no room to put the extra arguments to cxref on the command line. A .cxref file can contain the command line arguments so that you only need to need the arguments that are already there for the C compiler (See Q 3.7).
The cxref program was written by Andrew M. Bishop (amb@gedanken.demon.co.uk) in 1995,96,97. There is a cxref home-page on the World Wide Web, available via the author's home-page at http://www.gedanken.demon.co.uk/. This is kept updated with news about the program, as new versions become available. An earlier program by the same author using basically the same comment convention was written in Emacs Lisp in 1994. This version was slow, the amount of cross referencing was poor and the output was only in troff format. The current C program was written to replace this but has grown to become much better in the cross referencing that is done and the format of the output has increased greatly. The cxref program can be freely distributed according to the terms of the GNU General Public License (see the file `COPYING').
By e-mail, send them to me at amb@gedanken.demon.co.uk and put cxref somewhere in the subject line. You can also report bugs or provide comments via the feedback form on the cxref home-page on the World Wide Web accessible via http://www.gedanken.demon.co.uk/. Before doing this, you should check the FAQ and the cxref web-page to see if the answer is there. If it is not, and it is a parse error then check that it is a cxref problem and not a syntax error in the source file. When you are sure that it is a cxref bug, give me as much information as you can, about the error, when it happens, what system you are using etc. It is useful if you can provide a small example and the output of using the '-raw' option to provide the actual output that you are seeing. (If it is an HTML or LaTeX specific problem then send that file instead.)