Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a Fortran 77 application that uses Common declarations to "share" memory variables. Back in the day, when memory was expensive and hard to come by this was the way around it.

The equipment being controlled sets status flags. These flags reside in these Common variables.

Any suggestions on how to implement the Common functionality in c++?

A class perhaps, with all the common variables being public. Thus any program instantiating that class will have access to the contents of the Common variables.

Are there any tutorials/guidelines for converting Fortran to C or C++?

Thanks

share|improve this question
3  
25 years ago the standard answer on comp.lang.c to the question of how to convert Fortran to C was "rm -rf *.f will convert all your fortran programs to free disk blocks, which you can then use to re-write your programs correctly" –  Paul Tomblin Nov 30 '10 at 0:12
1  
wrt "The equipment being controlled sets status flags. These flags reside in these Common variables.", do you just need globals, or do you need your C++ code to interop with actual factual fortran style common blocks? The latter is possible depending on your compiler/linker. –  Logan Capaldo Nov 30 '10 at 0:38
    
Common varaibles dont really save much memory! As you talk about "equipment controlled" I would guess these variables are common as the device driver needs to map its control flags to a fixed memory area. C externs are functionally equivalent, BUT, be careful as the the linker maps the memory based on the actual field names so if you are mixing C and Legacy Fortran modules you need to ensure you define the same names in the same order! –  James Anderson Nov 30 '10 at 1:26

6 Answers 6

This Fortran to C/C++ Tutorial suggests:

      FORTRAN:
           DOUBLE PRECISION X
           INTEGER A, B, C
           COMMON/ABC/ X, A, B, C

      C:
           extern struct{
               double x;
               int a, b, c;
           } abc_;

      C++:
         extern "C" {
           extern struct{
               double x;
               int a, b, c;
           } abc_;
         }

You put the extern struct into an .h file which the C / C++ files refer to with #include, and in exactly one .c or .cpp file you put exactly what was in the .h file but without the "extern" word.

My assumption is that what you have to start with is relatively terse and borderline incomprehensible, and that you want to translate it into C++ in a way that preserves a near one-to-one correspondence to the original.

share|improve this answer

First of all, you can get rid of common blocks by using Fortran 90 modules.

If you do want to directly convert common blocks to C++ you would have to make a whole bunch of global/static variables or use an unnamed namespace.

However, that violates information hiding and most people would advise you against thoughtless use of global variables.

More generally, you might be interested in looking up the Barton-Nackman book Scientific and Engineering C++: An Introduction with Advanced Techniques and Examples. It's a bit outdated, but that shouldn't matter too much. It teaches you C++ for scientific or engineering applications assuming that you have a Fortran / procedural background.

share|improve this answer
3  
Oddly, back in the day common blocks were used to hide information from some parts of the code, though it had to be global to the modules that included them. –  dmckee Nov 30 '10 at 0:23

Apropos to my comment on Alexandros' answer the "natural" transliteration is to include everything in the common blocks as class statics in the c++ code. The result will not be good c++ code, but it would give a place to start refactoring.

That said, I would usually try to interface a c++ front end to the existing fortran back end first, and then start the translation process if it still seems like a good idea.

share|improve this answer

I know I am reapeating what I said in a comment, but, I dont think anyone got it.

The phrase "equipment being controlled" signals to me that the program is some sort of device driver and its highly likely that the device is expecting a its flags to be in a specific area of memory. The reason common storage is being used is that the various modules can access and update these areas directly. Translating these into a C extern should work but you would really need to get hold of the documentation for the device interface to make sure you are doing it properly.

Losing the common storgage as some posters suggest will simply not work under these circumstances. The best approach if you have the time and confidence would be to have a static class which handles all updates to the common storage and to replace all reads and writes to common storage with "get" s and "set"s to the new class.

share|improve this answer

Don't do it at all, common blocks are an anathema in the modern day.

share|improve this answer
    
You may have missed the point of the question...he has a code that uses common blocks and want to convert it to c++ where that construct doesn't have an obvious equivalent. –  dmckee Dec 1 '10 at 17:33
    
Yes I think you are right. –  David Heffernan Dec 2 '10 at 12:00

Strange as it may seem, this may be a place were c like bitfield should be used.

He has a piece of hardware, which probably has various control registers and status flags, mapped to some fixed memory address.

A struct with correctly laid out bit fields (compiler specific), with a pointer of that type pointing to the correct address may do the trick.

As the field values can change without notice, the violatile qualifer may be needed.

It would help if the questioner would provide more information on the layout of the common block, and the interpretation of the data within it.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.