I've got lots of problems with project i am currently working on. The project is more than 10 years old and it was based on one of those commercial C++ frameworks which were very populary in the 90's. The problem is with statecharts. The framework provides quite common implementation of state pattern. Each state is a separate class, with action on entry, action in state etc. There is a switch which sets current state according to received events.
Devil is hidden in details. That project is enormous. It's something about 2000 KLOC. There is definitely too much statecharts (i've seen "for" loops implemented using statecharts). What's more ... framework allows to embed statechart in another statechart so there are many statecherts with seven or even more levels of nesting. Because statecharts run in different threads, and it's possible to send events between statecharts we have lots of synchronization problems (and big mess in interfaces).
I must admit that scale of this problem is overwhelming and I don't know how to touch it. My first idea was to remove as much code as I can from statecharts and put it into separate classes. Then delegate these classes from statechart to do a job. But in result we will have many separate functions, which logically don't have any specific functionality and any change in statechart architecture will need also a change of that classes and functions.
So I asking for help:
Do you know any books/articles/magic artefacts which can help me to fix this ? I would like to at least separate as much code as I can from statechart without introducing any hidden dependencies and keep separated code maintainable, testable and reusable.
If you have any suggestion how to handle this, please let me know.
The statechart pattern is intended to be used specifically to remove switch statements, so this sounds like a horrid abuse. Additionally, states should only change on asynchronous events. If you are processing an event and you change through multiple states (or for loop, etc.), then this is also a horrid abuse of the pattern.
I would start from these two points, as they will solve much of your concurrency issues just fixing them up. What you need to determine is:
What are your external, asynchronous events to the system? These are the only things that should be determining state transitions, not things that happen during event processing. An event may cause 0 or 1 state transitions. Once you have a list of these state transitions, you can reconstruct the actual states of your system. If you are aware of UML State diagrams, this would be a perfect time to sketch one up in a charting program, not just for yourself (though it will help you immensely), but also for everyone in the future that has to return to the project. As you have learned, this happens.
Now that you know what are really states, list what are states in the code that shouldn't be. This usually indicates that something can be "functionally decomposed". Instead of a state object for each of these, likely all that is needed is a separate function. This will cut down on a lot of the overhead of state objects and should clean up the code immensely.
Now it's time to tackle those horrendous switch statements you mentioned. If they were truly based on state, you shouldn't need one at all. Instead, you should be able to call the state machine directly.
Something like:
myStateMachine->myEvent();
and it should work without any switch. But notice, this may be the case even for some of those objects that don't work across asynchronous events. This is also an indication of where you may just use inheritance to get the same effect. If you have:
switch (someTypeIdentifier)
{
case type1:
doSomething();
break;
case type2:
doSomethingElse();
break;
}
usually the correct OOP method to do is to create two actual types Type1, Type2, both derived from an abstract base TypeBase, with a virtual method doSomething() that does what you need. The reason this is useful is because it means you can "close" the handling (in the meaning of the Open/Closed Principle), and still extend the functionality by adding new derived types as needed (leaving it open to extension). This saves bugs like crazy because it gets developers hands out of those switch statements, which can get quite ugly and convoluted, instead encapsulating each separate behavior in separate classes.
4 - Now look to fix up your thread issues. Identify all objects used from multiple threads. Make a list. Now, how are these used? Are some of them always used together? Start making groups. The goal here is to find the level of encapsulation that best works for these objects, separate the objects into individual classes that control their own synchronisation, figure out the atomic level of actual "transactions" for the objects, and make methods of the classes that expose those meaningful transactions, wrapped behind the scenes with the appropriate mutexes, condition variables, etc.
You might be saying "that sounds like a lot of work! Why do all that instead of just writing it all over myself?" Good question! :) The reason is actually straightforward: if you are going to do it all by yourself, those are the steps you should be doing anyway. You should be identifying your states, your dynamic polymorphism, and getting a handle on the multithreaded transactions. But, if you start with the existing code, you also have all of those unspoken business rules that were never documented and may cause all sorts of unexpected bugs down the line. You don't have to bring everything over - if you suspect it's a bug, discuss the logic with the people who have worked with the system in the past (if available), QA, or whoever might identify bugs, and see if it really should be carried over. But you need to actually evaluate what the bugs are either way, or you may not code something that actually needed coding.
In the end, this is a manual process that is a part of software engineering. There are CASE tools that can help draw up the state diagrams and even publish them to code, there are refactoring tools, like those found in many IDEs, that can help move code between functions and classes, and similar tools which can help identify threading needs. However, those things shouldn't be picked up for a single project. They need to be learned throughout your career, picking them up and learning them more deeply over years of work, as they are a part of being a software engineer. They don't do it for you. You still need to know the whys and hows, and they just help get it done more efficiently.
Statecharts (including nested Statecharts) are a powerful way to specify, understand and even simulate/validate complex control flow. But to gain the benefit, you need the statechart model in a suitable tool (I used Statemate way back in the day, not sure if it's still available), plus a reliable mapping from the chart to the code (Statemate used to generate the code) - then you can forget about the state management code (mostly)! In your situation, if you don't have the model, I would try to reverse one from the code - as Ira says, chances are high that the original developers had a model in some form, and you may find the code making a lot of sense as the model emerges. If this works out, you will have a really good spec/model of the code which should make future code edits much easier (even if you don't want to go to automatic code generation, and maintain the code/model mapping manually (but you'll need to be meticulous!!))
Sounds to me like your best bet is (gulp!) likely to start from scratch if it's as horrifically broken as you make out. Is there any documentation? Could you begin to build some saner software based on the docs?
If a complete re-write isn't an option (and they never are in my experience) I'd try some of the following:
If you don't already have it, draw an architectural picture of the whole system. Sketch out how all the bits are supposed to work together and that will help you break the system down into potentially manageable / testable parts.
Do you have any kind of requirements or testing plan in place? If not, can you write one and start to put unit tests in place for the various chunks of code / functionality which exist already? If you can do that, you can start to refactor things without breaking as much of whatever does currently work.
Once you've broken things down a bit, start building your unit tests into integration tests which pull together more of the functionality.
I've not read them myself, but I've heard good things about these books which may have some advice you can use:
Refactoring: Improving the Design of Existing Code (Object Technology Series).
Working Effectively with Legacy Code (Robert C. Martin)
Good luck! :-)
So we have this huge (is 11000 lines huge?) mainmodule.cpp source file in our project and every time I have to touch it I cringe.
As this file is so central and large, it keeps accumulating more and more code and I can't think of a good way to make it actually start to shrink.
The file is used and actively changed in several (> 10) maintenance versions of our product and so it is really hard to refactor it. If I were to "simply" split it up, say for a start, into 3 files, then merging back changes from maintenance versions will become a nightmare. And also if you split up a file with such a long and rich history, tracking and checking old changes in the SCC history suddenly becomes a lot harder.
The file basically contains the "main class" (main internal work dispatching and coordination) of our program, so every time a feature is added, it also affects this file and every time it grows. :-(
What would you do in this situation? Any ideas on how to move new features to a separate source file without messing up the SCC workflow?
(Note on the tools: We use C++ with Visual Studio; We use AccuRev as SCC but I think the type of SCC doesn't really matter here; We use Araxis Merge to do actual comparison and merging of files)
Merging will not be such a big nightmare as it will be when you'll get 30000 LOC file in the future. So:
Stop adding more code to that file.
Split it.
If you can't just stop coding during refactoring process, you could leave this big file as is for a while at least without adding more code to it: since it contains one "main class" you could inherit from it and keep inherited class(es) with overloaded functions in several new small and well designed files.
Find some code in the file which is relatively stable (not changing fast, and doesn't vary much between branches) and could stand as an independent unit. Move this into its own file, and for that matter into its own class, in all branches. Because it's stable, this won't cause (many) "awkward" merges that have to be applied to a different file from the one they were originally made on, when you merge the change from one branch to another. Repeat.
Find some code in the file which basically only applies to a small number of branches, and could stand alone. Doesn't matter whether it's changing fast or not, because of the small number of branches. Move this into its own classes and files. Repeat.
So, we've got rid of the code that's the same everywhere, and the code that's specific to certain branches.
This leaves you with a nucleus of badly-managed code - it's needed everywhere, but it's different in every branch (and/or it changes constantly so that some branches are running behind others), and yet it's in a single file that you're unsuccessfully trying to merge between branches. Stop doing that. Branch the file permanently, perhaps by renaming it in each branch. It's not "main" any more, it's "main for configuration X". OK, so you lose the ability to apply the same change to multiple branches by merging, but this is in any case the core of code where merging doesn't work very well. If you're having to manually manage the merges anyway to deal with conflicts, then it's no loss to manually apply them independently on each branch.
I think you're wrong to say that the kind of SCC doesn't matter, because for example git's merging abilities are probably better than the merge tool you're using. So the core problem, "merging is difficult" occurs at different times for different SCCs. However, you're unlikely to be able to change SCCs, so the issue is probably irrelevant.
It sounds to me like you're facing a number of code smells here. First of all the main class appears to violate the open/closed principle. It also sounds like it is handling too many responsibilities. Due to this I would assume the code to be more brittle than it needs to be.
While I can understand your concerns regarding traceability following a refactoring, I would expect that this class is rather hard to maintain and enhance and that any changes you do make are likely to cause side effects. I would assume that the cost of these outweighs the cost of refactoring the class.
In any case, since the code smells will only get worse with time, at least at some point the cost of these will outweigh the cost of refactoring. From your description I would assume that you're past the tipping point.
Refactoring this should be done in small steps. If possible add automated tests to verify current behavior before refactoring anything. Then pick out small areas of isolated functionality and extract these as types in order to delegate the responsibility.
In any case, it sounds like a major project, so good luck :)
The only solution I have ever imagined to such problems follows. The actual gain by the described method is progressiveness of the evolutions. No revolutions here, otherwise you'll be in trouble very fast.
Insert a new cpp class above the original main class. For now, it would basically redirect all calls to the current main class, but aim at making the API of this new class as clear and succinct as possible.
Once this has been done, you get the possibility to add new functionalities in new classes.
As for existing functionalities, you have to progressively move them in new classes as they become stable enough. You will lose SCC help for this piece of code, but there is not much that can be done about that. Just pick the right timing.
I know this is not perfect, though I hope it can help, and the process must be adapted to your needs!
Additional information
Note that Git is an SCC that can follow pieces of code from one file to another. I have heard good things about it, so it could help while you are progressively moving your work.
Git is constructed around the notion of blobs which, if I understand correctly, represent pieces of code files. Move these pieces around in different files and Git will find them, even if you modify them. Apart from the video from Linus Torvalds mentioned in comments below, I have not been able to find something clear about this.
Confucius say: "first step to getting out of hole is to stop digging hole."
Let me guess: Ten clients with divergent feature sets and a sales manager that promotes "customization"? I've worked on products like that before. We had essentially the same problem.
You recognize that having an enormous file is trouble, but even more trouble is ten versions that you have to keep "current". That's multiple maintenance. SCC can make that easier, but it can't make it right.
Before you try to break the file into parts, you need to bring the ten branches back in sync with each other so that you can see and shape all the code at once. You can do this one branch at a time, testing both branches against the same main code file. To enforce the custom behavior, you can use #ifdef and friends, but it's better as much as possible to use ordinary if/else against defined constants. This way, your compiler will verify all types and most probably eliminate "dead" object code anyway. (You may want to turn off the warning about dead code, though.)
Once there's only one version of that file shared implicitly by all branches, then it's rather easier to begin traditional refactoring methods.
The #ifdefs are primarily better for sections where the affected code only makes sense in the context of other per-branch customizations. One may argue that these also present an opportunity for the same branch-merging scheme, but don't go hog-wild. One colossal project at a time, please.
In the short run, the file will appear to grow. This is OK. What you're doing is bringing things together that need to be together. Afterwards, you'll begin to see areas that are clearly the same regardless of version; these can be left alone or refactored at will. Other areas will clearly differ depending on the version. You have a number of options in this case. One method is to delegate the differences to per-version strategy objects. Another is to derive client versions from a common abstract class. But none of these transformations are possible as long as you have ten "tips" of development in different branches.
I don't know if this solves your problem, but what I guess you want to do is migrate the content of the file to smaller files independent of each other (summed up).
What I also get is that you have about 10 different versions of the software floating around and you need to support them all without messing things up.
First of all there is just no way that this is easy and will solve itself in a few minutes of brainstorming. The functions linked in your file are all vital to your application, and simply cutting them of and migrating them to other files won't save your problem.
I think you only have these options:
Don't migrate and stay with what you have. Possibly quit your job and start working on serious software with good design in addition. Extreme programming is not always the best solution if you are working on a long time project with enough funds to survive a crash or two.
Work out a layout of how you would love your file to look once it's split up. Create the necessary files and integrate them in your application. Rename the functions or overload them to take an additional parameter (maybe just a simple boolean?).
Once you have to work on your code, migrate the functions you need to work on to the new file and map the function calls of the old functions to the new functions.
You should still have your main-file this way, and still be able to see the changes that were made to it, once it comes to a specific function you know exactly when it was outsourced and so on.
Try to convince your co-workers with some good cake that workflow is overrated and that you need to rewrite some parts of the application in order to do serious business.
Exactly this problem is handled in one of the chapters of the book "Working Effectively with Legacy Code" (http://www.amazon.com/Working-Effectively-Legacy-Michael-Feathers/dp/0131177052).
I think you would be best off creating a set of command classes that map to the API points of the mainmodule.cpp.
Once they are in place, you will need to refactor the existing code base to access these API points via the command classes, once that's done, you are free to refactor each command's implementation into a new class structure.
Of course, with a single class of 11 KLOC the code in there is probably highly coupled and brittle, but creating individual command classes will help much more than any other proxy/facade strategy.
I don't envy the task, but as time goes on this problem will only get worse if it's not tackled.
Update
I'd suggest that the Command pattern is preferable to a Facade.
Maintaining/organizing a lot of different Command classes over a (relatively) monolithic Facade is preferable. Mapping a single Facade onto a 11 KLOC file will probably need to be broken up into a few different groups itself.
Why bother trying to figure out these facade groups? With the Command pattern you will be able to group and organise these small classes organically, so you have a lot more flexibility.
Of course, both options are better than the single 11 KLOC and growing, file.
One important advice: Do not mix refactoring and bugfixes. What you want is a Version of your program that is identical to the previous version, except that the source code is differently.
One way could be to start splitting up the least big function/part into it's own file and then either include with a header (thus turning main.cpp into a list of #includes, which sounds a code smell in itself *I'm not a C++ Guru though), but at least it's now split into files).
You could then try to switch all maintenance releases over to the "new" main.cpp or whatever your structure is. Again: No other changes or Bugfixes because tracking those is confusing as hell.
Another thing: As much as you may desire making one big pass at refactoring the whole thing in one go, you might bite off more than you can chew. Maybe just pick one or two "parts", get them into all the releases, then add some more value for your customer (after all, Refactoring does not add direct value so it is a cost that has to be justified) and then pick another one or two parts.
Obviously that requires some discipline in the team to actually use the split files and not just add new stuff to the main.cpp all the time, but again, trying to do one massive refactor may not be the best course of action.
Rofl, this reminds me of my old job. It seems that, before I joined, everything was inside one huge file (also C++). Then they've split it up (at completely random points using includes) into about three (still huge files). The quality of this software was, as you might expect, horrible. The project totaled at about 40k LOC. (containing almost no comments but LOTS of duplicate code)
In the end I did a complete rewrite of the project. I started by redoing the worst part of the project from scratch. Of course I had in mind a possible (small) interface between this new part and the rest. Then I did insert this part into the old project. I didn't refactor the old code to create the interface necessary, but just replaced it. Then I took made small steps from there, rewriting the old code.
I have to say that this took about half a year and there was no development of the old code base beside bugfixes during that time.
edit:
The size stayed at about 40k LOC but the new application contained many more features and presumably less bugs in its initial version than the 8 year old software. One reason of the rewrite was also that we needed the new features and introducing them inside the old code was nearly impossible.
The software was for an embedded system, a label printer.
Another point that I should add is that in theory the project was C++. But it wasn't OO at all, it could have been C. The new version was object oriented.
OK so for the most part rewriting API of production code is a bad idea as a start. Two things need to happen.
One, you need to actually have your team decide to do a code freeze on current production version of this file.
Two, you need to take this production version and create a branch that manages the builds using preprocessing directives to split up the big file. Splitting the compilation using JUST preprocessor directives (#ifdefs, #includes, #endifs) is easier than recoding the API. It's definitely easier for your SLAs and ongoing support.
Here you could simply cut out functions that relate to a particular subsystem within the class and put them in a file say mainloop_foostuff.cpp and include it in mainloop.cpp at the right location.
OR
A more time consuming but robust way would be to devise an internal dependencies structure with double-indirection in how things get included. This will allow you to split things up and still take care of co-dependencies. Note that this approach requires positional coding and therefore should be coupled with appropriate comments.
This approach would include components that get used based on which variant you are compiling.
The basic structure is that your mainclass.cpp will include a new file called MainClassComponents.cpp after a block of statements like the following:
#if VARIANT == 1
# define Uses_Component_1
# define Uses_Component_2
#elif VARIANT == 2
# define Uses_Component_1
# define Uses_Component_3
# define Uses_Component_6
...
#endif
#include "MainClassComponents.cpp"
The primary structure of the MainClassComponents.cpp file would be there to work out dependencies within the sub components like this:
#ifndef _MainClassComponents_cpp
#define _MainClassComponents_cpp
/* dependencies declarations */
#if defined(Activate_Component_1)
#define _REQUIRES_COMPONENT_1
#define _REQUIRES_COMPONENT_3 /* you also need component 3 for component 1 */
#endif
#if defined(Activate_Component_2)
#define _REQUIRES_COMPONENT_2
#define _REQUIRES_COMPONENT_15 /* you also need component 15 for this component */
#endif
/* later on in the header */
#ifdef _REQUIRES_COMPONENT_1
#include "component_1.cpp"
#endif
#ifdef _REQUIRES_COMPONENT_2
#include "component_2.cpp"
#endif
#ifdef _REQUIRES_COMPONENT_3
#include "component_3.cpp"
#endif
#endif /* _MainClassComponents_h */
And now for each component you create a component_xx.cpp file.
Of course i am using numbers but you should use something more logical based on your code.
Using preprocessor allows you to split things up without having to worry about API changes which is a nightmare in production.
Once you have production settled you can then actually work on redesign.
Well I understand your pain :) I've been in a few such projects as well and it's not pretty. There is no easy answer for this.
One approach that may work for you is to start adding safe guards in all functions, that is, checking arguments, pre/post-conditions in methods, then eventually adding unit tests all in order to capture the current functionality of the sources. Once you have this you are better equipped to re-factor the code because you will have asserts and errors popping up alerting you if you have forgotten something.
Sometimes though there are times when refactoring just may bring more pain than benefit. Then it may be better to just leave the original project and in a pseudo maintenance state and start from scratch and then incrementally adding the functionality from the beast.
You should not be concerned with reducing the file-size, but rather with reducing the class-size. It comes down to almost the same, but makes you look at the problem from a different angle (as #Brian Rasmussen suggests, your class seems to have to many responsibilities).
What you have is a classic example a known design antipattern called the blob. Take some time to read the article I point here, and maybe you may find something useful. Besides, if this project is as big as it looks, you should consider some design to prevent growing into code that you can't control.
This isn't an answer to the big problem, but a theoretical solution to a specific piece of it:
Figure out where you want to split the big file into subfiles. Put comments in some special format at each of those points.
Write a fairly trivial script that will break the file apart into subfiles at those points. (Perhaps the special comments have embedded filenames that the script can use as instructions for how to split it.) It should preserve the comments as part of the splitting.
Run the script. Delete the original file.
When you need to merge from a branch, first recreate the big file by concatenating the pieces back together, do the merge, and then re-split it.
Also, if you want to preserve the SCC file history, I expect the best way to do that is to tell your source control system that the individual piece files are copies of the original. Then it will preserve the history of the sections that were kept in that file, although of course it will also record that large parts were "deleted".
One way to split it without too much danger would be to take a historic look at all the line changes. Are there certain functions that are more stable than others? Hot spots of change if you will.
If a line hasn't been changed in a few years you can probably move it to another file without too much worry. I'd take a look at the source annotated with the last revision that touched a given line and see if there are any functions you could pull out.
Wow, sounds great. I think explaining to your boss, that you need a lot of time to refactor the beast is worth a try. If he doesn't agree, quitting is an option.
Anyway, what I suggest is basically throwing out all the implementation and regrouping it into new modules, let's call those "global services". The "main module" would only forward to those services and ANY new code you write will use them instead of the "main module". This should be feasible in a reasonable amount of time (because it's mostly copy and paste), you don't break existing code and you can do it one maintenance version at a time. And if you still have any time left, you can spend it refactoring all old depending modules to also use the global services.
Do not ever touch this file and the code again!
Treat is like something you are stuck with. Start writing adapters for the functionality encoded there.
Write new code in different units and talk only to adapters which encapsulate the functionality of the monster.
... if only one of the above is not possible, quit the job and get you a new one.
My sympathies - in my previous job I encountered a similar situation with a file that was several times larger than the one you have to deal with. Solution was:
Write code to exhaustively test the function in the program in question. Sounds like you won't already have this in hand...
Identify some code that can be abstracted out into a helper/utilities class. Need not be big, just something that is not truly part of your 'main' class.
Refactor the code identified in 2. into a separate class.
Rerun your tests to ensure nothing got broken.
When you have time, goto 2. and repeat as required to make the code manageable.
The classes you build in step 3. iterations will likely grow to absorb more code that is appropriate to their newly-clear function.
I could also add:
0: buy Michael Feathers' book on working with legacy code
Unfortunately this type of work is all too common, but my experience is that there is great value in being able to make working but horrid code incrementally less horrid while keeping it working.
Consider ways to rewrite the entire application in a more sensible way. Maybe rewrite a small section of it as a prototype to see if your idea is feasible.
If you've identified a workable solution, refactor the application accordingly.
If all attempts to produce a more rational architecture fail, then at least you know the solution is probably in redefining the program's functionality.
My 0.05 eurocents:
Re-design the whole mess, split it into subsystems taking into account the technical and business requirements (=many parallel maintenance tracks with potentially different codebase for each, there is obviously a need for high modifiability, etc.).
When splitting into subsystems, analyze the places which have most changed and separate those from the unchanging parts. This should show you the trouble-spots. Separate the most changing parts to their own modules (e.g. dll) in such a way that the module API can be kept intact and you don't need to break BC all the time. This way you can deploy different versions of the module for different maintenance branches, if needed, while having the core unchanged.
The redesign will likely need to be a separate project, trying to do it to a moving target will not work.
As for the source code history, my opinion: forget it for the new code. But keep the history somewhere so you can check it, if needed. I bet you won't need it that much after the beginning.
You most likely need to get management buy-in for this project. You can argue perhaps with faster development time, less bugs, easier maintaining and less overall chaos. Something along the lines of "Proactively enable the future-proofness and maintenance viability of our critical software assets" :)
This is how I'd start to tackle the problem at least.
Start by adding comments to it. With reference to where functions are called and if you can move things around. This can get things moving. You really need to assess how brittle the code base it. Then move common bits of functionality together. Small changes at a time.
Another book you may find interesting/helpful is Refactoring.
Something I find useful to do (and I'm doing it now although not at the scale you face), is to extract methods as classes (method object refactoring). The methods that differ across your different versions will become different classes which can be injected into a common base to provide the different behaviour you need.
I found this sentence to be the most interesting part of your post:
> The file is used and actively changed in several (> 10) maintenance versions of our product and so it is really hard to refactor it
First, I would recommend that you use a source control system for developing these 10 + maintenance versions that supports branching.
Second, I would create ten branches (one for each of your maintenance versions).
I can feel you cringing already! But either your source control isn't working for your situation because of a lack of features, or it's not being used correctly.
Now to the branch you work on - refactor it as you see fit, safe in the knowledge that you'll not upset the other nine branches of your product.
I would be a bit concerned that you have so much in your main() function.
In any projects I write, I would use main() only perform initialization of core objects - like a simulation or application object - these classes is where the real work should go on.
I would also initialize an application logging object in main for use globally throughout the program.
Finally, in main I also add leak detection code in preprocessor blocks that ensure it's only enabled in DEBUG builds. This is all I would add to main(). Main() should be short!
You say that
> The file basically contains the "main class" (main internal work dispatching and coordination) of our program
It sounds like these two tasks could be split into two separate objects - a co-ordinator and a work dispatcher.
When you split these up, you may mess up your "SCC workflow", but it sounds like adhering stringently to your SCC workflow is causing software maintenance problems. Ditch it, now and don't look back, because as soon as you fix it, you'll begin to sleep easy.
If you're not able to make the decision, fight tooth and nail with your manager for it - your application needs to be refactored - and badly by the sounds of it! Don't take no for an answer!
As you've described it, the main issue is diffing pre-split vs post-split, merging in bug fixes etc.. Tool around it. It won't take that long to hardcode a script in Perl, Ruby, etc. to rip out most of the noise from diffing pre-split against a concatenation of post-split. Do whatever's easiest in terms of handling noise:
remove certain lines pre/during concatenation (e.g. include guards)
remove other stuff from the diff output if necessary
You could even make it so whenever there's a checkin, the concatenation runs and you've got something prepared to diff against the single-file versions.
"The file basically contains the "main class" (main internal work dispatching and coordination) of our program, so every time a feature is added, it also affects this file and every time it grows."
If that big SWITCH (which I think there is) becomes the main maintenance problem, you could refactor it to use dictionary and the Command pattern and remove all switch logic from the existing code to the loader, which populates that map, i.e.:
// declaration
std::map<ID, ICommand*> dispatchTable;
...
// populating using some loader
dispatchTable[id] = concreteCommand;
...
// using
dispatchTable[id]->Execute();
I think the easiest way to track the history of source when splitting a file would be something like this:
Make copies of the original source code, using whatever history-preserving copy commands your SCM system provides. You'll probably need to submit at this point, but there's no need yet to tell your build system about the new files, so that should be ok.
Delete code from these copies. That should not break the history for the lines you keep.
I think what I would do in this situation is bit the bullet and:
Figure out how I wanted to split the file up (based on the current development version)
Put an administrative lock on the file ("Nobody touch mainmodule.cpp after 5pm Friday!!!"
Spend your long weekend applying that change to the >10 maintenance versions (from oldest to newest), up to and including the current version.
Delete mainmodule.cpp from all supported versions of the software. It's a new Age - there is no more mainmodule.cpp.
Convince Management that you shouldn't be supporting more than one maintenance version of the software (at least without a big $$$ support contract). If each of your customers have their own unique version.... yeeeeeshhhh. I'd be adding compiler directives rather than trying to maintain 10+ forks.
Tracking old changes to the file is simply solved by your first check-in comment saying something like "split from mainmodule.cpp". If you need to go back to something recent, most people will remember the change, if it's 2 year from now, the comment will tell them where to look. Of course, how valuable will it be to go back more than 2 years to look at who changed the code and why?
If you've got a codebase which is a bit messy in respect to coding standards - a mix of different conventions from different people - is it reasonable to give one person the task of going through every file and bringing it up to meet standards?
As well as being tremendously dull, you're going to get a mass of changes in SVN (or whatever) which can make comparing versions harder. Is it sensible to set someone on the whole codebase, or is it considered stupid to touch a file only to make it meet standards? Should files be left alone until some 'real' change is needed, and then updated?
Tagged as C++ since I think different languages have different automated tools for this.
Should files be left alone until some 'real' change is needed, and then updated?
This is what I would do.
Even if it's primarily text layout changes, doing it by a manual process on a large scale risks breaking code that was working.
Treat it as a refactor and do it locally whenever code has to be touched for some other reason. Add tests if they're missing to improve your chances of not breaking the code.
If your code is already well covered by tests, you might get away with something global, but I still wouldn't advocate it.
I also think this is pretty much language-agnostic.
It also depends on what kind of changes you are planning to make in order to bring it up to your coding standard. Everyone's definition of coding standard is different.
More specifically:
Can your proposed changes be made to the project with 100% guarantee that the entire project will work identically the same as before? For example, changes that only affect comments, line breaks and whitespaces should be fine.
If you do not have 100% guarantee, then there is a risk that should not be taken unless it can be balanced with a benefit. For example, is there a need to gain a deeper understanding of the current code base in order to continue its development, or fix its bugs? Is the jumble of coding conventions preventing these initiatives? If so, evaluate the costs and benefits and decide whether a makeover is justified.
If you need to understand the current code base, here is a technique: tracing.
Make a copy of the code base. Note that tracing involves adding code, so it should not be performed on the production copy.
In the new copy, insert many fprintf (trace) statements into any functions considered critical. It may be possible to automate this.
Run the project with various inputs and collect those tracing results. This will help everyone understand the current project's design.
Another technique for understanding the current code base is to document the dependencies in the project.
Some kinds of dependencies (interface dependency, C++ include dependency, C++ typedef / identifier dependency) can be extracted by automated tools.
Run-time dependency can only be extracted through tracing, or by profiling tools.
I was thinking it's a task you might give a work-experience kid or put out onto RentaCoder
This depends mainly on the codebase's size.
I've seen three trainees given the task to go through a 2MLoC codebase (several thousand source files) in order to insert one new line into the standard disclaimer at the top of all the source files (with the line's content depending on the file's name and path). It took them several days. One of the three used most of that time to write a script that would do it and later only fixed the files where the script had failed to insert the line correctly, the other two just ploughed through the files. (The one who wrote the script later got a job at that company.)
The job of manually adapting all those files in that codebase to certain coding standards would probably have to be measured in man-years.
OTOH, if it's just a few dozen files, it's certainly doable.
Your codebase is very likely somewhere in between, so your best bet might be to set a "work-experience kid" to find out whether there's a tool that can do this to your satisfaction and, if so, make it work.
Should files be left alone until some 'real' change is needed, and then updated?
I'd strongly advice against this. If you do this, you will have "real" changes intermingled with whatever reformatting took place, making it nigh impossible to see the "real" changes in the diff.
You can address the formatting aspect of coding style fairly easily. There are a number of tools that can auto-format your code. I recommend hooking one of these up to your version control tool's "check in" feature. This way, people can use whatever format they want while editing their code, but when it gets checked in, it's reformatted to the official style.
In general, I think it's best if you can do the big change all at once. In the past, we've done the following:
1. have a time dedicated to the reformatting when most people aren't working (e.g. at night or on the weekend
2. have a person check out as many files as possible at that time, reformat them, and check them in again
With a reformatting-only revision, you don't have to figure out what has changed in addition to the formatting.
Our team uses svn to manage our source. When performing a re-factor on a C file, I occasionally both change functions and move them within the file. Generally I try to avoid moving functions, because it makes the default svn diff get a bit addled about what's going on, and it often provides a diff which is more confusing than it needs to be.
None the less, occasionally I do make both function file-location changes, and function internal code changes. Another place this comes up is in branch merging, when the file is in conflict, and either or both branches have moves as well as intra-function changes.
So, what I am looking for is a semantically aware diff tool that could tell me diffs at two levels - function arrangement, and detail (intra-function). I tried using the "-p" option to diff (-x -p to svn diff), but that's not what it's intended for, it certainly didn't do what I wanted.
Another option I just thought of is using a diff program designed to catch code-copying such as a university might use for checking assignments, but nothing obvious came up in a quick search.
One way to do it with the tools you have is to move the functions first, check them in, then change them. Or have two enlistments, and when you see this happening move them in one, svn up the other, resolve the merge issue. It moves the work to you, but makes code reviews easier.
I make cosmetic changes (moving functions around) and functional changes in different commits, and put "cosmetics" in the commit message. That way, the huge and uninteresting diff for cosmetics work is ignored, and you have a concise diff for the functional changes.
since you increased the level of difficulty of the problem a bit with your last edit:
there are limits of what svn can do, thats the reason why git was written. the answer to your problem is basically "no, there are no tools which can track code on a semantic level with svn"
(actually there are no semantic tracking tools available for git as well, it tracks content)
you could try to do that refactoring with git:
And when using git, the whole 'keep code movement separate from changes' has an even more fundamental reason: git can track code movement (again, whether moving a whole file or just a function between files), and doing a 'git blame -C' will actually follow code movement between files. It does that by similarity analysis, but it does mean that if you both move the code and change it at the same time, git cannot see that 'oh, that function came originally from that other file', and now you get worse annotations about where code actually originated.
so, the idea would be to initialize a git repository and replay all the relevant svn-commits to that repository. after that, use git to find out which content moved to where.
Let’s say that you decide to change the name of Stack Overflow to Frack Overflow.
Now, in your code you already have dozens of objects and variables and selectors with some variation of the name "Stack". You want them to now be replaced with "Frack".
So my question is, would you opt to run your entire codebase through a regular expression filter and change all of these names? Or would you let them be?
I would use the "rename" feature of a good IDE to do it for me.
It depends, really.
In a language like C++, you can get away with this because the compiler will let you know right away if something would break. However, other less-picky languages will allow you to refer to variables which don't exist, and the worst that happens is a slap on the wrist in the form of an exception being thrown for a null reference.
I was working on a flex project once where the codebase was a real mess, and we decided to go through the code and beautify it a bit to meet the Adobe AS3 coding standards. Since I was new to the project, I didn't realize that the variable names in some classes actually referred to persistent objects which hibernate (running the java webapp for the backend server) was using to create mappings. So renaming these variables caused the entire flex frontend to misbehave, even when we did it with the "correct" refactoring tools in our IDE.
But really, I'd say to check your OCD at the door and make your changes a little at a time. Any time you change dozens of files in a large project, you risk destabilizing it, and in this case, the benefit derived from such a risk doesn't pay off.
I'd first ask myself the question why? It is a risk/reward judgement at the end of the day which only you can make.
I would be very reluctant to do it for stylistic reasons, but for class re-factoring it may be legitimate.
Well, not necessarily a disaster, but it certainly can cause some trouble on large code bases. That's why I hate hungarian notation: it makes you change all of your variable names if you happen to change its type.
If there are objects, members and fields in your solution with names that reference a certain customer implementation, I would work hard to re-factor these to use more generic names instead, and I would let Resharper do the re-naming, not some generic text-search-and-replace tool.
Just use a refactoring tool like Resharper by JetBrains or CodeRush and Refactor! by DevExpress. They change all references of a variable in your entire codebase automatically and can do much more.
I believe Refactor! is even included in the VB version of Visual Studio. I use Resharper and I refuse to develop without it.
If I were using a source code version control system (like svn, git, bazar, mercurial etc) I would not be afraid to refactor my code.
Use some kind of "find replace all" or refactoring of some IDE, compile (if it is not a dynamic language) and run your tests (if any).
If something goes horribly wrong, you can always revert your code using the source control system.
Renaming is perhaps the most common refactoring. It is rather encouraged to refactor your code as you go, as this gives you the flexibility of not having to make permanent decisions about names, code placement, etc. as you are first writing your application. If you are not familiar with the idea, I would suggest you start with the Wikipedia page and then dive into Martin Fowler's site.
However, if you need to write your own regex to rename things, then imho you could use some better tools. Don't waste your time reinventing the wheel -- and then fixing whatever your new wheel broke by accident. If you have the option, use an existing tool (IDE or whatever) to do the dirty work.
Even if you have "dozens" of things to rename, I think you're better off finding them one by one manually, and then using an automatic Rename to fix all instances throughout your code.
You need good justification for doing it, I think. When I make changes that have a large number of potential side effects across a large codebase, which happens from time to time, I usually look for a way to make the compiler fail on spots I've missed. And, if possible, I tend to do it in stages so as to minimize the break.
I wouldn't rename just for the sake of renaming, though.