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As discusses in The c++ Programming Language 3rd Edition in section 12.2.5, type fields tend to create code that is less versatile, error-prone, less intuitive, and less maintainable than the equivalent code that uses virtual functions and polymorphism.

As a short example, here is how a type field would be used:

void print(const Shape &s)
  case Shape::TRIANGE:
    cout << "Triangle" << endl;
  case Shape::SQUARE:
    cout << "Square" << endl;
    cout << "None" << endl;

Clearly, this is a nightmare as adding a new type of shape to this and a dozen similar functions would be error-prone and taxing.

Despite these shortcomings and those described in TC++PL, are there any examples where such an implementation (using a type field) is a better solution than utilizing the language features of virtual functions? Or should this practice be black listed as pure evil?

Realistic examples would be preferred over contrived ones, but I'd still be interested in contrived examples. Also, have you ever seen this in production code (even though virtual functions would have been easier)?

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In idiomatic C++, you would pass the shape by reference, not pointer. In fact, you'd most likely use a const reference. – Steven Sudit Sep 27 '10 at 21:58
I have seen this sort of thing done in code that was written by old c programmers. My suspicion is that they weren't aware of the better way, or didn't want to learn it. – JoshD Sep 27 '10 at 22:13
-1: Nobody should ever write that any language feature is 'pure evil' – Jay Sep 27 '10 at 22:27
@Jay: It's not a "language feature", it's a potential application of many language features in concert. There are definitely things you can do in any Turing-complete language which qualify as "pure evil". – Ben Voigt Sep 27 '10 at 22:31
@Jay: Ok, then it's an impure evil. :-) – Steven Sudit Sep 28 '10 at 16:00
up vote 6 down vote accepted

When you "know" you have a very specific, small, constant set of types, it can be easier to hardcode them like this. Of course, constants aren't and variables don't, so at some point you might have to rewrite the whole thing anyway.

This is, more or less, the technique used for discriminated unions in several of Alexandrescu's articles.

For example, if I was implementing a JSON library, I'd know each Value can only be an Object, Array, String, Integer, Boolean, or Null—the spec doesn't allow any others.

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+1: The obvious instance of a small, constant set of types being an external standard that's unlikely to change quickly (e.g., ISO standards take quite a while to change, even at best). – Jerry Coffin Sep 27 '10 at 22:03
Ok, I looked at an article, but I didn't see anything that would convince me to use Pascal-style discriminated unions in C++, as opposed to just leveraging polymorphism through virtual methods. What am I missing? – Steven Sudit Sep 27 '10 at 22:04
I wrote a JSON library where, despite the limited number of objects at the JSON level, it was convenient for me to implement more than one type of Object, which meant subclassing. (One type used a dictionary, the other used reflection on a DTO.) Again, maybe I'm missing something, but the argument for this technique seems underwhelming. – Steven Sudit Sep 27 '10 at 22:06
@Steven: You can, of course, use polymorphism instead. The above would give you tighter control over allocation (e.g. you can save space space with a small-object optimization) and could be faster in some scenarios. If it's not clear above, my Value type acts like any of the other types in a dynamic-language type of way, and a discriminated union allows a Value object to change its own type on the fly. But yes, an Array would still model a vector<Value> and an Object model map<String,Value>. – Roger Pate Sep 27 '10 at 22:10
@Steven: It's been some time since I read those articles (I still have the deadtree magazines somewhere with them ;), so I can't recall if he covers motivation or just assumes that and covers implementation. – Roger Pate Sep 27 '10 at 22:11

A type enum can be serialized via memcpy, a v-table can't. A similar feature is that corruption of a type enum value is easy to handle, corruption of the v-table pointer means instant badness. There's no portable way to even test a v-table pointer for validity, calling dynamic_cast or typeinfo to do RTTI checks on an invalid object is undefined behavior.

For example, one instance where I choose to use a type hierarchy with static dispatch controlled by a discriminator and not dynamic dispatch is when passing a pointer to a structure through a Windows message queue. This gives me some protection against other software that may have allocated broadcast messages from a range I'm using (it's supposed to be reserved for app-local messages, do not pass GO if you think that rule is actually respected).

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If something is randomly corrupting memory, I think you're hosed no matter what. A v-table can be serialized, actually, because you just add another method (or piggy back on RTTI) that returns an enum indicating the type or how the object needs to be deserialized. Or build it into the virtual serialize method. – Roger Pate Sep 27 '10 at 22:53
@Roger: You haven't fully grasped my message-passing example if you are thinking in terms of random corruption. The difference between memcpy and calling a virtual serialize method seems to have eluded you as well. Let me tie both of them together with a single example: an shm file. There's no guarantee that v-tables are stored at the same address in all processes sharing the file, so v-table pointers just won't work. You'd need to serialize and deserialize continually. And if a user accidentally overwrites the file, with v-table pointers you cannot detect and report the problem. – Ben Voigt Sep 27 '10 at 23:49
Uhm, so long as we're within the same process, a memcpy should work fine, since the instance merely contains a pointer to the vtable, not the table itself. The pointer is just as valid after being copied. If you mean full serialization, as to a file, then there are techniques for that as well. – Steven Sudit Sep 28 '10 at 1:19
I get the idea that people are reading the first sentence of my answer then stopping... Yes there are techniques for reconstructing the dynamic type (meaning vfptr) of an object during serialization, but they are very expensive compared to just storing the bits as a block, and way too expensive for use with shared memory. (They also usually subvert the type system as well, creating objects without first calling the constructor.) – Ben Voigt Sep 28 '10 at 1:48
@Steven: You can't memcpy a non-POD type; that's UB. – Roger Pate Sep 28 '10 at 3:38

The following guideline is from Clean Code by Robert C. Martin. "My general rule for switch statements is that they can be tolerated if they appear only once, are used to create polymorphic objects, and are hidden behind an inheritance relationship so that the rest of the system can't see them".

The rationale is this: if you expose type fields to the rest of your code, you'll get multiple instances of the above switch statement. That is a clear violation of DRY. When you add a type, all these switches need to change (or, even worse, they become inconsistent without breaking your build).

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My take is: It depends.

A parameterized Factory Method design pattern relies on this technique.

class Creator {
        virtual Product* Create(ProductId);

Product* Creator::Create (ProductId id) {
        if (id == MINE)  return new MyProduct;
        if (id == YOURS) return new YourProduct;
        // repeat for remaining products...

        return 0;

So, is this bad. I don't think so as we do not have any other alternative at this stage. This is a place where it is absolutely necessary as it involves creation of an object. The type of the object is yet to be known.

The example in OP is however an example which sure needs refactoring. Here we are already dealing with an existing object/type (passed as argument to function).

As Herb Sutter mentions -

"Switch off: Avoid switching on the type of an object to customize behavior. Use templates and virtual functions to let types (not their calling code) decide their behavior."

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This isn't exactly what I meant. In here, you're still creating either a MyProduct or a YourProduct. Two different classes. My question would involve always creating an 'OurProduct' but that product has a type in the class that determines if it's to behave like a MyProduct or a YourProduct. The actuall classes MyProduct and YourProduct wouldn't exist. This is such with the Shape class in my example. There is no triangle class. There is only a Shape with type == TRIANGLE. – JoshD Sep 28 '10 at 2:55
"place where it is absolutely necessary"... not so... objects can register their ids and creation functions, or you can successively invoke registered construct-if-you-can functions (read up on creation patterns in GoF), so the kind of centralised switching shown above isn't necessary. Not saying that it isn't still a simpler and perfectly acceptable solution for more localised code bases. – Tony D Sep 28 '10 at 3:27

Aren't there costs associated to virtual functions and polymorphism? Like maintaining a vtable per class, increase of each class object size by 4 byptes, runtime slowness (I have never measured it though) for resolving the virtual function appropriately. So, for simple situations, using a type field appears acceptable.

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The cost of a pointer to a vtable is countered by the cost of holding a type enum. Likewise, instead of checking for each type in a switch/case, we do a straight jump into a table offset. I don't believe there's much speed to be gained here with the type trick. – Steven Sudit Sep 27 '10 at 22:10
There are costs, yes, but the type field has some similar costs. The type member takes up some space; the switch statement to choose the right code to execute takes some time much as the vtable lookup would. I've also never measured, but I'd be surprised if there was a significant difference in favor of type fields. – JoshD Sep 27 '10 at 22:11
The difference between check against the type enum vs dynamic call generally is insignificant. However, the static check makes static calls which can be inlined with the potential for big savings. – Ben Voigt Sep 27 '10 at 22:27

I think that if the type corresponds precisely to the implied classes then type is wrong. Where it gets complicated is where the type does not quite match or its not so cut and dried.

Taking your example what if type was Red, Green, Blue. Those are types of shapes. You could even have a color class as a mixin; but its probably too much.

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I am thinking of using a type field to solve the problem of vector slicing. That is, I want a vector of hierarchical objects. For example I want my vector to be a vector of shapes, but I want to store circles, rectangles, triangles etc.

You can't do that in the most obvious simple way because of slicing. So the normal solution is to have a vector of pointers or smart pointers instead. But I think there are cases where using a type field will be a simpler solution, (avoids new/delete or alternative lifecycle techniques).

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The best example I can think of (and the one I've run into before), is when your set of types is fixed and the set of functions you want to do (that depend on those types) is fluid. That way, when you add a new function, you modify a single place (adding a single switch) rather than adding a new base virtual function with the real implementation scattered all across the classes in your type hierarchy.

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I don't know of any realistic examples. Contrived ones would depend on there being some good reason that virtual methods cannot be used.

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For the record, I'm not suggesting it's pure evil, just that it is pre-OO. – Steven Sudit Sep 27 '10 at 22:10
I'd be thrilled to see an explanation for the downvote, but I'm not holding my breath. I believe I've just called your bluff and you've got nothing. – Steven Sudit Sep 28 '10 at 1:21
I have no idea who downvoted you, but since your answer seems to say that there are no real examples (your second sentence implies that any example would necessarily be contrived) and other answers definitely show otherwise (e.g. structures passed through any form of IPC), so I can see how someone would consider it a bad answer. – Ben Voigt Sep 28 '10 at 4:16
@Ben: Such a person would have deficiencies in their literacy, as I explicitly stated that any counterexamples would have to depend on the existence of circumstances, such as shared memory, that would prevent virtual methods from being used. – Steven Sudit Sep 28 '10 at 14:01
And, to be clear, I do see "structures passed through any form of IPC" as contrived because IPC/RPC requires some form of serialization. The contrivance is in demanding that the serialized form be executable as is; a requirement I've never seen, except self-generated by people trying to over-optimize. – Steven Sudit Sep 28 '10 at 14:04

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