Boost C++ Libraries

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Identifier subtypes

Identifiers are the low-level data types which macro programmers use to pass preprocessing data most often. As we have seen VMD has a system for registering and detecting identifiers so that they can be parsed as part of preprocessor data. This system also includes comparing identifiers for equality or inequality using BOOST_VMD_EQUAL/BOOST_VMD_NOT_EQUAL and matching identifiers using identifier modifiers in BOOST_VMD_IS_IDENTIFIER and BOOST_VMD_ELEM. Together these facilities provide a rich set of functionality for handling identifiers in macros.

Both numbers and v-types are subtypes of identifiers, and can both be individually recognized as data types of their own or worked with as identifiers using the identifier facilities already mentioned. Numbers, in particular, also have a rich set of functionality within the Boost PP library. As subtypes numbers and v-types can be used as filter modifiers and can be returned as specific types either when invoking BOOST_VMD_GET_TYPE or when using return type modifiers. Furthermore VMD recognizes their individual v-types, BOOST_VMD_TYPE_NUMBER and BOOST_VMD_TYPE_TYPE, as VMD data when parsing sequences.

It is possible for the end-user to define his own identifier subtype. This is called a "user-defined subtype". Once a user-define subtype is created all the generic type facilities of VMD which subtypes such as a number or a v-type possess is automatically available for that user-defined subtype.

Defining a subtype

In order to define a user-defined subtype a number of steps need to be followed. These steps will be explained in detail further below:

  1. Register and pre-detect all identifiers of that subtype.
  2. Register and pre-detect a v-type name for that subtype.
  3. Subset register all identifiers of the subtype.
  4. Subset register the v-type name for the subtype.

When we do the above, it is best to put all the macros in a single header file and always include that header file when we work generically with our user-defined subtype.

Register and pre-detect all identifiers of that subtype

Registering and pre-detecting all of the identifiers of that subtype is exactly the same as registering and pre-detecting any identifier.

Let's create some identifiers based for use in the mythical "udef" library. We will put all our macros in the header file udef_vmd_macros.hpp.

We will need distinct names for the identifiers in our library, so we will append UDEF_ to our identifier names to make them unique. Our udef library deals in geometrical shapes so we will create a user-defined subtype which consists of identifiers for the various shapes our udef library can manipulate in their macros. So our identifier registrations and pre-detections placed in our header file will be:

#define BOOST_VMD_REGISTER_UDEF_CIRCLE (UDEF_CIRCLE)
#define BOOST_VMD_REGISTER_UDEF_SQUARE (UDEF_SQUARE)
#define BOOST_VMD_REGISTER_UDEF_TRIANGLE (UDEF_TRIANGLE)
#define BOOST_VMD_REGISTER_UDEF_HEXAGON (UDEF_HEXAGON)

#define BOOST_VMD_DETECT_UDEF_CIRCLE_UDEF_CIRCLE
#define BOOST_VMD_DETECT_UDEF_SQUARE_UDEF_SQUARE
#define BOOST_VMD_DETECT_UDEF_TRIANGLE_UDEF_TRIANGLE
#define BOOST_VMD_DETECT_UDEF_HEXAGON_UDEF_HEXAGON

Register and pre-detect a v-type name for that subtype

We need to create a unique v-type name for our user-defined subtype. The name does not have to begin with BOOST_VMD_TYPE_ but it should be unique. Since BOOST_VMD_TYPE_ is the common beginning of all v-types we will use it for consistency but will append to it UDEF_SHAPES to give it a uniqueness which should not be duplicated:

#define BOOST_VMD_REGISTER_BOOST_VMD_TYPE_UDEF_SHAPES (BOOST_VMD_TYPE_UDEF_SHAPES)

#define BOOST_VMD_DETECT_BOOST_VMD_TYPE_UDEF_SHAPES_BOOST_VMD_TYPE_UDEF_SHAPES

Subtype register all identifiers of the subtype

The macro to register an identifier subset starts with BOOST_VMD_SUBTYPE_REGISTER_ and you append to it each identifier in the subset. This is very much like the way you use the BOOST_VMD_REGISTER_ macro. The difference is that unlike the BOOST_VMD_REGISTER_ macro, which expands to a tuple whose single element is the identifier, the BOOST_VMD_SUBTYPE_REGISTER_ expands to a tuple of two elements where the first element is the subtype v-type and the second element is the identifier.

For our udef user-defined subtype this would be:

#define BOOST_VMD_SUBTYPE_REGISTER_UDEF_CIRCLE (BOOST_VMD_TYPE_UDEF_SHAPES,UDEF_CIRCLE)
#define BOOST_VMD_SUBTYPE_REGISTER_UDEF_SQUARE (BOOST_VMD_TYPE_UDEF_SHAPES,UDEF_SQUARE)
#define BOOST_VMD_SUBTYPE_REGISTER_UDEF_TRIANGLE (BOOST_VMD_TYPE_UDEF_SHAPES,UDEF_TRIANGLE)
#define BOOST_VMD_SUBTYPE_REGISTER_UDEF_HEXAGON (BOOST_VMD_TYPE_UDEF_SHAPES,UDEF_HEXAGON)

Subtype register the v-type name for the subtype

Doing a subset register of the actual udef v-type is fairly easy once we understand how to register an identifier subset. The only particular thing to realize is that the type of any v-type is the v-type BOOST_VMD_TYPE_TYPE. So our subset register of our new v-type BOOST_VMD_TYPE_UDEF_SHAPES is:

#define BOOST_VMD_SUBTYPE_REGISTER_BOOST_VMD_TYPE_UDEF_SHAPES (BOOST_VMD_TYPE_TYPE,BOOST_VMD_TYPE_UDEF_SHAPES)

Using our identifier subset

Once we have added all of the above object-like macros for defining our user-defined subtype to the udef_vmd_macros.hpp header file we have a new data type which we can use generically just like we can use numbers or v-types generically. It is important to include the header udef_vmd_macros.hpp in some translation unit whenever we need the VMD functionality for our new data type. So in our examples we will assume that an '#include udef_vmd_macros.hpp' precedes each example.

#include <boost/vmd/get_type.hpp>

#define A_SEQUENCE UDEF_SQUARE
#define A_SEQUENCE2 217
#define A_SEQUENCE3 BOOST_VMD_TYPE_UDEF_SHAPES
#define A_SEQUENCE4 BOOST_VMD_TYPE_NUMBER

BOOST_VMD_GET_TYPE(A_SEQUENCE) will return 'BOOST_VMD_TYPE_UDEF_SHAPES'
BOOST_VMD_GET_TYPE(A_SEQUENCE2) will return 'BOOST_VMD_TYPE_NUMBER'
BOOST_VMD_GET_TYPE(A_SEQUENCE3) will return 'BOOST_VMD_TYPE_TYPE'
BOOST_VMD_GET_TYPE(A_SEQUENCE4) will return 'BOOST_VMD_TYPE_TYPE'

Here we see that when we use our BOOST_VMD_GET_TYPE macro on a single-element sequence which is one of our user-defined subtype values we correctly get back our user-defined subtype's v-type, just like we do when we ask for the type of a number. Also when we use our BOOST_VMD_GET_TYPE macro on our user-defined subtype's v-type itself we correctly get back the type of all v-types, which is BOOST_VMD_TYPE_TYPE, just like we do when we ask for the type of the v-type of a number.

#include <boost/vmd/elem.hpp>

#define A_SEQUENCE5 (1,2) UDEF_TRIANGLE

BOOST_VMD_ELEM(1,A_SEQUENCE5,BOOST_VMD_RETURN_TYPE) will return '(BOOST_VMD_TYPE_UDEF_SHAPES,UDEF_TRIANGLE)'
BOOST_VMD_ELEM(0,A_SEQUENCE5,BOOST_VMD_RETURN_TYPE) will return '(BOOST_VMD_TYPE_TUPLE,(1,2))'

Here we see that we can use the return type modifier to get back both the type and the value in a two-element tuple for our user-defined subtype just as we so for any other type.

#include <boost/vmd/equal.hpp>

#define A_SEQUENCE6 UDEF_CIRCLE
#define A_SEQUENCE7 168

BOOST_VMD_EQUAL(A_SEQUENCE6,UDEF_CIRCLE,BOOST_VMD_TYPE_UDEF_SHAPES) will return '1'
BOOST_VMD_EQUAL(A_SEQUENCE6,UDEF_CIRCLE,BOOST_VMD_TYPE_LIST) will return '0'
BOOST_VMD_EQUAL(A_SEQUENCE7,168,BOOST_VMD_TYPE_NUMBER) will return '1'
BOOST_VMD_EQUAL(A_SEQUENCE7,168,BOOST_VMD_TYPE_SEQ) will return '0'

Here we can see that we can use the filter modifier with our user-defined subtype's v-type just as we can do with any other v-type, such as the number v-type.

In all respects once we define our subtype and provide those definitions in a header file, our user-defined subtype acts like any other v-type in our system. Since VMD functionality is largely based on being able to recognize the type of data in macro input being able to define another 'type', as an identifier subtype, which VMD understands has value for the macro programmer.

Uniqueness of identifier subtype values and v-type

When we define a new identifier subtype we need to be careful that the values of that subtype and its actual v-type are unique identifiers within any translation unit. This is the main difference between just defining identifiers and defining an identifier subtype.

Recall that when we just register and pre-detect identifiers we will have no problems if the same identifiers already have been registered and pre-detected within the same translation unit. This is because we are just redefining the exact same macro if this is the case.

But with identifier subtypes, when we use the BOOST_VMD_SUBTYPE_REGISTER_ macro to associate our subtype's v-type with our subtype identifiers, we will have problems if someone else has also defined an identifier subtype using the same identifiers as we use since we will be redefining the same object-like macro name with a different expansion. Even if someone else has registered/pre-detected an identifier we are using for out subtype without defining a subtype based on that identifier we will be causing a problem defining our subtype because VMD macros which generically return the type of a sequence or sequence element will return our subtype as the type rather than just BOOST_VMD_TYPE_IDENTIFIER which some programmer might expect.

The gist of this is that if we define a user-defined subtype its identifiers need to be unique within a given translation unit, and yet unique names make it harder for an end-user to use macros more naturally. In our given example with the mythical udef library we used identifiers such as 'UDEF_CIRCLE' etc. instead of the more natural sounding CIRCLE. So with user-defined identifier subtypes we have a tradeoff; we need unique identifier names both for our subtype identifiers and the v-type for our subtype identifiers so as not to conflict with others who might be using identifier subtypes, but those unique names might make using macros less "natural" On the other hand, just registering/pre-detecting identifiers has no such problem. This is an issue of which any user, looking to create his own data type using VMD by defining user-defined subtypes, should be aware.


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