[/ (C) Copyright Edward Diener 2011-2015 Distributed under the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt). ] [section:vmd_sequence Parsing sequences] In the normal use of Boost PP data is passed as arguments to a macro in discrete units so that each parameter expects a single data type. A typical macro might be: #define AMACRO(anumber,atuple,anidentifier) someoutput where the 'atuple', having the form of ( data1, data2, data3 ), itself may contain different data types of elements. This is the standard macro design and internally it is the easiest way to pass macro data back and forth. The Boost PP library has a rich set of functionality to deal with all of its high-level data types, and variadic data, with its own simpler functionality, also offers another alternative to representing data. Occasionally designers of macros, especially for the use of others programmers within a particular library, have expressed the need for a macro parameter to allow a more C/C++ like syntax where a single parameter might mimic a C++ function-call or a C-like type modification syntax, or some other more complicated construct. Something along the lines of: areturn afunction ( aparameter1, aparameter2, aparameter3 ) or ( type ) data etc. etc. In other words, from a syntactical level when designing possible macro input, is it possible to design parameter data to look more like C/C++ when macros are used in a library and still do a certain amount of preprocessor metaprogramming with such mixed token input ? VMD has functionality which allows more than one type of preprocessing token, excluding an 'empty' token which always refers to some entire input, to be part of a single parameter of input data. These preprocessing tokens as a single parameter are syntactically a consecutive series of data. The single limitation of this consecutive series of data is that each top-level part of the data of this series is of some VMD data type. What this means is that if some input consists of a series of data types it is possible to extract the data for each data type in that series. In practicality what this means is that, given the examples just above, if 'areturn', 'afunction', and 'data' are identifiers it would be possible to parse either of the two inputs above so that one could identify the different data types involved and do preprocessor metaprogramming based on those results. [heading Sequence definition] I will be calling such input data, which consists of all top-level data types in a series, by the term of a 'sequence'. Each separate data type in the sequence is called an 'element'. In this definition of a 'sequence' we can have 0 or more elements, so that a sequence is a general name for any VMD input. A sequence is therefore any input VMD can parse, whether it is emptiness, a single element, or more than one element in a series. Therefore when we speak of VMD macros parsing input data we are really speaking of VMD macros parsing a sequence. A sequence can therefore also be part of a Boost PP composite data type, or variadic data, and VMD can still parse such an embedded sequence if asked to do so. [heading Sequence parsing] Parsing a sequence means that VMD can step through each element of a sequence sequentially, determine the type and data of each element, then move on to the next element. Parsing is sequential and can only be done in a forward direction, but it can be done any number of times. In C++ iterator terms parsing of a sequence is a forward iterator. Working with a sequence is equivalent to using VMD macros 'generically'. Before I give an explanation of how to use a sequence using VMD generic functionality I would like to make two points: * The possibility of working with a sequence which contains more than one data type can be easily abused. In general keeping things simple is usually better than making things overly complicated when it comes to the syntactical side of things in a computer language. A macro parameter syntactical possibility has to be understandable to be used. * Using VMD to parse the individual data types of a sequence takes more preprocessing time than functionality offered with Boost PP data types, because it is based on forward access through each top-level type of the sequence. The one constraint in a sequence is that the top-level must consist of VMD data types, in other words preprocessor tokens which VMD understands. By top-level it is meant that a Boost PP composite data may have elements which VMD cannot parse but as long as the input consists of the composite data types and not the inner unparsable elements, VMD can parse the input. Therefore if preprocessor data is one of the examples above, you will be successful in using VMD. However if your preprocessor data takes the form of: &name identifier ( param ) or identifier "string literal" or identifier + number or identifier += 4.3 etc. etc. you will not be able to parse the data using VMD since '&', "string literal", '+', '+=', and "4.3" are preprocessor tokens which are not VMD top-level data types and therefore VMD cannot handle them at the parsing level. You can still of course pass such data as preprocessing input to macros but you cannot use VMD to recognize the parts of such data. This is similar to the fact that VMD cannot tell you what type preprocessor data is as a whole, using any of the VMD identifying macros already discussed, if the type is not one that VMD can handle. On the other hand you can still use VMD to parse such tokens in the input if you use Boost PP data types as top-level data types to do so. Such as: ( &name ) identifier ( param ) or identifier ( "string literal" ) or identifier ( + ) number or identifier ( += ) 4 ( . ) 3 The succeeding topics explain the VMD functionality for parsing a sequence for each individual VMD data type in that sequence. [heading Sequence types] A VMD sequence can be seen as one of either three general types: # An empty sequence # A single element sequence # A multi-element sequence An empty sequence is merely input that is empty, what VMD calls "emptiness". Use the previously explained BOOST_VMD_IS_EMPTY macro to test for an empty sequence. #include #define AN_EMPTY_SEQUENCE BOOST_VMD_IS_EMPTY(AN_EMPTY_SEQUENCE) will return 1 The type of an empty sequence is BOOST_VMD_TYPE_EMPTY. A single element sequence is a single VMD data type. This is what we have been previously discussing as data which VMD can parse in this documentation with our identifying macros. You can use the BOOST_VMD_IS_UNARY macro to test for a single element sequence. #include #define A_SINGLE_ELEMENT_SEQUENCE (1,2) BOOST_VMD_IS_UNARY(A_SINGLE_ELEMENT_SEQUENCE) will return 1 The type of a single element sequence is the type of the individual data type. In our example above the type of A_SINGLE_ELEMENT_SEQUENCE is BOOST_VMD_TYPE_TUPLE. A multi-element sequence consists of more than one data type. This is the "new" type which VMD can parse. You can use the BOOST_VMD_IS_MULTI macro to test for a multi-element sequence. #define A_MULTI_ELEMENT_SEQUENCE (1,2) (1)(2) 45 The A_MULTI_ELEMENT_SEQUENCE consists of a tuple followed by a seq followed by a number. #include BOOST_VMD_IS_MULTI(A_MULTI_ELEMENT_SEQUENCE) will return 1 The type of a multi-element sequence is always BOOST_VMD_TYPE_SEQUENCE. The type of a sequence can be obtained generically with the BOOST_VMD_GET_TYPE macro. We will be explaining this further in the documentation. [heading Sequence size] The size of any sequence can be accessed using the BOOST_VMD_SIZE macro. For an empty sequence the size is always 0. For a single element sequence the size is always 1. For a multi-element sequence the size is the number of individual top-level data types in the sequence. #include BOOST_VMD_SIZE(AN_EMPTY_SEQUENCE) will return 0 BOOST_VMD_SIZE(A_SINGLE_ELEMENT_SEQUENCE) will return 1 BOOST_VMD_SIZE(A_MULTI_ELEMENT_SEQUENCE) will return 3 [heading Using VMD to parse sequence input] For a VMD sequence essentially two ways of parsing into individual data types are offered by the VMD library: # The sequence can be converted to any of the Boost PP data types, or to variadic data, where each individual data type in the sequence becomes a separate element of the particular composite data type chosen. The conversion to a particular Boost PP data type or variadic data is slow, because it is based on forward access through each top-level type of the sequence, but afterwards accessing any individual element is as fast as accessing any element in the Boost PP data type or among variadic data. # The sequence can be accessed directly through its individual elements. This is slower than accessing an element of a Boost PP data type or variadic data but offers conceptual access to the original sequence as a series of elements. These two techniques will be discussed in succeeding topics. [include vmd_sequence_convert.qbk] [include vmd_sequence_access.qbk] [endsect]