PATENT ABSTRACT
An object oriented operating system handles all objects related to text strings as belonging to one of three classes, in which each class performs a different function and at least one such class is modified to do so in a way that reduces code and cycle overhead. This reduces executable code overhead to minimise the amount of memory required, and allows execution in a minimum number of cycles to minimise power consumption. The operating system is particularly well suited to ROM based mobile computing devices.

PATENT DESCRIPTION
BACKGROUND 
     1. Field of the Invention 
     This invention relates to an improved object oriented operating system for a computer. In particular, it relates to an operating system which is based on C++ programming techniques. The commercially available embodiment of this operating system is the EPOC32 operating system produced by Psion Software Plc of England. EPOC32 is a preferred operating system in the mobile computing environment. 
     2. Description of the Related Art 
     The C++ programming language is widely used for writing application programs for computers, such as Personal Computers, although it has only rarely been widely adopted for writing operating systems. When writing for Personal Computers, there is generally no overriding requirement to either minimise the size of the executable code or to minimise the number of cycles required for executing steps within the program. Typically, performance and ease of authorship are the more significant requirements. 
     But there are other contexts in which the executable code must occupy the minimum amount of space (e.g. to minimise the amount of ROM and/or RAM required to store it), and to execute in the minimum number of cycles (e.g. to minimise power consumption). 
     The mobile computing (e.g. personal digital assistants), smart phone (e.g. GSM cellular telephones with in-built word processing, facsimile send/receive and Internet browsing capabilities) and network computer (“NC”) environments exemplify contexts in which there are advantages to minimising the code size of the operating system: namely, the hardware costs (particularly ROM and/or RAM) can then be reduced. That is particularly significant in the above contexts since widespread consumer adoption is generally dependent on relatively low hardware pricing. Similarly, minimising processor execution cycles of the operating system is very important in the mobile computing and smart phone contexts, since doing so minimises power consumption and minimising power consumption is critical to long battery life. A fully architected operating system written in C++ would generally be substantial in size and be power hungry. Hence, it would it be unsuitable for the mobile computing, smart phone and NC environments. 
     Further, it is generally regarded as difficult to design a fully functional operating system in C++ that meets stringent requirements for code size and cycle overhead, particularly the stringent requirements associated with the mobile, smart phone and NC computing environments. 
     Some Terminology 
     “Objects of the String Class” 
     In C++, text (e.g. strings of letters that will actually appear on a computer screen) is represented as an “Object”. The implementer skilled in C++ or other object oriented languages will be familiar with this categorisation. Such text related Objects are of a particular type, which we shall call “Objects of the String Class”: The kind of Class that an Object belongs to (e.g. in the case of text, the String Class) defines the allowable manipulations that can be performed on that Object. Only certain manipulations can be performed on Objects of the String Class (e.g. concatenating 2 text strings together). A particular Object of the String Class therefore represents a particular text string. It can only be manipulated in certain, well defined ways. 
     The following steps are performed in conventional C++ programming in order to create an Object of the String Class from an item of text, where the text resides in a file in the filing system: 
     set aside a buffer location in memory 
     read the text into the buffer using a file reading service 
     use a string creation service to turn the buffered data into an Object of the String Class 
     discard the buffer contents 
     The actual storage location of the text string is difficult to identify in C++, but one does not need to know its location since it is the Object of the String Class that one manipulates directly: that in turn causes the actual text string to be manipulated. Hence the Object of the String Class in effect knows the memory location of the text string and can handle all the necessary memory management tasks associated with text manipulation. 
     Multiple Classes of Objects of the String Class 
     In the version of C++ known as the draft ANSL/ISO C++ Standard, all Objects of the String Class (as exemplified by the string class in that part of the draft C++ Standard Library of the above Standard referred to as &lt;string&gt;) are handled in a manner that enables sophisticated memory management tasks to be accomplished (e.g. re-allocating buffer space for text that can grow or shrink or be spliced—fully dynamic text). But this level of memory management uses a great deal of code and may require considerable heap space. 
     Two examples of conventional C++ memory management illustrate this: 
     Example 1: C++ Handling of Literal Text 
     In C++, there are many instances in which source code contains text strings. These strings are known as ‘Literal Text’ and are permanently stored in buffer memory on compilation of the source code into executable object code. When Literal Text is to be manipulated, then an Object of the String Class must be created from it. However, creation of that Object of the String Class itself leads to the creation in memory of the text string which the newly created Object of the String Class in fact manipulates. Hence, the text string is duplicated in memory: once in the original buffer that arises on compilation of the source code and again in the memory location associated with the Object of the String Class that enables the text to be manipulated. 
     As noted above, in some computing environments, code space and power consumption are at a premium. However, in conventional C++ (i.e. as implemented in the draft ANSI/ISO C++ Standard), there is no mechanism to overcome the inherent duplication in memory of Literal Text. That is problematic, especially for an operating system since, in an operating system, there are many occasions in which Literal Text must be handled. 
     Example 2: C++ Handling of Length Limited Text 
     In C++, a programmer handles text using heap memory. Text whose length is limited does not in fact require the fully flexible approach that is needed to handle text whose length is not limited. However, in conventional C++, there is no mechanism for using anything other than fully flexible, fully featured Objects of the String Class, irrespective of the length of text. That leads to a high overhead in memory management code since handling heap memory is code and cycle intensive. 
     Overall, text memory management in C++ is code and cycle intensive. Since code space and power consumption are at a premium in mobile environments, the conventional C++approach would lead to an operating system that is unacceptably large in terms of code size and is also too power hungry. 
     SUMMARY 
     The operating system of the present invention re-defines Objects of the String Class (i.e. as defined in the draft ANSI/ISO C++ Standard), by substituting them with a three fold structure of Objects of the String Class, namely three new Classes of Objects. The conventional, fully featured memory management functionality associated with &lt;string&gt; from the draft ANSI/ISO C++ Standard is not applied to all three of the new classes. Whilst that full functionality is useful in many environments, it is problematic in (inter alia) mobile computing environments in which code space and power consumption are at a premium. 
     Hence, the generalisation of the inventive concept of the present invention is to minimise code size and cycle overhead by providing, in a computer operating system, a family of three different Classes for handling text strings: each different class is appropriate for a different circumstance. This allows flexibility: for example, the fully featured memory management functionality can now be applied solely to those text strings that actually require it. 
     We shall refer to this new family of String Class Objects as “Descriptors”. In a preferred embodiment, we call the members of this family “Pointer Descriptors”, “Buffer Descriptors” and “Heap Descriptors”. Care should be taken to note that these concepts are different (although related to) the established concepts of “pointers”, “buffers” and “heaps”, with which the skilled implementer will be familiar. Care should also be taken to note that the Descriptors envisaged in this specification have no relationship to the VMS facility of the same name, nor the UNIX term for small integer numbers used to identify active operating system files. The skilled implementer may appreciate that it is possible to design an operating system in which the number of Classes for handling text strings exceeds three: such variants are within the scope of the present invention. The three fold structure is the minimum (and in almost all cases, the most effective) proliferation of Classes. 
     Further, Descriptors are preferably polymorphic: hence, a single service can operate on all Descriptors. That leads to significant savings in code and, to a lesser extent, cycle overhead, since otherwise modified services would be needed for each of different Descriptors. 
     Hence, in accordance with a first aspect of the present invention, there is provided a computer programmed with an object oriented operating system, in which the operating system is adapted to handle objects related to text strings; 
     characterised in that the operating system handles all such objects as belonging to one of three classes (namely the Pointer Descriptor Class, the Buffer Descriptor Class and the Heap Descriptor Class), in which each class performs a different function and at least one such class is modified to do so in a way that reduces code and cycle overhead. 
     The invention is founded upon the insight that in order to deliver significant reductions in code and cycle overhead, one has to redesign the operating system by substituting the conventional, single form of Object of the String Class (for example) with three different forms of that Object: each form is optimised for different circumstances. 
     In a preferred form of the invention, conventional, memory intensive text handling techniques are applied only to Objects which fall within the new Descriptor Class which defines Objects requiring such techniques (i.e. Heap Descriptors). The Pointer and Buffer Descriptor Classes are however designed in a manner that reduces code and processor cycles compared to conventional String Classes. 
     Using the two examples mentioned in the Description of the Prior Art above (i.e. Example 1: C++ Handling of literal text and Example 2: C++ Handling of length limited text), the operating system of the present invention (i) handles Literal Text in a manner that eliminates the need for a duplicate copy of Literal Text and (ii) handles text which is determined dynamically at run time in a manner that only requires code intensive utilisation of heap memory in those limited circumstances in which it is actually necessary to do so: in other circumstances (for example, where the programmer knows in advance the maximum length of the text), then static memory is used instead. Fuller details of the specific handling is given below (see section titled Detailed Description). 
     Preferably, the operating system is adapted to handle not only text but also raw data using the same three fold structure. 
     In addition to the combined computer/operating system as defined above, one can identify further inventive aspects. For example, any device that has to interface with such an operating system must also use the same three-fold structure for Objects of the String Class. For example, driver software for peripherals such as solid state memory devices will have to use this three fold-structure. Likewise, control panel software for peripherals will also have to. 
     Hence, in a second aspect of the present invention, there is provided a peripheral device for a computer programmed with an object oriented operating system, in which the operating system is adapted to handle objects related to text strings; 
     characterised in that the operating system handles all such objects as belonging to one of three classes (namely the Pointer Descriptor Class, the Buffer Descriptor Class and the Heap Descriptor Class), in which each class performs a different function and at least one such class is modified to do so in a way that reduces code and cycle overhead and is further characterised in that the peripheral device is programmed to handle objects which also fall into the above three classes. 
     In a third aspect of the present invention, there is provided an operating system encoded on computer readable media, in which the operating system handles objects related to text strings; 
     characterised in that the operating system is adapted to handle all such objects as belonging to one of three classes (namely the Pointer Descriptor Class, the Buffer Descriptor Class and the Heap Descriptor Class), in which each class performs a different function and at least one such class is modified to do so in a way that reduces code and cycle overhead. 
     In a fourth aspect of the invention, there is provided a method of operating a micro-processor using an operating system, in which the operating system is adapted to handle objects related to text strings; 
     characterised in that the operating system handles all such objects as belonging to one of three classes (namely the Pointer Descriptor Class, the Buffer Descriptor Class and the Heap Descriptor Class), in which each class performs a different function and at least one such class is modified to do so in a way that reduces code and cycle overhead. 
     In a fifth aspect, there is provided computer readable media encoded with an operating system adapted to handle objects related to text strings; 
     characterised in that the operating system handles all such objects as belonging to one of three classes, in which each class performs a different function and at least one such class is modified to do so in a way that reduces code and cycle overhead. Typically, the computer readable media will be a masked ROM. For distribution purposes, the media may also be a conventional CD-ROM or floppy disc. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is an illustration of a constant pointer descriptor; 
     FIG. 2A is an illustration of a modifiable pointer descriptor pointing to an area in at memory; 
     FIG. 2B is an illustration of a modifiable pointer descriptor pointing to another descriptor; 
     FIG. 3 is an illustration of a constant buffer descriptor; 
     FIG. 4 is an illustration of a modifiable pointer descriptor pointing to a constant buffer descriptor; 
     FIG. 5 is an illustration of a modifiable buffer descriptor; 
     FIG. 6 is an illustration of a constant heap descriptor; 
     FIG. 7 is an illustration of a modifiable pointer descriptor pointing to an allocated constant heap descriptor; 
     FIG. 8 is an illustration of the member functions available to members of the various descriptor classes; 
     FIGS. 9,  10  illustrate an example to construct a pointer descriptor for leftmost part of data; 
     FIGS. 11,  12  illustrate an example to construct a pointer descriptor for rightmost part of data; 
     FIGS. 13,  14  illustrate an example to create a new heap descriptor; 
     FIGS. 15,  16  illustrate an example to copy from a descriptor and justify; 
     FIG. 17 illustrates an example to append a descriptor and justify; 
     FIG. 18 illustrates an example to append part of a descriptor and justify; and 
     FIG. 19 illustrates an example to append a zero terminator. 
    
    
     DETAILED DESCRIPTION 
     The present invention will be described in relation to an embodiment known as EPOC32. EPOC32 is a 32 bit operating system developed by Psion Software plc of England for use in (inter alia) mobile and smart phone environments. Further details of the EPOC32 embodiment are disclosed in the SDK on EPOC32 published by Psion Software Plc, England, to the extent possible without limiting in any way the rights of the inventors and assignees of this invention, the full SDK is incorporated by reference into this specification. 
     EPOC32 has been ported to run on a number of different micro-processor architectures. The details of porting an operating system per se are beyond the scope of this specification, but will be understood by those skilled in the arts. In particular, EPOC32 has been ported to run on ARM RISC-based micro-processors from Advanced RISC Machines of England. Various models of ARM micro-processors are widely used in digital cellular telephones and will be familiar to those skilled in the art. However, the invention can be realised on many different micro-processors. Hence, the claims of this specification should be read to cover any and every hardware and software implementation in which the operating system performs the functions as limited in the claims. 
     Returning to the examples of Literal Text and Length Limited Text given in the Prior Art discussion above, EPOC32 applies the above three-fold structure for Objects of the String Class as follows: 
     Example 1: Literal Text in EPOC32 
     As explained above, in conventional C++, a text string relating to Literal Text is duplicated in memory: once in the original buffer that arises on compilation of the source code and again in the memory location associated with the Object of the String Class that enables the text to be manipulated. That duplication is wasteful. 
     EPOC32 however uses a Pointer Descriptor which points to the original memory location of the Literal Text (i.e. as laid down by the compiler). This Pointer Descriptor (called the TPtrC Pointer Descriptor in EPOC32) is the Object of the String Class for Literal Text. (In C++, pointers are not usually regarded as Objects per se). Hence, the hybrid pointer/object in EPOC32 leads to the complete elimination of the need for an additional copy of Literal Text. 
     Example 2: Length Limited Text in EPOC32 
     As noted above, in conventional C++, there is no mechanism for using anything other than fully flexible, fully featured Objects of the String Class, irrespective of the length of text. That leads to a high overhead in memory management code since handling heap memory is code and cycle intensive. 
     In EPOC32, there is a particular class of String Objects, known as Buffer Descriptors, which are size limited. Because they are size limited, complex memory allocation code is not required to manipulate them. Further, Buffer Descriptors can use Static Memory (rather than heap memory). Static memory cannot be re-allocated in the code intensive fashion that heap memory can be, but is more efficient to use in that fewer code cycles are required to achieve the necessary manipulations (hence leading to power saving). Only in the truly dynamic case does EPOC32 require use of the heap memory with its attendant high cycle overhead: Then, the Heap Descriptor Class is used. 
     EPOC32 lays down the parameters of length limited String Classes using a template class, the ‘TBuf’ class. (Class templates define the properties of numerous Objects of the String Class; e.g. TBuf is the template for all Buffer Descriptors—i.e. all Objects of the String Class of the Buffer variant. TBuf defines certain common properties for all such Objects of the String Class.) 
     EPOC32 exhibits several other significant features which lead to minimising code size and cycle overhead, namely that: 
     String and Raw Data Buffer Class Objects act as ‘flat’ structures 
     Descriptors give polymorphic characteristics 
     Descriptors allow for UNICODE and ASCII invariant coding 
     String and Raw Data Buffer Class Objects as Flat Structures 
     All Descriptors are ‘flat’ structures (i.e. if a Descriptor has to be copied, then only the Descriptor itself is copied. In conventional C++, copying an Object requires copying not only of the Object itself, but also all related pointers and the data pointed to—i.e. the complex, related structure that gives an Object meaning.) In EPOC32, copying a Descriptor is therefore far more economic in memory overhead and cycles than copying an equivalent Object in ordinary C++. 
     This is achieved in EPOC32 as follows, for Buffers and Pointers: 
     Buffer Descriptors (TBuf) contain the actual text referenced by the Buffer: hence, copying the Buffer inherently copies the related text. There is no need to copy a pointer and related data as there would be in C++. 
     Pointer Descriptors (TPtr) contain a C++ type pointer within them, so that copying TPtr alone is all that is required when duplicating: in conventional C++, one would have had to copy not just one entity, but also related and separate pointers and text. 
     Descriptors as Polymorphic Objects 
     A group of Objects are said to exhibit polymorphism if all the Objects in the Group behave like a single Object, yet achieve common behaviour through different mechanisms. Polymorphism is provided for in conventional C++ through Virtual Functions: all Objects which are polymorphic to one another include, at a common location, a pointer to a Virtual Function Table (a pointer is therefore required in each Object). This Table identifies the actual code for each polymorphic function. A separate Table is needed for each class that shares polymorphism. But this approach uses a considerable amount of space, since each pointer is 32 bits (i.e. 4 characters) and each Object needs a pointer to a Virtual Function Table. In addition, a 32 bit length field is also used in each Object. 
     In (inter alia) mobile operating system environments, this overhead is problematic. EPOC32 addresses this as follows for Objects of the String Class: a 32 bit length field is sub-divided so that the first 4 bits code for the type of Descriptor. A function then looks at the 4 bits and points to the correct text location (e.g. within the Descriptor itself if the Descriptor is a Buffer etc.) Hence, polymorphism is provided for in that each of the three different classes of Descriptors for Objects of the String Class (i.e. Pointer Descriptors, Buffer Descriptors and Heap Descriptors) can be coded for using merely the first 4 bits of a single 32 bit field. Hence, considerable memory savings can be achieved. In more general terms, the field shares a machine word with another data item. 
     UNICODE and ASCII Invariant Code 
     In C++, coding for 16 bit Unicode leads to doubling in size of all text data that would otherwise be in 8 bit code. Also, conventionally, a programmer has to decide when writing source code whether to code for text using ASCII or Unicode. 
     In EPOC32, the same source code is used irrespective of the ultimate choice of ASCII or Unicode. This is achieved by building the system using aliases for Class Names, which are ASCII and Unicode invariant, rather than Classes per se (e.g. Pointer Descriptors, Buffer Descriptors and Heap Descriptors). Hence, instead of building using the Pointer TPtr 16  to code for Unicode or TPtr 8  to code for ASCII, one instead builds using the TPtr Class Name. At build time, the Class Names can be compiled as either 16 bit Unicode or 8 bit ASCII. This approach can be used to encompass all character sets which can be encoded in different bit lengths. 
     Additional Advantages of EPOC32 
     In C++. text strings are conventionally terminated with a ‘0’ so that the system can readily know where a text string ends. In EPOC32, that is no longer necessary; Descriptors include a statement defining the length of the data referenced. Hence, there is a yet further saving in code since it no longer needs to use ‘0’ terminators to flag the end of each and every text item. 
     Summary of Descriptors Features 
     Descriptors come 3 classes: Pointer Descriptors, Buffer Descriptors and Heap Descriptors 
     Pointer Descriptors come in two forms: constant Pointer Descriptors: TPtrC and modifiable Pointer Descriptors: TPtr 
     constant Pointer Descriptors: TPtrC. 
     Data cannot be modified through this. 
     All member functions are constant. 
     Is used to reference constant strings or data (e.g. data that must not be altered). 
     Is derived from TDesC and hence has a large number of member functions. 
     modifiable Pointer Descriptors: TPtr. 
     Data can be modified though this Descriptor, so long as the data does not extend beyond the maximum length set by the constructor. 
     Points directly to a memory area containing the area to be modified. 
     Pointer length determines number of data items that are contained. 
     Inherits all the TDesC member functions, plus TDes member functions for manipulating and changing data. 
     Pointer Descriptors are separate from the data represented; but are constructed from a pre-existing area in memory. 
     Buffer Descriptors come in two forms 
     constant Buffer Descriptor, TBufC&lt;TInt S&gt; 
     data can be set into the Descriptor at construction time or by the assignment operator (operator=) later on. 
     length is defined by an integer template: TBufC&lt;40&gt; contains 40 data items. 
     Inherits all the TDesC member functions 
     a modifiable Buffer Descriptor:, TBuf&lt;TInt S&gt; 
     contains data that can be modified, so long as the data is not modified to extend beyond the maximum length. 
     maximum length defines the max. number of data items 
     actual length defines actual number of data items 
     length is defined by an integer template: TBuf&lt;40&gt; contains 40 data items and no more. 
     the data area is part of the Descriptor object 
     useful for containing data which needs to be manipulated and changed, but whose length will not exceed a known maximum (e.g. WP text). 
     Inherits all the TDesC member functions, plus TDes member functions for manipulating and changing data. 
     Heap Descriptors come in one form only 
     constant Heap Descriptor HBufC 
     contains a length followed by data 
     the data area is part of the Descriptor object; the whole object occupies a cell allocated from the heap. 
     Data can be set into the Descriptor at construction time or by the assignment operator (operator=) later on. 
     Inherits all the TDesC member functions 
     can be re-allocated: data area can expand or contract 
     TPtrC is a constant Descriptor through which no data can be modified. All of its member functions (except the constructors) are constant. TPtrC is shown schematically at FIG.  1 . TPtrC is useful for referencing constant strings or data; for example, accessing text built into ROM resident code, or passing a reference to data in RAM which must not be modified through that reference. TPtrC is derived from TDesC, which provides a large number of member functions for operating on its content; for example, locating characters within text or extracting portions of data. 
     TPtr is a modifiable pointer Descriptor through which data can be modified, provided that the data is not extended beyond the maximum length. The maximum length is set by the constructor. TPtr points directly to an area in memory containing the data to be modified. TPtr is shown schematically in FIGS. 2A and 2B. 
     TBufC is a buffer Descriptor containing a length followed by the data area. Data can be set into the Descriptor at construction time or by the assignment operator (operator=) at any other time. Data already held by the Descriptor is constant. TBufC is shown schematically at FIG.  3 . The length of a TBufC is defined by an integer template; for example, TBufC&lt;40&gt; defines a TBufC which can contain up to 40 data items. 
     TBufC is derived from TDesC, which provides a large number of member functions for operating on its content; for example, locating characters- within text or extracting portions of data. TBufC provides the member function, Des( ), which creates a modifiable pointer Descriptor (a TPtr) to reference the TBufC. This allows the TBufC data to be changed through the TPtr, as indicated schematically at FIG.  4 . The maximum length of the TPtr is the value of the integer template parameter. 
     TBuf is a modifiable buffer Descriptor containing data which can be modified, provided that the data is not extended beyond its maximum length. TBuf is shown schematically at FIG.  5 . The maximum number of data items that the data area within TBuf can contain, is defined by the maximum length. The length of the Descriptor indicates how many data items are currently contained within the data area. When this value is less than the maximum, a portion of the data area is unused. The maximum length of a TBuf is defined by an integer template; for example, TBuf&lt;40&gt; defines a TBuf which can contain up to data items (and no more!). A TBuf is useful for containing data which needs to be manipulated and changed but whose length will not exceed a known maximum; for example, word processor text. TBuf is derived from TDes which, in turn, is derived from TDesC. Therefore, it inherits all the const member functions defined in TDesC plus the member functions from TDes which can manipulate and change the data; for example, appending a character to the end of existing text. 
     HBufC is a Descriptor containing a length followed by data. It is allocated on the heap using the New( ), NewL( ) or NewLC( ) static member functions. The length of the Descriptor is passed as a parameter to these static functions. HBufC is shown schematically at FIG.  6 . Data can be set into the Descriptor at construction time or by the assignment operator (operator=) at any other time. Data already contained by the Descriptor is constant. HBufC is derived from TDesC, which provides a large number of member functions for operating on its content; for example, locating characters within text or extracting portions of data. 
     HBufC provides the member function, Des( ), which creates a modifiable pointer Descriptor (a TPtr) to reference the HBufC. This allows the HBufCC data to be changed through the TPtr. The maximum length of the TPtr its the length of the HBufC data area. FIG. 7 illustrates this schematically. 
     All of the Descriptor classes TPtrC, TPtr., TBufC, TBuf and HBufC are derived from the abstract base classes TDesC and TDes. The class TBufCBase, although marked as an abstract class, is merely an implementation convenience. FIG. 8 schematically illustrates the relationship between the classes. 
     EXAMPLE FUNCTIONS (See Appendix 1 for details and additional functions) 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 The code fragments illustrate the use of Left( ). 
               
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;8&gt;str(_L(“abcdefg”)); 
               
             
          
           
               
                   
                 . . . 
                 // returns a TPtrC descriptor 
               
               
                   
                 str.Left(4); 
                  / representing the sting 
               
               
                   
                 . . . // 
                 “abcd” 
               
               
                   
                   
               
             
          
         
       
     
     The result of this specific example can be visualized in a before (shown in FIG. 9) and after (shown in FIG. 10) fashion. The underlined text in the “after” diagram (FIG. 10) indicates the data represented by the returned descriptor. 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 The code fragments illustrate the use of Right( ). 
               
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;8&gt;str(_L(“abcdefg”)); 
               
             
          
           
               
                   
                 . . . 
                 // returns a TPtrC descriptor 
               
               
                   
                 str.Right(4); 
                    // representing the string 
               
               
                   
                 . . . 
                 // “defg” 
               
               
                   
                   
               
             
          
         
       
     
     The result of this specific example can be visualized in a before (FIG. 11) and after (FIG. 12) fashion. The underlined text in the “after” diagram (FIG. 12) indicates the data represented by the returned descriptor. 
     The code fragments illustrate the use of AllocL( ). 
     
       
         
               
               
             
               
               
               
             
               
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;16&gt;str(_L(“abcdefg”)); 
               
               
                   
                 HBufC*  ptr; 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 ptr = str.AllocL( ); 
                  // Returns address of new HBufC descriptor 
               
             
          
           
               
                   
                 . . . 
                 // holding the string “abcdefg”. 
               
             
          
           
               
                   
                 ptr.Length( ); 
                 // Returns the length 7 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     The result of this specific example can be visualised in a before (FIG. 13) and after (FIG. 14) fashion. 
     The following code fragments illustrate the use of Justify( ). 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     . . . 
     tgt.JustifyLL(“xyz”),8,ECenter,‘@’); 
     The descriptor tgt has a maximum length of 16 and initially holds the string “abc”. After the call to Justify( ), the content of tgt changes to “@@xyz@@@” as illustrated at FIG.  15 . 
     In this example, the content of the source descriptor is taken to form an 8 character field which replaces the original content of the descriptor tgt. The characters “xyz” are centred within the new field and padded on both sides with the fill character‘@’. Setting the alignment to ELeft would change the content of tgt to “xyz@@@@@” while setting the alignment to ERight would change the content of tgt to “@@@@@xyz” In all three cases, the length of the descriptor tgt changes from 3 to 8. 
     . . . 
     TBuf&lt;8&gt; tgtLL(“abc”)); . . . 
     . . . 
     tgt.JustifyLL(“xyz”),9,ECenter,‘@’); 
     This call to Justify( ) will panic because the resulting length of data in tgt would exceed the maximum length of tgt. 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     . . . 
     tgt.Justify(_L(“rstuvwxyz”),8,ECenter,‘@’); 
     In this call to Justify( ), the content of tgt changes to “rstuvwxy” as illustrated at FIG.  16 . Only eight of the nine characters in the source descriptor&#39;s data area are copied. 
     The following code fragments illustrate the use of AppendJustify( ). 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     tgt.AppendJustify(_L(“xyz”),8,ECenter,‘@’); 
     The descriptor tgt has a maximum length of 16 and initially holds the string “abc”. After the call to AppendJustify( ), the content of tgt changes to “abc@@xyz@@@” as illustrated at FIG.  17 . 
     The following code fragments illustrate the use of AppendJustify( ). 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     tgt.AppendJustify(_L(“xyz01234456’,789”),3,8,ECenter,‘@’); 
     The descriptor tgt has a maximum length of 16 and initially holds the string “abc”. After the call to AppendJustify( ), the content of tgt changes to “abc@@xyz@@@” as illustrated at FIG.  18 . 
     The following code fragment depited in FIG. 19 illustrates the use of ZeroTerminate( ). 
     . . . 
     TBuf&lt;8&gt; tgt(_L(“abcde”)); 
     . . . 
     tgt.ZeroTerminate( ) 
     . . . 
     The length of the descriptor tgt is 5 both before and after the call to ZeroTerminate( ). 
     The following code fragments extracted from the E3232def.h header file (see Appendix 1 for the SDK) show how this is implemented by defining the variant independent class names as appropriate. 
     #if defined(_UNICODE) 
     . . . 
     typedef TPtr 16  TPtr; 
     #else 
     . . . 
     typedef Ttr 8  TPtr; 
     . . . 
     #endif 
     Application code should avoid using ‘C’ style string literals directly. Instead, one should use the _S macro to create a ‘C’ style string of the appropriate width, returning a pointer of the appropriate type. Also, one should use the _L macro (_L for “literal”) to create a Descriptor of the appropriate type. See e32.macro._S and e32.macro._L for the definitions of these macros. 
     For example, 
     const TText* str=_S(“Hello”); 
     generates a string of single byte characters in an ASCII build but a string of double-byte characters in a UNICODE build. 
     _L(“Hello”); 
     generates an 8 bit Descriptor in an ASCII build and a 16 bit Descriptor in a UNICODE build. Always use _L(“abcdef”), for example, rather than plain “abcdef” as it will always construct a Descriptor of the correct variant. 
     Note that an 8 bit ‘C’ style string and an 8 bit pointer Descriptor can be explicitly constructed, independently of the build variant, by using the _S8 and _L8 macros respectively. The corresponding 16 bit versions, _S16 and _L16 are also available. See e32.macro._S8, e32.macro._L8, e32.macro._S16 and e32.macro._L16 for their definitions. 
     Length and Size 
     E3232.descriptors.length-and-size 
     A Descriptor characterizes the data it represents by the length of that data. The length of a Descriptor is the number of data items. For the 8 bit variants, the length of the Descriptor is the number of single-bytes of data it represents; for the 16 bit variants, the length of the Descriptor is the number of double-bytes of data it represents. 
     The size of a Descriptor is the number of bytes occupied by the Descriptor&#39;s data; this is not necessarily the same as the Descriptor&#39;s length. For the 8 bit variants, the size is the same as the length but for the 16 bit variants, the size is twice the length. Those Descriptors which allow their data to be modified are also characterized by their maximum length. For these Descriptors, the length of data represented can vary from zero up to and including this maximum value. The maximum length for any Descriptor is 2 28 . 
     Text and Binary Data 
     E3232.descriptors.text-and-binary 
     In ‘C’, strings are characterized by the need for a zero terminator to flag the end of the string. They suffer from a number of problems. In particular, they cannot include binary data within them (in case that data includes binary zeroes) and operations on them are, in general, inefficient. ‘C’ strings need to be handled in a different way to binary data, as reflected in the memxxx( ) and strxxx( ) function groups in the ANSI ‘C’ library. Descriptors allow strings and binary data to be represented in the same way; this allows the same functions to be used in both cases. For binary data, the 8 bit Descriptors should be used explicitly. The distinction between UNICODE and ASCH has no meaning for binary data. Note that there is no practical use for explicit 16 bit binary data. 
     Memory Allocation 
     E3232.descriptors.alloc 
     The Descriptor classes (except HBufC) behave as built-in types. They allocate no memory and have no destructors. This means that they can be orphaned on the stack in the same way as a built-in type. This is particularly important in situations where code can leave. (See E3232.exception.trap.cleanup.requirements for the implications of orphaning). An HBufC Descriptor object is allocated on the heap and cannot be created on the stack. 
     Exceptions 
     E3232.descriptors.exceptions 
     All parameters to Descriptor member functions are checked to ensure that the operations are correctly specified and that no data is written outside the Descriptor&#39;s data area. A particular consequence is that no member function can extend a modifiable Descriptor beyond its maximum allocated length. It is the programmer&#39;s responsibility to ensure that all Descriptors are sufficiently large to contain their data, either by making the original allocation large enough or by anticipating the need for a larger Descriptor and dynamically allocating one at run-time. The static approach is simpler to implement but if this were to prove wasteful in a specific case, then the dynamic approach could be more worthwhile. In the event of an exception, it can be safely assumed that no illegal access of memory has taken place and that no data has been moved or damaged. 
     The Descriptor Types 
     E3232.descriptors.types 
     There are three kinds of Descriptor object: 
     pointer Descriptors. 
     The Descriptor object is separate from the data it represents but is constructed for a pre-existing area in memory. They come in two forms: 
     a constant pointer Descriptor, TPtrC 
     a modifiable pointer Descriptor, TPtr 
     buffer Descriptors. 
     The data area is part of the Descriptor object. They come in two forms: 
     a constant buffer Descriptor, TBufC&lt;TInt S&gt; 
     a modifiable buffer Descriptor, TBuf&lt;TInt S&gt; 
     heap Descriptor. 
     The data area is part of the Descriptor object and the whole object occupies a cell allocated from the heap. This comes in only one form: 
     a constant heap Descriptor, HBufC 
     Pointer Descriptor—TPtrC 
     E3232.descriptors.buffer-descriptor.TPtrC 
     TPtrC is a constant Descriptor through which no data can be modified. All of its member functions (except the constructors) are constant. TPtrC is shown schematically at FIG.  1 . TPtrC is useful for referencing constant strings or data; for example, accessing text built into ROM resident code, or passing a reference to data in RAM which must not be modified through that reference. TPtr is derived from TDesC, which provides a large number of member functions for operating on its content; for example, locating characters within text or extracting portions of data. 
     Pointer Descriptor—TPtr 
     E3232.descriptors.buffer-descriptor.TPtr 
     TPtr is a modifiable pointer Descriptor through which data can be modified, provided that the data is not extended beyond the maximum length. The maximum length is set by the constructor. TPtr points directly to an area in memory containing the data to be modified. TPtr is shown schematically in FIGS. 2A and 2B. 
     The maximum number of data items that the area can contain is defined by the maximum length. The length of the TPtr indicates how many data items are currently contained within the data. When this value is less than the maximum, a portion of the data area is unused. TPtr is useful for constructing a reference to an area of RAM which contains data intended to be modified through that reference, or even to an area of RAM which contains no data yet but in which data will be constructed using the Descriptor reference and member functions. 
     TPtr is also useful for constructing a reference to a TBufC or an HBufC Descriptor which contain the data to be modified. A TPtr used in this way points to a TBufC or an HBufC Descriptor. The data contained by the TBufC or HBufC Descriptors can be modified through the TPtr. TPtr is derived from TDes which, in turn, is derived from TDesC. Therefore, it inherits all the const member functions defined in TDesC plus the member functions from TDes which can manipulate and change the data; for example, appending a character to the end of existing text. 
     Buffer Descriptor—TBufC&lt;TInt S&gt; 
     E3232.descriptors.buffer-descriptor.TBufC 
     TBufC is a buffer Descriptor containing a length followed by the data area. Data can be set into the Descriptor at construction time or by the assignment operator (operator=) at any other time. Data already held by the Descriptor is constant. TBufC is shown schematically at FIG.  3 . The length of a TBufC is defined by an integer template; for example, TBufC&lt;40&gt; defines a TBufC which can contain up to 40 data items. 
     TBufC is derived from TDesC, which provides a large number of member functions for operating on its content; for example, locating characters within text or extracting portions of data. TBufC provides the member function, Des( ), which creates a modifiable pointer Descriptor (a TPtr) to reference the TBufC. This allows the TBufC data to be changed through the TPtr, as indicated schematically at FIG.  4 . The maximum length of the TPtr is the value of the integer template parameter. 
     Buffer Descriptor—TBuf&lt;TInt S&gt; 
     E3232.descriptors.buffer-descriptor.TBuf 
     TBuf is a modifiable buffer Descriptor containing data which can be modified, provided that the data is not extended beyond its maximum length. TBuf is shown schematically at FIG.  5 . The maximum number of data items that the data area within TBuf can contain, is defined by the maximum length. The length of the Descriptor indicates how many data items are currently contained within the data area. When this value is less than the maximum, a portion of the data area is unused. The maximum length of a TBuf is defined by an integer template; for example, TBuf&lt;40&gt; defines a TBuf which can contain up to 40 data items (and no more!). A TBuf is useful for containing data which needs to be manipulated and changed but whose length will not exceed a known maximum; for example, word processor text. TBuf is derived from TDes which, in turn, is derived from TDesC. Therefore, it inherits all the const member functions defined in TDesC plus the member functions from TDes which can manipulate and change the data; for example, appending a character to the end of existing text. 
     Heap Descriptor—HBufC 
     E3232.descriptors.buffer-descriptor.HBufC 
     HBufC is a Descriptor containing a length followed by data It is allocated on the heap using the New( ), NewL( ) or NewLC( ) static member functions. The length of the Descriptor is passed as a parameter to these static functions. HBufC is shown schematically at FIG.  6 . Data can be set into the Descriptor at construction time or by the assignment operator (operator=) at any other time. Data already contained by the Descriptor is constant. HBufC is derived from TDesC, which provides a large number of member functions for operating on its content; for example, locating characters within text or extracting portions of data. 
     HBufC provides the member function, Des( ), which creates a modifiable pointer Descriptor (a TPtr) to reference the HBufC. This allows the HBufC data to be changed through the TPtr. The maximum length of the TPtr is the length of the HBufC data area. FIG. 7 illustrates this schematically. Heap Descriptors can be re-allocated. The ReAlloc( ) or ReAllocL( ) functions allow the heap Descriptor&#39;s data area to expand or contract. The length of the data area, however, cannot be made smaller than the length of data currently held. Before contracting the data area, the length of the data held by the Descriptor must be reduced. The length of data which the assignment operator can set into the heap Descriptor is limited by the space allocated to the Descriptor&#39;s data area The memory occupied by heap Descriptors must be explicitly freed either by calling User::Free( ) or by using the delete keyword. 
     The Descriptor Classes&#39; Relationships 
     E32.descriptors.classes 
     All of the Descriptor classes TPtrC, TPtr, TBufC, TBuf and HBufC are derived from the abstract base classes TDesC and TDes. The class TBufCBase, although marked as an abstract class, is merely an implementation convenience. FIG. 8 schematically illustrates the relationship between the classes. 
     The behaviour of the concrete Descriptor classes is very similar, and therefore, most of the functionality of Descriptors is provided by the abstract base classes. Because Descriptors are widely used (especially on the stack), the size of Descriptor objects must be kept to a minimum. To help with this, no virtual functions are defined in order to avoid the overhead of a virtual function table pointer in each Descriptor object. As a consequence, the base classes have implicit knowledge of the classes derived from them. E32 supplies two variants of the Descriptor classes, one for handling 8 bit (ASCII) text and binary data and the other for handling 16 bit (UNICODE) text. The 8 bit variants of the concrete classes are: TPtrC 8 , TPtr 8 , TBufC 8 &lt;TInt S&gt;, TBuf 8 &lt;TInt S&gt; and HBufC 8  while the 8 bit variants of the abstract classes are: TDesC 8 , TDes 8 . Similarly, the 16 bit variants are named: TPtrC, TPtr 16 , TBufC 16 &lt;TInt S&gt;, TBuf 16 &lt;TInt S&gt;, HBufC 16 , TDesC 16  and TDes 16  respectively. This distinction is transparent for Descriptors intended to represent text. By writing programs which construct and use TPtrC, TPtr, TBufC&lt;TInt S&gt;, TBuf&lt;TInt S&gt; and HBufC classes, compatibility is maintained between both UNICODE and ASCII. The appropriate variant is selected at build time depending on whether the _UNICODE macro has been defined or not. If the _UNICODE macro is defined, the 16 bit variant is used, otherwise the 8 bit variant is used as explained in e32descriptors.char-set 
     Descriptors for binary data must explicitly use the 8 bit variants; in other words, code must explicitly construct TPtrC 8 , TPtr 8 , TBufC 8 &lt;TInt S&gt;, TBuf 8 &lt;TInt S&gt; and HBufC 8  classes. Explicit use of the 16 bit variants for binary data is possible but not recommended. In general, 8 bit and 16 bit variants are identical in structure and implementation; the description of the classes themselves uses the build independent names throughout. 
     N.B. Many member functions take arguments which are either of type TUint 8 * or type TUint 16 * depending on whether the Descriptor is the 8 bit or 16 bit variant. To simplify explanation, these arguments are written in function prototypes as TUint??*. 
     Using Descriptors for Function Interfaces 
     e32.descriptors.using-function-interfaces 
     Many interfaces which use or manipulate text strings or general binary data use descriptors to specify the interface. In conventional ‘C’ programming, interfaces would be specified using a combination of char*, void* and length values. In E32 descriptors are always used. 
     There are four main cases: 
     Passing a constant string 
     In ‘C’: StringRead(const char* aString); 
     The length of the string is implied by the zero terminator; therefore, the function does not require the length to be explicitly specified. 
     In E32: StringRead(const TDesC&amp; aString); 
     The descriptor contains both the string and its length. 
     Passing a string which can be changed. 
     In ‘C’: StringWrite(char* aString, int aMaxLength); 
     The length of the passed string is implied by the zero terminator. aMaxLength indicates the maximum length to which the string may be extended. 
     In E32: StringWrite(TDes&amp; aString); 
     The descriptor contains the string, its length and the maximum length to which the string may be extended. 
     Passing a buffer containing general binary data 
     In ‘C’: BufferRead(const void* aBuffer, int aLength); 
     Both the address and length of the buffer must be specified. 
     In E32: BufferRead(const TDes 8 &amp; aBuffer); 
     The descriptor contains both the address and the length of the data. The 8 bit variant is explicitly specified; the buffer is treated as byte data, regardless of the build variant. 
     Passing a buffer containing general binary data which can be changed. 
     In ‘C’: 
     BufferWrite(void* aBuffer, int&amp; aLength, int aMaxLength); 
     The address of the buffer, the current length of the data and the maximum length of the buffer are specified. The aLength parameter is specified as a reference to allow the function to indicate the length of the data on return. 
     In E32: BufferRead(TDes 8 &amp; aBuffer); 
     The descriptor contains the address, the length of the data and the maximum length. The 8 bit variant is explicitly specified; the buffer is treated as byte data, regardless of the build variant. 
     Folding and Collating 
     e32.descriptors.folding-collating 
     There are two techniques that may be used to modify the characters in a descriptor prior to performing some operations on text: 
     folding 
     collating 
     Variants of member functions that fold or collate are provided where appropriate. 
     Folding 
     e32.descriptors.folding 
     Folding means the removal of differences between characters that are deemed unimportant for the purposes of inexact or case-insensitive matching. As well as ignoring differences of case, folding ignores any accent on a character. By convention, folding converts lower case characters into upper case and removes any accent. 
     Collating 
     e32.descriptors.collating 
     Collating means the removal of differences between characters that are deemed unimportant for the purposes of ordering characters into their collating sequence. For example, collate two strings if they are to be arranged in properly sorted order, this may be different from a strict alphabetic order. 
     Using Descriptors 
     e32.descriptors.using 
     The following series of examples show how descriptors can be used. Specifically, the examples illustrate: 
     the basic concepts of the pointer descriptors, TPtrC and TPtr. See e32.descriptors.using.pointer-descriptors. 
     the basic concepts of the buffer descriptors, TBufC and TBuf. See e32.descriptors.using.buffer-descriptors. 
     how descriptors can represent general binary data. See e32.descriptors.using.general-binary-data. 
     some of the member functions which do not modify the content of a descriptor. See e32.descriptors.using.non-modifying-functions. 
     some of the member functions which modify the content of a descriptor. See e32.descriptors.using.modifying-functions. 
     how descriptors can be used in interfaces. See e32.descritpors.using.interface-specifiers. 
     the basic concepts of the heap descriptor, HBufC. See e32.descritpors.using.heap-descriptors. 
     Pointer Descriptors 
     e32.descriptors.using.pointer-descriptors 
     The code fragments shown here to illustrate the use of pointer descriptors are extracted from the sample source code in the eudesptr project. Run the code in this project to see pointer descriptors in action. 
     TPtrC 
     The 8 bit variant 
     A TPtrC is useful for referencing constant strings or data; for example, accessing text built into ROM resident code, or passing a reference to data in RAM which must not be modified through that reference. 
     For example, define a constant ‘C’ style ASCII string: 
     const TText 8 * cstr 8 =(TText 8 *)“Hello World!”; 
     A TPtrC 8  descriptor can be constructed to represent this pre-defined area containing the string “Hello World!”: 
     TPtrC 8  ptrC 8 (cstr 8 ); 
     The descriptor is separate from the data it represents. 
     While the length of the ‘C’ string is 12, its size is 13 to allow for the zero terminator. From the descriptor&#39;s viewpoint, both the length and the size of the data is 12. The descriptor uses the length to determine the amount of data represented. The address of the descriptor&#39;s data area, as returned by: 
     ptrC 8 .Ptr( ); 
     is the same as same as the address of the original ‘C’ string, cstr 8 . 
     The 16 bit variant (UNICODE) 
     Similarly, define a constant ‘C’ style string of wide (or UNICODE) characters: 
     const TText 16  cstr 16 =(TText 16 )L“Hello World!”; 
     A TPtrC descriptor can be constructed to represent this area containing the string of double-byte characters “Hello World!”: 
     TPtrC ptrC(cstr 16 ); 
     Again, the descriptor is separate from the data it represents. The length of the descriptor, as returned by a call to ptrc 16 .Length( ), is 12 as it represents 12 text characters but the size, as returned by a call to ptrc 16 .Size( ), is now 24 as each character occupies 2 bytes. Again, the address of the descriptor&#39;s data area, as returned by: 
     ptrc 16 .Ptr( ); 
     is the same as the address of the original ‘C’ string, cstr 16 . 
     The _S macro and build independent names 
     Use the _S macro to define a constant ‘C’ style string of the appropriate width. The TText variant is defined at build time (as either TText 8  or TText 16 ) depending on whether the _UNICODE macro has been defined. For example: 
     const TText* cstr=_S(“Hello World!”); 
     The TPtrC descriptor: 
     TPtrC ptrc(cstr); 
     represents the area containing the text “Hello World!”; the TPtrC variant is defined at build time (as either TPtrC 8  or TPtr 16 ) depending on whether the _UNICODE macro has been defined. 
     The length of the descriptor, as returned by ptrc.Length( ), is 12 for all build variants but the size of the descriptor, as returned by ptrc.Size( ) is 12 for an ASCII build and 24 for a UNICODE build. 
     See e32.macro._S. 
     The _L macro 
     The _L macro constructs a TPtrC of the correct variant and is frequently used as a source descriptor when constructing a buffer descriptor or a heap descriptor. 
     The macro is also useful for constructing a TPtrC to be passed as a parameter to a function. For example, the Printf( ) member function of the RTest class used in these examples requires a descriptor as its first parameter. Here, the _L macro constructs a TPtrC representing the constant static area generated by the compiler containing the text “\nThe _L macro constructs a TPtrC”. 
     testConsole.Printf(_L(“\n The _L macro constructs a TPtrC”)); 
     See e32.macro._L. 
     TPtr 
     A TPtr is a modifiable pointer descriptor through which data can be modified, provided that the data is not extended beyond the maximum length. The maximum length is set by the constructor. 
     For example, define a TText area initialised to contain the string “Have a nice day”:            TText                   str        [   16   ]         =     {       H       ′           ′     ,     a       ′           ′     ,     v       ′           ′     ,     e       ′           ′            ,   ′     ′     ,     a       ′           ′            ,   ′     ′     ,     n       ′           ′     ,     i       ′           ′     ,     c       ′           ′     ,     e       ′           ′            ,   ′     ′     ,     d       ′           ′     ,     a       ′           ′     ,     y       ′           ′     ,     \0       ′           ′       }       ;                          
     A TPtr descriptor can be constructed to represent the data in this area; further, this data can be changed, contracted and expanded provided that the length of the data does not exceed the maximum. 
     TPtr ptr(&amp;str[ 0 ],15,16); 
     The descriptor ptr represents the data in str and is constructed to have a current length of 15 (the length of the text, excluding the zero terminator) and a maximum length of 16 (the actual length of str). Once the descriptor has been constructed, it has no farther use for the zero terminator. 
     The data can be completely replaced using the assignment operator: 
     ptr=_L(“Hi there”); 
     Note the use of the _L macro to construct a TPtrC of the correct build variant as the source of the assignment. 
     The length of ptr is now 8 but the maximum length remains 16. The size depends on the build variant. In an ASCII build, this is 8 but in a UNICODE build, this becomes 16 (two bytes for every character). 
     The length of the data represented can be changed. For example, after ptr.SetLength(2), the descriptor represents the text “Hi”. The length can even be set to zero so that after ptr.Zero( ), the descriptor represents no data. Nevertheless, the maximum length remains at 16 so that: 
     ptr=_L(“Have a nice day!”); puts the 16 characters “Have a nice day” into the descriptor&#39;s data area. 
     See also e32.macro._L. 
     Buffer Descriptors 
     e32.descriptors.using.buffer-descriptors 
     The code fragments shown here to illustrate the use of buffer descriptors are extracted from the sample source code in the eudesbuf project. Run the code in this project to see buffer descriptors in action. 
     TBufC 
     A TBufC is a buffer descriptor where the data area is part of the descriptor itself. 
     Data can be set into the descriptor at construction time or by the assignment operator at any other time. Data already held by the descriptor cannot be modified but it can be completely replaced (again, using the assignment operator). 
     For example: 
     TBufC&lt;16&gt; bufc 2 (_L(“Hello World!”)); 
     constructs a TBufC which can contain up to 16 data items. During construction, the descriptor&#39;s data area is set to contain the text “Hello World!” and the length of the descriptor is set to 12. 
     The data within bufc 2  cannot be modified but it can be replaced using the assignment operator: 
     bufc 2 =_L(“Replacement text”); 
     To prevent any possibility of replacing the data, declare bufc 2  as const. 
     The data within a TBufC can be changed by constructing a TPtr from the TBufC using the Des( ) member function; the data can then be changed through the TPtr. The maximum length of the TPtr is the value of the TBufC template parameter. For example: 
     bufc 2 =_L(“Hello World!”); 
     TPtr ptr=bufc 2 .Des( ); 
     ptr.Delete((ptr.Length( )-1),1); 
     ptr.Append(_L(“&amp; Hi”)); 
     This deletes the last character in the TBufC and adds the characters “&amp; Hi” so that the TBufC now contains the text “Hello World &amp; Hi” and its length is 16. Note that the length of both the TBufC and the TPtr reflect the changed data. 
     TBuf 
     A TBuf is a modifiable buffer descriptor where the data area is part of the descriptor itself. The data can be modified provided that the data is not extended beyond the maximum length. The maximum length is set by the constructor. 
     For example: 
     TBuf&lt;16&gt; buf(_L(“Hello World!”)); 
     constructs a TBuf which can contain up to 16 data items. During construction, the descriptor&#39;s data area is set to contain the text “Hello World!”, the length of the descriptor is set to 12 and its maximum length is set to 16. 
     The data can be modified directly: 
     buf.Append(‘@’); 
     changes buf&#39;s data to “Hello World!@” and its length to 13 while: 
     buf.SetLength(3); 
     changes it length to 3 and its data to “Hel”. 
     The maximum length of the descriptor always remains at 16. 
     Like a TBufC descriptor, the data contained within a TBuf can be replaced entirely using the assignment operator: 
     buf=_L(“Replacement text”); 
     replaces “Hello World” with “Replacement text” and changes the length of the descriptor to 16. 
     An attempt to increase the length of the data beyond the maximum generates an exception (a panic). For example: 
     buf=_L(“Text replacement causes panic!”); 
     generates a panic at run time because the length of the replacement text (30) is greater than the maximum (16). 
     General Binary Data 
     e32.descriptors.using.general-binary-data 
     The code fragments shown here, illustrating how descriptors can handle, general binary data, are extracted from the sample source code in the eudesbin project. Run the code in this project to see the sample in action. 
     The kind of data represented or contained by descriptors is not restricted to text. Descriptors can also handle general binary data. 
     To deal with general binary data, always explicitly construct an 8 bit variant descriptor. Binary data should always be treated as 8 bit data regardless of the build. 
     For example set up an area in memory initialised with binary data: 
     TUint 8  data[ 6 ]={0x00,0x01,0x02,0xAD,0xAE,0xAF}; 
     Construct a modifiable buffer descriptor using the default constructor: 
     TBuf 8 &lt;32&gt; buffer; 
     The following code extracted from the eudesbin project puts the binary data into the descriptor, appends a number of single byte values and then displays the data at the test console. The length of the buffer is 9, the maximum length is 32 and the size is 9 regardless of the build. 
     
       
         
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 TInt index; 
               
               
                   
                 TInt counter; 
               
               
                   
                 buffer.Append(&amp;data[0],sizeof(data)); 
               
               
                   
                 buffer.Append(0xFD); 
               
               
                   
                 buffer.Append(0xFE); 
               
               
                   
                 buffer.Append(0xFF); 
               
               
                   
                 counter = buffer.Length( ); 
               
               
                   
                 for (index = 0; index &lt; counter; index++) 
               
             
          
           
               
                   
                 testConsole.Printf(_L(“0x%02x”),buffer[index]); 
               
             
          
           
               
                   
                 testConsole.Printf(_L(“; Length( )=%d;\n”), 
               
             
          
           
               
                   
                 buffer.Length( ) 
               
             
          
           
               
                   
                 ); 
               
             
          
           
               
                   
                 testConsole.Printf(_L(“Size( )=%d; MaxLength( )=%d\n”), 
               
             
          
           
               
                   
                 buffer.Size( ), 
               
               
                   
                 buffer.MaxLength( ) 
               
             
          
           
               
                   
                 ); 
               
             
          
           
               
                   
                 Text and general binary data can be freely mixed; so that: 
               
             
          
           
               
                   
                 buffer.Append(‘A’); 
               
               
                   
                 buffer.Append(‘B’); 
               
               
                   
                 buffer.Append(0x11); 
               
             
          
           
               
                   
                 is acceptable. 
               
               
                   
                   
               
             
          
         
       
     
     Non-modifying Functions 
     e32.descriptors.using.non-modifying-functions 
     The code fragments shown here, illustrating some of the non-modifying descriptor member functions, are extracted from the sample source code in the eudesc project. Look at the code in this project to see the full set of examples 
     These examples all use a TBufC descriptor constructed to contain the text “Hello World!”. Note also that the descriptor is declared const so that its data cannot be replaced using the assignment operator: 
     const TBufC&lt;16&gt; bufc(_L(“Hello World!”)); 
     Right( ) &amp; Mid( ) 
     These functions construct a TPtrc to represent a portion of bufc&#39;s data 
     TPtrC ptrc 1 =bufc.Right(5); ptrc 1  represents the right hand 5 data items in bufc. ptrc 1 &#39;s data is “orld!”, its length is 5 and the address of its data area is the address of bufc&#39;s data area plus 7. 
     The Left( ) member function works in a similar way. 
     TPtrC ptrc 2 =bufc.Mid(3,6); 
     ptrc 2  represents the 6 data items offset 3 from the start of bufc&#39;s data area ptrc 2 &#39;s data is “lo Wor”, its length is 6 and the address of its data area is the address of bufc&#39;s data area plus 3. 
     In practice, it may not be necessary to assign the returned TPtrC to another TPtrC. For example, the following code puts a value of 3 in pos; this is the offset of char ‘W’ within the chars “lo Wor” (see later for an explicit example of Locate( )) 
     TInt pos; 
     . . . 
     pos=(bufc.Mid(3,6)).Locate(‘W’); 
     These functions can panic. For example, requesting the 13 right hand data items in bufc will cause an exception (there are only 12): 
     TPtrC ptrc 3 =bufc.Right(13); 
     Compare( ) &amp; CompareF( ) 
     The compare functions can be used to compare the content of two descriptors. Any kind of data can be compared. For binary data, use Compare( ). For text use Compare( ), CompareF( ) or CompareC( ). 
     The following example compares the content of bufc with the content of a number of descriptors and displays the results at the test console: 
     
       
         
               
               
             
               
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TInt index; 
               
               
                   
                 . . . 
               
               
                   
                 TPtrC   genptr; 
               
               
                   
                 const TBufC&lt;19&gt;lessthan(_L(“ is less than  ”)); 
               
               
                   
                 const TBufC&lt;19&gt;greaterthan(_L(“ is greater than ”)); 
               
               
                   
                 const TBufC&lt;19&gt;equalto(_L(“ is equal to  ”)); 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 const TBufC&lt;16&gt;compstr[7] = 
                 {_L(“Hello World!@@”), 
               
               
                   
                   
                 _L(“Hello”), 
               
               
                   
                   
                 _L(“Hello Worl”), 
               
               
                   
                   
                 _L(“Hello World!”), 
               
               
                   
                   
                 _L(“hello world!”), 
               
               
                   
                   
                 _L(“Hello World”), 
               
               
                   
                   
                 _L(“Hello World@”), 
               
               
                   
                   
                 }; 
               
             
          
           
               
                   
                 for (index = 0; index &lt; 7; index++) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 if( (bufc.Compare(compstr[index])) &lt; 0) 
               
             
          
           
               
                   
                 genptr.Set(lessthan); 
               
             
          
           
               
                   
                 else if( (bufc.Compare(compstr[index])) &gt; 0) 
               
             
          
           
               
                   
                 genptr.Set(greaterthan); 
               
             
          
           
               
                   
                 else genptr.Set(equalto); 
               
             
          
           
               
                   
                 testConsole.Printf(_L(“\”%S\“%S\”%S\“\n”), 
               
             
          
           
               
                   
                 &amp;bufc, 
               
               
                   
                 &amp;genptr, 
               
               
                   
                 &amp;compstr[index] 
               
               
                   
                 ); 
               
             
          
           
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     The case of text is important using Compare( ); the fourth comparison is equal but the fifth comparison is not (the ‘w’ characters are a different case). 
     Using CompareF( ), the case is not important; both the fourth and fifth comparisons return an equal result. 
     Locate( ), LocateF( ) &amp; LocateReverse( ) 
     The locate functions can be used to find the position (offset) of a character within text or a specific value within general binary data. 
     The following example attempts to find the positions (i.e. the offsets) of the characters ‘H’, ‘!’, ‘o’ and ‘w’ within the text “Hello World!” and displays the result at the test console: 
     
       
         
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
               
             
             
               
                 . . . 
               
               
                 TInt index; 
               
               
                 TInt pos; 
               
               
                 TPtrC genptr; 
               
               
                 const TBufC&lt;9&gt; notfound(_L(“NOT FOUND”)), 
               
               
                 const TBufC&lt;5&gt; found(_L(“found”)); 
               
               
                 . . . 
               
               
                 TChar ch[4] = {‘H’, ‘!’, ‘o’, ‘w’}; 
               
               
                 . . . 
               
               
                 testConsole.Printf(_L(“using Locate( )\n”)); 
               
               
                 for (index = 0 ; index &lt; 4; index++) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 pos = bufc.Locate(ch[index]); 
               
               
                   
                 if (pos &lt; 0) 
               
             
          
           
               
                   
                 genptr.Set(notfound); 
               
             
          
           
               
                   
                 else 
               
             
          
           
               
                   
                 genptr.Set(found); 
               
             
          
           
               
                   
                 testConsole.Printf(_L(“\”%S\“ Char %c is at pos %d (%S)\n”), 
               
             
          
           
               
                   
                 &amp;bufc, 
               
               
                   
                 ch[index], 
               
               
                   
                 pos, 
               
               
                   
                 &amp;genptr 
               
               
                   
                 ); 
               
             
          
           
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     The character ‘w’ is not found using Locate( ) but is found using LocateF( ). This is because Locate( ) is case sensitive while LocateF( ). 
     This example uses LocateReverse( ) which is used to find the position of a character starting from the end of the descriptor&#39;s data area 
     
       
         
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
               
             
             
               
                 . . . 
               
               
                 testConsole.Printf(_L(“using LocateReverse( )\n”)); 
               
               
                 for (index = 0 ; index &lt; 4; index++) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 pos = bufc.LocateReverse(ch[index]); 
               
               
                   
                 if(pos &lt; 0) 
               
             
          
           
               
                   
                 genptr.Set(notfound); 
               
             
          
           
               
                   
                 else 
               
             
          
           
               
                   
                 genptr.Set(found); 
               
             
          
           
               
                   
                 testConsole.Printf(_L(“\”%S\“ Char %c is at pos %d (%S)\n”), 
               
             
          
           
               
                   
                 &amp;bufc, 
               
               
                   
                 ch[index], 
               
               
                   
                 pos, 
               
               
                   
                 &amp;genptr 
               
             
          
           
               
                   
                 ); 
               
             
          
           
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     Note that the 2nd char ‘o’ in the string “Hello World!” is found this time. 
     Match( ) &amp; MatchF( ) 
     The following example shows the use of the Match( ) and MatchF( ) member functions. The result of a matches between the content of buf and a series of descriptors with varying combinations of match strings is displayed at the test console. 
     
       
         
               
               
             
               
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TInt index; 
               
               
                   
                 TInt pos; 
               
               
                   
                 TPtrC genptr; 
               
               
                   
                 const TBufC&lt;9&gt; notfound(_L(“NOT FOUND”)); 
               
               
                   
                 const TBufC&lt;5&gt; found(_L(“found”)); 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 TBufC&lt;8&gt;matchstr[7] = 
                 {_L(“*World*”), 
               
               
                   
                   
                 _L(“*W?rld*”), 
               
               
                   
                   
                 _L(“*Wor*”), 
               
               
                   
                   
                 _L(“Hello”), 
               
               
                   
                   
                 _L(“*W*”), 
               
               
                   
                   
                 _L(“hello”), 
               
               
                   
                   
                 _L(“*”), 
               
               
                   
                   
                 }; 
               
             
          
           
               
                   
                 for (index = 0 ; index &lt; 7; index++) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 pos = bufc.Match(matchstr[index]); 
               
               
                   
                 if(pos &lt; 0) 
               
             
          
           
               
                   
                 genptr.Set(notfound); 
               
             
          
           
               
                   
                 else 
               
             
          
           
               
                   
                 genptr.Set(found); 
               
             
          
           
               
                   
                 testConsole.Printf(_L(“%- 8S pos %2d (%S)\n”), 
               
             
          
           
               
                   
                 &amp;matchstr[index], 
               
               
                   
                 pos, 
               
               
                   
                 &amp;genptr 
               
             
          
           
               
                   
                 ): 
               
             
          
           
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     Note that when using MatchF( ), the result is different when matching the 6th string where the case is ignored. 
     Modifying Functions 
     e32.descriptors.using.modifying-functions 
     The code fragments shown here, illustrating some of the modifying descriptor member functions, are extracted from the sample source code in the eudes project. Look at the code in this project to see the full set of examples. 
     These examples all use a TBuf descriptor constructed to contain the text “Hello World!”. 
     TBuf&lt;32&gt; buf(_L(“Hello World!”)); 
     Swap( ) 
     The contents, length and size of altbuf 1  and buf are swapped; the maximum lengths of the descriptors do NOT change. 
     TBuf&lt;16&gt; altbuf 1 (_L(“What a nice day”)); 
     . . . 
     buf.Swap(altbuf 1 ); 
     Repeat( ) 
     The current length of buf is set to 16. Repeat copying the characters “Hello” generates the text sequence “HelloHelloHelloH” in buf. 
     buf.SetLength(16); 
     buf.Repeat(_L(“Hello”)); 
     Setting the length of buf to and re-doing the repeat generates the text sequence “HelloHel”. 
     Justify( ) 
     The example uses src as the source descriptor. 
     TBufVC&lt;40&gt; src(_“Hello World!”)); 
     . . . 
     buf.Justify(src,16,ELeft,‘@’); 
     The descriptor src has length 12. 
     The target field in buf has width 16 (this is greater than the length of the descriptor src). src is copied into the target field, aligned left and padded with ‘@’ characters. The length of buf becomes the same as the specified width, i.e 16. 
     buf.Justify(src,16,ECenter,‘@’); 
     The target field in buf has width 16 (this is greater than the length of the descriptor src). src is copied into target field, aligned centrally and padded with ‘@’ characters. The length of buf becomes the same as the specified width, i.e 16 
     buf.Justify(src,10,ECenter,‘@’); 
     The target field in buf has width 10 (this is smaller than the length of the descriptor src). src is copied into the target field but truncated to 10 characters and, therefore, alignment and padding information is not used. The length of buf becomes the same as the width, i.e. 10 
     buf.Justify(src,KDefaultJustifyWidth,ECenter,‘@’); 
     The target field in buf is set to the length of the descriptor src (whatever it currently is). src is copied into the target field. No padding and no truncation is needed and so the alignment and padding information is not used. The length of buf becomes the same as the length of src, i.e. 12. 
     Descriptors as Interface Specifiers 
     e32.descriptors.using.interface-specifiers 
     See the eudesint project for examples illustrating the use of descriptors in function interfaces. 
     Heap Descriptors 
     e32.descriptors.using.heap-descriptors 
     The code fragments shown here, illustrating the use of heap descriptors, are extracted from the sample source code in the eudeshbc project. Look at the code in this project to see the the sample in action. 
     An HBufC is always constructed on the heap using the static member functions New( ), NewL( ) or NewLC( ). For example: 
     HBufC* buf; 
     . . . 
     buf=HBufC::NewL(15); 
     This constructs an HBufC which can hold up to 15 data items. The current length is zero. Although existing data within an HBufC cannot be modified, the assignment operator can be used to replace that data For example: 
     *buf=_L(“Hello World!”); 
     To allow more than 15 characters or data items to be assigned into the HBufC, it must be reallocated first. For example: 
     buf=buf-&gt; ReAllocL(20); 
     This permits the following assignment to be done without causing a panic: 
     *buf=_L(“Hello World! Morning”); 
     buf may or may not point to a different location in the heap after relocation. The location of the reallocated descriptor depends on the heap fragmentation and the size of the new cell. 
     The Des( ) function returns a TPtr to the HBufC. The data in the HBufC can be modified through the TPtr. The maximum length of the TPtr is determined from the size of the cell allocated to the data area of the HBufC. For example: 
     TPtr ptr=buf-&gt; Des( ); 
     . . . 
     ptr.Delete((ptr.Length( )-9),9); 
     ptr.Append(_L(“&amp; Hi”)); 
     This changes the data in the HBufC and the length of the HBufC. 
     TPtrC Class Constant Pointer Descriptor 
     Overview 
     Derivation 
     TDesC Abstract: implements descriptor behaviour which does not modify data. 
     TPtrC A constant pointer descriptor. 
     Defined in 
     e32des8.h for the 8 bit variant (TPtr 8 ). 
     e32des16.h for the 16bit variant (TPtr 16 ). 
     Description 
     Create a TPtrC descriptor to access a pre-existing location in either ROM or RAM where the data at that location is to be accessed but not changed (or where the data cannot be changed). 
     A common use for a TPtrC is to access a string of text in a code segment. This will normally be constructed using the _L macro which constructs a TPtrC descriptor for either an ASCII or UNICODE build. 
     Often, a TPtrC will appear as the right hand side of an expression or as an initialisation value for another descriptor, for example: 
     TBuf&lt;16&gt; str(_L“abcdefghijklmnop”)); 
     . . . 
     str.Find(_L“abc”); 
     str.Find(_L“bcde”); 
     The _L macro expands to a TPtrC which is defined as either a TPtr 8  or TPtrC 16  depending on the build variant (TBuf is also defined in a similar way). 
     The 8 bit variant, TPtrC 8  can be constructed to access binary data The 8 bit variant is always explicitly used for binary data. 
     Five constructors are available to build a TPtr and include a default constructor. A TPtrC can be (re-)initialised after construction by using the set( ) functions. 
     All the member functions described under the TDesC class are available for use by a TPtrc descriptor. In summary these are: 
     
       
         
               
               
             
           
               
                   
               
             
             
               
                 Length( ) 
                 Fetch length of descriptor data. 
               
               
                 Size( ) 
                 Fetch the number of bytes occupied by 
               
               
                   
                 descriptor data. 
               
               
                 Ptr( ) 
                 Return a pointer to the descriptor data. 
               
               
                 Compare( ), 
                 Compare data (normally), (folded), (collated). 
               
               
                 CompareF( ), 
               
               
                 CompareC( ) 
               
               
                 Match( ), 
                 Pattern match data (normally), (folded), 
               
               
                 MatchF( ), MatchC( ) 
                 (collated). 
               
               
                 Locate( ), LocateF( ) 
                 Locate a character in forwards direction 
               
               
                   
                 (normally), (folded). 
               
               
                 LocateReverse( ), 
                 Locate a character in reverse direction 
               
               
                 LocateReverseF( ) 
                 (normally), (folded). 
               
               
                 Find( ), FindF( ), FindC 
                 Find data (normally), (folded), (collated). 
               
               
                 Left( ) 
                 Construct TPtrC for leftmost part of data. 
               
               
                 Right( ) 
                 Construct TPtrC for rightmost part of data. 
               
               
                 Mid( ) 
                 Construct TPtrC for portion of data. 
               
               
                 Alloc( ), 
                 Construct an HBufC for this descriptor. 
               
               
                 AllocL( ), AllocLC( ) 
               
               
                 HufEncode( ) 
                 Huffman encode 
               
               
                 HufDecode( ) 
                 Huffman decode 
               
               
                 operators &lt; &lt;= &gt; &gt;= == 
                 Comparison operators 
               
               
                 operator [ ] 
                 Indexing operator 
               
               
                   
               
             
          
         
       
     
     Construction 
     e32.descriptors.TPtrC.construction 
     TPtrC( ) Default C++ constructor 
     Description 
     The default C++ constructor is used to construct a constant pointer descriptor. 
     The length of the constructed descriptor is set to zero and its pointer is set to NULL. 
     Notes 
     Use the Set( ) member function to initialise the pointer descriptor. 
     TPtrC( ) Copy constructor 
     TPtrC(const TPtrC&amp; aDes); 
     Description 
     The C++ copy constructor constructs a new TPtrC object from the existing one. 
     The length of the constructed descriptor is set to the length of aDes and is set to point to aDes&#39;s. data. 
     TPtrC( ) C++ constructor [with any descriptor] 
     TPtrC(const TDesC&amp; aDes); 
     Description 
     The C++ constructor is used to construct the TPtrC with any kind of descriptor. 
     The length of the constructed descriptor is set to the length of aDes, and it is set to point to aDes&#39;s data. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor used to construct the TPtrC. 
     Notes 
     If aDes is a reference to a heap descriptor (HBufC), then the data also resides on the heap. 
     TPtrC( ) C++ constructor [with zero terminated string] 
     TPtrC(const TText* aString); 
     Description 
     The C++ constructor is used to construct the TPtrC object with a zero terminated string. 
     The length of the descriptor is set to the length of the zero terminated string, excluding the zero terminator. 
     The constructed descriptor is set to point to the location of the string, whether in RAM or ROM. 
     Arguments 
     const TText* aString A pointer to the zero terminated used to construct the TPtrC. 
     TPtrC( )C++ constructor [with address and length] 
     TPtrC(const TUint??* aBuf,TInt aLength); 
     Description 
     The C++ constructor is used to construct the TPtrC with the memory address and length. 
     The length of the constructed descriptor is set to the value of aLength. 
     The constructed descriptor is set to point to the memory address supplied in aBuf; the address can refer to RAM or ROM. 
     Arguments 
     const TUint??* aBuf The address which is to be the data area of the constant pointer descriptor. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of the constructed constant pointer descriptor. 
      This value must be non-negative otherwise the constructor will panic with ETDes 8 LengthNegative for the 8 bit variant or ETDes 16 LengthNegative for the 16 bit variant. 
     Late Initialisation 
     e32.descriptors.TPtrC.late-initialisation 
     Set( ) Initialisation taking any descriptor 
     void Set(const TDesC&amp; aDes); 
     Description 
     Use this function to initialise (or re-initialise) a constant pointer descriptor using the content of any kind of descriptor. 
     The length of this constant pointer descriptor is set to the length of aDes. 
     This descriptor is set (or re-set) to point to aDes&#39;s data 
     Arguments 
     const TDesC&amp; aDes A reference to any descriptor whose content is to be used to initialise this constant pointer descriptor. 
     Notes 
     The Set( ) function can be used to initialise a constant pointer descriptor constructed using the default constructor. 
     If aDes is a reference to a heap descriptor (HBufC), then the data also resides on the heap. 
     Set( ) Initialisation taking address and length 
     void Set(const TUint??* aBuf,TInt aLength); 
     Use this function to initialise (or re-initialise) a constant pointer descriptor using the supplied memory address and length. 
     The length of this constant pointer descriptor is set to the value of aLength. 
     The descriptor is set to point to the memory address supplied in aBuf; the address can refer to RAM or ROM. 
     Arguments 
     const TUint??* aBuf The address which is to be the data area of the constant pointer descriptor. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of the constant pointer descriptor. 
      This value must be non-negative otherwise the constructor will panic with ETDes 8 LengthNegative for the 8 bit variant or ETDes 16 LengthNegative for the 16 bit variant. 
     Notes 
     The Set( ) function can be used to initialise a constant pointer descriptor constructed using the default constructor. 
     TPtr Class Modifiable Pointer Descriptor 
     Overview 
     Derivation 
     TDesC Abstract: implements descriptor behaviour which does not modify data. 
     TDes Abstract: implements descriptor behaviour which can change data. 
     TPtr A modifiable pointer descriptor. 
     Defined in 
     e32des8.h for the 8 bit variant (TPtr 8 ). 
     e32des16.h for the 16 bit variant (TPtr 16 ). 
     Description 
     Create a TPtr descriptor to access a pre-existing area or buffer in RAM where the contents of that buffer are to be accessed and manipulated. 
     A common use for a TPtr is to access the buffer of an existing TBufC or an HBufC descriptor using the Des( ) member functions (of TBufC and HBufC). For example: 
     TBufC&lt;8&gt; str(_L(“abc”)); 
     str.Des( ).Append(‘x’); 
     TPtr is defined as either a TPtr 8  or TPtr 16  depending on the build variant and can be used to access text. 
     The 8 bit variant, TPtr 8  can be constructed to access binary data. The 8 bit variant is always explicitly used for binary data 
     Two constructors are available to build a TPtr and include a default constructor. A TPtr can be (re-)initialised after construction by using the set( ) functions. 
     All the member functions described under the TDesC and TDes classes are available for use by a TPtr descriptor. In summary these are: 
     
       
         
               
               
             
           
               
                   
               
             
             
               
                 Length( ) 
                 Fetch length of descriptor data. 
               
               
                 Size( ) 
                 Fetch the number of bytes occupied by 
               
               
                   
                 descriptor data. 
               
               
                 Ptr( ) 
                 Fetch address of descriptor data. 
               
               
                 Compare( ), 
                 Compare data (normally), (folded), (collated). 
               
               
                 CompareF( ), 
               
               
                 CompareC( ) 
               
               
                 Match( ), 
                 Pattern match data (normally), (folded), 
               
               
                 MatchF( ), MatchC( ) 
                 (collated). 
               
               
                 Locate( ), LocateF( ) 
                 Locate a character in forwards direction 
               
               
                   
                 (normally), (folded). 
               
               
                 LocateReverse( ), 
                 Locate a character in reverse direction 
               
               
                 LocateReverseF( ) 
                 (normally), (folded). 
               
               
                 Find( ), FindF( ), FindC 
                 Find data (normally), (folded), (collated). 
               
               
                 Left( ) 
                 Construct TPtrC for leftmost part of data. 
               
               
                 Right( ) 
                 Construct TPtrC for rightmost part of data. 
               
               
                 Mid( ) 
                 Construct TPtrC for portion of data. 
               
               
                 Alloc( ), 
                 Construct an HBufC for this descriptor. 
               
               
                 AllocL( ), AllocLC( ) 
               
               
                 HufEncode( ) 
                 Huffman encode 
               
               
                 HufDecode( ) 
                 Huffman decode 
               
               
                 MaxLength( ) 
                 Fetch maximum length of descriptor. 
               
               
                 MaxSize( ) 
                 Fetch maximum size of descriptor 
               
               
                 SetLength( ) 
                 Set length of descriptor data 
               
               
                 Zero( ) 
                 Set length of descriptor data to zero 
               
               
                 SetMax( ) 
                 Set length of descriptor data to the 
               
               
                   
                 maximum value. 
               
               
                 Swap( ) 
                 Swap data between two descriptors. 
               
               
                 Copy( ), 
                 Copy data (normally), (and fold), (and collate). 
               
               
                 CopyF( ), CopyC( ) 
               
               
                 CopyLC( ) 
                 Copy data and convert to lower case. 
               
               
                 CopyUC( ) 
                 Copy data and convert to upper case 
               
               
                 CopyCP( ) 
                 Copy data and capitalise 
               
               
                 Repeat( ) 
                 Copy and repeat. 
               
               
                 Justify( ) 
                 Copy and justify. 
               
               
                 Insert( ) 
                 Insert data. 
               
               
                 Delete( ) 
                 Delete data. 
               
               
                 Replace( ) 
                 Replace data. 
               
               
                 TrimLeft( ) 
                 Delete spaces from left side of data area. 
               
               
                 TrimRight( ) 
                 Delete spaces from right side of data area. 
               
               
                 Trim( ) 
                 Delete spaces from both left and right side of 
               
               
                   
                 data area. 
               
               
                 Fold( ) 
                 Fold characters. 
               
               
                 Collate( ) 
                 Collate characters. 
               
               
                 LowerCase( ) 
                 Convert to lower case. 
               
               
                 UpperCase( ) 
                 Convert to upper case. 
               
               
                 Capitalise( ) 
                 Capitalise. 
               
               
                 Fill( ) 
                 Fill with specified character. 
               
               
                 FillZ( ) 
                 Fill with 0x00. 
               
               
                 Num( ) 
                 Convert numerics to character (hex.digits to 
               
               
                   
                 lower case). 
               
               
                 NumUC( ) 
                 Convert numerics to (upper case) character. 
               
               
                 Format( ), 
                 Convert multiple arguments to character 
               
               
                 FormatList( ) 
                 according to format specification. 
               
               
                 Append( ) 
                 Append data. 
               
               
                 AppendFill( ) 
                 Append with fill characters. 
               
               
                 AppendJustify( ) 
                 Append data and justify 
               
               
                 AppendNum( ) 
                 Append from converted numerics. 
               
               
                 AppendNumUC( ) 
                 Append from converted numerics; convert to 
               
               
                   
                 upper case. 
               
               
                 AppendFormat( ), 
                 Append from converted multiple arguments. 
               
               
                 AppendFormatList( ) 
               
               
                 ZeroTerminate( ) 
                 Append zero terminator. 
               
               
                 PtrZ( ) 
                 Append zero terminator and return a pointer. 
               
               
                 operators &lt; &lt;= &gt; &gt;= == 
                 Comparison operators. 
               
               
                 operator += 
                 Appending operator. 
               
               
                 operator [ ] 
                 Indexing operator. 
               
               
                   
               
             
          
         
       
     
     Construction 
     e32.descriptors.TPtr.construction 
     TPtr( ) C++ constructor [with address and maximum length] 
     TPtr(TUint??* aBuf,TInt aMaxLength); 
     Description 
     The C++ constructor is used to construct the TPtr with the address and maximum length. 
     The length of the constructed descriptor is set to zero and its maximum length is set to aMaxLength. 
     The constructed descriptor is set to point to the memory address supplied in aBuf which can refer either to RAM or ROM. 
     Arguments 
     TUint??* aBuf The address which is to be the data area of the modifiable pointer descriptor. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aMaxLength The maximum length of the new modifiable pointer descriptor. 
      This value must be non-negative otherwise the constructor will panic with ETDes 8 MaxLengthNegative for the 8 bit variant or ETDes 16 MaxLengthNegative for the 16 bit variant. 
     TPtr( ) C++ constructor [with address, length and maximum length] 
     TPtr(TUint??* aBuf,TInt aLength,TInt aMaxLength); 
     Description 
     The C++ constructor is used to construct the TPtr with the address, length and maximum length. 
     Use this to construct a modifiable pointer descriptor using the supplied memory address, length and maximum length to initialise it. 
     The length of the constructed descriptor is set to aLength and its maximum length is set to aMaxLength. 
     The constructed descriptor is set to point to the memory address supplied in aBuf which can refer either to RAM or ROM. 
     Arguments 
     TUint??* aBuf The address which is to be the data area of the modifiable pointer descriptor. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of the new modifiable pointer descriptor. 
      This value must be non-negative and not greater than the value of aMaxLength otherwise the constructor will panic with ETDes 8 LengthOutOfRange for the 8 bit variant or ETDes 8 LengthOutOfRange for 16 bit variant. 
     TInt aMaxLength The maximum length of the new modifiable pointer descriptor. 
      This value must be non-negative otherwise the constructor will panic with ETDes 8 MaxLengthNegative for the 8 bit variant or ETDes 16 MaxLengthNegative for 16 bit variant. 
     Late Initialisation 
     e32.descriptors.TPtr.late-initialisation 
     Set( ) Initialisation by copying a TPtr 
     void Set(TPtr&amp; apt); 
     Use this function to initialise (or re-initialise) a modifiable pointer descriptor using the content of another modifiable pointer descriptor. The function behaves as a copy constructor. 
     The length of the descriptor is set to the length of aPtr and its maximum length is set to the maximum length of aPtr. 
     The descriptor is set (or re-set) to point to aPtr&#39;s data. 
     Arguments 
     TPtr&amp; aPtr A reference to a modifiable pointer descriptor whose content is to be used to initialise this modifiable pointer descriptor. 
     Set( ) Initialisation taking address, length and maximum length 
     void Set(TUint??* aBuf,TInt aLength,TInt aMaxLength); 
     Use this function to initialise (or re-initialise) a modifiable pointer descriptor using the supplied memory address, length and maximum length. 
     The length of the resulting descriptor is set to the value of aLength and its maximum length is set to the value of aMaxLength. 
     The descriptor is set (or re-set) to point to the memory address supplied in aBuf; the address can refer to RAM or ROM. 
     Arguments 
     TUint??* aBuf The address which is to be the data area of the modifiable pointer descriptor. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of the modifiable pointer descriptor. 
      This value must be non-negative and not greater than the value of aMaxLength otherwise the constructor will panic with ETDes 8 LengthOutOfRange for the 8 bit variant or ETDes 16 LengthOutOfRange for the 16 bit variant 
     TInt aMaxLength The maximum length of the modifiable pointer descriptor. This value must be non-negative otherwise the constructor will panic with ETDes 8 MaxLengthNegative for the 8 bit variant or ETDes 16 MaxLengthNegative for the 16 bit variant 
     Assignment Operators 
     e32.descriptors.TPtr.assignment-operators 
     See also e32.descriptors.TDes.assignment-operators. 
     operator= Operator=taking a TPtr 
     TPtr&amp; operator=(const TPtr&amp; aDes); 
     Description 
     This assignment operator copies a modifiable pointer descriptor to this modifiable pointer descriptor. 
     aDes&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aDes. 
     Arguments 
     const TPtr&amp; aDes A reference to the modifiable pointer descriptor whose data is to be copied. 
     Return value 
     TPtr&amp; A reference to this descriptor. 
     Notes 
     The length of aDes must not be greater than the maximum length of this descriptor otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     operator= Operator=taking any descriptor 
     TPtr&amp; operator=(const TDesC&amp; aDes); 
     Description 
     This assignment operator copies the content of any type of descriptor, aDes, to this modifiable pointer descriptor. 
     aDes&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aDes. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose data is to be copied. 
     Return value 
     TPtr&amp; A reference to this descriptor. 
     Notes 
     The length of aDes must not be greater than the maximum length of this descriptor otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     operator= Operator=taking a zero terminated string 
     TPtr&amp; operator=(const TText aString); 
     Description 
     This assignment operator copies a zero terminated string, excluding the zero terminator, into this modifiable pointer descriptor. 
     The copied string replaces the existing content of this descriptor. 
     The length of this descriptor is set to the length of the string (excluding the zero terminator). 
     Arguments 
     const TText* aString The address of the zero terminated string to be copied. 
     Return value 
     TPtr&amp; A reference to this descriptor. 
     Notes 
     The length of the string, excluding the zero terminator, must not be greater than the maximum length of this descriptor otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     TBufC&lt;TInt S&gt; Class Constant Buffer Descriptor 
     Overview 
     Derivation 
     TDesC Abstract: implements descriptor behaviour which does not modify data. 
     TBufCBase Abstract: implementation convenience. 
     TBufC&lt;TInt S&gt; A constant buffer descriptor. 
     Defined in 
     e32des8.h for the 8 bit variant (TBufC 8 &lt;TInt S&gt;). 
     e32des16.h for the 16 bit variant (TBufC16&lt;TInt S&gt;) 
     Description 
     Create a TBufC descriptor to provide a buffer of fixed length for containing and accessing constant data. 
     The data held in a TBufC descriptor cannot be modified, although it can be replaced. 
     Four constructors are available to build a TBufC descriptor and include a default constructor. The content of TBufC descriptor can be replaced after construction using the assignment operators. 
     For example, to create a buffer of length 16 set to contain the characters “ABC” 
     TBufC&lt;16&gt; str(_L(“ABC”)); 
     The content cannot be modified but may be replaced, for example: 
     str=_L(“xyz”), 
     To create a buffer which is intended to contain general binary data, explicitly construct the 8 bit variant of TBufC; for example, to create a 256 byte buffer: 
     TBufC 8 &lt;256&gt; buf; 
     . . . 
     buf= . . . ; 
     All the member functions described under the TDesC class are available for use by a TBufC descriptor. In summary these are: 
     
       
         
               
               
             
           
               
                   
               
             
             
               
                 Length( ) 
                 Fetch length of descriptor data. 
               
               
                 Size( ) 
                 Fetch the number of bytes occupied by 
               
               
                   
                 descriptor data. 
               
               
                 Ptr( ) 
                 Fetch address of descriptor data. 
               
               
                 Compare( ), 
                 Compare data (normally), (folded), (collated). 
               
               
                 CompareF( ), 
               
               
                 CompareC( ) 
               
               
                 Match( ), 
                 Pattern match data (normally), (folded), 
               
               
                 MatchF( ), MatchC( ) 
                 (collated). 
               
               
                 Locate( ), LocateF( ) 
                 Locate a character in forwards direction 
               
               
                   
                 (normally), (folded). 
               
               
                 LocateReverse( ), 
                 Locate a character in reverse direction 
               
               
                 LocateReverseF( ) 
                 (normally), (folded). 
               
               
                 Find( ), 
                 Find data (normally), (folded), (collated). 
               
               
                 FindF( ), FindC 
               
               
                 Left( ) 
                 Construct TPtrC for leftmost part of data. 
               
               
                 Right( ) 
                 Construct TPtrC for rightmost part of data. 
               
               
                 Mid( ) 
                 Construct TPtrC for portion of data. 
               
               
                 Alloc( ), 
                 Construct an HBufC for this descriptor. 
               
               
                 AllocL( ), AllocLC( ) 
               
               
                 HufEncode( ) 
                 Huffman encode 
               
               
                 HufDecode( ) 
                 Huffman decode 
               
               
                 operators &lt; &lt;= &gt; &gt;= == 
                 Comparison operators 
               
               
                 operator [ ] 
                 Indexing operator 
               
               
                   
               
             
          
         
       
     
     Construction 
     e32.descriptors.TBufC.construction 
     TBufC( ) Default C++ constructor 
     TfBufC( ); 
     Description 
     The default C++ constructor is used construct a non-modifiable buffer descriptor. 
     The integer template parameter&lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the descriptor object. 
     The length of the constructed descriptor is set to zero. 
     Notes 
     Use the assignment operators to initialise the non-modifiable buffer descriptor. 
     TBufC( ) Copy constructor 
     TBuf(const TBufC&lt;S&gt;&amp; aLcb); 
     Description 
     The C++ copy constructor constructs a new TBufC&lt;S&gt; object from the existing one. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor. 
     aLcb&#39;s data is copied into the constructed descriptor&#39;s data area. 
     The length of the constructed descriptor is set to the length of aLcb. 
     TBufC( ) C++ constructor [with any descriptor] 
     TBufC(const TDesC&amp; aDes); 
     Description 
     The C++ constructor is used to construct the TBufC&lt;S&gt; with any kind of descriptor. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor. 
     aDes&#39;s data is copied into the constructed descriptor&#39;s data area. 
     The length of the constructed descriptor is set to the length of aDes. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor used to construct the TBufC&lt;S&gt;. 
     Notes 
     The length of aDes must not be greater than the value of the integer template parameter &lt;TInt S&gt; otherwise the constructor will panic with ETDes 8 LengthOutOfRange for the 8 bit variant or ETDes 16 LengthOutOfRange for the 16 bit variant. 
     TBufC( ) C++ constructor[with zero terminated string] 
     TBufC(const TText* aString); 
     Description 
     The C++ constructor is used to construct the TBufC&lt;S&gt; with a zero terminated string. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor object. 
     The string, excluding the zero terminator, is copied into the constructed descriptor&#39;s data area. 
     The length of the constructed descriptor is set to the length of the string, excluding the zero terminator. 
     Arguments 
     const TText* aString The address of the zero terminated string used to construct the TBufC&lt;S&gt;. 
     Notes 
     The length of the string, excluding the zero terminator, must not be greater than the value of the integer template parameter &lt;TInt S&gt; otherwise the constructor will panic with ETDes 8 LengthOutOfRange for the 8 bit variant or ETDes 16 LengthOutOfRange for the 16 bit variant. 
     Create a Modifiable Pointer Descriptor 
     e32.descriptors.TBufC.create-TPtr 
     Des( ) Create &amp; return a TPtr 
     TPtr Des( ); 
     Description 
     Use this function to construct and return a modifiable pointer descriptor to represent this descriptor. 
     The content of a non-modifiable buffer descriptor cannot be altered but creating a modifiable pointer descriptor provides a mechanism for modifying that data. 
     The length of the new TPtr is set to the length of this descriptor. 
     The maximum length of the new TPtr is set to the value of the integer template parameter &lt;TInt S&gt;. 
     The new TPtr is set to point to this descriptor. This descriptor&#39;s data is neither copied nor moved. 
     This descriptor&#39;s data can be modified through the newly constructed TPtr. If there is any change to the length of the data, then the length of both this descriptor and the TPtr is modified to reflect that change. 
     Return value 
     TPtr A modifiable pointer descriptor representing this non-modifiable buffer descriptor. 
     Assignment Operators 
     e32.descriptors.TBufC.assignment-operators 
     See also e32.descriptors.TDes.assignment-operators. 
     operator= Operator=taking a TBufC&lt;S&gt; 
     TBufC&lt;S&gt;&amp; operator=(const TBufC&lt;S&gt;&amp; aLcb); 
     Description 
     This assignment operator copies the content of the non-modifiable buffer descriptor aLcb into this non-modifiable buffer descriptor. 
     aLcb&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aLcb. 
     Arguments 
     const TBufC&lt;S&gt;&amp; aLcb A reference to a non-modifiable buffer descriptor whose content is to be copied. 
     Return value 
     TBufC&lt;S&gt;&amp; A reference to this descriptor. 
     operator= Operator=taking any descriptor 
     TBufC&lt;S&gt;&amp; operator=(const TDesC&amp; aDes); 
     Description 
     This assignment operator copies the content of any type of descriptor aDes into this non-modifiable buffer descriptor. aDes&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aDes. 
     Arguments 
     const TDesc&amp; aDes A reference to any type of descriptor whose data is to be copied. 
     Return value 
     TBufC&lt;S&gt;&amp; A reference to this descriptor. 
     Notes 
     The length of aDes must not be greater than the value of the integer template parameter &lt;TInt S&gt; otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     operator=Operator=taking zero terminated string 
     TBufC&lt;S&gt;&amp; operator=(const TText* aString); 
     Description 
     This assignment operator copies a zero terminated string, excluding the zero terminator, into this non-modifiable buffer descriptor. 
     The copied string replaces the existing content of this descriptor. The length of this descriptor is set to the length of the string, excluding the zero terminator. 
     Arguments 
     const TText* aString The address of the zero terminated string to be copied. 
     Return value 
     TBufC&lt;S&gt;&amp; A reference to this descriptor. 
     Notes 
     The length of the string, excluding the zero terminator, must not be greater than the value of the template parameter &lt;TInt S&gt; otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     TBuf&lt;TInt S&gt; Class Modifiable Buffer Descriptor 
     Overview 
     Derivation 
     TDesC Abstract: implements descriptor behaviour which does not modify data. 
     TDes Abstract: implements descriptor behaviour which can change data. 
      A modifiable buffer descriptor. 
     TBuf&lt;TInt S&gt; 
     Defined In 
     e32des8.h for the 8 bit variant (TBuf&lt;TInt S&gt;). 
     e32des16.h for the 16 bit variant (TBuf&lt;TInt S&gt;). 
     Description 
     Create a TBuf descriptor to provide a buffer of fixed length for containing, accessing and manipulating data. 
     Five constructors are available to build a TBuf descriptor and include a default constructor. 
     The content of a TBuf descriptor can be replaced after construction using the assignment operators. 
     For example, to create a buffer of length 8 initially set to contain the characters “ABC” 
     TBuf&lt;8&gt; str(_L(“ABC”)); 
     The content of the buffer descriptor can be replaced provided the length of the new data does not exceed the value of the integer template parameter, for example: 
     str=_L(“xyz”); //OK 
     str=_L(“rstuvwxyz”); //causes an exception 
     To create a buffer which is intended to contain general binary data, explicitly construct the 8 bit variant TBuf 8 , for example, to create a 256 byte buffer: 
     TBuf 8 &lt;256&gt; buf; 
     . . . 
     buf= . . . ; 
     All the member functions described under the TDesC and TDes classes are available for use by a TBuf descriptor. In summary these are: 
     
       
         
               
               
             
           
               
                   
               
             
             
               
                 Length( ) 
                 Fetch length of descriptor data. 
               
               
                 Size( ) 
                 Fetch the number of bytes occupied by 
               
               
                   
                 descriptor data. 
               
               
                 Ptr( ) 
                 Fetch address of descriptor data. 
               
               
                 Compare( ), 
                 Compare data (normally), (folded), (collated). 
               
               
                 CompareF( ), 
               
               
                 CompareC( ) 
               
               
                 Match( ), 
                 Pattern match data (normally), (folded), 
               
               
                 MatchF( ), MatchC( ) 
                 (collated). 
               
               
                 Locate( ), LocateF( ) 
                 Locate a character in forwards direction 
               
               
                   
                 (normally), (folded). 
               
               
                 LocateReverse( ), 
                 Locate a character in reverse direction 
               
               
                 LocateReverseF( ) 
                 (normally), (folded). 
               
               
                 Find( ), 
                 Find data (normally), (folded), (collated). 
               
               
                 FindF( ), FindC 
               
               
                 Left( ) 
                 Construct TPtrC for leftmost part of data. 
               
               
                 Right( ) 
                 Construct TPtrC for rightmost part of data. 
               
               
                 Mid( ) 
                 Construct TPtrC for portion of data. 
               
               
                 Alloc( ), 
                 Construct an HBufC for this descriptor. 
               
               
                 AllocL( ), AllocLC( ) 
               
               
                 HufEncode( ) 
                 Huffman encode 
               
               
                 HufDecode( ) 
                 Huffman decode 
               
               
                 MaxLength( ) 
                 Fetch maximum length of descriptor. 
               
               
                 MaxSize( ) 
                 Fetch maximum size of descriptor 
               
               
                 SetLength( ) 
                 Set length of descriptor data 
               
               
                 Zero( ) 
                 Set length of descriptor data to zero 
               
               
                 SetMax( ) 
                 Set length of descriptor data to the 
               
               
                   
                 maximum value. 
               
               
                 Swap( ) 
                 Swap data between two descriptors. 
               
               
                 Copy( ), 
                 Copy data (normally), (and fold), (and collate). 
               
               
                 CopyF( ), CopyC( ) 
               
               
                 CopyLC( ) 
                 Copy data and convert to lower case. 
               
               
                 CopyUC( ) 
                 Copy data and convert to upper case 
               
               
                 CopyCP( ) 
                 Copy data and capitalise 
               
               
                 Repeat( ) 
                 Copy and repeat. 
               
               
                 Justify( ) 
                 Copy and justify. 
               
               
                 Insert( ) 
                 Insert data. 
               
               
                 Delete( ) 
                 Delete data. 
               
               
                 Replace( ) 
                 Replace data. 
               
               
                 TrimLeft( ) 
                 Delete spaces from left side of data area. 
               
               
                 TrimRight( ) 
                 Delete spaces from right side of data area. 
               
               
                 Trim( ) 
                 Delete spaces from both left and right side of 
               
               
                   
                 data area. 
               
               
                 Fold( ) 
                 Fold characters. 
               
               
                 Collate( ) 
                 Collate characters. 
               
               
                 LowerCase( ) 
                 Convert to lower case. 
               
               
                 UpperCase( ) 
                 Convert to upper case. 
               
               
                 Capitalise( ) 
                 Capitalise. 
               
               
                 Fill( ) 
                 Fill with specified character. 
               
               
                 FillZ( ) 
                 Fill with 0x00. 
               
               
                 Num( ) 
                 Convert numerics to character (hex digits to 
               
               
                   
                 lower case). 
               
               
                 NumUC( ) 
                 Convert numerics to (upper case) character. 
               
               
                 Format( ), 
                 Convert multiple arguments to character 
               
               
                 FormatList( ) 
                 according to format specification. 
               
               
                 Append( ) 
                 Append data. 
               
               
                 AppendFill( ) 
                 Append with fill characters. 
               
               
                 AppendJustify( ) 
                 Append data and justify 
               
               
                 AppendNum( ) 
                 Append from converted numerics (hex digits 
               
               
                   
                 to lower case). 
               
               
                 AppendNumUC( ) 
                 Append from converted numerics; convert 
               
               
                   
                 to uppercase. 
               
               
                 AppendFormat( ), 
                 Append from converted multiple arguments. 
               
               
                 AppendFormatList( ) 
               
               
                 ZeroTerminate( ) 
                 Append zero terminator. 
               
               
                 PtrZ( ) 
                 Append zero terminator and return a pointer. 
               
               
                 operators &lt; &lt;= &gt; &gt;= == 
                 Comparison operators. 
               
               
                 operator += 
                 Appending operator. 
               
               
                 operator [ ] 
                 Indexing operator. 
               
               
                   
               
             
          
         
       
     
     Construction 
     e32.descriptors.TBuf.construction 
     TBuf( ) Default C++ constructor 
     TBuf( ); 
     Description 
     The default C++ constructor is used to construct a modifiable buffer descriptor. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor. 
     The length of the constructed descriptor is set to zero and the maximum length is set to the value of the integer template parameter &lt;TInt S&gt;. 
     TBuf( ) C++ constructor[with length] 
     TBuf(TInt aLength); 
     Description 
     The C++ constructor is used to construct the TBuf&lt;S&gt; with the length. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor. 
     The length of the constructed descriptor is set to aLength and the maximum length is set to the value of the integer template parameter &lt;TInt S&gt;. 
     Arguments 
     TInt aLength The length of the constructed modifiable buffer descriptor. 
      This value must be non-negative and not greater than the value of the integer template parameter &lt;1Int S&gt; otherwise the constructor will panic with ETDes 8 LengthOutOfRange for the 8 bit variant or ETDes 16 LengthOutOfRange for the 16 bit variant 
     TBuf( ) Copy constructor 
     TBuf(const TBuf&lt;S&gt;&amp; aBuf); 
     Description 
     The C++ copy constructor constructs a new TBuf&lt;S&gt; object from the existing one. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor object. 
     aBuf&#39;s data is copied into the constructed descriptor&#39;s data area. 
     The length of the constructed descriptor is set to the length of aBuf and the maximum length is set to the value of the integer template parameter &lt;TInt S&gt;. 
     TBuf( ) C++ constructor [with any descriptor] 
     TBuf(const TDesC&amp; aDes); 
     Description 
     The C++ constructor is used to construct the TBuf&lt;S&gt; with any kind of descriptor. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor. 
     aDes&#39;s data is copied into the constructed descriptor&#39;s data area. 
     The length of the constructed descriptor is set to the length of aDes and the maximum length is set to the value of the integer template parameter &lt;TInt S&gt;. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor used to construct the TBuf&lt;S&gt;. 
     Notes 
     The length of aDes must not be greater than the value of the integer template parameter &lt;TInt S&gt; otherwise the constructor will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     TBuf( ) C++ constructor [with zero terminated string] 
     TBuf(const TText aString); 
     Description 
     The Cup constructor is used to construct the TBuf&lt;S&gt; with a zero terminated string. 
     The integer template parameter &lt;TInt S&gt; is used, by the compiler, to calculate the size of the data area to be created as part of the constructed descriptor. 
     The string, excluding the zero terminator, is copied into the constructed descriptor&#39;s data area. 
     The length of the constructed descriptor is set to the length of the string, excluding the zero terminator, and the maximum length is set to the value of the integer template parameter &lt;TInt S&gt;. 
     Arguments 
     const Text* aString The address of the zero terminated string used to construct the TBuf&lt;S&gt;. 
     Notes 
     The length of the string, excluding the zero terminator must not be greater than the value of the integer template parameter &lt;TInt S&gt; otherwise the constructor will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     Assignment Operators 
     e32.descriptors.TBuf.assignment-operators 
     See also e32.descriptors.TDes.assignment-operators. 
     operator= Operator=taking a TBuf&lt;S&gt; 
     TBuf&lt;S&gt;&amp; operator=(const TBuf&lt;S&gt;&amp; aBuf); 
     Description 
     This assignment operator copies the content of the modifiable buffer descriptor aBuf into this modifiable buffer descriptor. 
     aBuf&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aBuf. 
     Arguments 
     const TBuf&lt;S&gt;&amp; aBuf A reference to the modifiable pointer descriptor whose content is to be copied. 
     Return value 
     TBuf&lt;S&gt;&amp; A reference to this descriptor. 
     Operator= Operator=taking any descriptor 
     TBuf&lt;S&gt;&amp; operator=(const TDesC&amp; aDes); 
     Description 
     This assignment operator copies the content of any type of descriptor aDes into this modifiable buffer descriptor. 
     aDes&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aDes. 
     Arguments 
     const TDesc&amp; aDes A reference to any type of descriptor whose content is to be copied. 
     Return value 
     TBuf&lt;S&gt;&amp; A reference to this descriptor. 
     Notes 
     The length of aDes must not be greater than the value of the integer template parameter &lt;TInt S&gt; otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     operator= Operator=taking a zero terminated string 
     TBuf&lt;S&gt;&amp; operator=(const TText* aString); 
     Description 
     This assignment operator copies a zero terminated string, excluding the zero terminator, into this modifiable buffer descriptor. 
     The copied string replaces the existing content of this descriptor. 
     The length of this descriptor is set to the length of the string, excluding the zero terminator. 
     Arguments 
     const TText* aString The address of the zero terminated string to be copied. 
     Return value 
     TBuf&lt;S&gt;&amp; A reference to this descriptor. 
     Notes 
     The length of the string, excluding the zero terminator, must not be greater than the value of the template parameter &lt;TInt S&gt; otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     HBufC Class Heap Descriptor 
     Overview 
     Derivation 
     TDesC Abstract: implements descriptor behaviour which does not modify data. 
     TBufCBase Abstract: implementation convenience. 
     HBufC A heap descriptor. 
     Defined in 
     e32des8.h for the 8 bit variant (HBufC 8 ). 
     e32des16.h for the 16 bit variant (HBufC) 
     Description 
     Create an HBufC descriptor to provide a buffer of fixed length for containing and accessing data. 
     The data held in an HBufC descriptor cannot be modified, although it can be replaced using the assignment operators. 
     The descriptor exists only on the heap but has the important property that it can be resized, i.e. made either larger or smaller, to change the size of its data area. This is achieved by reallocating the descriptor. Unlike the behaviour of dynamic buffers (see e32.dynamic-buffers) reallocation is not done automatically. 
     An HBufC descriptor is useful in situations where a large fixed length buffer may be required initially but, thereafter, a smaller fixed length buffer is sufficient. 
     An HBufC descriptor must be constructed using the static member functions New( ), NewL( ) or NewLC( ) and resized using the ReAlloc( ) or ReAllocL( ) member functions. A code fragment illustrates bow these might be used: 
     
       
         
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 class CAnyClass: CBase 
               
             
          
           
               
                   
                 { 
               
             
          
           
               
                   
                 public: 
               
             
          
           
               
                   
                 void AddToBuf(const TDesC&amp; aSrcBuf); 
               
             
          
           
               
                   
                 private: 
               
             
          
           
               
                   
                 HBufC* iTgtBuf; 
               
               
                   
                 TInt iAllocLen; 
               
               
                   
                 } 
               
             
          
           
               
                   
                 void CAnyClass::AddToBuf(const TDesC&amp; aSrcBuf) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 TInt SrcLen = aSrcBuf.Length( ); 
               
               
                   
                 if(iTgtBuf) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 if (SrcLen &gt; iAllocLen) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 iTgtBuf = iTgtBuf-&gt;ReAllocL(SrcLen); 
               
               
                   
                 iAllocLen = SrcLen; 
               
               
                   
                 } 
               
             
          
           
               
                   
                 } 
               
             
          
           
               
                   
                 else 
               
             
          
           
               
                   
                 { 
               
               
                   
                 iTgtBuf = HBufC::NewL(SrcLen); 
               
               
                   
                 iAllocLen = SrcLen; 
               
               
                   
                 } 
               
             
          
           
               
                   
                 *iTgtBuf = aSrcBuf; 
               
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     In practice, the use of ReAlloc( ) here is a little inefficient as the data in the HBufC descriptor is saved across the re-allocation but is then discarded when the content of aSrcBuf is assigned to it. 
     All the member functions described under the TDesC class are available for use by a TBufC descriptor. In summary these are: 
     
       
         
               
               
             
           
               
                   
               
             
             
               
                 Length( ) 
                 Fetch length of descriptor data. 
               
               
                 Size( ) 
                 Fetch the number of bytes occupied by 
               
               
                   
                 descriptor data. 
               
               
                 Ptr( ) 
                 Fetch address of descriptor data. 
               
               
                 Compare( ), 
                 Compare data (normally), (folded), (collated). 
               
               
                 CompareF( ), 
               
               
                 CompareC( ) 
               
               
                 Match( ), 
                 Pattern match data (normally), (folded), 
               
               
                 MatchF( ), MatchC( ) 
                 (collated). 
               
               
                 Locate( ), LocateF( ) 
                 Locate a character in forwards direction 
               
               
                   
                 (normally), (folded). 
               
               
                 LocateReverse( ), 
                 Locate a character in reverse direction 
               
               
                 LocateReverseF( ) 
                 (normally), (folded). 
               
               
                 Find( ), FindF( ), FindC 
                 Find data (normally), (folded), (collated). 
               
               
                 Left( ) 
                 Construct TPtrC for leftmost part of data. 
               
               
                 Right( ) 
                 Construct TPtrC for rightmost part of data. 
               
               
                 Mid( ) 
                 Construct TPtrC for portion of data. 
               
               
                 Alloc( ), 
                 Construct an HBufC for this descriptor. 
               
               
                 AllocL( ), AllocLC( ) 
               
               
                 HufEncode( ) 
                 Huffman encode 
               
               
                 HufDecode( ) 
                 Huffman decode 
               
               
                 operators &lt; &lt;= &gt; &gt;= == 
                 Comparison operators 
               
               
                 operator [ ] 
                 Indexing operator 
               
               
                   
               
             
          
         
       
     
     Allocation and Construction 
     e32.descriptors.HBufC.allocation-and-construction 
     New( ), NewL( ), NewLC( ) Create new HBufC 
     e32.descriptors.new 
     static HBufC* New(TInt aMaxLength); 
     static HBufC* NewL(TInt aMaxLength); 
     static HBufC* NewLC(TInt aMaxLength); 
     Description 
     Use these functions to construct a new HBufC descriptor on the heap. 
     The functions attempt to acquire a single cell large enough to hold an HBufC object containing a data area with a length which is at least aMaxLength. The resulting length of the data area may be larger than aMaxLength, depending on the way memory allocation is implemented, but is guaranteed to be not less than aMaxLength. 
     If there is insufficient memory available to create the descriptor, New( ) returns NULL but both NewL( ) and NewLC( ) leave. See e32.exception.intro for more information on leave processing. 
     If the new descriptor is successfully constructed, NewLC( ) will place the descriptor on the clean-up stack before returning with the address of that descriptor. See e32.exception.transient for more information on the clean-up stack. 
     The length of the new descriptor is set to zero. 
     Use operator= to assign data into the descriptor. 
     See example eudeshbc. 
     Arguments 
     TInt aMaxLength The required length of the new descriptor&#39;s data area. 
      This value must be non-negative otherwise the function will panic with ETDes 8 MaxLengthNegative for the 8 bit variant or ETDes 16 MaxLengthNegative for the 16 bit variant. 
     Return value 
     HBufC* The address of the newly created HBufC descriptor. 
      New( ) returns NULL, if there is insufficient memory. 
      NewL( ) and NewLC( ) leave, if there is insufficient memory. 
     Example 
     These code fragments illustrate how an HBufC descriptor can be constructed. 
     
       
         
               
               
             
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 Use of New( ); 
               
             
          
           
               
                   
                 HBufC* ptr; 
               
               
                   
                 . . . 
               
               
                   
                 ptr = HBufC::New(64);//buffer length is 64 
               
               
                   
                 if (!ptr) 
               
             
          
           
               
                   
                 { 
               
             
          
           
               
                   
                  . . . 
                 // could not create the descriptor 
               
               
                   
                 } 
               
             
          
           
               
                   
                 Use of NewL( ): 
               
             
          
           
               
                   
                 ptr = HBufC::NewL(64); 
               
             
          
           
               
                   
                 . . . 
                 // if control returns, allocation is OK 
               
               
                   
                 . . . 
                 // and ptr has sensible value 
               
               
                   
                   
               
             
          
         
       
     
     NewL( ), NewLC( ) Create new HBufC from a stream 
     e32.descriptors.newfromstream 
     static HBufC* NewL(RReadStream&amp; aStream,TInt aMaxLength); 
     static HBuf* NewLC(RReadStream&amp; aStream,TInt aMaxLength); 
     Description 
     Use these functions to construct a new HBufC descriptor on the heap and to assign to this new descriptor, data held in the stream aStream. 
     The functions attempt to acquire a single cell large enough to hold an HBufC object containing a data area whose length is sufficient to contain the data held in the stream. The stream contains both the length of the data and the data itself. 
     If there is insufficient memory available to create the descriptor or the length value held in the stream is greater then aMaxLength, both NewL( ) and NewLC( ) leave. See e32.exception.intro for more information on leave processing. 
     If the new descriptor is successfully constructed, NewLC( ) places the descriptor on the clean-up stack before returning with the address of that descriptor. See e32 exception.transient for more information on the clean-up stack. 
     These functions assume that the stream is currently positioned at an appropriate place, i.e. a point where a descriptor has previously been streamed out (using the operator &lt;&lt;). 
     See externalizing store.streams.externalizing.descriptors and internalizing store.stream.internalizinig.descriptors. 
     For general information on streams see store.streams-basic and store.streams. 
     For general information on stores, see store.stores. 
     Arguments 
     RReadStream&amp; aStream The stream from which the length of the new descriptor and the data to be assigned to the new descriptor, are to be taken. 
     TInt aMaxLength The maximum permitted length of the new descriptor. 
      The resulting length of the new descriptor must not exceed this value, otherwise the functions leave with a KErrOverflow. 
     Return value 
     HBufC* The address of the newly created HBufC descriptor. 
      Both NewL( ) and NewLC( ) leave, if there is insufficient memory or the resulting length exceeds the value of aMaxLength. 
     NewMax( ), NewMaxL( ), NewMaxLC( ) Create new HBufC and set length 
     static HBuf* NewMax(TInt aMaxLength); 
     static HBufC* NewMaxL(TInt aMaxLength); 
     static HBufC* NewMaxLC(TInt aMaxLength); 
     Description 
     Use these functions to construct a new HBufC descriptor on the heap. 
     The functions attempt to acquire a single cell large enough to hold an HBufC object containing a data area with a length which is at least aMaxLength. The resulting length of the data area may be larger than aMaxLength, depending on the way memory allocation is implemented, but is guaranteed to be not less than aMaxLength. 
     If there is insufficient memory available to create the descriptor, NewMax( ) returns NULL but both NewMaxL( ) and NewMaxLC( ) leave. See e32 exception.intro for more information on leave processing. 
     If the new descriptor is successfully constructed, NewMaxLC( ) will place the descriptor on the clean-up stack before returning with the address of that descriptor. See e32.exception.transient for more information on the clean-up stack. 
     The length of the new descriptor is set to the value of aMaxLength. 
     Use operator=to assign data into the descriptor. 
     Arguments 
     TInt aMaxLength The required length of the new descriptor&#39;s data area and the length given to the descriptor. 
      This value must be non-negative otherwise the function will panic with ETDes 8 MaxLengthNegative for the 8 bit variant or ETDes 16 MaxLengthNegative for the 16 bit variant. 
     Return value 
     HBufC* The address of the newly created HBufC descriptor. 
      NewMax( ) returns NULL, if there is insufficient memory. 
      NewMaxL( ) and NewMaxLC( ) leave, if there is insufficient memory. 
     Example 
     See e32.descriptors.new for an example 
     Reallocation 
     e32.descriptors.HBufC.reallocation 
     ReAlloc( ), ReAllocL( ) Expand/contract the HBufC buffer 
     HBufC* ReAlloc(TInt aMaxLength); 
     HBufC* ReAllocL(TInt aMaxLength); 
     Description 
     Use this function to expand or contract the data area of an existing HBufC descriptor. This is done by: 
     constructing a new HBufC descriptor on the heap containing a data area of length aMaxLength 
     copying the contents of the original descriptor into the new descriptor 
     deleting the original descriptor 
     The functions attempt to acquire a single cell large enough to hold an HBufC object containing a data area of length aMaxLength. 
     If there is insufficient memory available to construct the new descriptor, ReAlloc( ) returns NULL but ReAllocL( ) leaves. In either case the original descriptor remains unchanged; see e32.exception.intro for more information on leave processing. 
     If the new descriptor is successfully constructed, then the content of the original descriptor is copied into the new descriptor, the original descriptor is deleted and the address of the new descriptor is returned to the caller. The length of the re-allocated descriptor remains unchanged. 
     Arguments 
     TInt aMaxLength The new length of the descriptor&#39;s data area. 
      This value must be non-negative otherwise the function will panic with ETDes 8 MaxLengthNegative for the 8 bit variant or ETDes 16 MaxLengthNegative for the 16 bit variant 
      This value must not be less than the length of the data in the original descriptor otherwise the function will panic with ETDes 8 ReAllocTooSmall for the 8 bit variant or ETDes 16 ReAllocTooSmall for the 8 bit variant 
     Return value 
     HBufC* The address of the expanded or contracted HBufC descriptor. 
      ReAlloc( ) returns NULL, if there is insufficient memory. 
      ReAllocL( ) leaves, if there is insufficient memory. 
     Notes 
     If re-allocation is successful, be aware that any pointers containing the address of the original HBufC descriptor are no longer valid. This also applies to the cleanup stack; care must be taken in the design and implementation of code when a pointer to an HBufC descriptor is placed on the cleanup stack and the descriptor is subsequently re-allocated. 
     Take particular care if using the Des( ) member function to create a TPtr descriptor. A TPtr descriptor created before re-allocating the HBufC descriptor, is not guaranteed to have a valid pointer after re-allocation. Any attempt to modify data using the TPtr after re-allocation may have undefined consequences. 
     Example 
     These code fragments illustrate how ReAlloc( ) can work. 
     HBufC* old; 
     HBufC* newgood; 
     HBufC* newbad; 
     . . . 
     old=HBufC::NewL(16); //buffer length is 16 
     *old=_L(“abcdefghijkl”); //descriptor length is 12 
     . . . 
     newgood=old-&gt;ReAllocL(24); //first reallocation OK 
     newbad=newgood-&gt;ReAllocL(8); //second reallocation panics 
     After the first reallocation, newgood points to the re-allocated descriptor, old contains an invalid address. The second re-allocation panics because an attempt is being made to contract the data area to a length of 8 which is smaller than the original length of the descriptor. 
     Create a Modifiable Pointer Descriptor 
     e32.descriptors.HBufC.create-TPtr 
     Des( ) Create &amp; return a TPtr 
     TPtr Des( ); 
     Description 
     Use this function to construct and return a modifiable pointer descriptor to represent this descriptor. 
     The content of a HBufC descriptor cannot be altered but creating a modifiable pointer descriptor provides a mechanism for modifying that data. 
     The length of the new TPtr is set to the length of this descriptor. 
     The maximum length of the new TPtr is set to the length of this descriptor&#39;s data area. 
     The new TPtr is set to point to this descriptor. This descriptor&#39;s data is neither copied nor moved. 
     This descriptor&#39;s data can be modified through the newly constructed TPtr. If there is any change to the length of the data, then the length of both this descriptor and the TPtr is modified to reflect that change. 
     Return value 
     TPtr A modifiable pointer descriptor representing this HBufC descriptor. 
     Notes 
     Take particular care if using ReAlloc( ) or ReallocL( ). A TPtr descriptor created before re-allocating the HBufC descriptor, is not guaranteed to have a valid pointer after re-allocation. Any attempt to modify data using the TPtr after re-allocation may have undefined consequences. 
     Assignment Operators 
     e32.descriptors.HBufC.assignment-operators 
     See also e3?.descriptors.TDes.assignment-operators. 
     operator= Operator=taking HBufC descriptor 
     HBufC&amp; operator=(const HBufC&amp; aLcb); 
     Description 
     This assignment operator copies the content of the heap descriptor aLcb into this heap descriptor. 
     aLcb&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aLcb. 
     Arguments 
     const HBufC&amp; aLcb A reference to the heap descriptor whose content is to be copied. 
     Return value 
     HBufC&amp; A reference to this descriptor. 
     Notes 
     The length of the descriptor aLcb must not be greater than the length of this descriptor&#39;s data area otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     Operator= Operator=taking any descriptor 
     HBufC&amp; operator=(const TDesC&amp; aDes); 
     Description 
     This assignment operator copies the content of any type of descriptor aDes into this heap descriptor. 
     aDes&#39;s data is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of aDes. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be copied. 
     Return value 
     HBUfC&amp; A reference to this descriptor. 
     Notes 
     The length of the descriptor aDes must not be greater than the length of this descriptor&#39;s data area otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     operator=Operator=taking zero terminated string 
     HBuf&amp; operator=(const TText* aString); 
     Description 
     This assignment operator copies a zero terminated string, excluding the zero terminator, into this heap descriptor. 
     The string, excluding the zero terminator, is copied into this descriptor&#39;s data area, replacing the existing content. The length of this descriptor is set to the length of the string, excluding the zero terminator. 
     Arguments 
     const TText* aString The address of the zero terminated string to be copied. 
     Return value 
     HBufC&amp; A reference to this descriptor. 
     Notes 
     The length of the string, excluding the zero terminator, must not be greater than the length of this descriptor&#39;s data area otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     TDesC Class 
     Overview 
     Derivation 
     TDesC Abstract: implements descriptor behaviour which does not modify data 
     Defined in 
     e32des8.h for the 8 bit variant (TDesC 8 ). 
     e32des16.h for the 16 bit variant (TDesc 16 ) 
     Description 
     The class is abstract and cannot be constructed. It implements that aspect of descriptor behaviour which does not modify the descriptor&#39;s data. 
     All member functions described here are available to all derived descriptor classes. 
     Basic Information 
     e32.descriptors.TDesC.basic-functions 
     Length( ) Fetch descriptor length 
     TInt Length( ) const; 
     Description 
     Use this member function to return the number of data items in the descriptor&#39;s data area. 
     For 8 bit descriptors, data is single-byte valued and the length has the same value as the number of bytes occupied by that data. For 16 bit descriptors, data is double-byte valued and the length value is half the number of bytes occupied by that data, 
     For example, if a descriptor data area contains one ASCII text character, the returned length is one and it occupies one byte (and the Size( ) function returns one); if a data area contains one UNICODE text character, the returned length is also one but it occupies two bytes (and the Size( ) function returns two). 
     Return value 
     TInt The length of the data within the data area. 
     Size( ) Fetch the number of bytes occupied by data 
     TInt Size( ) const; 
     Use this member function to return the number of bytes occupied by data in the descriptor&#39;s data area. For 8 bit descriptors, this value is the same as the length of the data For 16 bit descriptors, this value is twice the length of the data. 
     Return value 
     TInt The number of bytes occupied by data within the descriptor&#39;s data area. 
     Ptr( ) Fetch address of descriptor&#39;s data area 
     const TUint??* Ptr( ) const; 
     Description 
     Use this member function to return the address of the descriptor&#39;s data area. The address cannot be used to change the descriptor&#39;s data. 
     Return Value 
     const TUint??* The address of the data area. For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     Notes 
     If the descriptor is used for strings, then the pointer can be regarded as a TText type and there is no need to distinguish between the 8 bit and 16 bit variants. If the descriptor is used for binary data then the pointer should be regarded as a TUint 8  type. 
     Comparison 
     e32.descriptors.TDesC.comparison 
     Compare( ), CompareF( ), CompareC( ) Compare data 
     TInt Compare(const TDesC&amp; aDes) const; 
     TInt CompareF(const TDesC&amp; aDes) const; 
     TInt CompareC(const TDesC&amp; aDes) const; 
     Description 
     Use these functions to compare the content of this descriptor with the content of the descriptor aDes. 
     The comparison proceeds on a byte for byte basis in the 8 bit variant and on a double-byte for double-byte basis in the 16 bit variant. 
     The result of the comparison is based on the difference of the first bytes (or double-bytes) to disagree. Two descriptors are equal if they have the same length and content. Where two descriptors have different lengths and the shorter matches the first part of the longer, the shorter is considered to be less than the longer. 
     CompareF( ) takes the folded content of both descriptors for comparison while CompareC( ) takes the collated content of both descriptors for comparison. Compare( ) simply takes the content of both descriptors as they stand. 
     See e32.descriptors.folding for more information on folding and e32.descriptors.collating for more information on collating. 
     Compare( ) is useful for comparing both text and binary data. CompareF( ) is useful for making case-insensitive text comparisons. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be compared with this descriptor&#39;s content. 
     Return value 
     TInt Positive, if this descriptor is greater than aDes. 
      Negative, if this descriptor is less than aDes. 
     Zero, if both descriptors have the same length and the their contents are the same. 
     Example 
     This code fragment illustrates the use of Compare( ). 
     TBufC&lt;8&gt; str(_L(“abcd”)); 
     . . . 
     str.Compare(_L(“abcde”)); //returns −ve 
     str.Compare(_L(“abc”)); //returns +ve 
     str.Compare(_L(“abcd”)); //returns zero 
     str.Compare(_L(“abcx”)); //returns −ve 
     Thus: 
     &lt;“abcd” is less than “abode”. 
     &lt;“abed” is greater than “abc”. 
     &lt;“abed” is equal to “abcd”. 
     &lt;“abcd” is less than “abcx”. 
     Pattern Matching 
     e32.descriptors.TDesC.pattern-matching 
     Match( ), MatchF( ), MatchC( ) Pattern match data 
     TInt Match(const TDesC&amp; aDes) const; 
     TInt MatchF(const TDesC&amp; aDes) const; 
     TInt MatchC(const TDesC&amp; aDes) const; 
     Description 
     Use these functions to compare the match pattern in aDes&#39;s data area against the content of this descriptor. 
     The match pattern can contain the wildcard characters ‘*’ and ‘?’, where ‘*’ matches zero or more consecutive occurrences of any character and ‘?’ matches a single occurrence of any character. 
     MatchF( ) takes the folded content of both descriptors for matching while MatchC( ) takes the collated content of both descriptors for matching. Match( ) simply takes the content of both descriptors as they stand. 
     See e32.descriptors.folding for more information on folding and e32.descriptors.collating for more information on collating. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose data area contains the match pattern. 
     Return value 
     TInt If the content of this descriptor matches the pattern supplied in aDes&#39;s data area, then this is the length of the most significant portion (i.e. the leftmost part) of this data area an which matches the pattern. 
      If the content of this descriptor does not match the pattern supplied in aDes, KNotFound is returned. 
     Notes 
     To test for the existence of a pattern within a text string, the pattern must start and end with an‘*’. 
     If the pattern terminates with an ‘*’ wildcard character and the supplied string matches the pattern, then the value returned is the length of the string which matches the pattern up to but not including the final asterisk. This is illustrated in the examples below. 
     Example 
     This code fragment illustrates the use of Match( ) 
     
       
         
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;32&gt;str(_L(“abcdefghijklmnopqrstuvwxyz”)); 
               
               
                   
                 . . . 
               
               
                   
                 str.Match(_L(“*ijk*”));  //returns −&gt; 11 
               
               
                   
                 str.Match(_L(“*i?k*”));  //  −&gt; 11 
               
               
                   
                 str.Match(_L(“ijk*”));  //  −&gt; KNotFound 
               
               
                   
                 str.Match(_L(“abcd”));  //  −&gt; KNotFound 
               
               
                   
                 str.Match(_L(“*i*mn*”));  //  −&gt; 14 
               
               
                   
                 str.Match(_L(“abcdef*”));  //  −&gt; 6 
               
               
                   
                 str.Match(_L(“*”));  //  −&gt; 0 
               
               
                   
                   
               
             
          
         
       
     
     Locate a Character 
     e32.descriptors.TDesC.locate-character 
     Locate( ), LocateF( ) Locate a character forwards 
     TInt Locate(TChar aChar) const; 
     TInt LocateF(TChar aChar) const; 
     Description. 
     Use these functions to find the first occurrence of a character within this descriptor. The search starts at the beginning (i.e. the left side) of the data area. 
     LocateF( ) takes the folded content of the descriptor and folds the supplied character before searching. This is useful in searching for a character in a case-insensitive manner. 
     See e32.descriptors.folding for more information on folding. 
     Arguments 
     TChar aChar The character to be found. 
     Return value 
     TInt If the character is found, this is the offset of its position from the beginning of the data area. 
      KNotFound is returned if the character is not found. 
     Example 
     This code fragment illustrates the use of Locate( ). 
     . . . 
     TBufC&lt;8&gt; str(_L(“abcd”)); 
     . . . 
     str.Locate(‘d’); //returns 3 
     str.Locate(‘a’); //returns 0 
     str.Locate(‘b’); // returns 1 
     str.Locate(‘x’); //returns KNotFound 
     LocateReverse( ), LocateReverseF( ) Locate a character in reverse 
     TInt LocateReverse(TChar aChar) coast; 
     TInt LocateReverseF(TChar aChar) const; 
     Description 
     Use these functions to find the first occurrence of a character within this descriptor, searching from the back (i.e. the right side) of the data area. 
     LocateReverseF( ) takes the folded content of the descriptor and folds the supplied character before searching. This is useful in searching for a character in a case-insensitive manner. 
     See e32.descriptors.folding for more information on folding. 
     Arguments 
     TChar aChar The character to be found. 
     Return value 
     TInt If the character is found, this is the offset of its position from beginning of data area. 
      KNotFound is returned if the character is-not found. 
     Find Data 
     e32.descriptors.TDesC.find-data 
     Find( ), FindF( ), FindC( ) Find data (given by descriptor) 
     TInt Find(const TDesC&amp; aDes) const; 
     TInt FindF(const TDesC &amp;aDes) const; 
     TInt FindC(const TDesC &amp;aDes) const; 
     Description 
     Use these functions to find the location, within this descriptor, of the data supplied in aDes&#39;s. The search starts at the beginning (i.e. the left side) of this descriptor&#39;s data area. 
     FindF( ) folds the content of both descriptors for the purposes of searching while FindC( ) collates the content. See e3?.descriptors.folding for more information on folding and e32.descriptors.collating for more information on collating. 
     While these functions are most useful in searching for the existence and location of a sub-string within a string, they can, nevertheless, be used on general binary data. 
     FindF( ) is useful in performing a case-independent search of a string for a sub-string; 
     FindC( ) is useful in searching a string for a sub-string on the basis of their collating sequence. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor which contains the data sequence to be found within this descriptor. 
     Return value 
     TInt If the data is found, the offset of the starting position of the data from the beginning of this descriptor&#39;s data area. 
      KNotFound is returned if the data is not found. 
     Notes 
     If the descriptor aDes has zero length, then the returned value will be zero. 
     Example 
     This code fragment illustrates the use of Find( ). 
     
       
         
               
             
               
               
             
               
             
               
               
             
           
               
                   
               
             
             
               
                 . . . 
               
               
                 TBufC&lt;32&gt;str(_L(“abcdefghijklmnopqrstuvwxyz”)); 
               
               
                 . . . 
               
             
          
           
               
                 str.Find(_L(“abc”)); 
                 // returns 0 
               
               
                 str.Find(_L(“bcde”)); 
                  // returns 1 
               
               
                 str.Find(_L(“uvwxyz”)); 
                  // returns 20 
               
               
                 str.Find(_L(“0123”)); 
                  // returns KNotFound 
               
             
          
           
               
                 str.Find(_L(“abcdefghijklmnopqrstuvwxyz01”)); // returns KNotFound 
               
             
          
           
               
                 str.Find(_L(“”)) ; 
                 // returns 0 
               
               
                 . . . 
               
               
                   
               
             
          
         
       
     
     Find( ), FindF( ), FindC( ) Find data (given by address and length) 
     TInt Find(const TUint??* aBuf,TInt aLen) const; 
     TInt FindF(const TUint??* aBuf,TInt aLen) const; 
     TInt FindC(const TUint??* aBuf,TInt aLen) const; 
     Description 
     Use these functions to find the location, within this descriptor, of the data of length aLen at address aBuf. The search starts at the beginning (i.e. the left side) of this descriptor&#39;s data area. 
     FindF( ) folds the content of both this descriptor and the data at aBuf for the purposes of searching, while FindC( ) collates the content. See e32.descriptors.folding for more information on folding and e.32.descriptors.collating for more information on collating. 
     While these functions are most useful in searching for the existence and location of a sub-string within a string, they can, nevertheless, be used on general binary data. 
     FindF( ) is useful in performing a case-independent search of a string for a sub-string; 
     FindC( ) is useful in searching a string for a sub-string on the basis of their collating sequence. 
     Arguments 
     const TUint??* aBuf The address of the data sequence to be found within this descriptor. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLen The length of the data sequence. 
      This value must be non-negative otherwise the function will panic with ETDes 8 LengthNegative for the 8 bit variant or ETDes 16 LengthNegative for the 16 bit variant. 
     Return value 
     TInt If the data is found, the offset of the starting position of the data from the beginning of this descriptor&#39;s data area. 
      KNotFound is returned if the data is not found. 
     Notes 
     If aLen is zero, then the returned value will be zero. 
     Extraction 
     e32.descriptors.TDesC.extraction 
     Left( ) Construct TPtrC for leftmost part of data 
     TPtrC Left(TInt aLength) const; 
     Description 
     Use this function to construct and return a constant pointer descriptor to represent the leftmost part of this descriptor&#39;s data. 
     Arguments 
     TInt aLength The length of data within this descriptor which the new descriptor is to represent. 
      This value must not be negative and must not be greater than the current length of this descriptor otherwise the function will panic with ETDes 8 PosOutOfRange for the 8 bit variant or ETDes 16 PosOutOfRange for the 16 bit variant. 
     Return value 
     TPtrC The constant pointer descriptor representing the leftmost part of this descriptor&#39;s data area. 
     Notes 
     No movement or copying of data takes place; the data represented by the returned descriptor occupies the same memory as the original. 
     Specifying a zero value for aLength will result in a descriptor which represents no data. 
     Example 
     The code fragments illustrate the use of Left( ). 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;8&gt;str(_L(“abcdefg”)); 
               
             
          
           
               
                   
                 . . . 
                 // returns a TPtrC descriptor 
               
               
                   
                 str.Left(4); 
                  // representing the string 
               
               
                   
                 . . . 
                 // “abcd” 
               
               
                   
                   
               
             
          
         
       
     
     The result of this specific example can be visualised in a before (shown in FIG. 9) and after (shown in FIG. 10) fashion. The underlined text in the “after” diagram (FIG. 10) indicates the data represented by the returned descriptor. 
     Note that the result of the following calls to Left( ) will result in a panic. 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;8&gt;str(_L(“abcdefg”)); 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 str.Left(8); 
                 // panic !! 
               
               
                   
                 str.Left(−1); 
                 // panic !! 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Right( ) Construct TPtrC for rightmost part of data 
     TPtrC Right(TInt aLength) const; 
     Description 
     Use this function to create and return a constant pointer descriptor to represent the rightmost part of this descriptor&#39;s data. 
     Arguments 
     TInt aLength The length of data within this descriptor which the new descriptor is to represent. 
      This value must not be negative and must not be greater than the current length of this descriptor otherwise the function will panic with ETDes 8 PosOutOfRange for the 8 bit variant or ETDes 16 PosOutOfRange for the 16 bit variant. 
     Return value 
     TPtrC The constant pointer descriptor representing the rightmost part of this descriptor&#39;s data area. 
     Notes 
     No movement or copying of data takes place; the data represented by the returned descriptor occupies the same memory as the original. 
     Specifying a zero value for aLength will result in a descriptor which represents no data. 
     Example 
     The code fragments illustrate the use of Right( ). 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;8&gt;str(_L(“abcdefg”)); 
               
             
          
           
               
                   
                 . . . 
                 // returns a TPtrC descriptor 
               
               
                   
                 str.Right(4); 
                  // representing the string 
               
               
                   
                 . . . 
                 // “defg” 
               
               
                   
                   
               
             
          
         
       
     
     The result of this specific example can be visualised in a before (FIG. 11) and after (FIG. 12) fashion. The underlined text in the “after” diagram (FIG. 12) indicates the data represented by the returned descriptor. 
     Note that the result of the following calls to Right( ) will result in a panic. 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;8&gt;str(_L(“abcdefg”)); 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 str.Right(8); 
                 // panic !! 
               
               
                   
                 str.Right(−1); 
                 // panic !! 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Mid( ) Construct TPtrC for portion of data 
     TPtrC Mid(TInt aPos) const; 
     TPtrC Mid(TInt aPos,TInt aLength) const; 
     Description 
     Use these functions to create and return a constant pointer descriptor to represent a portion of the data held in this descriptor. 
     The portion can be identified either by position alone or by position and length. If identified by position alone, the implied length is the length of data from the specified position to the end of the data in this descriptor. 
     Arguments 
     TInt aPos The starting position, within this descriptor, of the data to be represented by the new constant descriptor. The position is given relative to zero; i.e. a zero value implies the leftmost data position. 
      This value is subject to the constraints outlined below. 
     TInt aLength The length of data which the new descriptor is to represent. 
      This value is subject to the constraints outlined below. 
     If aPos alone is specified, then 0&lt;=aPos&lt;=length of this descriptor. 
     If aPos and aLength are specified, then 0&lt;=(aPos+aLength)&lt;=length of this descriptor. 
     If these limits are exceeded, then the functions will panic with ETDes 8 PosOutOfRange for the 8 bit variant or ETDes 16 PosOutOfRange for the 16 bit variant. 
     Return value 
     TPtrC The constant pointer descriptor representing the selected portion of this descriptor&#39;s data. 
     Notes 
     No movement or copying of data takes place; the data represented by the returned descriptor occupies the same memory as the original. 
     Specifying a value of aPos which has the same value as the length of the data, will result in a constant pointer descriptor which represents no data. 
     Example 
     The code fragments illustrate the use of Mid( ). 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC str(_L(“abcdefg”)); 
               
             
          
           
               
                   
                 . . . 
                 // returns TPtrC descriptors 
               
               
                   
                   
                 // representing the strings . . . 
               
               
                   
                 str.Mid(0); 
                 //“abcdefg” 
               
               
                   
                 str.Mid(1); 
                 //“bcdefg” 
               
               
                   
                 str.Mid(6); 
                 //“g” 
               
               
                   
                 str.Mid(3,3); 
                 //“def” 
               
               
                   
                 str.Mid((0,7); 
                 //“abcdefg” 
               
               
                   
                 . . . 
               
               
                   
                 str.Mid(8); 
                 // Panics !! 
               
               
                   
                 str.Mid(3,5); 
                 // Panics !! 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Create a Heap Descriptor (HBufC) 
     e32.descriptors.TDesC.create-HBufC 
     Alloc( ), AllocL( ), AllocLC( ) Create new HBufC for this descriptor 
     HBufC* Alloc( ) const; 
     HBufC AllocL( ) const; 
     HBufC* AllocLC( ) const; 
     Description 
     Use these functions to allocate and construct a new HBufC descriptor on the heap and initialise it using the content of this descriptor. 
     The functions attempt to acquire a single cell large enough to hold an HBufC object containing a data area whose length is the same as the current length of this descriptor. The content of this descriptor is copied into the new HBufC descriptor. 
     If there is insufficient memory available to create the new HBufC descriptor, Alloc( ) returns NULL but both AllocL( ) and AllocLC( ) leave. See e32.exception.intro for more information or, leave processing. 
     If the new descriptor is successfully created, AllocLC( ) will place the new descriptor on the clean-up stack before returning with the address of that descriptor. See e32.exception.transient for more information on the clean-up stack. 
     Return value 
     HBufC* The address of the newly created HBufC descriptor. 
      Alloc( ) returns NULL, if there is insufficient memory. 
      AllocL( ) and AllocLC( ) leave, if there is insufficient memory. 
     Example 
     The code fragments illustrate the use of AllocL( ). 
     
       
         
               
               
             
               
               
               
             
               
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBufC&lt;16&gt;str(_L(“abcdefg”)); 
               
               
                   
                 HBufC*  ptr; 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 ptr = str.AllocL( ); 
                  // Returns address of new HBufC descriptor 
               
             
          
           
               
                   
                 . . . 
                 // holding the string “abcdefg”. 
               
             
          
           
               
                   
                 ptr.Length( ); 
                 // Returns the length 7 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     The result of this specific example can be visualised in a before (FIG. 13) and after (FIG. 14) fashion. 
     Huffman Encoding/Decoding 
     e32.descriptors.TDesC.huffman-encoding-decoding 
     HufEncode( ) Huffman encode 
     TInt HufEncode(TDes&amp; aDest) const; 
     TInt HufEncode(TDes&amp; aDest,const TUint 8 * aHufBits) const; 
     Description 
     Use this function to Huffman encode the data in this descriptor and place the result into the descriptor aDest. The target descriptor must be a modifiable type; i.e. either a TPtr or TBuf. 
     The caller can supply a Huffman tree or use the built-in tree. 
     Arguments 
     TDes&amp; aDest A reference to the modifiable descriptor which is to hold the result of encoding the data in this descriptor. 
     const TUint 8 * aHufBits If specified, the Huffman tree to be used for encoding. 
      This is of type TUint 8 * for both 8 bit and 16 bit descriptors. 
      If not supplied, the built-in Huffman tree is used. 
     Return value 
     TInt The total number of bits occupied by the encoded data. 
     HufDecode( ) Huffman decode 
     void HufDecode(TDes &amp;aDest) const; 
     void HufDecode(TDes &amp;aDest,const TUint 8  *aHufTree) const; 
     Description 
     Use this function to Huffman decode the data in this descriptor and place the result into the descriptor aDest. The target descriptor must be a modifiable type; i.e. either a TPtr or TBuf. 
     The caller can supply a Huffman tree or use the built-in tree. 
     Arguments 
     TDes&amp; aDest A reference to the descriptor which is to hold the result of decoding the data in this descriptor. 
     const TUint 8 * aHufBits If specified, the Huffman tree to be used for decoding. 
      This is of type TUint 8 * for both 8 bit and 16 bit descriptors. 
      If not supplied, the built-in Huffman tree is used. 
     Comparison Operators 
     e32.descriptors.TDesC.comparison-operators 
     operators &lt; &lt;= &gt; &gt;= == != Comparison operators taking any descriptor 
     TInt operator&lt;(const TDesC&amp; aDes) const; 
     TInt operator&lt;=(const TDesC&amp; aDes) const; 
     TInt operator&gt;(const TDesC&amp; aDes) const; 
     TInt operator&gt;=(const TDesC&amp; aDes) const; 
     TInt operator==(const TDesC&amp; aDes) const; 
     TInt operator!=(const TDesC&amp; aDes) const; 
     Description 
     Use these operators to determine whether the content of this descriptor is: 
     3 less than 
     less than or equal to 
     greater than 
     greater than or equal to 
     equal to 
     not equal to 
     the content of aDes. 
     The comparison is implemented using the TDesC::Compare( ) member function. See this member function for more detail on the comparison process. 
     Arguments 
     const TDesC&amp; aDes A reference to the descriptor whose content is to be compared with the content of this descriptor. 
     Return value 
     TInt true or false 
     Example 
     This code fragment illustrates the use of Compare( ). 
     
       
         
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 TBufC&lt;8&gt;str(_L(“abcd”)); 
               
               
                   
                 . . . 
               
               
                   
                 if (str == _L(“abcde”)) // returns false 
               
             
          
           
               
                   
                 { 
               
               
                   
                 . . . 
               
               
                   
                 } 
               
             
          
           
               
                   
                 if (str &lt; _L(“abcx”))  // returns true 
               
             
          
           
               
                   
                 { 
               
               
                   
                 . . . 
               
               
                   
                 } 
               
             
          
           
               
                   
                 if (str &gt; _L(“abc”))  // returns true 
               
             
          
           
               
                   
                 { 
               
               
                   
                 . . . 
               
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     Indexing Operator 
     e32.descriptors.TDesC.indexing-operator 
     operator [ ] operator [ ] 
     const TUint??&amp; operator[ ](TInt anIndex) const; 
     Description 
     Use this operator to return a reference to a single data item within this descriptor (e.g. a text character). The data can be considered as an array of ASCII or UNICODE characters or as an array of bytes (or double-bytes) of binary data. 
     This operator allows the individual elements of the array to be accessed but not changed. 
     Arguments 
     TInt anIndex The index value indicating the position of the element within the data area. The index is given relative to zero; i.e. zero implies the leftmost data position. 
      This value must be non-negative and less than the current length of the descriptor otherwise the operation will panic with ETDes 8 IndexOutOfRange for the 8 bit variant or ETDes 16 IndexOutOfRange for the 16 bit variant 
     Return value 
     const TUint??&amp; A reference to the data at position anIndex. The data is of type TUint 8 &amp; for 8 bit variants and of type TUint 16 &amp; for 16 bit variants. 
     Example 
     The code fragments illustrates the use of operator[ ]. 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 TBufC&lt;8&gt;str(_L(“abcdefg”)); 
               
             
          
           
               
                   
                 . . . 
                   
               
               
                   
                 str[0]; 
                 // returns reference to ‘a’ 
               
               
                   
                 str[3]; 
                 // returns reference to ‘d’ 
               
               
                   
                 str[7]; 
                 // Panics !! 
               
               
                   
                 if (str[0] == ‘a’) 
                  // . . . compare returns True 
               
               
                   
                 { 
               
               
                   
                 . . . 
               
               
                   
                 } 
               
               
                   
                 if (str[6] == ‘x’) 
                  // . . . compare returns False 
               
               
                   
                 { 
               
               
                   
                 . . . 
               
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     TDes Class 
     Overview 
     Derivation 
     TDesC Abstract: implements descriptor behaviour which does not modify data. 
     TDes Abstract: implements descriptor behaviour which can change data. 
     Defined in 
     e32des8.h for the 8 bit variant (TDes 8 ). 
     e32des16.h for the 16 bit variant (TDes 16 ) 
     Description 
     The class is abstract and cannot be constructed. It implements that aspect of descriptor behaviour which modifies the descriptor&#39;s data. 
     All member functions described here are available to all derived descriptor classes. 
     Basic Functions 
     e32.descriptors.TDes.basic-functions 
     MaxLength( ) Fetch maximum length of descriptor 
     TInt MaxLength( ) const; 
     Description 
     Use this function to return the maximum length of data that the descriptor&#39;s data area can hold. 
     For modifiable descriptors, the amount of data that a descriptor&#39;s data area can hold is variable; however, there is an upper limit and this limit is the value returned by the function. 
     For 8 bit descriptors, data is single-byte valued and the maximum length has the same value as the maximum size. For 16 bit descriptors, data is double-byte valued and the value of the maximum length is half the maximum size. 
     Return value 
     TInt The maximum length of data that the descriptor&#39;s data area can hold. 
     MaxSize( ) Fetch maximum size of descriptor 
     TInt MaxSize( ) const; 
     Description 
     Use this function to fetch the maximum size of the descriptor&#39;s data area, in bytes. 
     For 8 bit descriptors, data is single-byte and the maximum size is the same value as the maximum length. 
     For 16 bit descriptors, data is double-byte and the maximum size is twice the value of the maximum length. 
     Return value 
     TInt The maximum size of the descriptor&#39;s data area. 
     Change Length 
     e32.descriptors.TDes.change-length 
     SetLength( ) Set length of data 
     void SetLength(TInt aLength); 
     Description 
     Use this function to set the length of the descriptor to the value of aLength. 
     Arguments 
     TInt aLength The new length of the descriptor. 
      This value must be non-negative and must not be greater than the maximum length otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     Zero( ) Set length of data to zero 
     void Zero( ); 
     Description 
     Use this function to set the length of the descriptor to zero. 
     SetMax( ) Set length of data to maximum 
     void SetMax( ); 
     Description 
     Use this function to set the length of the descriptor to its maximum value. 
     Swap 
     e32.descriptors.TDes.swap 
     Swap( ) Swap descriptor contents 
     void Swap(TDes&amp; aDes); 
     Description 
     Swap the contents of this descriptor with the contents of aDes. The lengths of both descriptors are also swapped to reflect the change of data. 
     Arguments 
     TDes&amp; aDes A reference to the descriptor whose contents are to be swapped with the contents of this descriptor. This descriptor must be a modifiable type; i.e. either a TPtr or TBuf. 
     Notes 
     Each descriptor must be capable of accommodating the contents of the other descriptor. If the maximum length of a descriptor is smaller than the length of the other descriptor, then the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     Example 
     The following code fragment illustrates the use of Swap( ) 
     . . . 
     TBuf&lt;8&gt; buf 1 (_L(“abcde”)); 
     TBuf&lt;8&gt; buf 2 (_L(“xyz”)); 
     TBuf&lt;16&gt; buf 3 (_L(“0123456789”)); 
     . . . 
     buf 1 .Swap(buf 2 ); //contents of buf 1  and buf 2  swapped OK 
     buf 1 .Swap(buf 3 ); //Panic!! 
     . . . 
     Copy 
     e32.descriptors.TDes.copy 
     Copy( ) Copy (unmodified) from any 8 bit or 16 bit descriptor 
     void Copy(const TDesC&amp;&amp; aDes); 
     void Copy(const TDesC&amp; aDes); 
     Description 
     Use these functions to copy the content of any descriptor aDes into this descriptor. The copied data replaces the existing content of this descriptor. 
     The length of this descriptor is set to the length of aDes. 
     If this descriptor is the 8 bit variant, Copy( ) is overloaded so that it can take another 8 bit descriptor or a 16 bit descriptor as source. 
     If this descriptor is the 16 bit variant, Copy( ) is overloaded so that it can take an 8 bit descriptor or another 16 bit descriptor as source. 
     Thus: 
     an 8 bit descriptor can be copied to an 8 bit descriptor 
     an 8 bit descriptor can be copied to a 16 bit descriptor 
     a 16 bit descriptor can be copied to an 8 bit descriptor 
     a 16 bit descriptor can be copied to a 16 bit descriptor 
     In the case where a 16 bit descriptor is copied to an 8 bit descriptor, each double-byte is copied into the corresponding single byte where the value of the double-byte is less than decimal 256. A double-byte value of 256 or greater cannot be copied and the corresponding single byte is set to a value of decimal 1. 
     In practice, the most common situation is to copy either 8 bit to 8 bit or 16 bit to 16 bit. 
     Arguments 
     const TDesC 8 &amp; aDes A reference to any type of descriptor whose content is to be or copied into this descriptor. 
     const TDesC 16 &amp; aDes 
     Notes 
     The length of the data in aDes cannot be greater than the maximum length of this descriptor otherwise the: function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Example 
     The code fragment illustrates the use of Copy( ). 
     
       
         
               
               
             
           
               
                   
               
             
             
               
                 . . . 
                   
               
               
                 TBuf&lt;8&gt;str; 
               
               
                 . . . 
               
               
                 str.Copy(_L“abcdefg”); 
                  // copies “abcdefg” to tmp 
               
               
                 str.Length( ); 
                 // returns 7 
               
               
                 str.MaxLength( ); 
                  // returns 8 
               
               
                 . . . 
               
               
                 str.Copy(_L“abc”), 
                  // copies “abc” to tmp 
               
               
                 str.Length( ); 
                 // returns 3 
               
               
                 str.MaxLength( ); 
                  // returns 8 
               
               
                 . . . 
               
               
                 str.Copy(_L“abcdefghi”); 
                  // Panics !! 
               
               
                   
               
             
          
         
       
     
     Copy( ) Copy from zero terminated string 
     void Copy(const TText* aString); 
     Description 
     Use this function to copy a zero terminated string, excluding the zero terminator, into this descriptor replacing the existing content. 
     The length of this descriptor is set to the length of the string, excluding the zero terminator. 
     Arguments 
     const TText* aString The address of the zero terminated string to be copied. 
     Notes 
     The length of the string, excluding the zero terminator, must not be greater than the maximum length of this descriptor otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Copy( ) Copy from address 
     void Copy(const TUint?? aBuf,TInt aLength); 
     Description 
     Use this function to copy data of length aLength from the memory location aBuf. 
     The length of this descriptor is set to the value of aLength. 
     Arguments 
     const TUint??* aBuf The address of the data to be copied. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of the data to be copied. 
      This value must be non-negative and must not be greater than maximum length of this descriptor otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     CopyF( ), CopyC( ) Copy (and fold/collate) from any descriptor 
     void CopyF(const TDesC&amp; aDes); 
     void CopyC(const TDesC&amp; aDes); 
     Description 
     Use these functions to copy the content of aDesC into this descriptor, replacing the existing content. 
     The length of this descriptor is set to the length of aDes. 
     CopyF( ) folds the data before insertion into this descriptor and CopyC( ) collates the data before insertion. See e32.descriptors.folding for more information on folding and e32.descriptors.collating for more information on collating. 
     These functions are only of practical use for text data. 
     Arguments 
     const TDesC&amp; aDes A reference to the descriptor whose content is to be copied into this descriptor. 
     Notes 
     The length of the data in aDes must not be greater than the maximum length of this descriptor otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     CopyLC( ), CopyUC( ), CopyCP( ) Copy (and change case) from any descriptor 
     void CopyLC(const TDesC&amp; aDes); 
     void CopyUC(const TDesC&amp; aDes); 
     void CopyCP(const TDesC&amp; aDes); 
     Description 
     Use these functions to copy the content of aDesC into this descriptor, replacing the existing content. 
     The length of this descriptor is set to the length of aDes. 
     Before copying data , CopyLC( ) converts characters to lower case, CopyUC( ) converts characters to upper case and CopyCP( ) capitalises text. 
     Capitalisation means the conversion of the first character in a string to upper case and converting all remaining characters to lower case. 
     Accented characters retain their accents. 
     These functions are only of practical use for string data. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be copied into this descriptor. 
     Notes 
     The length of the data in aDes must not be greater than the maximum length of this descriptor otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     Copy Repeat 
     e32.descriptors.TDes.copy-repeat 
     Repeat( ) Copy from descriptor and repeat 
     void Repeat(const TDesC&amp; aDes) 
     Description 
     Use this function to copy the content of the descriptor aDes, repeatedly into this descriptor. 
     The copies are concatenated together within this descriptor and replace any existing data. 
     Copying proceeds until this descriptor is filled up to its current length. If it cannot contain a whole number of copies of aDes, then the last copy within this descriptor is truncated. 
     Arguments 
     const TDes&amp; aDes A reference to any type of descriptor whose contents are to be repeatedly copied. 
     Example 
     The following code fragment illustrates the use of Repeat( ). 
     
       
         
               
               
               
             
               
               
               
             
               
               
               
             
               
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
                   
               
               
                   
                 TBuf&lt;8&gt;tgt(8); 
                 // length of tgt is the same as the 
               
             
          
           
               
                   
                   
                 // maximum which is 8 
               
               
                   
                 . . . 
               
               
                   
                   
                 // following strings generated in tgt 
               
             
          
           
               
                   
                 tgt.Repeat(_L(“ab”)); 
                 // “abababab” 
               
               
                   
                 tgt.Repeat(_L(“abc”); 
                 // “abcabcab” 
               
               
                   
                 tgt.Repeat(_L(“abcde”)); 
                  // “abcdeabc” 
               
             
          
           
               
                   
                 . . . 
                   
               
               
                   
                 . . . 
                 // changing length to 7 has the 
               
               
                   
                   
                 // following effect 
               
               
                   
                 tgt.SetLength(7); 
               
             
          
           
               
                   
                 tgt.Repeat(_L(“ab”)); 
                 // “abababa” 
               
               
                   
                 tgt.Repeat(_L(“abc”)); 
                 // “abcabca” 
               
               
                   
                 tgt.Repeat(_L(“abcde”)); 
                 // “abcdeab” 
               
               
                   
                   
               
             
          
         
       
     
     Repeat( ) Copy from address and repeat 
     void Repeat(const TUint??* aBuf,TInt aLength); 
     Description 
     Use this function to copy data of length aLength from the memory location aBuf, repeatedly into this descriptor. The copies are concatenated together within this descriptor and replace any existing data. 
     Copying proceeds until this descriptor is filled up to its current length. If it cannot contain a whole number of copies, then the last copy within this descriptor is truncated. 
     Arguments 
     const TUint??* aBuf The address of the data to be repeatedly copied. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of the data to be repeatedly copied. 
      This value must be non-negative otherwise the function will panic with ETDes 8 LengthNegative for the 8 bit variant or ETDes 16 LengthNegative for the 16 bit variant. 
     Copy and Justify 
     e32 descriptors.TDes.copy-justify 
     Justify( ) Copy from descriptor and justify 
     e32.descriptors.TDes.copy-justify.justify 
     void Justify(const TDesC&amp; aDes,TInt aWidth,TAlign anAlignment,TChar aFill); 
     Description 
     Use this function to copy the content of aDes into this descriptor, replacing the existing content. The target area is considered to be a field of width aWidth positioned at the beginning (i.e. the left hand side) of this descriptor&#39;s data area. The content of aDes is copied into the target area and aligned within it as dictated by the value of anAlignment. 
     If aWidth has the value KDefaultJustifyWidth, then the width of the target area (i.e. the value of aWidth) is re-set to the length of aDes. 
     If the length of aDes is smaller than the width of the target area, then any spare space within the target area is padded with the fill character aFill. 
     If the length of aDes is greater than the width of the target area, then the amount of data copied from aDes is limited to the value of aWidth. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be copied. 
     TInt aWidth The width of the target area. This must be one of: 
     KDefaultJustifyWidth 
     a non-negative value 
      If it has the value KDefaultjustifyWidth, then it is re-set to the length of aDes. 
      If the value is less than the length of aDes, then the amount of data copied from aDes into the target area is limited to aWidth. 
     TAlign anAlignment An enumeration which dictates the alignment of the data within the target area. See e32.enum.TAlign. 
     TChar aFill The fill character used to pad the target area. 
     Notes 
     If the width of the target area is greater than the maximum length of this descriptor, then the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Do not set aWidth to a negative value (other than KDefaultjustifyWidth) as this may have unpredictable consequences. 
     Example 
     The following code fragments illustrate the use of Justify( ). 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     tgt.Justify(_L(“xyz”),8,ECenter,‘@’); 
     The descriptor tgt has a maximum length of 16 and initially holds the string “abc”. After the call to Justify( ), the content of tgt changes to “@@xyz@@@” as illustrated at FIG.  15 . 
     In this example, the content of the source descriptor is taken to form an 8 character field which replaces the original content of the descriptor tgt. The characters “xyz” are centred within the new field and padded on both sides with the fill character‘@’. 
     Setting the alignment to ELeft would change the content of tgt to “xyz@@@@@ ” while setting the alignment to ERight would change the content of tgt to “@@@@@xyz”In all three cases, the length of the descriptor tgt changes from 3 to 8. 
     TBuf&lt;8&gt; tgt(_L(“abc”)); 
     . . . 
     tgt.Justify(_L(“xyz”),9,ECenter,‘@’); 
     This call to Justify( ) will panic because the resulting length of data in tgt would exceed the maximum length of tgt. 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     . . . 
     tgt.Justify(_L(“rstuvwxyz”),8,ECenter,‘@’); 
     In this call to Justify( ), the content of tgt changes to “rstuvwxy” as illustrated at FIG.  16 . 
     Only eight of the nine characters in the source descriptor&#39;s data area are copied. 
     Insertion/Deletion 
     e32.descriptors.TDes.insertion-deletion 
     Insert( ) Insert from descriptor 
     void Insert(TInt aPos,const TDesC&amp; aDes); 
     Description 
     Use this function to insert the content of aDes into this descriptor&#39;s data area at the specified position. The existing data at the specified position within this descriptor is moved to the right to make way for the inserted data. 
     The length of this descriptor is increased to reflect the increase in content. 
     Arguments 
     TInt aPos The offset within this descriptor&#39;s data area where the content of aDes is to be inserted. This value can range from zero to the length of this descriptor. 
      A value of zero means insert at the beginning of this descriptor&#39;s data area, while a value equal to the length of this descriptor means insert at the end (i.e. append). 
      aPos must not be negative and must not be greater than the length of this descriptor, otherwise the function will panic with ETDes 8 PosOutOfRange for the 8 bit variant or ETDes 16 PosOutOfRange for the 16 bit variant. 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be inserted into this descriptor. 
      The length of aDes plus the length of this descriptor must not exceed the maximum length of this descriptor otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Example 
     The following code fragment illustrates the use of Insert( ). 
     
       
         
               
               
             
               
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBuf&lt;8&gt;tgt(3); 
               
               
                   
                 TPtrC  src(_L(“abc”)); 
               
             
          
           
               
                   
                 . . . 
                 // generates the strings . . . 
               
             
          
           
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Insert(0,_L(“XYZ”));    // “XYZabc” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Insert(1,_L(“XYZ”));    // “aXYZbc” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Insert(tgt.Length( ),_L(“XYZ”)); // “abcXYZ” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Insert(tgt.Length( )+1,_L(“XYZ”)),// ----&gt; Panic !! 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Insert(1,_L(“WXYZ”));   // “aWXYZbc” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Insert(1,_L(“VWXYZ”));   // “aVWXYZbc” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Insert(1,_L(“UVWXYZ”));   // ----&gt; Panic !! 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Delete( ) Delete 
     void Delete(TInt aPos,TInt aLength); 
     Description 
     Use this function to delete a portion of data of length aLength from this descriptor&#39;s data area, starting at position aPos. 
     The length of this descriptor is decreased to reflect the reduction in content. 
     Arguments 
     TInt aPos The offset within this descriptor&#39;s data area where deletion is to start. This value can range from zero to the length of this descriptor. 
      A value of zero means delete from the beginning of this descriptor&#39;s data area, while a value equal to the length of this descriptor means, in effect, that no data will be deleted. 
      aPos must not be negative and must not be greater than the length of this descriptor, otherwise the function will panic with ETDes 8 PosOutOfRange for the 8 bit variant or ETDes 16 PosOutOfRange for the 16 bit variant. 
     TInt aLength The length of data to be deleted from the descriptor. 
      If (aLength+aPos) is greater than the length of this descriptor, then the length of data deleted is (this descriptor length—aPos). In effect, the value of aLength is truncated. 
     Example 
     The following code fragment illustrates the use of Delete( ). 
     
       
         
               
               
             
               
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBuf&lt;8&gt;tgt(4); 
               
               
                   
                 TBufC&lt;4&gt;src(_L(“abcd”)); 
               
             
          
           
               
                   
                 . . . 
                 // generates the strings 
               
             
          
           
               
                   
                 tgt = src; 
                   
               
               
                   
                 tgt.Delete(0,1); 
                 // “bcd” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(0,2); 
                 // “cd” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(0,4); 
                 // “” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(1,2); 
                 // “ad” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(2,2); 
                 // “ab” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(2,3); 
                 // “ab” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(2,256); 
                 // “ab” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(5,1); 
                 // ----&gt; Panics !! 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Delete(−1,1); 
                 // ----&gt; Panics !! 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Replace( ) Replace 
     void Replace(TInt aPos,TInt aLength,const TDesC&amp; aDes); 
     Description 
     Use this function to replace a portion of data of length aLength in this descriptor&#39;s data area, starting at position aPos, with the content of the descriptor aDes. 
     The length of aDes may be less than aLength, in which case the resulting length of this descriptor decreases. 
     The length of aDes may be greater than aLength, in which case the resulting length of this descriptor increases. 
     The length of this descriptor changes to reflect the changed content. 
     Arguments 
     TInt aPos The offset within this descriptor&#39;s data area where replacement is to start. This value can range from zero to the length of this descriptor. 
      A value of zero means replace at the beginning of this descriptor&#39;s data area aPos must not be negative and must not be greater than the length of this descriptor, otherwise the function panics with ETDes 8 PosOutOfRange for the 8 bit variant or ETDes 16 PosOutOfRange for the 16 bit variant. 
     TInt aLength The length of data in this descriptor which is to be replaced. 
      aLength must not be negative and (aLength+aPos) must not be greater than the current length of this descriptor, otherwise the function panics with ETDes 8 LengthOutOfRange for the 8 bit variant or ETDes 16 LengthOutOfRange for the 16 bit variant. 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to replace the data of length aLength at position aPos in this descriptor. 
      The length of aDes must not be negative and must not exceed the maximum length of this descriptor otherwise the function panics with ETDes 8 RemoteLengthOutOfRange for the 8 bit variant or ETDes 8 RemoteLengthOutOfRange for the 16 bit variant. 
      The resulting length of this descriptor must not exceed the maximum length of this descriptor, otherwise the function panics with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Example 
     The following code fragment illustrates the use of Replace( ). 
     
       
         
               
               
             
               
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBuf&lt;8&gt;tgt(4); 
               
               
                   
                 TBufC&lt;4&gt;src(_L(“abcd”)); 
               
             
          
           
               
                   
                 . . . 
                 // generates the strings 
               
             
          
           
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(0,1,_L(“u”));  // “ubcd” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(0,1,_L(“uv”));  // “uvbcd” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(0,1,_L(“uvw”)); // “uvwbcd” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(0,1_L(“uvwxyz”));// ----&gt; Panic !! 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(1,2,_L(“u”));  // “aud” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(1,2,_L(“”));  // “ad” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(1,4,_L(“uvw”)); // ----&gt; Panics !! 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(3,1,_L(“uvw”)); // “abcuvw” 
               
               
                   
                 . . . 
               
               
                   
                 tgt = src; 
               
               
                   
                 tgt.Replace(4,0,_L(“uvw”)); // “abcduvw” 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Delete Leading and Trailing Spaces 
     e32.descriptors.TDes.delete-spaces 
     TrimLeft( ) Delete spaces from left side of descriptor 
     void TrimLeft( ); 
     Description 
     Use this function to delete space characters from the left hand side of the descriptor&#39;s data area. The function deletes every space character, starting at the beginning, until it meets the first non-space character. 
     The length of the descriptor is reduced to reflect the loss of the space characters. 
     Example 
     The following code fragment illustrates the use of TrimLeft( ). 
     
       
         
               
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
                   
               
               
                   
                 TBuf&lt;8&gt; str1(_L(“ abcd ”)); 
                 // generates the following strings 
               
               
                   
                 TBuf&lt;8&gt; str2(_L(“a b ”)); 
                 // in the descriptors str1 and str2 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 str1.Length( ); 
                 // returns 8 
               
               
                   
                 str1.TrimLeft( ); 
                  // “abcd ” 
               
               
                   
                 str1.Length( ); 
                 // returns 6 
               
               
                   
                 . . . 
               
               
                   
                 str2.Length( ); 
                 // returns 5 
               
               
                   
                 str2.TrimLeft( ); 
                  // “ab ” 
               
               
                   
                 str2.Length( ); 
                 // returns 4 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     TrimRight( ) Delete spaces from right side of descriptor 
     void TrimRight( ) 
     Description 
     Use this function to delete space characters from the right hand side of the descriptor&#39;s data area. The function deletes every space character, starting at the end and moving towards the beginning, until it meets the first non-space character. 
     The length of the descriptor is reduced to reflect the loss of the space characters. 
     Example 
     The following code fragment illustrates the use of TrimRight( ). 
     
       
         
               
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
                   
               
               
                   
                 TBuf&lt;8&gt; str1(_L(“ abcd ”)); 
                 // generates the following strings 
               
               
                   
                 TBuf&lt;8&gt; str2(_L(“a b”)); 
                 // in the descriptors str1 and str2 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 str1.Length( ); 
                 // returns 8 
               
               
                   
                 str1.TrimRight( ); 
                  //“ abcd” 
               
               
                   
                 str1.Length( ); 
                 // returns 6 
               
               
                   
                 . . . 
               
               
                   
                 str2.Length( ); 
                 // returns 5 
               
               
                   
                 str2.TrimRight( ); 
                  // “a b” 
               
               
                   
                 str2.Length( ); 
                 // returns 4 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Trim( ) Delete spaces from both sides of descriptor 
     void Trim( ); 
     Use this function to delete space characters from both the left and the right hand sides of the descriptor&#39;s data area. 
     The function deletes every space character starting at the beginning until it meets the first non-space character and deletes every space character starting at the end and moving towards the beginning, until it meets the first non-space character. 
     The length of the descriptor is reduced to reflect the loss of the space characters. 
     Example 
     The following code fragment illustrates the use of Trim( ). 
     
       
         
               
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
                   
               
               
                   
                 TBuf&lt;8&gt; str1(_L(“ abcd ”)); 
                 // generates the following strings 
               
               
                   
                 TBuf&lt;8&gt; str2(_L(“a b”)); 
                 // in the descriptors str1 and str2 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 str1.Length( ); 
                 // returns 8 
               
               
                   
                 str1.Trim( ); 
                  //“ abcd” 
               
               
                   
                 str1.Length( ); 
                 // returns 4 
               
               
                   
                 . . . 
               
               
                   
                 str2.Length( ); 
                 // returns 5 
               
               
                   
                 str2.Trim( ); 
                  // “a b” 
               
               
                   
                 str2.Length( ); 
                 // returns 3 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Fold/Collate 
     e32.descriptors.TDes.fold-collate 
     Fold( ). Fold 
     void Fold( ); 
     Description 
     Use this function to fold the content of this descriptor. See e32descriptors.folding for more information on folding. 
     Collate( ) Collate 
     void Collate( ); 
     Description 
     Use this function to collate the content of this descriptor. See e32:descriptors.collating for more information on collating. 
     Change Case 
     e32.descriptors.TDes.change-case 
     LowerCase( ) Convert to lower case 
     void LowerCase( ); 
     Description 
     Use this function to convert the characters in this descriptor to lower case. 
     UpperCase( ) Convert to upper case 
     void UpperCase( ); 
     Description 
     Use this function to convert the characters of this descriptor to upper case. 
     Capitalise( ) Capitalise 
     void Capitalise( ); 
     Description 
     Use this unction to capitalise the content of this descriptor. 
     Capitalisation here means the conversion of the first character to upper case and the conversion of all remaining characters to lower case. 
     Example 
     The following code fragment illustrates the use of Capitalise( ) 
     
       
         
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBuf&lt;24&gt; tgt(_L(“tHe CaT sAt On ThE mAt.”)); 
               
               
                   
                 . . . 
               
               
                   
                 tgt.Capitalise( ); // changes string to 
               
               
                   
                 // “The cat sat on the mat.” 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Filling 
     e32.descriptors.TDes.filling 
     Fill( ) Fill with character 
     void Fill(TChar aChar); 
     Description 
     Use this function to fill the this descriptor&#39;s data area with the character aChar, replacing any existing content. 
     The data area is filled from the beginning up to its current length. It is not filled to its maximum length. 
     The length of the descriptor remains unchanged. 
     Arguments 
     TChar aChar The character used to fill the descriptor&#39;s data area. 
     Fill( ) Fill with character up to specified length 
     void Fill(TChar aChar,TInt aLength); 
     Description 
     Use this function to fill this descriptor&#39;s data area with aLength characters aChar, replacing any existing content. 
     The length of the descriptor is set to aLength. 
     Arguments 
     TChar aChar The character used to fill this descriptor&#39;s data area 
     TInt aLength The new length of the descriptor. This value must not be negative and must not be greater than the maximum length of this descriptor otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     FillZ( ) Fill with zeroes 
     void FillZ( ); 
     Description 
     Use this function to fill the this descriptor&#39;s data area with zeroes (i.e. 0x00 or 0x0000), replacing any existing content. 
     The descriptor&#39;s data area is filled from the beginning up to its current length. It is not filled up to its maximum length. 
     The length of the descriptor remains unchanged. 
     FillZ( ) Fill with zeroes up to specified length 
     void FillZ(TInt aLength); 
     Description 
     Use this function to fill the this descriptor&#39;s data area with aLength zeroes (i.e. 0x00 or 0x0000), replacing any existing content. 
     The length of the descriptor is set to aLength. 
     Arguments 
     TInt aLength The new length of the descriptor. This value must not be negative and must not be greater than the maximum length of this descriptor otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Integer Conversion 
     e32.descriptors.TDes.integer-conversion 
     Num( ) Convert signed integer 
     void Num(TInt aVal); 
     Description 
     Use this function to convert the signed integer aVal into a decimal character representation and place the resulting characters into this descriptor&#39;s data area, replacing any existing content. If the integer is negative, the character representation is prefixed by a minus sign. 
     Arguments 
     TInt aVal The value to be converted to decimal characters. 
     Example 
     The following code fragment illustrates the use of Num( ). 
     
       
         
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
                   
               
               
                   
                 TBuf&lt;16&gt; tgt; 
                 // generates the following strings 
               
               
                   
                 TInt numpos(176); 
                  // in the descriptor tgt . . . 
               
               
                   
                 TInt numneg(−176); 
               
               
                   
                 . . . 
               
               
                   
                 tgt.Num(numpos); 
                  // “176” 
               
               
                   
                 tgt.Num(numneg); 
                  // “−176” 
               
               
                   
                 . . . 
               
               
                   
                   
               
             
          
         
       
     
     Num( ), NumUC( ) Convert unsigned integer 
     e32.descriptors.TDes.integer-conversion.Numusi 
     void Num(TUint aVal,TRadix aRadix=EDecimal); 
     void NumUC(TUint aVal,TRadix aRadix=EDecimal); 
     Description 
     Use these functions to convert the unsigned integer aVal into its corresponding character representation and place the resulting characters into this descriptor&#39;s data area, replacing any existing content. 
     Num( ) converts the hexadecimal characters ‘a’, ‘b’, ‘c’, ‘d’, ‘e’ and ‘f’ to lower case, while NumUC( ) converts them to upper case. 
     The choice of function is dependent on the needs of applications. 
     Arguments 
     TUint aVal The value to be converted to characters. 
     TRadix aRadix The number system representation for the unsigned integer. This is an enumeration; see e32.descriptors.TRadix. 
      If no value is supplied, then EDecimal is taken by default. 
     Example 
     The following code fragment illustrates the use of Num( ) and NumUC( ). 
     
       
         
               
             
           
               
                   
               
             
             
               
                 . . . 
               
               
                 TBuf&lt;16&gt;tgt;   // generates the following strings 
               
               
                 TUint number(176);   // in the descriptor tgt . . . 
               
               
                 . . . 
               
               
                 tgt.Num(number,EBinary);  // “10101010” 
               
               
                 tgt.Num(number,EOctol);  // “252” 
               
               
                 tgt.Num(number,EDecimal);  // “176” 
               
               
                 tgt.Num(number,EHex);   // “aa” &lt;-NB hex value in lower case 
               
               
                 tgt.NumUC(number,EHex);  // “AA” &lt;-NB hex value in UPPER case 
               
               
                 tgt.Num(number);    // “176” &lt;-EDecimal taken as default 
               
               
                   
               
             
          
         
       
     
     Real Number Conversion 
     e32.descriptors.TDes.real-number-conversion 
     Num( ) Convert floating point number 
     e32.descriptors.num-float 
     TInt Num(TReal aVal,const TRealFormat&amp; aFormat); 
     Description 
     Use this function to convert the floating point number aVal into a character representation and place the resulting characters into this descriptor&#39;s data area, replacing any existing content. 
     The format of the character representation is dictated by aFormat, an object of type TRealFormat. See e32.class.TRealFormat for more information on the TRealFormat class. 
     Arguments 
     TReal aVal The floating point number to be converted. The value must be such that 1.0E-99&lt;=|aVal|&lt;=1.0E99. 
      Any value smaller than 1.0E-99 is assumed to be zero. 
     TRealFormat&amp; aFormat A reference to a TRealFormat object which dictates the format of the conversion. 
     Return value 
     TInt If the conversion is successful, the length of the converted string. 
      If the conversion fails, a negative value indicating the cause of failure. The possible values and their meaning are as follows: 
     KErrArgument The length of the converted number is greater than the maximum length of this descriptor. In other words, there is insufficient space in this descriptor to hold the character representation. 
     KErrOverflow The number is too large to represent 
     KErrUnderflow The number is too small to represent 
     KErrGeneral The conversion cannot be completed; e.g. the value of the iWidth member of TRealFormat is too small. 
     Formatting 
     e32.descriptors.TDes.formatting 
     Format( ) Convert multiple arguments 
     e32.descriptors.format 
     void Format(TRefByValue&lt;const TDesC&gt; aFmt, . . . ); 
     Description 
     Use this function to insert formatted text into this descriptor, as controlled by the format string supplied in the descriptor aFmt and the argument list which follows it. Any existing content in this descriptor is discarded. 
     The format string contained in aFmt contains literal text, embedded with commands for converting the trailing list of arguments into text. 
     The embedded commands are character sequences prefixed with the ‘%’ character. The literal text is simply copied into this descriptor unaltered while the ‘%’ commands are used to convert successive arguments (which follow aFmt in the argument list). 
     The resulting stream of literal text and converted arguments is inserted into this descriptor. The syntax of the embedded commands follows one of the four general patterns shown below. Each bracketed item indicates a character or sequence of characters having a specific meaning. 
     A bracketed item within square brackets is optional. 
     %&lt;type&gt; 
      where &lt;type&gt; is a character code which indicates how data is to be converted. The data is converted without padding and only occupies the space required. 
     %&lt;width&gt;[&lt;prec&gt;]&lt;type&gt; 
      where &lt;type&gt; is a character code indicating how data is to be converted and &lt;width&gt; contains either numeric characters which directly define the size of the field to be occupied by the converted data or an ‘*’ character. An ‘*’ indicates that the size of the field is taken from the next TUint value in the argument list. &lt;prec&gt; is optional and is only relevant when a real number is to be converted. If specified, &lt;prec&gt; must be a ‘.’ character followed by an integer representing the precision of the real number, (i.e. the number of decimal places). If &lt;prec&gt; is omitted, the precision for the conversion of a real number defaults to KDefaultPrecision. 
      The converted data is right-aligned within the field; if it occupies fewer character positions than specified in &lt;width&gt;, it is padded to the left with blank characters. 
      If more than &lt;width&gt; characters are generated by the conversion, then the outcome depends on the value of &lt;type&gt;. 
      If type&gt; is either e, E, f, or F, (the source data is a real number), the value of &lt;width&gt; is ignored and all the generated characters are accepted; however, the maximum number of characters generated can never exceed KMaxRealWidth. 
      If &lt;type&gt; is either g, or G, (the source data is a real number), the value of &lt;Width&gt; is ignored and all the generated characters are accepted; however, the maximum number of characters generated can never exceed KDefaultRealWidth. 
      If the source data is any other type, the converted data is truncated so that only &lt;width&gt; characters are taken. 
     %0&lt;width&gt; [&lt;prec&gt; ]&lt;type&gt; 
      where &lt;type&gt; is a character code indicating how data is to be converted and &lt;width&gt; contains numeric characters which directly define the size of the field to be occupied by the converted data. 
      The converted data is right-aligned within this field; if it occupies fewer character positions than specified in &lt;width&gt;, it is padded to the left with ‘0’ characters. 
      If more than &lt;width&gt; characters are generated by the conversion, then the outcome depends on the value of &lt;type&gt;. 
      If type&gt; is either e, E, f, or F, (the source data is a real number), the value of &lt;width&gt; is ignored and all the generated characters are accepted; however, the maximum number of characters generated can never exceed KMaxRealWidth. 
      If &lt;type&gt; is either g, or G, (the source data is a real number), the value of &lt;width&gt; is ignored and all the generated characters are accepted; however, the maximum number of characters generated can never exceed KDefaultRealWidth. 
      If the source data is any other type, the converted data is truncated so that only &lt;width&gt; characters are taken. 
      &lt;prec&gt; is optional and is only relevant when a real number is to be converted. 
      If specified, &lt;prec&gt; must be a‘.’ character followed by an integer representing the precision of the real number, (i.e. the number of decimal places). If &lt;prec&gt; is omitted, the precision for the conversion of a real number defaults to KDefaultPrecision. 
      (Note: in this specific case, &lt;width&gt; cannot be a single ‘*’ character. If it is necessary to take the width value from the argument list, use the more general pattern %&lt;a&gt;&lt;p&gt; &lt;width&gt;&lt;type&gt;). 
     %&lt;a&gt;&lt;p&gt;&lt;width&gt;[&lt;prec&gt;]&lt;type&gt; 
      where &lt;type&gt; is a character code indicating how data is to be converted and &lt;width&gt; contains either numeric characters which directly define the size of the field to be occupied by the converted data or an ‘*’ character. An ‘*’ indicates that the size of the field is taken from the next TUint value in the argument list. 
      &lt;prec&gt; is optional and is only relevant when a real number is to be converted. 
      If specified, &lt;prec&gt; must be a ‘.’ character followed by an integer representing the precision of the real number, (i.e. the number of decimal places). If &lt;prec&gt; is omitted, the precision for the conversion of a real number defaults to KDefaultPrecision. 
      The converted data is aligned within this field as defined by the value of &lt;a&gt; as follows: 
      + right aligned 
      − left aligned 
      = centre aligned 
      If the converted data occupies fewer character positions than specified in &lt;width&gt;, it is padded with the pad character defined by &lt;p&gt;. 
      Note that a pad character of ‘*’ is a special case. It indicates that the code value of the pad character is taken from the next TUint value in the argument list. The data for conversion is taken from the following argument. 
      Thus, to pad with asterisks, the code value of the asterisk character must be supplied through the argument list. 
      If more than &lt;width&gt; characters are generated by the conversion, then the outcome depends on the value of &lt;type&gt;. 
      If &lt;type&gt; is either e, E, f, or F, (the source data is a real number), the value of &lt;width&gt; is ignored and all the generated characters are accepted; however, the maximum number of characters generated can never exceed KMaxRealWidth. 
      If &lt;type&gt; is either g, or G, (the source data is a real number), the value of &lt;Width&gt; is ignored and all the generated characters are accepted; however, the maximum number of characters generated can never exceed KDefaultRealWidth. 
      If the source data is any other type, the converted data is truncated so that only &lt;widths characters are taken. 
     The conversion of argument data is dictated by the value of &lt;type&gt; which consists of a single character. Note the case of the character as this is significant. 
     The possible values for &lt;type&gt; are as follows: 
     b Interpret the argument as a TUint and convert it to its binary character representation. This can be either upper or lower case. 
     o Interpret the argument as a TUint and convert it to its octal character representation. This can be either upper or lower case. 
     d Interpret the argument as a TInt and convert it to its signed decimal representation. This can be either upper or lower case. 
      If the value is negative, the representation will be prefixed by a minus sign. 
     e Interpret the argument as a TReal and convert it to exponent format representation (See e32.class.TRealFormat and e32.enum.TRealFormatType.) 
      (Note the lower case) 
     E Interpret the argument as a TReal 96  and convert it to exponent format representation (See e32.class.TRealFormat and e32.enum.TRealFormatType). 
      (Note the upper case) 
     f Interpret the argument as a TReal and convert it to fixed format representation (See e32.class.TReal Format and e32.enum.TRealFormatType). 
      (Note the lower case) 
     F Interpret the argument as a TReal 96  and convert it to fixed format representation (See e32.class.TRealFormat and e32.enum.TRealFormatType). 
      (Note the upper case) 
     g Interpret the argument as a TReal and convert it to either fixed or exponent format representation, whichever format can present the greater number of significant digits (See e32.class.TRealFormat and e32.enum.TRealFormatType). 
      (Note the lower case) 
     G Interpret the argument as a TReal 96  and convert it to either fixed or exponent format representation, whichever format can present the greater number of significant digits (See e32.class.TRealFormat and e32.enum.TRealFormatType). 
      (Note the upper case) 
     u Interpret the argument as a TUint and convert it to its unsigned decimal representation. This can be either upper or lower case. 
     x Interpret the argument as a TUint and convert it to its hexadecimal representation. This can be either upper or lower case. 
     p Generate the required number of pad characters. No arguments are accessed. 
      This can be either upper or lower case. 
     c Interpret the argument as a TUint value and convert it to a single ASCH character value. This can be either upper or lower case. 
     s Interpret the argument as a zero terminated string. Copy the characters from the string but exclude the zero terminator. 
      (Note the lower case). 
     S Interpret the argument as the address of a descriptor and copy the characters from it. 
      (Note the upper case). 
     w Interpret the argument as a TUint and convert the value to a two byte binary numeric representation with the least significant byte first. The generated output is two bytes whether this descriptor is an 8 bit or a 16 bit variant. 
      (Note the lower case). 
     W Interpret the argument as a TUint and convert the value to a four byte binary numeric representation with the least significant byte first. The generated output is four bytes whether this descriptor is an 8 bit or a 16 bit variant. 
      (Note the upper case). 
     m Interpret the argument as a TUint and convert the value to a two byte binary numeric representation with the most significant byte first. The generated output is two bytes whether this descriptor is an 8 bit or a 16 bit variant. 
      (Note the lower case). 
     M Interpret the argument as a TUint and convert the value to a four byte binary numeric representation with the most significant byte first. The generated output is four bytes whether this descriptor is an 8 bit or a 16 bit variant. 
      (Note the upper case). 
     Arguments 
     TRefByValue&lt;const TDesC&gt; aFmt Any type of descriptor containing the format string. The TRefByValue is constructed from the aFmt. 
     . . . A variable number of arguments to be converted to text as dictated by the format string in aFmt. 
     Notes 
     Two successive ‘%’ characters are interpreted as literal text and causes one ‘%’ character to be generated. 
     Blank characters are interpreted as literal text. 
     Specifying a pad character of ‘*’ is a special case. It indicates that the code value of the pad character is taken as the next TUint value from the argument list. Any data needed for conversion is taken from the following argument. 
     Thus, to use asterisks as a pad character, the code value of the asterisk character must be supplied in the argument list. 
     Using an ‘*’ character for both &lt;width&gt; and &lt;p&gt; means that the width value and the pad character will be taken from the argument list. Note that the first ‘*’ character will be interpreted as representing the width only if it is preceded by one of the alignment characters ‘+’ ‘−’ or ‘=’ (i.e., if the command follows the fourth general pattern outlined above). 
     Specifying the command %p results in no characters being generated. To be useful, a width needs to specified; for example ‘%1p’ or ‘%6p’. 
     If &lt;prec&gt; is specified when the data to be converted is not a real number, then it is ignored. 
     If any command has incorrect syntax, then the function will panic with ETDes 8 BadFormatDescriptor for the 8 bit variant or ETDes 16 BadFormatDescriptor for the 16 bit variant 
     If the resulting length of text in this descriptor exceeds its maximum length, then the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Example 
     The following code fragments illustrate the various possibilities of Format( ). 
     
       
         
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBuf&lt;256&gt;tgt; 
               
               
                   
                 . . . 
               
               
                   
                 tgt.Format(_L(“[%b %c %d %o %u %x]”),65,65,65,65,65,65); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[1000001 A 65 101 65 41]. 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%04x]”),65; 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[0041] 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%4x]”),65; 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[ 41] 
               
               
                   
                   
                 //  note the use of blanks as 
               
               
                   
                   
                 //  default fill characters 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%*x]”),4,65; 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[ 41] 
               
               
                   
                   
                 //  width taken from the 
               
               
                   
                   
                 //  argument list 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%+$4d.00 %S]”),65,&amp;(_L(“over”))); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[$$65.00 over] 
               
               
                   
                   
                 //   note that %ls can be 
               
               
                   
                   
                 //   replaced by %S 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%+0*S]”),10,&amp;(_L(“fred”))); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[000000fred] 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%=*6x]”),‘*’,65); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[**41**] 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%+**d]”),‘.’,10,(−65)); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[ . . . −65] 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%-A4p]”),65); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[AAAA] 
               
               
                   
                   
                 //   and makes no use of the 
               
               
                   
                   
                 //   argument list 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%m]”),4660); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //the character ‘[’ 
               
               
                   
                   
                 //followed by a byte holding 0x12 
               
               
                   
                   
                 //followed by a byte holding 0x34 
               
               
                   
                   
                 //followed by the character ‘]’ 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%M]”),4660); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //the character ‘[’ 
               
               
                   
                   
                 //followed by a byte holding 0x00 
               
               
                   
                   
                 //followed by a byte holding 0x00 
               
               
                   
                   
                 //followed by a byte holding 0x12 
               
               
                   
                   
                 //followed by a byte holding 0x34 
               
               
                   
                   
                 //followed by the character ‘]’ 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%w]”),4660); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //the character ‘[’ 
               
               
                   
                   
                 //followed by a byte holding 0x34 
               
               
                   
                   
                 //followed by a byte holding 0x12 
               
               
                   
                   
                 //followed by the character ‘]’ 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%W]”),4660); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //the character ‘[’ 
               
               
                   
                   
                 //followed by a byte holding 0x34 
               
               
                   
                   
                 //followed by a byte holding 0x12 
               
               
                   
                   
                 //followed by a byte holding 0x00 
               
               
                   
                   
                 //followed by a byte holding 0x00 
               
               
                   
                   
                 //followed by the character ‘]’ 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%6.2e]”),3.4555); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[3.46E+00] 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%6.2f]”),3.4555); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[ 3.46] 
               
             
          
           
               
                   
                 tgt.Format(_L(“[%6.2g]”),3.4555); 
               
             
          
           
               
                   
                 . . . 
                 //generates: 
               
               
                   
                   
                 //[3.4555] 
               
               
                   
                   
               
             
          
         
       
     
     FormatList( ) Convert multiple arguments 
     void FormatList(const TDesC&amp; aFmt,VA_LIST aList); 
     Description 
     This function is equivalent to Format( ). 
     Arguments 
     const TDesC&amp; aFmt A reference to any type of descriptor containing the format string. 
     VA_LIST aList A pointer to a variable number of arguments to be converted to text as dictated by the format string in aFmt. 
     Appending 
     e32.descriptors.TDes.appending 
     Append( ) Append a character 
     void Append(TChar aChar); 
     Description 
     Use this function to add a character onto the end of the content of this descriptor. 
     The length of this descriptor is incremented by one. 
     Arguments 
     TChar aChar The character to be appended. 
     Notes 
     The length of this descriptor must be less than its maximum length. If the descriptor is already at its maximum length, any attempt to append another character will cause the function to panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Append( ) Append any descriptor 
     void Append(const TDesC&amp; aDes); 
     Description 
     Use this function to append the content of aDes onto the end of the content of this descriptor. 
     The length of this descriptor is incremented by the length of aDes. 
     There is an extra overloaded variation of Append( ) so that, if this descriptor is the 8 bit variant, Append( ) can take the 16 bit variant of aDes as well as the expected 8 bit variant. 
     Thus: 
     an 8 bit descriptor can be appended onto an 8 bit descriptor 
     a 16 bit descriptor can be appended onto a 16 bit descriptor 
     a 16 bit descriptor can be appended onto an 8 bit descriptor. 
     In the case where a 16 bit descriptor is appended to an 8 bit descriptor, each double-byte is appended as a single byte where the value of the double-byte is less than decimal 256. A double-byte value of decimal 256 or greater cannot be appended as a single byte value and, in this case, the single byte is set to a value of decimal 1. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be appended. 
     Notes 
     The resulting length of this descriptor must not be greater than its maximum length otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     Append( ) Append from address 
     void Append(const TUint??* aBuf,TInt aLength); 
     Description 
     Use this function to append data of length aLength at address aBuf onto the end of the content of this descriptor. 
     The length of this descriptor is incremented by the value of aLength. 
     Arguments 
     const TUint??* aBuf The address of the data to be appended. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of the data to be appended. 
     Notes 
     The resulting length of this descriptor must not be greater than its maximum length otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     The value of aLength must be non-negative otherwise the results may be unpredictable. 
     AppendFill( ) Append with fill characters 
     void AppendFill(TChar aChar, TInt aLength); 
     Description 
     Use this function to add aLength characters aChar onto the end of any existing data in this descriptor. 
     Arguments 
     TChar aChar The fill character. 
     TInt aLength The number of fill characters to be appended. 
     Notes 
     The resulting length of this descriptor must not be greater than its maximum length otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     AppendJustify( ) Append any descriptor and justify 
     e32.descriptors.TDes.appending.appendjustify-anydesc 
     void AppendJustify(const TDesC&amp; aDes,TInt aWidth, 
     TAlign anAlignment,TChar aFill); 
     Description 
     Use this function to copy the content of aDes onto the end of the content of this descriptor. 
     The target area within this descriptor is considered to be an area of width aWidth, immediately following the existing data. The source data is copied into this target area and aligned within it as dictated by the value of anAlignment. 
     If aWidth has the value KDefaultJustifyWidth, then the width of the target area (i.e. the value of aWidth) is re-set to the value of aLength. 
     If aLength is smaller than the width of the target area, then any spare space within the target area is padded with the fill character aFill. 
     If aLength is greater than the width of the target area, then the amount of data copied from the location aString is limited to the value of aWidth. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be copied. 
     TInt aWidth The width of the target area. This must be one of: 
     KDefaultJustifyWidth 
     a non-negative value 
      If it has the value KDefaultJustifyWidth, then it is re-set to the length of aDes. 
      If the value is less than the length of aDes, then the amount of data copied from aDes into the target area is limited to this value. 
     TAlign anAlignment An enumeration which dictates the alignment of the data within the target area. See e32.enum.TAlign. 
     TChar aFill The fill character used to pad the target area. 
     Notes 
     If the width of the target area is greater than the maximum length of this descriptor, then the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Do not set aWidth to a negative value (other than KDefaultJustifyWidth) as this may have unpredictable consequences. 
     Example 
     The following code fragments illustrate the use of AppendJustify( ). 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     tgt.AppendJustify(_L(“xyz”),8,ECenter,‘@’); 
     The descriptor tgt has a maximum length of 16 and initially holds the string “abc”. After the call to AppendJustify( ), the content of tgt changes to “abc@@xyz@@@” as illustrated at FIG.  17 . 
     In this example, the content of the source descriptor is taken to form an 8 character field which is appended to the content of the descriptor tgt. The characters “xyz” are centred within the new field and padded on both sides with the fill character ‘@’. 
     Setting the alignment to ELeft would change the content of tmp to “abcxyz@@@@@” while setting the alignment to ERight would change the content of tmp to “abc@@@@@xyz” 
     In all three cases, the length of the descriptor tgt changes from 3 to 11. 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abcdefghik”)); 
     tgt.AppendJustify(_L(“0123456”),7,ECenter,‘@’); 
     This call to AppendJustify( ) will panic because the resulting length of tgt would exceed its maximum length. 
     AppendJustify( ) Append part of any descriptor and justify 
     e32.descriptors.TDes.appending.appendjustify-partdesc 
     void AppendJustify(const TDesC &amp;Des,TInt aLength,TInt aWidth, 
     TAlign anAlignment,TChar aFill); 
     Description 
     Use this function to append data of length aLength from the descriptor aDes onto the end of the content of this descriptor. 
     The target area within this descriptor&#39;s data area is considered to be an area of width aWidth, immediately following the existing data. The source data is copied into this target area and aligned within it as dictated by the value of anAlignment. 
     If aWidth has the value KDefaultJustifyWidth, then the width of the target area (i.e. the value of aWidth) is re-set to the value of aLength. 
     If aLength is smaller than the width of the target area, then any spare space within the target area is padded with the fill character aFill. 
     If aLength is greater than the width of the target area, then the amount of data copied from aDes is limited to the value of aWidth. 
     Arguments 
     coast TDesC&amp; aDes A reference to any type of descriptor whose content is to be copied. 
     TInt aLength The length of data to be copied from the source descriptor aDes. 
      If this value is greater then the value of aWidth, then it is truncated to the value of aWidth. 
     TInt aWidth The width of the target area. This must be one of: 
     &lt;KDefaultJustifyWidth 
     &lt;a non-negative value 
      If it has the value KDefaultJustifyWidth, then it is re-set to the value of aLength. 
      If this value is less than aLength, then the amount of data copied from aDes is limited to aWidth. 
     TAlign anAlignment An enumeration which dictates the alignment of the data within the target area. See e32.enum.TAlign. 
     TChar aFill The fill character used to pad the target area. 
     Notes 
     If the width of the target area is greater than the maximum length of this descriptor, then the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Do not set aWidth to a negative value (other than KDefaultJustifyWidth) as this may have unpredictable consequences. 
     Do not set aLength to a negative value as this may have unpredictable consequences. 
     Make sure that the value of aLength is not greater than the length of aDes otherwise unexpected data may be copied. 
     Example 
     The following code fragments illustrate the use of AppendJustify( ). 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     tgt.AppendJustify(_L(“xyz01234456789”),3,8,ECenter,‘@’); 
     The descriptor tgt has a maximum length of 16 and initially holds the string “abc”. After the call AppendJustify( ), the content of tgt changes to “abc@@xyz@@@” as illustrated in FIG.  18 . 
     In this example, the first three characters of _L“xyz0123456789” are taken to form an 8 character field which is appended to the existing content of the descriptor tgt. The characters “xyz” are centred within the new field and padded on both sides with the fill character ‘@’. 
     Setting the alignment to ELeft would change the content of tgt to “abcxyz@@@@@” while setting the alignment to ERight would change the content of tgt to “abc@@@@@xyz” 
     In all three cases, the length of the descriptor tgt changes from 3 to 11. 
     . . . 
     TBuf&lt;16&gt; tgt(_L(“abc”)); 
     tgt.AppendJustify(_L“0123456789”,9,8,ECenter,‘@’); 
     In this example, the call to AppendJustify( ) changes the content of tgt to “abc01234567”. 
     As the specified length is greater than the specified width, the length is truncated so that only eight characters are copied from the source descriptor. 
     . . . 
     TBuf&lt; 16 &gt; tgt(_L(“abcdefghik”)); 
     tgt.AppendJustify(_L“0123456789”,3,7,ECenter,‘@’); 
     This call to AppendJustify( ) panics because the resulting length of tgt would exceed its maximum length. 
     AppendJustify( ) Append from address and justify 
     e32.descriptors.TDes.appending.appendjustify-fromadr 
     void AppendJustify(const TUint??* aString,TInt aLength,TInt aWidth, 
     TAlign anAlignment,TChar aFill); 
     Description 
     Use this function to append data of length aLength from the address aString onto the end of the content of this descriptor. 
     The target area within this descriptor&#39;s data area is considered to be an area of width aWidth, immediately following the existing data. The source data is copied into this target area and aligned within it as dictated by the value of anAlignment. 
     If aWidth has the value KDefaultJustifyWidth, then the width of the target area (i.e. the value of aWidth) is re-set to the value of aLength. 
     If aLength is smaller than the width of the target area, then any spare space within the target area is padded with the fill character aFill. 
     If aLength is greater than the width of the target area, then the amount of data copied from the location aString is limited to the value of aWidth. 
     Arguments 
     const TUint??* aBuf The address of the data to be copied and appended. 
      For the 8 bit variant, this is type TUint 8 *; for the 16 bit variant, this is type TUint 16 *. 
     TInt aLength The length of data to be copied from the location aString. 
      If this value is greater then the value of aWidth, then it is truncated to the value of aWidth. 
     TInt aWidth The width of the target area This must be one of: 
     KDefaultJustifyWidth 
     a non-negative value 
      If it has the value KDefaultJustifyWidth, then it is re-set to the value of aLength. 
      If this value is less than aLength, then the amount of data copied from the location aString is limited to aWidth. 
     TAlign anAlignment An enumeration which dictates the alignment of the data within the target area See e32.enum.TAlign. 
     TChar aFill The fill character used to pad the target area. 
     Notes 
     If the width of the target area is greater than the maximum length of this descriptor, then the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Do not set aWidth to a negative value (other than KDefaultJustifyWidth) as this may have unpredictable consequences. 
     Do not set aLength to a negative value as this may have unpredictable consequences. 
     AppendJustify( ) Append zero terminated string and justify 
     e32.descriptors.TDes.appending.appendjustify-zeroterm 
     void AppendJustify(const TText* aString,TInt aWidth, 
     TAlign anAlignment,TChar aFill); 
     Description 
     Use this function to append the zero terminated string, located at aString, onto the end of the content of this descriptor. The zero terminator is not copied. 
     The target area within this descriptor&#39;s data area is considered to be an area of width aWidth, immediately following the existing data. The zero terminated string is copied into this target area and aligned within it as dictated by the value of anAlignment. 
     If aWidth has the value KDefaultJustifyWidth, then the width of the target area (i.e. the value of aWidth) is re-set to the length of the zero terminated string, excluding the zero terminator. 
     If the length of the zero terminated string (excluding the zero terminator) is smaller than the width of the target area, then any spare space within the target area is padded with the fill character aFill. 
     If the length of the zero terminated string (excluding the zero terminator) is greater than the width of the target area, then the number of characters copied from aString is limited to the value of aWidth. 
     Arguments 
     const TText* aBuf The address of the zero terminated string to be copied and appended. 
     TInt aWidth The width of the target area. This must be one of: 
     &lt;KDefaultJustifyWidth 
     &lt;a non-negative value 
      If it has the value KDefaultJustifyWidth, then it is re-set to the length of the zero terminated string (excluding the zero terminator). 
      If this value is less than the length of the zero terminated string (excluding the zero terminator), then the number of characters copied from aString is limited to aWidth. 
     TAlign anAlignment An enumeration which dictates the alignment of the data within the target area. See e32.enum.TAlign. 
     TChar aFill The fill character used to pad the target area. 
     Notes 
     If the width of the target area is greater than the maximum length of this descriptor, then the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     Do not set aWidth to a negative value (other than KDefaultJustifyWidth) as this may have unpredictable consequences. 
     AppendNum( ) Append converted signed integer 
     void AppendNum(TInt aVal); 
     Description 
     Use this function to convert the signed integer aVal into a decimal character representation and append the resulting characters onto the end of the content of this descriptor. If the integer is negative, the character representation is prefixed by a minus sign. 
     Arguments 
     TUint aVal The value to be converted to decimal characters. 
     Example 
     The following code fragment illustrates the use of AppendNum( ). 
     
       
         
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
                   
               
               
                   
                 TBuf&lt;16&gt;tgt(_L(“abc”)); 
                  // generates the following strings 
               
               
                   
                 TInt numpos(176); 
                 // in the descriptor tgt . . . 
               
               
                   
                 TInt numneg(−176); 
               
               
                   
                 . . . 
               
               
                   
                 tgt.AppendNum(numpos); 
                 // “abc176” 
               
               
                   
                 tgt.AppendNum(numneg); 
                 // “abc−176” 
               
               
                   
                   
               
             
          
         
       
     
     AppendNum( ), AppendNumUC( ) Append converted unsigned integer 
     e32.descriptors.TDes.appending.Appendnumusi 
     void AppeadNum(TUint aVal,TRadix aRadix=EDecimal); 
     void AppendNunUC(TUint aVal,TRadix aRadix=EDecimal); 
     Description 
     Use these functions to convert the unsigned integer aVal into its corresponding character representation and append the resulting characters onto the end of content of this descriptor. 
     AppendNum( ) converts the hexadecimal characters ‘a’, ‘b’, ‘c’, ‘d’, ‘e’ and ‘f’ to lower case. 
     AppendNumUC( ) converts the hexadecimal characters ‘A’, ‘B’, ‘C’, ‘D’, ‘E’ and ‘F’ to upper case. 
     Arguments 
     TUint aVal The value to be converted to characters. 
     TRadix aRadix The number system representation for the unsigned integer. This is an enumeration; see e32.descriptors.TRadix. 
      If no value is supplied, then EDecimal is taken by default. 
     Example 
     The following code fragment illustrates the use of AppendNum( ) and AppendNumUC( ). 
     
       
         
               
             
               
               
             
               
             
           
               
                   
               
             
             
               
                 . . . 
               
               
                 TBuf&lt;16&gt;tgt(_L(“abc”));  // generates the following strings 
               
               
                 TUint num(176);    // in the descriptor tgt . . . 
               
               
                 . . . 
               
               
                 tgt.AppendNum(num,EBinary);  // “abc 10101010” 
               
               
                 tgt.AppendNum(nwn.EOctol);  // “abc252” 
               
               
                 tgt.AppendNum(num,EDecimal); // “abc176” 
               
               
                 tgt.AppendNum(num,EHex);  // “abcaa” &lt;-NB hex value in lower case 
               
               
                 tgt.AppendNumUC(num,EHex);  // “abcAA” &lt;-NB hex value in UPPER case 
               
             
          
           
               
                   
                 //  and current descriptor 
               
               
                   
                 //  content converted to 
               
               
                   
                 //  upper case. 
               
             
          
           
               
                 tgt.AppendNum(num);   // “abc176”&lt;-EDecimal taken as default 
               
               
                   
               
             
          
         
       
     
     AppendFormat( ) Append converted multiple arguments 
     e32.descriptors.TDes.appending.AppendFormat 
     void AppendFormat(TRefByValue&lt;const TDesC&gt; aFmt, . . . ); 
     void AppendFormat(TRefByValue&lt;const TDesC&gt; aFmt, 
     TDes??Overflow* aOverflowHandler, 
     . . . ); 
     Description 
     Use this function to append formatted text into this descriptor, as controlled by the format string supplied in the descriptor aFmt and the argument list which follows it. The generated text is appended to any existing data within this descriptor. 
     The format string contained in aFmt contains literal text, embedded with commands for converting the trailing list of arguments into text. 
     See the e32.descriptors.format member function for the syntax of the embedded commands. 
     The resulting length of this descriptor must not exceed its maximum length. Once the descriptor reaches its maximum length, any attempt to append more text will result in one of the following: 
     if aOverflowHandler is not supplied, the function panics with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     if aOverflowHandler is supplied, the Overflow( ) member function of either TDes 8 Overflow for the 8 bit variant or TDes 16 Overflow for the 16 bit variant, is called to handle the condition; On return from Overflow( ), AppendFormat( ) completes without panic. 
     Arguments 
     TRefByValue&lt;const TDesC&gt; aFmt Any type of descriptor containing the format string. The TRefByValue is constructed from the aFmt. 
     TDes??Overflow* aOverflowHandler If supplied, a pointer to either a TDes 8 Overflow object (for the 8 bit variant) or a TDes 16 Overflow object (for the 16 bit variant). 
      aOverflowHandler-&gt;Overflow( ) is called if an attempt is made to exceed the maximum length of this descriptor. 
      A variable number of arguments to be converted to text as dictated by the format string in aFmt. 
     AppendFormatList( ) Append converted multiple arguments 
     e32.descriptors.TDes.appending.AppendFormatList 
     void AppendFormatList(const TDesC&amp; aFmt, 
     VA_LIST aList, 
     TDes??Overflow* aOverflowHandler=NULL); 
     Description 
     This function is equivalent to AppendFormat( ). 
     Arguments 
     const TDesC&amp; aFmt A reference to any type of descriptor containing the format string. 
     VA_LIST aList A pointer to a variable number of arguments to be converted to text as dictated by the format string in aFmt. 
     TDes??Overflow* aOverflowHandler If supplied, a pointer to either a TDes 8 Overflow object (for the 8 bit variant) or a TDes 16 Overflow object (for the 16 bit variant). 
      aOverflowHandler-&gt;Overflow( ) is called if an attempt is made to exceed the maximum length of this descriptor. 
     AppendNum( ) Append converted floating point number 
     e32.descriptors.appendnum-float 
     TInt AppendNum(TReal aVal,const TRealFormat&amp; aFormat); 
     Description 
     Use this function to convert the floating point number aVal into a character representation and append the resulting characters onto the end of the content of this descriptor. 
     The format of the character representation is dictated by aFormat, an object of type TRealFormat. See e32.class.TRealFormat for more information on the TRealFormat class. 
     Arguments 
     TReal aVal The floating point number to be converted. The value must be such that 1.0E-99&lt;=|aVal|&lt;=1.0E99. 
     Any value smaller than 1.0E-99 is assumed to be zero. 
     TRealFormat&amp; aFormat A reference to a TRealFormat object which dictates the format of the conversion. 
     Return value 
     TInt If the conversion is successful, the length of the converted string. 
      If the conversion fails, a negative value indicating the cause of failure. The possible values and their meaning are as follows: 
     KErrArgument The length of the converted number is greater than the maximum length of this descriptor. In other words, there is insufficient space in this descriptor to bold the character representation. 
     KErrOverflow The number is too large to represent 
     KErrUnderflow The number is too small to represent 
     KErrGeneral The conversion cannot be completed; e.g. the value of the iWidth member of TRealFormat is too small. 
     Add Zero Terminator 
     e32.descriptors.TDes.zero-terminator 
     ZeroTerminate( ) Append zero terminator 
     void ZeroTerminate( ); 
     Description 
     Use this function to append a zero terminator (i.e. a NULL) onto the end of the content of this descriptor. 
     The length of the descriptor is not changed. 
     Notes 
     The length of the descriptor must be strictly less than its maximum length otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. This condition guarantees that there is sufficient space in the descriptor&#39;s data area for the zero terminator. 
     Example 
     The following code fragment depited in FIG. 19 illustrates the use of ZeroTerminate( ). 
     . . . 
     TBufC&lt;8&gt; str(_L(“abcd”)); 
     . . . 
     tgt.ZeroTerminate( ) 
     . . . 
     The length of the descriptor tgt is 5 both before and after the call to ZeroTerminate( ) 
     PtrZ( ) Append zero terminator and return a pointer 
     const TText PtrZ( ); 
     Description 
     Use this function to append a zero terminator (i.e. a NULL) onto the end of the content of this descriptor and return a pointer to the descriptor&#39;s data area 
     The length of the descriptor is not changed. 
     If the data area only contains text characters, then adding a zero terminator creates a ‘C’ style zero terminated string. 
     Return value 
     const TText* A pointer to the zero terminated string 
     Notes 
     The length of the descriptor must be strictly less than its maximum length otherwise the function will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. This condition guarantees that there is sufficient space in the descriptor&#39;s data area for the zero terminator. 
     The zero terminated string can be accessed through the returned pointer but cannot be changed. 
     Indexing Operators 
     e32.descriptors.TDes.indexing-operators 
     operator[ ] Operator[ ] 
     const TUint??&amp; operator[ ](TInt anIndex) const; 
     TUint??&amp; operator[ ](TInt anIndex); 
     Description 
     Use these operators to return a reference to a single data item within this descriptor (e.g. a text character). The data can be considered as an array of ASCII or UNICODE characters or as an array of bytes (or double-bytes, but not recommended) of binary data. 
     These operators allow the individual elements of the array to be accessed and changed. 
     Two variants of the operator are supplied so that it can return a lvalue when applied to a non-const argument or an rvalue when applied to a const argument. The decision as to which variant to use, is made by the compiler. 
     Arguments 
     TInt anIndex The index value indicating the position of the element within the data area. The index is given relative to zero; i.e. a zero value implies the leftmost data position. 
      This value must be non-negative and less than the current length of the descriptor otherwise the operation will panic with ETDes 8 IndexOutOfRange for the 8 bit variant or ETDes 16 IndexOutOfRange for the 16 bit variant 
     Return value 
     TUint??&amp; A non-const reference to the data at position anIndex. The data is of type TUint8&amp; for 8 bit variants and of type TUint 16 &amp; for 16 bit variants. 
      This is returned when the operator is used to return a lvalue. 
     const TUint??&amp; A const reference to the data at position anIndex. The data is of type TUint8&amp; for 8 bit variants and of type TUint 16 &amp; for 16 bit variants. 
      This is returned when the operator is used to return an rvalue. 
     Example 
     The code fragments illustrates the use of operator[ ]. 
     
       
         
               
               
             
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBuf&lt;8&gt; str(_L(“abcdefg”)); 
               
               
                   
                 TChar ch; 
               
               
                   
                 . . . 
               
             
          
           
               
                   
                 str.Length( ); 
                 // returns 7 
               
               
                   
                 ch = str[0]; 
                 // ch contains the character ‘a’ 
               
               
                   
                 ch = str[3]; 
                 // ch contains the character ‘d’ 
               
               
                   
                 . . . 
               
               
                   
                 str[0] = ‘z’; 
                 // changes str to “zbcdefg” 
               
               
                   
                 str[3] = ‘z’; 
                 // changes str to “abczefg” 
               
               
                   
                 . . . 
               
               
                   
                 ch = str[7]; 
                 // Panic !! 
               
               
                   
                 str[7] = ‘z’; 
                 // Panic !! 
               
               
                   
                   
               
             
          
         
       
     
     Appending Operators 
     e32.descriptors.TDes.appending-operators 
     operator+= Operator+= 
     TDes&amp; operator+=(const TDesC&amp; aDes); 
     Description 
     Use this operator to append the content of aDes onto the end of the content of this descriptor. 
     The length of this descriptor is incremented by the length of aDes. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be appended. 
     Return value 
     TDes&amp; A reference to this descriptor. 
     Notes 
     The operator can only be used by classes derived from TDes, specifically TPtr and TBuf. 
     The resulting length of this descriptor must not be greater than its maximum length otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant 
     Example 
     The following code fragment illustrates the use of this operator. 
     
       
         
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 . . . 
               
               
                   
                 TBuf&lt;16&gt;tgt(_L(“abc”)); 
               
               
                   
                 . . . 
               
               
                   
                 tgt+=(_L(“0123456789”));    // generates “abc0123456789” 
               
               
                   
                 tgt+=(_L(“0123456789qwerty”));  // Panics !! 
               
               
                   
                   
               
             
          
         
       
     
     Non-class Specific Assignment Operators 
     e32.descriptors.TDes.assignment-operators 
     The behaviour of these operators is exactly the same as the class specific operators. However, unlike the class specific operators, these non-class specific operators are not inline. 
     The compiler invokes these non-class specific assignment operators whenever the left hand variable of an assignment operation is not of a concrete type i.e. one of TPtr, TBufC&lt;class S&gt;, TBuf&lt;class S&gt; or HBufC. 
     For example, 
     
       
         
               
             
               
               
             
               
             
               
               
             
               
               
             
               
               
             
           
               
                   
               
             
             
               
                 class TMyClass 
               
             
          
           
               
                   
                 { 
               
             
          
           
               
                 public: 
               
             
          
           
               
                   
                 void MyCopy(TDes&amp; aTarget, TDesC&amp; aSource); 
               
               
                   
                 } 
               
               
                   
                 void TMyClass::MyCopy(TDes&amp; aTarget, TDesC&amp; aSource) 
               
             
          
           
               
                   
                 { 
               
               
                   
                 aTarget = aSource; // Non-class specific operator used. 
               
               
                   
                 } 
               
             
          
           
               
                   
                 { 
               
               
                   
                 TBuf&lt;16&gt;target; 
               
               
                   
                 TBuf&lt;16&gt;source(_L(“ABCDEF”)); 
               
               
                   
                 TMyClass mine; 
               
               
                   
                 mine.MyCopy(target,source); 
               
               
                   
                   
               
             
          
         
       
     
     If the member function MyCopy is changed so that it is prototyped as: 
     void MyCopy(TBuf&lt;16&gt;&amp; aTarget, TDesC&amp; aSource); 
     or even 
     void MyCopy(TBuf&lt;16&gt;&amp; aTarget, TBufC&lt;16&gt;&amp; aSource); 
     then the TBuf&lt;class S&gt; class assignment operator would be used by the compiler. 
     However, such a change could compromise the design of the class TMyclass. 
     operator= Operator=taking any descriptor 
     TDes&amp; operator=(const TDesC&amp; aDes); 
     Description 
     This assignment operator copies the content of any type of descriptor aDes into this descriptor. 
     The content of aDes is copied into this descriptor, replacing the existing content. The length of this descriptor is set to the length of aDes. 
     Arguments 
     const TDesC&amp; aDes A reference to any type of descriptor whose content is to be copied. 
     Return value 
     TDes&amp; A reference to this descriptor. 
     Notes 
     This assignment operator returns a reference to type TDes, i.e. the base abstract class for modifiable descriptors. 
     The length of aDes must not be greater than the maximum length of this descriptor otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     operator= Operator=taking a modifiable descriptor 
     TDes&amp; operator=(const TDesC&amp; aDes); 
     Description 
     This assignment operator copies the content of a modifiable descriptor aDes into this descriptor. 
     The content of aDes is copied into this descriptor, replacing the existing content. The length of this descriptor is set to the length of aDes. 
     Arguments 
     const TDes&amp; aDes A reference to a modifiable type descriptor whose content is to be copied. 
     Return value 
     TDes&amp; A reference to this descriptor. 
     Notes 
     This assignment operator returns a reference to type TDes, i.e. the base abstract class for modifiable descriptors. 
     The length of aDes must not be greater than the maximum length of this descriptor otherwise the operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     operator= Operator=taking zero terminated string 
     TDes&amp; operator=(const TText* aString); 
     Description 
     This assignment operator copies a zero terminated string, excluding the zero terminator, into this descriptor. 
     The copied string replaces the existing content of this descriptor. 
     The length of this descriptor is set to the length of the string (excluding the zero terminator). 
     Arguments 
     const TText* aString The address of the zero terminated string to be copied. 
     Return value 
     TDes&amp; A reference to this descriptor. 
     Notes 
     This assignment operator returns a reference to type TDes, i.e. the base abstract class for modifiable descriptors. 
     The length of aDes must not be greater than the maximum length of this descriptor otherwise the: operation will panic with ETDes 8 Overflow for the 8 bit variant or ETDes 16 Overflow for the 16 bit variant. 
     TDes 8 Overflow Class Overflow Handler (8 bit) 
     Overview 
     Derivation 
     TDes 8 Overflow Abstract: 8 bit variant overflow handler. 
     Defined in 
     e32des8.h 
     Description 
     A TDes 8 Overflow derived object is used by the AppendFormat( ) and AppendFormatList( ) member functions of 8 bit variant descriptors to handle descriptor overflow. 
     Overflow occurs if an attempt is made to append text to the descriptor when the descriptor is already at its maximum length. 
     The class is abstract and defines the pure virtual member function Overflow( ). 
     See e32.descriptors.TDes.appending.AppendFormat and e32 descriptors.TDes.appending.AppendFormatList. 
     Writing derived classes 
     A derived class must provide an implementation for the Overflow( ) member function. 
     Overflow Handling 
     Overflow( ) Overflow handler function 
     virtual void Overflow(TDes 8 &amp; Des); 
     Description 
     A pure virtual function. 
     The function is called by the AppendFormat( ) and the AppendFormatList( ) member functions of an 8bit variant descriptor if an attempt is made to append text to this descriptor when the descriptor is already at its maximum length. 
     A derived class must provide an implementation for this function. 
     Arguments 
     TDes 8 &amp; aDes A reference to the 8 bit variant modifiable descriptor whose overflow has resulted in the call to this function 
     TDes 16 Overflow Class Overflow Handler (16 bit) 
     Overview 
     Derivation 
     TDes 16 Overflow Abstract: 16 bit variant overflow handler. 
     Defined in 
     e32des16.h 
     Description 
     A TDes 16 Overflow derived object is used by the AppendFormat( ) and AppendFormatList( ) member functions of 16 bit variant descriptors to handle descriptor overflow. 
     Overflow occurs if an attempt is made to append text to the descriptor when the descriptor is already at its maximum length. 
     The class is abstract and defines the pure virtual member function Overflow( ). 
     See e32.descriptors.TDes.appending.AppendFormat and e32.descriptors.TDes.appending.AppendFormatList. 
     Writing derived classes 
     A derived class must provide an implementation for the Overflow( ) member function. 
     Overflow Handling 
     Overflow( ) Overflow handler function 
     virtual void Overflow(TDes 16 &amp; aDes); 
     Description 
     A pure virtual function. 
     The function is called by the AppendFormat( ) and the AppendFormatList( ) member functions of an 16 bit variant descriptor if an attempt is made to append text to this descriptor when the descriptor is already at its maximum length. 
     A derived class must provide an implementation for this function. 
     Arguments 
     TDes 16 &amp; aDes A reference to the 16 bit variant modifiable descriptor whose overflow has resulted in the call to this function 
     TRadix enum Number System Representation 
     e32.descriptors.TRadix 
     Defined in 
     e32std.h 
     Description 
     An enumeration whose enumerators govern the number system representation of signed and unsigned integers when converting them into character format. 
     The enumeration is used by the descriptor member functions e32.descriptors.TDes.integer-conversion.Numusi and e32.descriptors.TDes.appending.Appendnumusi. 
     Members 
     
       
         
               
               
             
           
               
                   
               
             
             
               
                 EBinary 
                 Conversion into binary character representation. 
               
               
                 EOctal 
                 Conversion into octal character representation. 
               
               
                 EDecimal 
                 Conversion into decimal character representation. 
               
               
                 EHex 
                 Conversion into hexadecimal character representation 
               
               
                   
               
             
          
         
       
     
     TAlign enum Alignment of data 
     Defined in 
     e32std.h 
     Description 
     An enumeration whose enumerators govern the alignment of data within an area. The enumeration is used by the descriptor member functions e32.descriptors.TDes.copy-justify.justify, e32.descriptors.TDes.appending.appendjustify-anydesc, e32.descriptors.TDes.appending.appendjustify-fromadr and e32.descriptors.TDes.appending.appendjustify-zeroterm. 
     Members 
     
       
         
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 ELeft 
                 Data is left aligned. 
               
               
                   
                 ERight 
                 Data is right aligned. 
               
               
                   
                 ECenter 
                 Data is centered. 
               
               
                   
                   
               
             
          
         
       
     
     _S macro Build independent string 
     Defined in 
     e32def.h 
     Description 
     #if defined(_UNICODE) 
     typedef Text 16  TText; 
     . . . 
     #define _S(a) ((const TText *)L ## a) 
     #else 
     typedef TText 8  TText; 
     . . . 
     #define _S(a) ((const TText *)a) 
     #endif 
     Notes 
     The definition of _S in e32std.def is intertwined with the definition of _L. 
     _L macro Build independent literal 
     Defined in 
     e32def.h 
     Description 
     #if defined( UNICODE) 
     typedef TText 16  TText; 
     #define _L(a) (TPtrC((const TText *)L ## a)) 
     . . . 
     #else 
     typedef TText 8  TText; 
     #define _L(a) (TPtrC((const TText *)(a))) 
     . . . 
     #endif 
     Notes 
     The definition of _L in e32std.def is intertwined with the definition of _S. 
     _S 8  macro 8 bit string 
     Defined in 
     e32def.h 
     Description 
     #define _S 8 (a) ((const TText 8  *)a) 
     _L 8  macro 8 bit literal 
     Defined in 
     e32def.h 
     Description 
     #define L 8 (a) (TPtrC 8 ((const TText 8  *)(a))) 
     _S 16  macro 16 bit string 
     Defined in 
     e32def.h 
     Description 
     #define S  16 (a) ((const TText  16  *)L #a) 
     _L 16  macro 16 bit literal 
     Defined in 
     e32def.h 
     Description 
     #define _L 16 (a) (TPtrC 16 ((const TText 16  *)L ## a)) 
     Glossary definitions 
     
       
         
               
               
               
             
           
               
                   
               
               
                 Term 
                 Aliases 
                 Meaning          See Also 
               
               
                   
               
             
             
               
                 built-in type 
                 n 
                 Data types which are part of the C++ language; 
               
               
                   
                   
                 e.g. unsigned int, unsigned char etc 
               
               
                 descriptor 
                 n 
                 An object capable of representing contiguous data 
               
               
                   
                   
                 and providing member functions to operate on 
               
               
                   
                   
                 that data. 
               
               
                 huffman 
                 v 
                 A process of compressing data. 
               
               
                 encode 
                   
               
               
                 huffman 
                 v 
                 A process of decompressing data which was 
               
               
                 decode 
                   
                 originally compressed using Huffman encoding. 
               
               
                 length 
                 n 
                 The length of data currently represented by a 
               
               
                   
                   
                 descriptor. 
               
               
                 maximum 
                 n 
                 The maximum length of data which a modifiable 
               
               
                 length 
                   
                 type descriptor is capable of holding. 
               
               
                 fold 
                 v 
                 The removal of differences between characters 
               
               
                   
                   
                 that are deemed unimportant for the purposes of 
               
               
                   
                   
                 inexact or case-insensitive matching. As well as 
               
               
                   
                   
                 ignoring differences of case, folding ignores any 
               
               
                   
                   
                 accent on a character. 
               
               
                 collate 
                 v 
                 The removal of differences between characters 
               
               
                   
                   
                 that are deemed unimportant for the purposes of 
               
               
                   
                   
                 ordering characters into their collating sequence 
               
               
                 unicode 
                   
                 ISO 10646-1 defines a “universal character 
               
               
                   
                   
                 code” which uses either 2 or 4 bytes to represent 
               
               
                   
                   
                 characters from a large character set. Thus, Far 
               
               
                   
                   
                 Eastern character sets can be represented. 
               
               
                   
                   
                 In ERA, 2-byte UNICODE support is built deep 
               
               
                   
                   
                 into the system.