% % $Id$ % This file is part of the FPC documentation. % Copyright (C) 1998, by Michael Van Canneyt % % The FPC documentation is free text; you can redistribute it and/or % modify it under the terms of the GNU Library General Public License as % published by the Free Software Foundation; either version 2 of the % License, or (at your option) any later version. % % The FPC Documentation is distributed in the hope that it will be useful, % but WITHOUT ANY WARRANTY; without even the implied warranty of % MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU % Library General Public License for more details. % % You should have received a copy of the GNU Library General Public % License along with the FPC documentation; see the file COPYING.LIB. If not, % write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, % Boston, MA 02111-1307, USA. % \chapter{The Objects unit.} \label{ch:objectsunit} \FPCexampledir{objectex} This chapter documents the \file{objects} unit. The unit was implemented by many people, and was mainly taken from the FreeVision sources. It has been ported to all supported platforms. The methods and fields that are in a \var{Private} part of an object declaration have been left out of this documentation. \section{Constants} The following constants are error codes, returned by the various stream objects. \begin{verbatim} CONST stOk = 0; { No stream error } stError = -1; { Access error } stInitError = -2; { Initialize error } stReadError = -3; { Stream read error } stWriteError = -4; { Stream write error } stGetError = -5; { Get object error } stPutError = -6; { Put object error } stSeekError = -7; { Seek error in stream } stOpenError = -8; { Error opening stream } \end{verbatim} These constants can be passed to constructors of file streams: \begin{verbatim} CONST stCreate = $3C00; { Create new file } stOpenRead = $3D00; { Read access only } stOpenWrite = $3D01; { Write access only } stOpen = $3D02; { Read/write access } \end{verbatim} The following constants are error codes, returned by the collection list objects: \begin{verbatim} CONST coIndexError = -1; { Index out of range } coOverflow = -2; { Overflow } \end{verbatim} Maximum data sizes (used in determining how many data can be used. \begin{verbatim} CONST MaxBytes = 128*1024*1024; { Maximum data size } MaxWords = MaxBytes DIV SizeOf(Word); { Max word data size } MaxPtrs = MaxBytes DIV SizeOf(Pointer); { Max ptr data size } MaxCollectionSize = MaxBytes DIV SizeOf(Pointer); { Max collection size } \end{verbatim} \section{Types} The follwing auxiliary types are defined: \begin{verbatim} TYPE { Character set } TCharSet = SET Of Char; PCharSet = ^TCharSet; { Byte array } TByteArray = ARRAY [0..MaxBytes-1] Of Byte; PByteArray = ^TByteArray; { Word array } TWordArray = ARRAY [0..MaxWords-1] Of Word; PWordArray = ^TWordArray; { Pointer array } TPointerArray = Array [0..MaxPtrs-1] Of Pointer; PPointerArray = ^TPointerArray; { String pointer } PString = ^String; { Filename array } AsciiZ = Array [0..255] Of Char; Sw_Word = Cardinal; Sw_Integer = LongInt; \end{verbatim} The following records are used internaly for easy type conversion: \begin{verbatim} TYPE { Word to bytes} WordRec = packed RECORD Lo, Hi: Byte; END; { LongInt to words } LongRec = packed RECORD Lo, Hi: Word; END; { Pointer to words } PtrRec = packed RECORD Ofs, Seg: Word; END; \end{verbatim} The following record is used when streaming objects: \begin{verbatim} TYPE PStreamRec = ^TStreamRec; TStreamRec = Packed RECORD ObjType: Sw_Word; VmtLink: pointer; Load : Pointer; Store: Pointer; Next : PStreamRec; END; \end{verbatim} The \var{TPoint} basic object is used in the \var{TRect} object (see \sees{TRect}): \begin{verbatim} TYPE PPoint = ^TPoint; TPoint = OBJECT X, Y: Sw_Integer; END; \end{verbatim} \section{Procedures and Functions} \begin{function}{NewStr} \Declaration Function NewStr (Const S: String): PString; \Description \var{NewStr} makes a copy of the string \var{S} on the heap, and returns a pointer to this copy. The allocated memory is not based on the declared size of the string passed to \var{NewStr}, but is baed on the actual length of the string. \Errors If not enough memory is available, an 'out of memory' error will occur. \SeeAlso \seep{DisposeStr} \end{function} \FPCexample{ex40} \begin{procedure}{DisposeStr} \Declaration Procedure DisposeStr (P: PString); \Description \var{DisposeStr} removes a dynamically allocated string from the heap. \Errors None. \SeeAlso \seef{NewStr} \end{procedure} For an example, see \seef{NewStr}. \begin{procedure}{Abstract} \Declaration Procedure Abstract; \Description When implementing abstract methods, do not declare them as \var{abstract}. Instead, define them simply as \var{virtual}. In the implementation of such abstract methods, call the \var{Abstract} procedure. This allows explicit control of what happens when an abstract method is called. The current implementation of \var{Abstract} terminates the program with a run-time error 211. \Errors None. \SeeAlso Most abstract types. \end{procedure} \begin{procedure}{RegisterObjects} \Declaration Procedure RegisterObjects; \Description \var{RegisterObjects} registers the following objects for streaming: \begin{enumerate} \item \var{TCollection}, see \sees{TCollection}. \item \var{TStringCollection}, see \sees{TStringCollection}. \item \var{TStrCollection}, see \sees{TStrCollection}. \end{enumerate} \Errors None. \SeeAlso \seep{RegisterType} \end{procedure} \begin{procedure}{RegisterType} \Declaration Procedure RegisterType (Var S: TStreamRec); \Description \var{RegisterType} registers a new type for streaming. An object cannot be streamed unless it has been registered first. The stream record \var{S} needs to have the following fields set: \begin{description} \item[ObjType: Sw\_Word] This should be a unique identifier. Each possible type should have it's own identifier. \item[VmtLink: pointer] This should contain a pointer to the VMT (Virtual Method Table) of the object you try to register. You can get it with the following expression: \begin{verbatim} VmtLink: Ofs(TypeOf(MyType)^); \end{verbatim} \item[Load : Pointer] is a pointer to a method that initializes an instance of that object, and reads the initial values from a stream. This method should accept as it's sole argument a \var{PStream} type variable. \item[Store: Pointer]is a pointer to a method that stores an instance of the object to a stream. This method should accept as it's sole argument a \var{PStream} type variable. \end{description} \Errors In case of error (if a object with the same \var{ObjType}) is already registered), run-time error 212 occurs. \end{procedure} \FPCexample{myobject} \begin{function}{LongMul} \Declaration Function LongMul (X, Y: Integer): LongInt; \Description \var{LongMul} multiplies \var{X} with \var{Y}. The result is of type \var{Longint}. This avoids possible overflow errors you would normally get when multiplying \var{X} and \var{Y} that are too big. \Errors None. \SeeAlso \seef{LongDiv} \end{function} \begin{function}{LongDiv} \Declaration Function LongDiv (X: Longint; Y: Integer): Integer; \Description \var{LongDiv} divides \var{X} by \var{Y}. The result is of type \var{Integer} instead of type \var{Longint}, as you would get normally. \Errors If Y is zero, a run-time error will be generated. \SeeAlso \seef{LongMul} \end{function} \section{TRect} \label{se:TRect} The \var{TRect} object is declared as follows: \begin{verbatim} TRect = OBJECT A, B: TPoint; FUNCTION Empty: Boolean; FUNCTION Equals (R: TRect): Boolean; FUNCTION Contains (P: TPoint): Boolean; PROCEDURE Copy (R: TRect); PROCEDURE Union (R: TRect); PROCEDURE Intersect (R: TRect); PROCEDURE Move (ADX, ADY: Sw_Integer); PROCEDURE Grow (ADX, ADY: Sw_Integer); PROCEDURE Assign (XA, YA, XB, YB: Sw_Integer); END; \end{verbatim} \begin{function}{TRect.Empty} \Declaration Function TRect.Empty: Boolean; \Description \var{Empty} returns \var{True} if the rectangle defined by the corner points \var{A}, \var{B} has zero or negative surface. \Errors None. \SeeAlso \seef{TRect.Equals}, \seef{TRect.Contains} \end{function} \FPCexample{ex1} \begin{function}{TRect.Equals} \Declaration Function TRect.Equals (R: TRect): Boolean; \Description \var{Equals} returns \var{True} if the rectangle has the same corner points \var{A,B} as the rectangle R, and \var{False} otherwise. \Errors None. \SeeAlso \seefl{Empty}{TRect.Empty}, \seefl{Contains}{TRect.Contains} \end{function} For an example, see \seef{TRect.Empty} \begin{function}{TRect.Contains} \Declaration Function TRect.Contains (P: TPoint): Boolean; \Description \var{Contains} returns \var{True} if the point \var{P} is contained in the rectangle (including borders), \var{False} otherwise. \Errors None. \SeeAlso \seepl{Intersect}{TRect.Intersect}, \seefl{Equals}{TRect.Equals} \end{function} \begin{procedure}{TRect.Copy} \Declaration Procedure TRect.Copy (R: TRect); \Description Assigns the rectangle R to the object. After the call to \var{Copy}, the rectangle R has been copied to the object that invoked \var{Copy}. \Errors None. \SeeAlso \seepl{Assign}{TRect.Assign} \end{procedure} \FPCexample{ex2} \begin{procedure}{TRect.Union} \Declaration Procedure TRect.Union (R: TRect); \Description \var{Union} enlarges the current rectangle so that it becomes the union of the current rectangle with the rectangle \var{R}. \Errors None. \SeeAlso \seepl{Intersect}{TRect.Intersect} \end{procedure} \FPCexample{ex3} \begin{procedure}{TRect.Intersect} \Declaration Procedure TRect.Intersect (R: TRect); \Description \var{Intersect} makes the intersection of the current rectangle with \var{R}. If the intersection is empty, then the rectangle is set to the empty rectangle at coordinate (0,0). \Errors None. \SeeAlso \seepl{Union}{TRect.Union} \end{procedure} \FPCexample{ex4} \begin{procedure}{TRect.Move} \Declaration Procedure TRect.Move (ADX, ADY: Sw\_Integer); \Description \var{Move} moves the current rectangle along a vector with components \var{(ADX,ADY)}. It adds \var{ADX} to the X-coordinate of both corner points, and \var{ADY} to both end points. \Errors None. \SeeAlso \seepl{Grow}{TRect.Grow} \end{procedure} \FPCexample{ex5} \begin{procedure}{TRect.Grow} \Declaration Procedure TRect.Grow (ADX, ADY: Sw\_Integer); \Description \var{Grow} expands the rectangle with an amount \var{ADX} in the \var{X} direction (both on the left and right side of the rectangle, thus adding a length 2*ADX to the width of the rectangle), and an amount \var{ADY} in the \var{Y} direction (both on the top and the bottom side of the rectangle, adding a length 2*ADY to the height of the rectangle. \var{ADX} and \var{ADY} can be negative. If the resulting rectangle is empty, it is set to the empty rectangle at \var{(0,0)}. \Errors None. \SeeAlso \seepl{Move}{TRect.Move}. \end{procedure} \FPCexample{ex6} \begin{procedure}{TRect.Assign} \Declaration Procedure Trect.Assign (XA, YA, XB, YB: Sw\_Integer); \Description \var{Assign} sets the corner points of the rectangle to \var{(XA,YA)} and \var{(Xb,Yb)}. \Errors None. \SeeAlso \seepl{Copy}{TRect.Copy} \end{procedure} For an example, see \seep{TRect.Copy}. \section{TObject} \label{se:TObject} The full declaration of the \var{TObject} type is: \begin{verbatim} TYPE TObject = OBJECT CONSTRUCTOR Init; PROCEDURE Free; DESTRUCTOR Done;Virtual; END; PObject = ^TObject; \end{verbatim} \begin{procedure}{TObject.Init} \Declaration Constructor TObject.Init; \Description Instantiates a new object of type \var{TObject}. It fills the instance up with Zero bytes. \Errors None. \SeeAlso \seepl{Free}{TObject.Free}, \seepl{Done}{TObject.Done} \end{procedure} For an example, see \seepl{Free}{TObject.Free} \begin{procedure}{TObject.Free} \Declaration Procedure TObject.Free; \Description \var{Free} calls the destructor of the object, and releases the memory occupied by the instance of the object. \Errors No checking is performed to see whether \var{self} is \var{nil} and whether the object is indeed allocated on the heap. \SeeAlso \seepl{Init}{TObject.Init}, \seepl{Done}{TObject.Done} \end{procedure} \FPCexample{ex7} \begin{procedure}{TObject.Done} \Declaration Destructor TObject.Done;Virtual; \Description \var{Done}, the destructor of \var{TObject} does nothing. It is mainly intended to be used in the \seep{TObject.Free} method. The destructore Done does not free the memory occupied by the object. \Errors None. \SeeAlso \seepl{Free}{TObject.Free}, \seepl{Init}{TObject.Init} \end{procedure} \FPCexample{ex8} \section{TStream} \label{se:TStream} The \var{TStream} object is the ancestor for all streaming objects, i.e. objects that have the capability to store and retrieve data. It defines a number of methods that are common to all objects that implement streaming, many of them are virtual, and are only implemented in the descendrnt types. Programs should not instantiate objects of type TStream directly, but instead instantiate a descendant type, such as \var{TDosStream}, \var{TMemoryStream}. This is the full declaration of the \var{TStream} object: \begin{verbatim} TYPE TStream = OBJECT (TObject) Status : Integer; { Stream status } ErrorInfo : Integer; { Stream error info } StreamSize: LongInt; { Stream current size } Position : LongInt; { Current position } FUNCTION Get: PObject; FUNCTION StrRead: PChar; FUNCTION GetPos: Longint; Virtual; FUNCTION GetSize: Longint; Virtual; FUNCTION ReadStr: PString; PROCEDURE Open (OpenMode: Word); Virtual; PROCEDURE Close; Virtual; PROCEDURE Reset; PROCEDURE Flush; Virtual; PROCEDURE Truncate; Virtual; PROCEDURE Put (P: PObject); PROCEDURE StrWrite (P: PChar); PROCEDURE WriteStr (P: PString); PROCEDURE Seek (Pos: LongInt); Virtual; PROCEDURE Error (Code, Info: Integer); Virtual; PROCEDURE Read (Var Buf; Count: Sw_Word); Virtual; PROCEDURE Write (Var Buf; Count: Sw_Word); Virtual; PROCEDURE CopyFrom (Var S: TStream; Count: Longint); END; PStream = ^TStream; \end{verbatim} \begin{function}{TStream.Get} \Declaration Function TStream.Get : PObject; \Description \var{Get} reads an object definition from a stream, and returns a pointer to an instance of this object. \Errors On error, \var{TStream.Status} is set, and NIL is returned. \SeeAlso \seepl{Put}{TStream.Put} \end{function} \FPCexample{ex9} \begin{function}{TStream.StrRead} \Declaration Function TStream.StrRead: PChar; \Description \var{StrRead} reads a string from the stream, allocates memory for it, and returns a pointer to a null-terminated copy of the string on the heap. \Errors On error, \var{Nil} is returned. \SeeAlso \seepl{StrWrite}{TStream.StrWrite}, \seefl{ReadStr}{TStream.ReadStr} \end{function} \FPCexample{ex10} \begin{function}{TStream.GetPos} \Declaration TSTream.GetPos : Longint; Virtual; \Description If the stream's status is \var{stOk}, \var{GetPos} returns the current position in the stream. Otherwise it returns \var{-1} \Errors \var{-1} is returned if the status is an error condition. \SeeAlso \seepl{Seek}{TStream.Seek}, \seefl{GetSize}{TStream.GetSize} \end{function} \FPCexample{ex11} \begin{function}{TStream.GetSize} \Declaration Function TStream.GetSize: Longint; Virtual; \Description If the stream's status is \var{stOk} then \var{GetSize} returns the size of the stream, otherwise it returns \var{-1}. \Errors \var{-1} is returned if the status is an error condition. \SeeAlso \seepl{Seek}{TStream.Seek}, \seefl{GetPos}{TStream.GetPos} \end{function} \FPCexample{ex12} \begin{function}{TStream.ReadStr} \Declaration Function TStream.ReadStr: PString; \Description \var{ReadStr} reads a string from the stream, copies it to the heap and returns a pointer to this copy. The string is saved as a pascal string, and hence is NOT null terminated. \Errors On error (e.g. not enough memory), \var{Nil} is returned. \SeeAlso \seefl{StrRead}{TStream.StrRead} \end{function} \FPCexample{ex13} \begin{procedure}{TStream.Open} \Declaration Procedure TStream.Open (OpenMode: Word); Virtual; \Description \var{Open} is an abstract method, that should be overridden by descendent objects. Since opening a stream depends on the stream's type this is not surprising. \Errors None. \SeeAlso \seepl{Close}{TStream.Close}, \seepl{Reset}{TStream.Reset} \end{procedure} For an example, see \seep{TDosStream.Open}. \begin{procedure}{TStream.Close} \Declaration Procedure TStream.Close; Virtual; \Description \var{Close} is an abstract method, that should be overridden by descendent objects. Since Closing a stream depends on the stream's type this is not surprising. \Errors None. \SeeAlso \seepl{Open}{TStream.Open}, \seepl{Reset}{TStream.Reset} \end{procedure} for an example, see \seep{TDosStream.Open}. \begin{procedure}{TStream.Reset} \Declaration PROCEDURE TStream.Reset; \Description \var{Reset} sets the stream's status to \var{0}, as well as the ErrorInfo \Errors None. \SeeAlso \seepl{Open}{TStream.Open}, \seepl{Close}{TStream.Close} \end{procedure} \begin{procedure}{TStream.Flush} \Declaration Procedure TStream.Flush; Virtual; \Description \var{Flush} is an abstract method that should be overridden by descendent objects. It serves to enable the programmer to tell streams that implement a buffer to clear the buffer. \Errors None. \SeeAlso \seepl{Truncate}{TStream.Truncate} \end{procedure} for an example, see \seep{TBufStream.Flush}. \begin{procedure}{TStream.Truncate} \Declaration Procedure TStream.Truncate; Virtual; \Description \var{Truncate} is an abstract procedure that should be overridden by descendent objects. It serves to enable the programmer to truncate the size of the stream to the current file position. \Errors None. \SeeAlso \seepl{Seek}{TStream.Seek} \end{procedure} For an example, see \seep{TDosStream.Truncate}. \begin{procedure}{TStream.Put} \Declaration Procedure TStream.Put (P: PObject); \Description \var{Put} writes the object pointed to by \var{P}. \var{P} should be non-nil. The object type must have been registered with \seep{RegisterType}. After the object has been written, it can be read again with \seefl{Get}{TStream.Get}. \Errors No check is done whether P is \var{Nil} or not. Passing \var{Nil} will cause a run-time error 216 to be generated. If the object has not been registered, the status of the stream will be set to \var{stPutError}. \SeeAlso \seefl{Get}{TStream.Get} \end{procedure} For an example, see \seef{TStream.Get}; \begin{procedure}{TStream.StrWrite} \Declaration Procedure TStream.StrWrite (P: PChar); \Description \var{StrWrite} writes the null-terminated string \var{P} to the stream. \var{P} can only be 65355 bytes long. \Errors None. \SeeAlso \seepl{WriteStr}{TStream.WriteStr}, \seefl{StrRead}{TStream.StrRead}, \seefl{ReadStr}{TStream.ReadStr} \end{procedure} For an example, see \seef{TStream.StrRead}. \begin{procedure}{TStream.WriteStr} \Declaration Procedure TStream.WriteStr (P: PString); \Description \var{StrWrite} writes the pascal string pointed to by \var{P} to the stream. \Errors None. \SeeAlso \seepl{StrWrite}{TStream.StrWrite}, \seefl{StrRead}{TStream.StrRead}, \seefl{ReadStr}{TStream.ReadStr} \end{procedure} For an example, see \seef{TStream.ReadStr}. \begin{procedure}{TStream.Seek} \Declaration PROCEDURE TStream.Seek (Pos: LongInt); Virtual; \Description Seek sets the position to \var{Pos}. This position is counted from the beginning, and is zero based. (i.e. seeek(0) sets the position pointer on the first byte of the stream) \Errors If \var{Pos} is larger than the stream size, \var{Status} is set to \var{StSeekError}. \SeeAlso \seefl{GetPos}{TStream.GetPos}, \seefl{GetSize}{TStream.GetSize} \end{procedure} For an example, see \seep{TDosStream.Seek}. \begin{procedure}{TStream.Error} \Declaration Procedure TStream.Error (Code, Info: Integer); Virtual; \Description \var{Error} sets the stream's status to \var{Code} and \var{ErrorInfo} to \var{Info}. If the \var{StreamError} procedural variable is set, \var{Error} executes it, passing \var{Self} as an argument. This method should not be called directly from a program. It is intended to be used in descendent objects. \Errors None. \SeeAlso \end{procedure} \begin{procedure}{TStream.Read} \Declaration Procedure TStream.Read (Var Buf; Count: Sw\_Word); Virtual; \Description \var{Read} is an abstract method that should be overridden by descendent objects. \var{Read} reads \var{Count} bytes from the stream into \var{Buf}. It updates the position pointer, increasing it's value with \var{Count}. \var{Buf} must be large enough to contain \var{Count} bytes. \Errors No checking is done to see if \var{Buf} is large enough to contain \var{Count} bytes. \SeeAlso \seepl{Write}{TStream.Write}, \seefl{ReadStr}{TStream.ReadStr}, \seefl{StrRead}{TStream.StrRead} \end{procedure} \FPCexample{ex18} \begin{procedure}{TStream.Write} \Declaration Procedure TStream.Write (Var Buf; Count: Sw\_Word); Virtual; \Description \var{Write} is an abstract method that should be overridden by descendent objects. \var{Write} writes \var{Count} bytes to the stream from \var{Buf}. It updates the position pointer, increasing it's value with \var{Count}. \Errors No checking is done to see if \var{Buf} actually contains \var{Count} bytes. \SeeAlso \seepl{Read}{TStream.Read}, \seepl{WriteStr}{TStream.WriteStr}, \seepl{StrWrite}{TStream.StrWrite} \end{procedure} For an example, see \seep{TStream.Read}. \begin{procedure}{TStream.CopyFrom} \Declaration Procedure TStream.CopyFrom (Var S: TStream; Count: Longint); \Description \var{CopyFrom} reads Count bytes from stream \var{S} and stores them in the current stream. It uses the \seepl{Read}{TStream.Read} method to read the data, and the \seepl{Write}{TStream.Write} method to write in the current stream. \Errors None. \SeeAlso \seepl{Read}{TStream.Read}, \seepl{Write}{TStream.Write} \end{procedure} \FPCexample{ex19} \section{TDosStream} \label{se:TDosStream} \var{TDosStream} is a stream that stores it's contents in a file. it overrides a couple of methods of \var{TSteam} for this. In addition to the fields inherited from \var{TStream} (see \sees{TStream}), there are some extra fields, that describe the file. (mainly the name and the OS file handle) No buffering in memory is done when using \var{TDosStream}. All data are written directly to the file. For a stream that buffers in memory, see \sees{TBufStream}. Here is the full declaration of the \var{TDosStream} object: \begin{verbatim} TYPE TDosStream = OBJECT (TStream) Handle: THandle; { DOS file handle } FName : AsciiZ; { AsciiZ filename } CONSTRUCTOR Init (FileName: FNameStr; Mode: Word); DESTRUCTOR Done; Virtual; PROCEDURE Close; Virtual; PROCEDURE Truncate; Virtual; PROCEDURE Seek (Pos: LongInt); Virtual; PROCEDURE Open (OpenMode: Word); Virtual; PROCEDURE Read (Var Buf; Count: Sw_Word); Virtual; PROCEDURE Write (Var Buf; Count: Sw_Word); Virtual; END; PDosStream = ^TDosStream; \end{verbatim} \begin{procedure}{TDosStream.Init} \Declaration Constructor Init (FileName: FNameStr; Mode: Word); \Description \var{Init} instantiates an instance of \var{TDosStream}. The name of the file that contains (or will contain) the data of the stream is given in \var{FileName}. The \var{Mode} parameter determines whether a new file should be created and what access rights you have on the file. It can be one of the following constants: \begin{description} \item[stCreate] Creates a new file. \item[stOpenRead] Read access only. \item[stOpenWrite] Write access only. \item[stOpen] Read and write access. \end{description} \Errors On error, \var{Status} is set to \var{stInitError}, and \var{ErrorInfo} is set to the \dos error code. \SeeAlso \seepl{Done}{TDosStream.Done} \end{procedure} For an example, see \seep{TDosStream.Truncate}. \begin{procedure}{TDosStream.Done} \Declaration Destructor TDosStream.Done; Virtual; \Description \var{Done} closes the file if it was open and cleans up the instance of \var{TDosStream}. \Errors None. \SeeAlso \seepl{Init}{TDosStream.Init}, \seepl{Close}{TDosStream.Close} \end{procedure} for an example, see e.g. \seep{TDosStream.Truncate}. \begin{procedure}{TDosStream.Close} \Declaration Pocedure TDosStream.Close; Virtual; \Description \var{Close} closes the file if it was open, and sets \var{Handle} to -1. Contrary to \seepl{Done}{TDosStream.Done} it does not clean up the instance of \var{TDosStream} \Errors None. \SeeAlso \seep{TStream.Close}, \seepl{Init}{TDosStream.Init}, \seepl{Done}{TDosStream.Done} \end{procedure} For an example, see \seep{TDosStream.Open}. \begin{procedure}{TDosStream.Truncate} \Declaration Procedure TDosStream.Truncate; Virtual; \Description If the status of the stream is \var{stOK}, then \var{Truncate} tries to truncate the stream size to the current file position. \Errors If an error occurs, the stream's status is set to \var{stError} and \var{ErrorInfo} is set to the OS error code. \SeeAlso \seep{TStream.Truncate}, \seefl{GetSize}{TStream.GetSize} \end{procedure} \FPCexample{ex16} \begin{procedure}{TDosStream.Seek} \Declaration Procedure TDosStream.Seek (Pos: LongInt); Virtual; \Description If the stream's status is \var{stOK}, then \var{Seek} sets the file position to \var{Pos}. \var{Pos} is a zero-based offset, counted from the beginning of the file. \Errors In case an error occurs, the stream's status is set to \var{stSeekError}, and the OS error code is stored in \var{ErrorInfo}. \SeeAlso \seep{TStream.Seek}, \seefl{GetPos}{TStream.GetPos} \end{procedure} \FPCexample{ex17} \begin{procedure}{TDosStream.Open} \Declaration Procedure TDosStream.Open (OpenMode: Word); Virtual; \Description If the stream's status is \var{stOK}, and the stream is closed then \var{Open} re-opens the file stream with mode \var{OpenMode}. This call can be used after a \seepl{Close}{TDosStream.Close} call. \Errors If an error occurs when re-opening the file, then \var{Status} is set to \var{stOpenError}, and the OS error code is stored in \var{ErrorInfo} \SeeAlso \seep{TStream.Open}, \seepl{Close}{TDosStream.Close} \end{procedure} \FPCexample{ex14} \begin{procedure}{TDosStream.Read} \Declaration Procedure TDosStream.Read (Var Buf; Count: Sw\_Word); Virtual; \Description If the Stream is open and the stream status is \var{stOK} then \var{Read} will read \var{Count} bytes from the stream and place them in \var{Buf}. \Errors In case of an error, \var{Status} is set to \var{StReadError}, and \var{ErrorInfo} gets the OS specific error, or 0 when an attempt was made to read beyond the end of the stream. \SeeAlso \seep{TStream.Read}, \seepl{Write}{TDosStream.Write} \end{procedure} For an example, see \seep{TStream.Read}. \begin{procedure}{TDosStream.Write} \Declaration Procedure TDosStream.Write (Var Buf; Count: Sw\_Word); Virtual; \Description If the Stream is open and the stream status is \var{stOK} then \var{Write} will write \var{Count} bytes from \var{Buf} and place them in the stream. \Errors In case of an error, \var{Status} is set to \var{StWriteError}, and \var{ErrorInfo} gets the OS specific error. \SeeAlso \seep{TStream.Write}, \seepl{Read}{TDosStream.Read} \end{procedure} For an example, see \seep{TStream.Read}. \section{TBufStream} \label{se:TBufStream} \var{Bufstream} implements a buffered file stream. That is, all data written to the stream is written to memory first. Only when the buffer is full, or on explicit request, the data is written to disk. Also, when reading from the stream, first the buffer is checked if there is any unread data in it. If so, this is read first. If not the buffer is filled again, and then the data is read from the buffer. The size of the buffer is fixed and is set when constructing the file. This is useful if you need heavy throughput for your stream, because it speeds up operations. \begin{verbatim} TYPE TBufStream = OBJECT (TDosStream) LastMode: Byte; { Last buffer mode } BufSize : Sw_Word; { Buffer size } BufPtr : Sw_Word; { Buffer start } BufEnd : Sw_Word; { Buffer end } Buffer : PByteArray; { Buffer allocated } CONSTRUCTOR Init (FileName: FNameStr; Mode, Size: Word); DESTRUCTOR Done; Virtual; PROCEDURE Close; Virtual; PROCEDURE Flush; Virtual; PROCEDURE Truncate; Virtual; PROCEDURE Seek (Pos: LongInt); Virtual; PROCEDURE Open (OpenMode: Word); Virtual; PROCEDURE Read (Var Buf; Count: Sw_Word); Virtual; PROCEDURE Write (Var Buf; Count: Sw_Word); Virtual; END; PBufStream = ^TBufStream; \end{verbatim} \begin{procedure}{TBufStream.Init} \Declaration Constructor Init (FileName: FNameStr; Mode,Size: Word); \Description \var{Init} instantiates an instance of \var{TBufStream}. The name of the file that contains (or will contain) the data of the stream is given in \var{FileName}. The \var{Mode} parameter determines whether a new file should be created and what access rights you have on the file. It can be one of the following constants: \begin{description} \item[stCreate] Creates a new file. \item[stOpenRead] Read access only. \item[stOpenWrite] Write access only. \item[stOpen] Read and write access. \end{description} The \var{Size} parameter determines the size of the buffer that will be created. It should be different from zero. \Errors On error, \var{Status} is set to \var{stInitError}, and \var{ErrorInfo} is set to the \dos error code. \SeeAlso \seep{TDosStream.Init}, \seepl{Done}{TBufStream.Done} \end{procedure} For an example see \seep{TBufStream.Flush}. \begin{procedure}{TBufStream.Done} \Declaration Destructor TBufStream.Done; Virtual; \Description \var{Done} flushes and closes the file if it was open and cleans up the instance of \var{TBufStream}. \Errors None. \SeeAlso \seep{TDosStream.Done}, \seepl{Init}{TBufStream.Init}, \seepl{Close}{TBufStream.Close} \end{procedure} For an example see \seep{TBufStream.Flush}. \begin{procedure}{TBufStream.Close} \Declaration Pocedure TBufStream.Close; Virtual; \Description \var{Close} flushes and closes the file if it was open, and sets \var{Handle} to -1. Contrary to \seepl{Done}{TBufStream.Done} it does not clean up the instance of \var{TBufStream} \Errors None. \SeeAlso \seep{TStream.Close}, \seepl{Init}{TBufStream.Init}, \seepl{Done}{TBufStream.Done} \end{procedure} For an example see \seep{TBufStream.Flush}. \begin{procedure}{TBufStream.Flush} \Declaration Pocedure TBufStream.Flush; Virtual; \Description When the stream is in write mode, the contents of the buffer are written to disk, and the buffer position is set to zero. When the stream is in read mode, the buffer position is set to zero. \Errors Write errors may occur if the file was in write mode. see \seepl{Write}{TBufStream.Write} for more info on the errors. \SeeAlso \seep{TStream.Close}, \seepl{Init}{TBufStream.Init}, \seepl{Done}{TBufStream.Done} \end{procedure} \FPCexample{ex15} \begin{procedure}{TBufStream.Truncate} \Declaration Procedure TBufStream.Truncate; Virtual; \Description If the status of the stream is \var{stOK}, then \var{Truncate} tries to flush the buffer, and then truncates the stream size to the current file position. \Errors Errors can be those of \seepl{Flush}{TBufStream.Flush} or \seep{TDosStream.Truncate}. \SeeAlso \seep{TStream.Truncate}, \seep{TDosStream.Truncate}, \seefl{GetSize}{TStream.GetSize} \end{procedure} For an example, see \seep{TDosStream.Truncate}. \begin{procedure}{TBufStream.Seek} \Declaration Procedure TBufStream.Seek (Pos: LongInt); Virtual; \Description If the stream's status is \var{stOK}, then \var{Seek} sets the file position to \var{Pos}. \var{Pos} is a zero-based offset, counted from the beginning of the file. \Errors In case an error occurs, the stream's status is set to \var{stSeekError}, and the OS error code is stored in \var{ErrorInfo}. \SeeAlso \seep{TStream.Seek}, \seefl{GetPos}{TStream.GetPos} \end{procedure} For an example, see \seep{TStream.Seek}; \begin{procedure}{TBufStream.Open} \Declaration Procedure TBufStream.Open (OpenMode: Word); Virtual; \Description If the stream's status is \var{stOK}, and the stream is closed then \var{Open} re-opens the file stream with mode \var{OpenMode}. This call can be used after a \seepl{Close}{TBufStream.Close} call. \Errors If an error occurs when re-opening the file, then \var{Status} is set to \var{stOpenError}, and the OS error code is stored in \var{ErrorInfo} \SeeAlso \seep{TStream.Open}, \seepl{Close}{TBufStream.Close} \end{procedure} For an example, see \seep{TDosStream.Open}. \begin{procedure}{TBufStream.Read} \Declaration Procedure TBufStream.Read (Var Buf; Count: Sw\_Word); Virtual; \Description If the Stream is open and the stream status is \var{stOK} then \var{Read} will read \var{Count} bytes from the stream and place them in \var{Buf}. \var{Read} will first try to read the data from the stream's internal buffer. If insufficient data is available, the buffer will be filled before contiunuing to read. This process is repeated until all needed data has been read. \Errors In case of an error, \var{Status} is set to \var{StReadError}, and \var{ErrorInfo} gets the OS specific error, or 0 when an attempt was made to read beyond the end of the stream. \SeeAlso \seep{TStream.Read}, \seepl{Write}{TBufStream.Write} \end{procedure} For an example, see \seep{TStream.Read}. \begin{procedure}{TBufStream.Write} \Declaration Procedure TBufStream.Write (Var Buf; Count: Sw\_Word); Virtual; \Description If the Stream is open and the stream status is \var{stOK} then \var{Write} will write \var{Count} bytes from \var{Buf} and place them in the stream. \var{Write} will first try to write the data to the stream's internal buffer. When the internal buffer is full, then the contents will be written to disk. This process is repeated until all data has been written. \Errors In case of an error, \var{Status} is set to \var{StWriteError}, and \var{ErrorInfo} gets the OS specific error. \SeeAlso \seep{TStream.Write}, \seepl{Read}{TBufStream.Read} \end{procedure} For an example, see \seep{TStream.Read}. \section{TMemoryStream} \label{se:TMemoryStream} The \var{TMemoryStream} object implements a stream that stores it's data in memory. The data is stored on the heap, with the possibility to specify the maximum amout of data, and the the size of the memory blocks being used. \begin{verbatim} TYPE TMemoryStream = OBJECT (TStream) BlkCount: Sw_Word; { Number of segments } BlkSize : Word; { Memory block size } MemSize : LongInt; { Memory alloc size } BlkList : PPointerArray; { Memory block list } CONSTRUCTOR Init (ALimit: Longint; ABlockSize: Word); DESTRUCTOR Done; Virtual; PROCEDURE Truncate; Virtual; PROCEDURE Read (Var Buf; Count: Sw_Word); Virtual; PROCEDURE Write (Var Buf; Count: Sw_Word); Virtual; END; PMemoryStream = ^TMemoryStream; \end{verbatim} \begin{procedure}{TMemoryStream.Init} \Declaration Constructor TMemoryStream.Init (ALimit: Longint; ABlockSize: Word); \Description \var{Init} instantiates a new \var{TMemoryStream} object. The memorystreamobject will initially allocate at least \var{ALimit} bytes memory, divided into memory blocks of size \var{ABlockSize}. The number of blocks needed to get to \var{ALimit} bytes is rounded up. By default, the number of blocks is 1, and the size of a block is 8192. This is selected if you specify 0 as the blocksize. \Errors If the stream cannot allocate the initial memory needed for the memory blocks, then the stream's status is set to \var{stInitError}. \SeeAlso \seepl{Done}{TMemoryStream.Done} \end{procedure} For an example, see e.g \seep{TStream.CopyFrom}. \begin{procedure}{TMemoryStream.Done} \Declaration Destructor TMemoryStream.Done; Virtual; \Description \var{Done} releases the memory blocks used by the stream, and then cleans up the memory used by the stream object itself. \Errors None. \SeeAlso \seepl{Init}{TMemoryStream.Init} \end{procedure} For an example, see e.g \seep{TStream.CopyFrom}. \begin{procedure}{TMemoryStream.Truncate} \Declaration Procedure TMemoryStream.Truncate; Virtual; \Description \var{Truncate} sets the size of the memory stream equal to the current position. It de-allocates any memory-blocks that are no longer needed, so that the new size of the stream is the current position in the stream, rounded up to the first multiple of the stream blocksize. \Errors If an error occurs during memory de-allocation, the stream's status is set to \var{stError} \SeeAlso \seep{TStream.Truncate} \end{procedure} \FPCexample{ex20} \begin{procedure}{TMemoryStream.Read} \Declaration Procedure Read (Var Buf; Count: Sw\_Word); Virtual; \Description \var{Read} reads \var{Count} bytes from the stream to \var{Buf}. It updates the position of the stream. \Errors If there is not enough data available, no data is read, and the stream's status is set to \var{stReadError}. \SeeAlso \var{TStream.Read}, \seepl{Write}{TMemoryStream.Write} \end{procedure} For an example, see \seep{TStream.Read}. \begin{procedure}{TMemoryStream.Write} \Declaration Procedure Write (Var Buf; Count: Sw\_Word); Virtual; \Description \var{Write} copies \var{Count} bytes from \var{Buf} to the stream. It updates the position of the stream. If not enough memory is available to hold the extra \var{Count} bytes, then the stream will try to expand, by allocating as much blocks with size \var{BlkSize} (as specified in the constuctor call \seepl{Init}{TMemoryStream.Init}) as needed. \Errors If the stream cannot allocate more memory, then the status is set to \var{stWriteError} \SeeAlso \seep{TStream.Write}, \seepl{Read}{TMemoryStream.Read} \end{procedure} For an example, see \seep{TStream.Read}. \section{TCollection} \label{se:TCollection} The \var{TCollection} object manages a collection of pointers or objects. It also provides a series of methods to manipulate these pointers or objects. Whether or not objects are used depends on the kind of calls you use. ALl kinds come in 2 flavors, one for objects, one for pointers. This is the full declaration of the \var{TCollection} object: \begin{verbatim} TYPE TItemList = Array [0..MaxCollectionSize - 1] Of Pointer; PItemList = ^TItemList; TCollection = OBJECT (TObject) Items: PItemList; { Item list pointer } Count: Sw_Integer; { Item count } Limit: Sw_Integer; { Item limit count } Delta: Sw_Integer; { Inc delta size } Constructor Init (ALimit, ADelta: Sw_Integer); Constructor Load (Var S: TStream); Destructor Done; Virtual; Function At (Index: Sw_Integer): Pointer; Function IndexOf (Item: Pointer): Sw_Integer; Virtual; Function GetItem (Var S: TStream): Pointer; Virtual; Function LastThat (Test: Pointer): Pointer; Function FirstThat (Test: Pointer): Pointer; Procedure Pack; Procedure FreeAll; Procedure DeleteAll; Procedure Free (Item: Pointer); Procedure Insert (Item: Pointer); Virtual; Procedure Delete (Item: Pointer); Procedure AtFree (Index: Sw_Integer); Procedure FreeItem (Item: Pointer); Virtual; Procedure AtDelete (Index: Sw_Integer); Procedure ForEach (Action: Pointer); Procedure SetLimit (ALimit: Sw_Integer); Virtual; Procedure Error (Code, Info: Integer); Virtual; Procedure AtPut (Index: Sw_Integer; Item: Pointer); Procedure AtInsert (Index: Sw_Integer; Item: Pointer); Procedure Store (Var S: TStream); Procedure PutItem (Var S: TStream; Item: Pointer); Virtual; END; PCollection = ^TCollection; \end{verbatim} \begin{procedure}{TCollection.Init} \Declaration Constructor TCollection.Init (ALimit, ADelta: Sw\_Integer); \Description \var{Init} initializes a new instance of a collection. It sets the (initial) maximum number of items in the collection to \var{ALimit}. \var{ADelta} is the increase size : The number of memory places that will be allocatiod in case \var{ALimit} is reached, and another element is added to the collection. \Errors None. \SeeAlso \seepl{Load}{TCollection.Load}, \seepl{Done}{TCollection.Done} \end{procedure} For an example, see \seep{TCollection.ForEach}. \begin{procedure}{TCollection.Load} \Declaration Constructor TCollection.Load (Var S: TStream); \Description \var{Load} initializes a new instance of a collection. It reads from stream \var{S} the item count, the item limit count, and the increase size. After that, it reads the specified number of items from the stream. % Do not call this method if you intend to use only pointers in your collection. \Errors Errors returned can be those of \seefl{GetItem}{TCollection.GetItem}. \SeeAlso \seepl{Init}{TCollection.Init}, \seefl{GetItem}{TCollection.GetItem}, \seepl{Done}{TCollection.Done}. \end{procedure} \FPCexample{ex22} \begin{procedure}{TCollection.Done} \Declaration Destructor TCollection.Done; Virtual; \Description \var{Done} frees all objects in the collection, and then releases all memory occupied by the instance. % Do not call this method if you intend to use only pointers in your collection. \Errors None. \SeeAlso \seepl{Init}{TCollection.Init}, \seepl{FreeAll}{TCollection.FreeAll} \end{procedure} For an example, see \seep{TCollection.ForEach}. \begin{function}{TCollection.At} \Declaration Function TCollection.At (Index: Sw\_Integer): Pointer; \Description \var{At} returns the item at position \var{Index}. \Errors If \var{Index} is less than zero or larger than the number of items in the collection, seepl{Error}{TCollection.Error} is called with \var{coIndexError} and \var{Index} as arguments, resulting in a run-time error. \SeeAlso \seepl{Insert}{TCollection.Insert} \end{function} \FPCexample{ex23} \begin{function}{TCollection.IndexOf} \Declaration Function TCollection.IndexOf (Item: Pointer): Sw\_Integer; Virtual; \Description \var{IndexOf} returns the index of \var{Item} in the collection. If \var{Item} isn't present in the collection, -1 is returned. \Errors \SeeAlso \end{function} \FPCexample{ex24} \begin{function}{TCollection.GetItem} \Declaration Function TCollection.GetItem (Var S: TStream): Pointer; Virtual; \Description \var{GetItem} reads a single item off the stream \var{S}, and returns a pointer to this item. This method is used internally by the Load method, and should not be used directly. \Errors Possible errors are the ones from \seef{TStream.Get}. \SeeAlso \seef{TStream.Get}, seepl{Store}{TCollection.Store} \end{function} \begin{function}{TCollection.LastThat} \Declaration Function TCollection.LastThat (Test: Pointer): Pointer; \Description This function returns the last item in the collection for which \var{Test} returns a non-nil result. \var{Test} is a function that accepts 1 argument: a pointer to an object, and that returns a pointer as a result. \Errors None. \SeeAlso \seefl{FirstThat}{TCollection.FirstThat} \end{function} \FPCexample{ex25} \begin{function}{TCollection.FirstThat} \Declaration Function TCollection.FirstThat (Test: Pointer): Pointer; \Description This function returns the first item in the collection for which \var{Test} returns a non-nil result. \var{Test} is a function that accepts 1 argument: a pointer to an object, and that returns a pointer as a result. \Errors None. \SeeAlso \seefl{LastThat}{TCollection.LastThat} \end{function} \FPCexample{ex26} \begin{procedure}{TCollection.Pack} \Declaration Procedure TCollection.Pack; \Description \var{Pack} removes all \var{Nil} pointers from the collection, and adjusts \var{Count} to reflect this change. No memory is freed as a result of this call. In order to free any memory, you can call \var{SetLimit} with an argument of \var{Count} after a call to \var{Pack}. \Errors None. \SeeAlso \seepl{SetLimit}{TCollection.SetLimit} \end{procedure} \FPCexample{ex26} \begin{procedure}{TCollection.FreeAll} \Declaration Procedure TCollection.FreeAll; \Description \var{FreeAll} calls the destructor of each object in the collection. It doesn't release any memory occumpied by the collection itself, but it does set \var{Count} to zero. \Errors \SeeAlso \seepl{DeleteAll}{TCollection.DeleteAll}, \seepl{FreeItem}{TCollection.FreeItem} \end{procedure} \FPCexample{ex28} \begin{procedure}{TCollection.DeleteAll} \Declaration Procedure TCollection.DeleteAll; \Description \var{DeleteAll} deletes all elements from the collection. It just sets the \var{Count} variable to zero. Contrary to \seepl{FreeAll}{TCollection.FreeAll}, \var{DeletAll} doesn't call the destructor of the objects. \Errors None. \SeeAlso \seepl{FreeAll}{TCollection.FreeAll}, \seepl{Delete}{TCollection.Delete} \end{procedure} \FPCexample{ex29} \begin{procedure}{TCollection.Free} \Declaration Procedure TCollection.Free (Item: Pointer); \Description \var{Free} Deletes \var{Item} from the collection, and calls the destructor \var{Done} of the object. \Errors If the \var{Item} is not in the collection, \var{Error} will be called with \var{coIndexError}. \SeeAlso \seepl{FreeItem}{TCollection.FreeItem}, \end{procedure} \FPCexample{ex30} \begin{procedure}{TCollection.Insert} \Declaration Procedure TCollection.Insert (Item: Pointer); Virtual; \Description \var{Insert} inserts \var{Item} in the collection. \var{TCollection} inserts this item at the end, but descendent objects may insert it at another place. \Errors None. \SeeAlso \seepl{AtInsert}{TCollection.AtInsert}, \seepl{AtPut}{TCollection.AtPut}, \end{procedure} \begin{procedure}{TCollection.Delete} \Declaration Procedure TCollection.Delete (Item: Pointer); \Description \var{Delete} deletes \var{Item} from the collection. It doesn't call the item's destructor, though. For this the \seepl{Free}{TCollection.Free} call is provided. \Errors If the \var{Item} is not in the collection, \var{Error} will be called with \var{coIndexError}. \SeeAlso \seepl{AtDelete}{TCollection.AtDelete},\seepl{Free}{TCollection.Free} \end{procedure} \FPCexample{ex31} \begin{procedure}{TCollection.AtFree} \Declaration Procedure TCollection.AtFree (Index: Sw\_Integer); \Description \var{AtFree} deletes the item at position \var{Index} in the collection, and calls the item's destructor if it is not \var{Nil}. \Errors If \var{Index} isn't valid then \seepl{Error}{TCollection.Error} is called with \var{CoIndexError}. \SeeAlso \seepl{Free}{TCollection.Free}, \seepl{AtDelete}{TCollection.AtDelete} \end{procedure} \FPCexample{ex32} \begin{procedure}{TCollection.FreeItem} \Declaration Procedure TCollection.FreeItem (Item: Pointer); Virtual; \Description \var{FreeItem} calls the destructor of \var{Item} if it is not nil. This function is used internally by the TCollection object, and should not be called directly. \Errors None. \SeeAlso \seepl{Free}{TCollection.AtFree}, seepl{AtFree}{TCollection.AtFree} \end{procedure} \begin{procedure}{TCollection.AtDelete} \Declaration Procedure TCollection.AtDelete (Index: Sw\_Integer); \Description \var{AtDelete} deletes the pointer at position \var{Index} in the collection. It doesn't call the object's destructor. \Errors If \var{Index} isn't valid then \seepl{Error}{TCollection.Error} is called with \var{CoIndexError}. \SeeAlso \seepl{Delete}{TCollection.Delete} \end{procedure} \FPCexample{ex33} \begin{procedure}{TCollection.ForEach} \Declaration Procedure TCollection.ForEach (Action: Pointer); \Description \var{ForEach} calls \var{Action} for each element in the collection, and passes the element as an argument to \var{Action}. \var{Action} is a procedural type variable that accepts a pointer as an argument. \Errors None. \SeeAlso \seefl{FirstThat}{TCollection.FirstThat}, \seefl{LastThat}{TCollection.LastThat} \end{procedure} \FPCexample{ex21} \begin{procedure}{TCollection.SetLimit} \Declaration Procedure TCollection.SetLimit (ALimit: Sw\_Integer); Virtual; \Description \var{SetLimit} sets the maximum number of elements in the collection. \var{ALimit} must not be less than \var{Count}, and should not be larger than \var{MaxCollectionSize} \Errors None. \SeeAlso \seepl{Init}{TCollection.Init} \end{procedure} For an example, see \seepl{Pack}{TCollection.Pack}. \begin{procedure}{TCollection.Error} \Declaration Procedure TCollection.Error (Code, Info: Integer); Virtual; \Description \var{Error} is called by the various \var{TCollection} methods in case of an error condition. The default behaviour is to make a call to \var{RunError} with an error of \var{212-Code}. This method can be overridden by descendent objects to implement a different error-handling. \Errors \SeeAlso \seep{Abstract} \end{procedure} \begin{procedure}{TCollection.AtPut} \Declaration Procedure TCollection.AtPut (Index: Sw\_Integer; Item: Pointer); \Description \var{AtPut} sets the element at position \var{Index} in the collection to \var{Item}. Any previous value is overwritten. \Errors If \var{Index} isn't valid then \seepl{Error}{TCollection.Error} is called with \var{CoIndexError}. \SeeAlso \end{procedure} For an example, see \seepl{Pack}{TCollection.Pack}. \begin{procedure}{TCollection.AtInsert} \Declaration Procedure TCollection.AtInsert (Index: Sw\_Integer; Item: Pointer); \Description \var{AtInsert} inserts \var{Item} in the collection at position \var{Index}, shifting all elements by one position. In case the current limit is reached, the collection will try to expand with a call to \var{SetLimit} \Errors If \var{Index} isn't valid then \seepl{Error}{TCollection.Error} is called with \var{CoIndexError}. If the collection fails to expand, then \var{coOverFlow} is passd to \var{Error}. \SeeAlso \seepl{Insert}{TCollection.Insert} \end{procedure} \FPCexample{ex34} \begin{procedure}{TCollection.Store} \Declaration Procedure TCollection.Store (Var S: TStream); \Description \var{Store} writes the collection to the stream \var{S}. It does this by writeing the current \var{Count}, \var{Limit} and \var{Delta} to the stream, and then writing each item to the stream. The contents of the stream are then suitable for instantiating another collection with \seepl{Load}{TCollection.Load}. \Errors Errors returned are those by \seep{TStream.Put}. \SeeAlso \seepl{Load}{TCollection.Load}, \seepl{PutItem}{TCollection.PutItem} \end{procedure} For an example, see seepl{Load}{TCollection.Load}. \begin{procedure}{TCollection.PutItem} \Declaration Procedure TCollection.PutItem (Var S: TStream; Item: Pointer); Virtual; \Description \var{PutItem} writes \var{Item} to stream \var{S}. This method is used internaly by the \var{TCollection} object, and should not be called directly. \Errors Errors are those returned by \seep{TStream.Put}. \SeeAlso \seepl{Store}{TCollection.Store}, \seefl{GetItem}{TCollection.GetItem}. \end{procedure} \section{TSortedCollection} \label{se:TSortedCollection} \var{TSortedCollection} is an abstract class, implementing a sorted collection. You should never use an instance of \var{TSortedCollection} directly, instead you should declare a descendent type, and override the \seefl{Compare}{TSortedCollection.Compare} method. Because the collection is ordered, \var{TSortedCollection} overrides some \var{TCollection} methods, to provide faster routines for lookup. The \seefl{Compare}{TSortedCollection.Compare} method decides how elements in the collection should be ordered. Since \var{TCollection} has no way of knowing how to order pointers, you must override the compare method. Additionally, \var{TCollection} provides a means to filter out duplicates. if you set \var{Duplicates} to \var{False} (the default) then duplicates will not be allowed. Here is the complete declaration of \var{TSortedCollection} \begin{verbatim} TYPE TSortedCollection = OBJECT (TCollection) Duplicates: Boolean; { Duplicates flag } Constructor Init (ALimit, ADelta: Sw_Integer); Constructor Load (Var S: TStream); Function KeyOf (Item: Pointer): Pointer; Virtual; Function IndexOf (Item: Pointer): Sw_Integer; Virtual; Function Compare (Key1, Key2: Pointer): Sw_Integer; Virtual; Function Search (Key: Pointer; Var Index: Sw_Integer): Boolean;Virtual; Procedure Insert (Item: Pointer); Virtual; Procedure Store (Var S: TStream); END; PSortedCollection = ^TSortedCollection; \end{verbatim} In the subsequent examples, the following descendent of \var{TSortedCollection} is used: \FPCexample{mysortc} \begin{procedure}{TSortedCollection.Init} \Declaration Constructor TSortedCollection.Init (ALimit, ADelta: Sw\_Integer); \Description \var{Init} calls the inherited constuctor (see \seep{TCollection.Init}) and sets the \var{Duplicates} flag to false. You should not call this method directly, since \var{TSortedCollection} is a abstract class. Instead, the descendent classes should call it via the \var{inherited} keyword. \Errors None. \SeeAlso \seepl{Load}{TSortedCollection.Load}, \seepl{Done}{TCollection.Done} \end{procedure} For an example, see \begin{procedure}{TSortedCollection.Load} \Declaration Constructor Load (Var S: TStream); \Description \var{Load} calls the inherited constuctor (see \seep{TCollection.Load}) and reads the \var{Duplicates} flag from the stream.. You should not call this method directly, since \var{TSortedCollection} is a abstract class. Instead, the descendent classes should call it via the \var{inherited} keyword. \Errors None. \SeeAlso \seepl{Init}{TSortedCollection.Init}, \seepl{Done}{TCollection.Done} \end{procedure} For an example, see \seep{TCollection.Load}. \begin{function}{TSortedCollection.KeyOf} \Declaration Function TSortedCollection.KeyOf (Item: Pointer): Pointer; Virtual; \Description \var{KeyOf} returns the key associated with \var{Item}. \var{TSortedCollection} returns the item itself as the key, descendent objects can override this method to calculate a (unique) key based on the item passed (such as hash values). \var{Keys} are used to sort the objects, they are used to search and sort the items in the collection. If descendent types override this method then it allows possibly for faster search/sort methods based on keys rather than on the objects themselves. \Errors None. \SeeAlso \seefl{IndexOf}{TSortedCollection.IndexOf}, \seefl{Compare}{TSortedCollection.Compare}. \end{function} \begin{function}{TSortedCollection.IndexOf} \Declaration Function TSortedCollection.IndexOf (Item: Pointer): Sw\_Integer; Virtual; \Description \var{IndexOf} returns the index of \var{Item} in the collection. It searches for the object based on it's key. If duplicates are allowed, then it returns the index of last object that matches \var{Item}. In case \var{Item} is not found in the collection, -1 is returned. \Errors None. \SeeAlso \seefl{Search}{TSortedCollection.Search}, \seefl{Compare}{TSortedCollection.Compare}. \end{function} For an example, see \seef{TCollection.IndexOf} \begin{function}{TSortedCollection.Compare} \Declaration Function TSortedCollection.Compare (Key1, Key2: Pointer): Sw\_Integer; Virtual; \Description \var{Compare} is an abstract method that should be overridden by descendent objects in order to compare two items in the collection. This method is used in the \seefl{Search}{TSortedCollection.Search} method and in the \seepl{Insert}{TSortedCollection.Insert} method to determine the ordering of the objects. The function should compare the two keys of items and return the following function results: \begin{description} \item [Result < 0] If \var{Key1} is logically before \var{Key2} (\var{Key1 0] If \var{Key1} is logically after \var{Key2} (\var{Key1>Key2}) \end{description} \Errors An 'abstract run-time error' will be generated if you call \var{TSortedCollection.Compare} directly. \SeeAlso \seefl{IndexOf}{TSortedCollection.IndexOf}, \seefl{Search}{TSortedCollection.Search} \end{function} \FPCexample{mysortc} \begin{function}{TSortedCollection.Search} \Declaration Function TSortedCollection.Search (Key: Pointer; Var Index: Sw\_Integer): Boolean;Virtual; \Description \var{Search} looks for the item with key \var{Key} and returns the position of the item (if present) in the collection in \var{Index}. Instead of a linear search as \var{TCollection} does, \var{TSortedCollection} uses a binary search based on the keys of the objects. It uses the \seefl{Compare}{TSortedCollection.Compare} function to implement this search. If the item is found, \var{Search} returns \var{True}, otherwise \var{False} is returned. \Errors None. \SeeAlso \seefl{IndexOf}{TCollection.IndexOf}. \end{function} \FPCexample{ex36} \begin{procedure}{TSortedCollection.Insert} \Declaration Procedure TSortedCollection.Insert (Item: Pointer); Virtual; \Description \var{Insert} inserts an item in the collection at the correct position, such that the collection is ordered at all times. You should never use \seepl{Atinsert}{TCollection.AtInsert}, since then the collection ordering is not guaranteed. If \var{Item} is already present in the collection, and \var{Duplicates} is \var{False}, the item will not be inserted. \Errors None. \SeeAlso \seepl{AtInsert}{TCollection.AtInsert} \end{procedure} \FPCexample{ex35} \begin{procedure}{TSortedCollection.Store} \Declaration Procedure TSortedCollection.Store (Var S: TStream); \Description \var{Store} writes the collection to the stream \var{S}. It does this by calling the inherited \seep{TCollection.Store}, and then writing the \var{Duplicates} flag to the stream. After a \var{Store}, the collection can be loaded from the stream with the constructor \seepl{Load}{TSortedCollection.Load} \Errors Errors can be those of \seep{TStream.Put}. \SeeAlso \seepl{Load}{TSortedCollection.Load} \end{procedure} For an example, see \seep{TCollection.Load}. \section{TStringCollection} \label{se:TStringCollection} The \var{TStringCollection} object manages a sorted collection of pascal strings. To this end, it overrides the \seefl{Compare}{TSortedCollection.Compare} method of \var{TSortedCollection}, and it introduces methods to read/write strings from a stream. Here is the full declaration of the \var{TStringCollection} object: \begin{verbatim} TYPE TStringCollection = OBJECT (TSortedCollection) Function GetItem (Var S: TStream): Pointer; Virtual; Function Compare (Key1, Key2: Pointer): Sw_Integer; Virtual; Procedure FreeItem (Item: Pointer); Virtual; Procedure PutItem (Var S: TStream; Item: Pointer); Virtual; END; PStringCollection = ^TStringCollection; \end{verbatim} \begin{function}{TStringCollection.GetItem} \Declaration Function TStringCollection.GetItem (Var S: TStream): Pointer; Virtual; \Description \var{GetItem} reads a string from the stream \var{S} and returns a pointer to it. It doesn't insert the string in the collection. This method is primarily introduced to be able to load and store the collection from and to a stream. \Errors The errors returned are those of \seef{TStream.ReadStr}. \SeeAlso \seepl{PutItem}{TStringCollection.PutItem} \end{function} \begin{function}{TStringCollection.Compare} \Declaration Function TStringCollection.Compare (Key1, Key2: Pointer): Sw\_Integer; Virtual; \Description \var{TStringCollection} overrides the \var{Compare} function so it compares the two keys as if they were pointers to strings. The compare is done case sensitive. It returns the following results: \begin{description} \item[-1] if the first string is alphabetically earlier than the second string. \item[0] if the two strings are equal. \item[1] if the first string is alphabetically later than the second string. \end{description} \Errors None. \SeeAlso \seef{TSortedCollection.Compare} \end{function} \FPCexample{ex37} \begin{procedure}{TStringCollection.FreeItem} \Declaration Procedure TStringCollection.FreeItem (Item: Pointer); Virtual; \Description \var{TStringCollection} overrides \var{FreeItem} so that the string pointed to by \var{Item} is disposed from memory. \Errors None. \SeeAlso \seep{TCollection.FreeItem} \end{procedure} \begin{procedure}{TStringCollection.PutItem} \Declaration Procedure TStringCollection.PutItem (Var S: TStream; Item: Pointer); Virtual; \Description \var{PutItem} writes the string pointed to by \var{Item} to the stream \var{S}. This method is primarily used in the \var{Load} and \var{Store} methods, and should not be used directly. \Errors Errors are those of \seep{TStream.WriteStr}. \SeeAlso \seefl{GetItem}{TStringCollection.GetItem} \end{procedure} \section{TStrCollection} \label{se:TStrCollection} The \var{TStrCollection} object manages a sorted collection of null-terminated strings (pchar strings). To this end, it overrides the \seefl{Compare}{TSortedCollection.Compare} method of \var{TSortedCollection}, and it introduces methods to read/write strings from a stream. Here is the full declaration of the \var{TStrCollection} object: \begin{verbatim} TYPE TStrCollection = OBJECT (TSortedCollection) Function Compare (Key1, Key2: Pointer): Sw_Integer; Virtual; Function GetItem (Var S: TStream): Pointer; Virtual; Procedure FreeItem (Item: Pointer); Virtual; Procedure PutItem (Var S: TStream; Item: Pointer); Virtual; END; PStrCollection = ^TStrCollection; \end{verbatim} \begin{function}{TStrCollection.GetItem} \Declaration Function TStrCollection.GetItem (Var S: TStream): Pointer; Virtual; \Description \var{GetItem} reads a null-terminated string from the stream \var{S} and returns a pointer to it. It doesn't insert the string in the collection. This method is primarily introduced to be able to load and store the collection from and to a stream. \Errors The errors returned are those of \seef{TStream.StrRead}. \SeeAlso \seepl{PutItem}{TStrCollection.PutItem} \end{function} \begin{function}{TStrCollection.Compare} \Declaration Function TStrCollection.Compare (Key1, Key2: Pointer): Sw\_Integer; Virtual; \Description \var{TStrCollection} overrides the \var{Compare} function so it compares the two keys as if they were pointers to strings. The compare is done case sensitive. It returns \begin{description} \item[-1] if the first string is alphabetically earlier than the second string. \item[0] if the two strings are equal. \item[1] if the first string is alphabetically later than the second string. \end{description} \Errors None. \SeeAlso \seef{TSortedCollection.Compare} \end{function} \FPCexample{ex38} \begin{procedure}{TStrCollection.FreeItem} \Declaration Procedure TStrCollection.FreeItem (Item: Pointer); Virtual; \Description \var{TStrCollection} overrides \var{FreeItem} so that the string pointed to by \var{Item} is disposed from memory. \Errors None. \SeeAlso \seep{TCollection.FreeItem} \end{procedure} \begin{procedure}{TStrCollection.PutItem} \Declaration Procedure TStrCollection.PutItem (Var S: TStream; Item: Pointer); Virtual; \Description \var{PutItem} writes the string pointed to by \var{Item} to the stream \var{S}. This method is primarily used in the \var{Load} and \var{Store} methods, and should not be used directly. \Errors Errors are those of \seep{TStream.StrWrite}. \SeeAlso \seefl{GetItem}{TStrCollection.GetItem} \end{procedure} \section{TUnSortedStrCollection} \label{se:TUnSortedStrCollection} The \var{TUnSortedStrCollection} object manages an unsorted list of strings. To this end, it overrides the \seep{TStringCollection.Insert} method to add strings at the end of the collection, rather than in the alphabetically correct position. Take care, the \seefl{Search}{TSortedCollection.Search} and \seefl{IndexOf}{TCollection.IndexOf} methods will not work on an unsorted string collection. Here is the full declaration of the {TUnsortedStrCollection} object: \begin{verbatim} TYPE TUnSortedStrCollection = OBJECT (TStringCollection) Procedure Insert (Item: Pointer); Virtual; END; PUnSortedStrCollection = ^TUnSortedStrCollection; \end{verbatim} \begin{procedure}{TUnSortedStrCollection.Insert} \Declaration Procedure TUnSortedStrCollection.Insert (Item: Pointer); Virtual; \Description \var{Insert} inserts a string at the end of the collection, instead of on it's alphabetical place, resulting in an unsorted collection of strings. \Errors \SeeAlso \end{procedure} \FPCexample{ex39} \section{TResourceCollection} \label{se:TResourceCollection} A \var{TResourceCollection} manages a collection of resource names. It stores the position and the size of a resource, as well as the name of the resource. It stores these items in records that look like this: \begin{verbatim} TYPE TResourceItem = packed RECORD Posn: LongInt; Size: LongInt; Key : String; End; PResourceItem = ^TResourceItem; \end{verbatim} It overrides some methods of \var{TStringCollection} in order to accomplish this. Remark that the \var{TResourceCollection} manages the names of the resources and their assiciated positions and sizes, it doesn't manage the resources themselves. Here is the full declaration of the \var{TResourceCollection} object: \begin{verbatim} TYPE TResourceCollection = OBJECT (TStringCollection) Function KeyOf (Item: Pointer): Pointer; Virtual; Function GetItem (Var S: TStream): Pointer; Virtual; Procedure FreeItem (Item: Pointer); Virtual; Procedure PutItem (Var S: TStream; Item: Pointer); Virtual; END; PResourceCollection = ^TResourceCollection; \end{verbatim} \begin{function}{TResourceCollection.KeyOf} \Declaration Function TResourceCollection.KeyOf (Item: Pointer): Pointer; Virtual; \Description \var{KeyOf} returns the key of an item in the collection. For resources, the key is a pointer to the string with the resource name. \Errors None. \SeeAlso \seef{TStringCollection.Compare} \end{function} \begin{function}{TResourceCollection.GetItem} \Declaration Function TResourceCollection.GetItem (Var S: TStream): Pointer; Virtual; \Description \var{GetItem} reads a resource item from the stream \var{S}. It reads the position, size and name from the stream, in that order. It DOES NOT read the resource itself from the stream. The resulting item is not inserted in the collection. This call is manly for internal use by the \seep{TCollection.Load} method. \Errors Errors returned are those by \seep{TStream.Read} \SeeAlso \seep{TCollection.Load}, \seep{TStream.Read} \end{function} \begin{procedure}{TResourceCollection.FreeItem} \Declaration Procedure TResourceCollection.FreeItem (Item: Pointer); Virtual; \Description \var{FreeItem} releases the memory occupied by \var{Item}. It de-allocates the name, and then the resourceitem record. It does NOT remove the item from the collection. \Errors None. \SeeAlso \seep{TCollection.FreeItem} \end{procedure} \begin{procedure}{TResourceCollection.PutItem} \Declaration Procedure TResourceCollection.PutItem (Var S: TStream; Item: Pointer); Virtual; \Description \var{PutItem} writes \var{Item} to the stream \var{S}. It does this by writing the position and size and name of the resource item to the stream. This method is used primarily by the \seepl{Store}{TCollection.Store} method. \Errors Errors returned are those by \seep{TStream.Write}. \SeeAlso \seepl{Store}{TCollection.Store} \end{procedure} \section{TResourceFile} \label{se:TResourceFile} \begin{verbatim} TYPE TResourceFile = OBJECT (TObject) Stream : PStream; { File as a stream } Modified: Boolean; { Modified flag } Constructor Init (AStream: PStream); Destructor Done; Virtual; Function Count: Sw_Integer; Function KeyAt (I: Sw_Integer): String; Function Get (Key: String): PObject; Function SwitchTo (AStream: PStream; Pack: Boolean): PStream; Procedure Flush; Procedure Delete (Key: String); Procedure Put (Item: PObject; Key: String); END; PResourceFile = ^TResourceFile; \end{verbatim} \subsection{TResourceFile Fields} \var{TResourceFile} has the following fields: \begin{description} \item[Stream] contains the (file) stream that has the executable image and the resources. It can be initialized by the \seepl{Init}{TResourceFile.Init} constructor call. \item[Modified] is set to \var{True} if one of the resources has been changed. It is set by the \seepl{SwitchTo}{TResourceFile.Init}, \seepl{Delete}{TResourceFile.Delete} and \seepl{Put}{TResourceFile.Put} methods. Calling \seepl{Flush}{TResourceFile.Flush} will clear the \var{Modified} flag. \end{description} \begin{procedure}{TResourceFile.Init} \Declaration Constructor TResourceFile.Init (AStream: PStream); \Description \var{Init} instantiates a new instance of a \var{TResourceFile} object. If \var{AStream} is not nil then it is considered as a stream describing an executable image on disk. \var{Init} will try to position the stream on the start of the resources section, and read all resources from the stream. \Errors None. \SeeAlso \seepl{Done}{TResourceFile.Done} \end{procedure} \begin{procedure}{TResourceFile.Done} \Declaration Destructor TResourceFile.Done; Virtual; \Description \var{Done} cleans up the instance of the \var{TResourceFile} Object. If \var{Stream} was specified at initialization, then \var{Stream} is disposed of too. \Errors None. \SeeAlso \seepl{Init}{TResourceFile.Init} \end{procedure} \begin{function}{TResourceFile.Count} \Declaration Function TResourceFile.Count: Sw\_Integer; \Description \var{Count} returns the number of resources. If no resources were read, zero is returned. \Errors None. \SeeAlso \seepl{Init}{TResourceFile.Init} \end{function} \begin{function}{TResourceFile.KeyAt} \Declaration Function TResourceFile.KeyAt (I: Sw\_Integer): String; \Description \var{KeyAt} returns the key (the name) of the \var{I}-th resource. \Errors In case \var{I} is invalid, \var{TCollection.Error} will be executed. \SeeAlso \seefl{Get}{TResourceFile.Get} \end{function} \begin{function}{TResourceFile.Get} \Declaration Function TResourceFile.Get (Key: String): PObject; \Description \var{Get} returns a pointer to a instance of a resource identified by \var{Key}. If \var{Key} cannot be found in the list of resources, then \var{Nil} is returned. \Errors Errors returned may be those by \var{TStream.Get} \SeeAlso \end{function} \begin{function}{TResourceFile.SwitchTo} \Declaration Function TResourceFile.SwitchTo (AStream: PStream; Pack: Boolean): PStream; \Description \var{SwitchTo} switches to a new stream to hold the resources in. \var{AStream} will be the new stream after the call to \var{SwitchTo}. If \var{Pack} is true, then all the known resources will be copied from the current stream to the new stream (\var{AStream}). If \var{Pack} is \var{False}, then only the current resource is copied. The return value is the value of the original stream: \var{Stream}. The \var{Modified} flag is set as a consequence of this call. \Errors Errors returned can be those of \seep{TStream.Read} and \seep{TStream.Write}. \SeeAlso \seepl{Flush}{TResourceFile.Flush} \end{function} \begin{procedure}{TResourceFile.Flush} \Declaration Procedure TResourceFile.Flush; \Description If the \var{Modified} flag is set to \var{True}, then \var{Flush} writes the resources to the stream \var{Stream}. It sets the \var{Modified} flag to true after that. \Errors Errors can be those by \seep{TStream.Seek} and \seep{TStream.Write}. \SeeAlso \seefl{SwitchTo}{TResourceFile.SwitchTo} \end{procedure} \begin{procedure}{TResourceFile.Delete} \Declaration Procedure TResourceFile.Delete (Key: String); \Description \var{Delete} deletes the resource identified by \var{Key} from the collection. It sets the \var{Modified} flag to true. \Errors None. \SeeAlso \seepl{Flush}{TResourceFile.Flush} \end{procedure} \begin{procedure}{TResourceFile.Put} \Declaration Procedure TResourceFile.Put (Item: PObject; Key: String); \Description \var{Put} sets the resource identified by \var{Key} to \var{Item}. If no such resource exists, a new one is created. The item is written to the stream. \Errors Errors returned may be those by \seep{TStream.Put} and \var{TStream.Seek} \SeeAlso \seefl{Get}{TResourceFile.Get} \end{procedure} \section{TStringList} \label{se:TStringList} A \var{TStringList} object can be used to read a collection of strings stored in a stream. If you register this object with the \seep{RegisterType} function, you cannot register the \var{TStrListMaker} object. This is the public declaration of the \var{TStringList} object: \begin{verbatim} TYPE TStrIndexRec = Packed RECORD Key, Count, Offset: Word; END; TStrIndex = Array [0..9999] Of TStrIndexRec; PStrIndex = ^TStrIndex; TStringList = OBJECT (TObject) Constructor Load (Var S: TStream); Destructor Done; Virtual; Function Get (Key: Sw_Word): String; END; PStringList = ^TStringList; \end{verbatim} \begin{procedure}{TStringList.Load} \Declaration Constructor TstringList.Load (Var S: TStream); \Description The \var{Load} constructor reads the \var{TStringList} object from the stream \var{S}. It also reads the descriptions of the strings from the stream. The string descriptions are stored as an array of \var{TstrIndexrec} records, where each record describes a string on the stream. These records are kept in memory. \Errors If an error occurs, a stream error is triggered. \SeeAlso \seepl{Done}{TStringList.Done} \end{procedure} \begin{procedure}{TStringList.Done} \Declaration Destructor TstringList.Done; Virtual; \Description The \var{Done} destructor frees the memory occupied by the string descriptions, and destroys the object. \Errors None. \SeeAlso \seepl{Load}{TStringList.Load}, \seep{TObject.Done} \end{procedure} \begin{function}{TStringList.Get} \Declaration Function TStringList.Get (Key: Sw\_Word): String; \Description \var{Get} reads the string with key \var{Key} from the list of strings on the stream, and returns this string. If there is no string with such a key, an empty string is returned. \Errors If no string with key \var{Key} is found, an empty string is returned. A stream error may result if the stream doesn't contain the needed strings. \SeeAlso \seep{TStrListMaker.Put} \end{function} \section{TStrListMaker} \label{se:TStrListMaker} The \var{TStrListMaker} object can be used to generate a stream with strings, which can be read with the \var{TStringList} object. If you register this object with the \seep{RegisterType} function, you cannot register the \var{TStringList} object. This is the public declaration of the \var{TStrListMaker} object: \begin{verbatim} TYPE TStrListMaker = OBJECT (TObject) Constructor Init (AStrSize, AIndexSize: Sw_Word); Destructor Done; Virtual; Procedure Put (Key: SwWord; S: String); Procedure Store (Var S: TStream); END; PStrListMaker = ^TStrListMaker; \end{verbatim} \begin{procedure}{TStrListMaker.Init} \Declaration Constructor TStrListMaker.Init (AStrSize, AIndexSize: SwWord); \Description The \var{Init} constructor creates a new instance of the \var{TstrListMaker} object. It allocates \var{AStrSize} bytes on the heap to hold all the strings you wish to store. It also allocates enough room for \var{AIndexSize} key description entries (of the type \var{TStrIndexrec}). \var{AStrSize} must be large enough to contain all the strings you wish to store. If not enough memory is allocated, other memory will be overwritten. The same is true for \var{AIndexSize} : maximally \var{AIndexSize} strings can be written to the stream. \Errors None. \SeeAlso \seep{TObject.Init}, \seepl{Done}{TStrListMaker.Done} \end{procedure} \begin{procedure}{TStrListMaker.Done} \Declaration Destructor TStrListMaker.Done; Virtual; \Description The \var{Done} destructor de-allocates the memory for the index description records and the string data, and then destroys the object. \Errors None. \SeeAlso \seep{TObject.Done}, \seepl{Init}{TStrListMaker.Init} \end{procedure} \begin{procedure}{TStrListMaker.Put} \Declaration Procedure TStrListMaker.Put (Key: Sw\_Word; S: String); \Description \var{Put} adds they string \var{S} with key \var{Key} to the collection of strings. This action doesn't write the string to a stream. To write the strings to the stream, see the \seepl{Store}{TStrListMaker.Store} method. \Errors None. \SeeAlso \seepl{Store}{TStrListMaker.Store}. \end{procedure} \begin{procedure}{TStrListMaker.Store} \Declaration Procedure TStrListMaker.Store (Var S: TStream); \Description \var{Store} writes the collection of strings to the stream \var{S}. The collection can then be read with the \var{TStringList} object. \Errors A stream error may occur when writing the strings to the stream. \SeeAlso \seep{TStringList.Load}, \seepl{Put}{TStrListMaker.Put}. \end{procedure}