% % $Id$ % This file is part of the FPC documentation. % Copyright (C) 1997, 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. % \documentclass{report} % % Preamble % \usepackage{a4} \usepackage{makeidx} \usepackage{html} \latex{\usepackage{fpk}} \html{\input{fpk-html.tex}} \makeindex % % start of document. % \begin{document} \title{Free Pascal :\\ Reference guide.} \docdescription{Reference guide for Free Pascal.} \docversion{1.3} \date{September 1997} \author{Micha\"el Van Canneyt % \\ Florian Kl\"ampfl } \maketitle \tableofcontents \newpage \listoftables \newpage \section*{About this guide} This document describes all constants, types, variables, functions and procedures as they are declared in the system unit. Furthermore, it describes all pascal constructs supported by \fpk, and lists all supported data types. It does not, however, give a detailed explanation of the pascal language. The aim is to list which Pascal constructs are supported, and to show where the \fpk implementation differs from the Turbo Pascal implementation. Throughout this document, we will refer to functions, types and variables with \var{typewriter} font. Functions and procedures gave their own subsections, and for each function or procedure we have the following topics: \begin{description} \item [Declaration] The exact declaration of the function. \item [Description] What does the procedure exactly do ? \item [Errors] What errors can occur. \item [See Also] Cross references to other related functions/commands. \end{description} The cross-references come in two flavours: \begin{itemize} \item References to other functions in this manual. In the printed copy, a number will appear after this reference. It refers to the page where this function is explained. In the on-line help pages, this is a hyperlink, on which you can click to jump to the declaration. \item References to Unix manual pages. (For linux related things only) they are printed in \var{typewriter} font, and the number after it is the Unix manual section. \end{itemize} % % The Pascal language % \chapter{Supported Pascal language constructs} In this chapter we describe the pascal constructs supported by \fpk, as well as the supported data types. This is not intended as an introduction to the Pascal language, although all language constructs will be covered. The main goal is to explain what is supported by \fpk, and where the Free implementation differs from the Turbo Pascal one. \section{Data types} \fpk supports the same data types as Turbo Pascal, with some extensions from Delphi. \subsection{Integer types} The integer types predefined in \fpk are listed in \seet{integers}. \begin{FPKltable}{lcr}{Predefined integer types}{integers} Type & Range & Size in bytes \\ \hline Byte & 0 .. 255 & 1 \\ Shortint & -127 .. 127 & 1\\ Integer & -32768 .. 32767 & 2 \\ Word & 0 .. 65535 & 2 \\ Longint & -2147483648 .. 2147483648 & 4\\ Cardinal\footnote{The cardinal type support is buggy until version 0.9.3} & 0..4294967296 & 4 \\ \hline \end{FPKltable} \fpk does automatic type conversion in expressions where different kinds of integer types are used. \fpk supports hexadecimal format the same way as Turbo Pascal does. To specify a constant value in hexadecimal format, prepend it with a dollar sign (\var{\$}). Thus, the hexadecimal \var{\$FF} equals 255 decimal. In addition to the support for hexadecimal notation, \fpk also supports binary notation. You can specify a binary number by preceding it with a percent sign (\var{\%}). Thus, \var{255} can be specified in binary notation as \var{\%11111111}. \subsection{Real types} \fpk uses the math coprocessor (or an emulation) for al its floating-point calculations. The native type for the coprocessor is \var{Double}. Other than that, all Turbo Pascal real types are supported. They're listed in \seet{Reals}. \begin{FPKltable}{lccr}{Supported Real types}{Reals} Type & Range & Significant digits & Size\footnote{In Turbo Pascal.} \\ \hline Real & 2.9E-39 .. 1.7E38 & 11-12 & 6 \\ Single & 1.5E-45 .. 3.4E38 & 7-8 & 4 \\ Double & 5.0E-324 .. 1.7E308 & 15-16 & 8 \\ Extended & 1.9E-4951 .. 1.1E4932 & 19-20 & 10\\ %Comp\footnote{\var{Comp} only holds integer values.} & -2E64+1 .. 2E63-1 & 19-20 & 8 \\ \end{FPKltable} Until version 0.9.1 of the compiler, all the real types are mapped to type \var{Double}, meaning that they all have size 8. From version 0.9.3, the \var{Extended} and \var{single} types are defined with the same suze as in Turbo Pascal. The \seef{SizeOf} function is your friend here. \subsection{Character types} \subsubsection{Char} \fpk supports the type \var{Char}. A \var{Char} is exactly 1 byte in size, and contains one character. You can specify a character constant by enclosing the character in single quotes, as follows : 'a' or 'A' are both character constants. You can also specify a character by their ASCII value, by preceding the ASCII value with the number symbol (\#). For example specifying \var{\#65} would be the same as \var{'A'}. Also, the caret character (\verb+^+) can be used in combination with a letter to specify a character with ASCII value less than 27. Thus \verb+^G+ equals \var{\#7} (G is the seventh letter in the alphabet.) If you want to represent the single quote character, type it two times successively, thus \var{''''} represents the single quote character. \subsubsection{Strings} \fpk supports the \var{String} type as it is defined in Turbo Pascal. To declare a variable as a string, use the following declaration: \begin{verbatim} Var S : String[Size]; \end{verbatim} This will declare \var{S} as a variable of type \var{String}, with maximum length \var{Size}. \var{Size} can be any value from \var{1} to \var{255}. \fpk reserves \var{Size+1} bytes for the string \var{S}, and in the zeroeth element of the string (\var{S[0]}) it will store the length of the variable. If you don't specify the size of the string, \var{255} is taken as a default. To specify a constant string, you enclose the string in single-quotes, just as a \var{Char} type, only now you can have more than one character. Given that \var{S} is of type \var{String}, the following are valid assignments: \begin{verbatim} S:='This is a string.'; S:='One'+', Two'+', Three'; S:='This isn''t difficult !'; S:='This is a weird character : '#145' !'; \end{verbatim} As you can see, the single quote character is represented by 2 single-quote characters next to each other. Strange characters can be specified by their ASCII value. The example shows also that you can add two strings. The resulting string is just the concatenation of the first with the second string, without spaces in between them. Strings can not be substracted, however. \subsubsection{PChar} \fpk supports the Delphi implementation of the \var{PChar} type. \var{PChar} is defined as a pointer to a \var{Char} type, but allows additional operations. The \var{PChar} type can be understood best as the Pascal equivalent of a C-style null-terminated string, i.e. a variable of type \var{PChar} is a pointer that points to an array of type \var{Char}, which is ended by a null-character (\var{\#0}). \fpk supports initializing of \var{PChar} typed constants, or a direct assignment. For example, the following pieces of code are equivalent: \begin{CodEx} \begin{verbatim} program one; var p : pchar; begin P:='This is a null-terminated string.'; writeln (P); end. \end{verbatim} \end{CodEx} Results in the same as \begin{CodEx} \begin{verbatim} program two; const P : PChar = 'This is a null-terminated string.' begin Writeln (P); end. \end{verbatim} \end{CodEx} These examples also show that it is possible to write {\em the contents} of the string to a file of type \var{Text}. The \seestrings\_ unit contains procedures and functions that manipulate the \var{PChar} type as you can do it in C. Since it is equivalent to a pointer to a type \var{Char} variable, it is also possible to do the following: \begin{CodEx} \begin{verbatim} Program three; Var S : String[30]; P : Pchar; begin S:='This is a null-terminated string.'#0; P:=@S[1]; writeln (P); end. \end{verbatim} \end{CodEx} This will have the same result as the previous two examples. You cannot add null-terminated strings as you can do with normal Pascal strings. If you want to concatenate two \var{PChar} strings, you will need to use the \seestrings unit. However, it is possible to do some pointer arithmetic. You can use the operators \var{+} and \var{-} to do operations on \var{PChar} pointers. In \seet{PCharMath}, \var{P} and \var{Q} are of type \var{PChar}, and \var{I} is of type \var{Longint}. \begin{FPKltable}{lr}{\var{PChar} pointer arithmetic}{PCharMath} Operation & Result \\ \hline \var{P + I} & Adds \var{I} to the address pointed to by \var{P}. \\ \var{I + P} & Adds \var{I} to the address pointed to by \var{P}. \\ \var{P - I} & Substracts \var{I} from the address pointed to by \var{P}. \\ \var{P - Q} & Returns, as an integer, the distance between 2 addresses \\ & (or the number of characters between \var{P} and \var{Q}) \\ \hline \end{FPKltable} \subsection{Booleans} \fpk supports the \var{Boolean} type, with its two pre-defined possible values \var{True} and \var{False}. These are the only two values that can be assigned to a \var{Boolean} type. Of course, any expression that resolves to a \var{boolean} value, can also be assigned to a boolean type. Assuming \var{B} to be of type \var{Boolean}, the following are valid assignments: \begin{verbatim} B:=True; B:=False; B:=1<>2; { Results in B:=True } \end{verbatim} Boolean expressions are also used in conditions. {\em Remark:} In \fpk, boolean expressions are always evaluated in such a way that when the result is known, the rest of the expression will no longer be evaluated (Called short-cut evaluation). In the following example, the function \var{Func} will never be called, which may have strange side-effects. \begin{verbatim} ... B:=False; A := B and Func; \end{verbatim} Here \var{Func} is a function which returns a \var{Boolean} type. \subsection{Arrays} \fpk supports arrays as in Turbo Pascal, except that packed arrays are not supported. Multi-dimensional arrays are also supported. \subsection{Pointers} \fpk supports the use of pointers. A variable of the type \var{Pointer} contains an address in memory, where the data of another variable may be stored. Pointers can be typed, which means that they point to a particular kind of data. The type of this data is known at compile time. Consider the following example: \begin{CodEx} \begin{verbatim} Program pointers; type Buffer = String[255]; BufPtr = ^Buffer; Var B : Buffer; BP : BufPtr; PP : Pointer; etc.. \end{verbatim} \end{CodEx} In this example, \var{BP} {\em is a pointer to} a \var{Buffer} type; while \var{B} {\em is} a variable of type \var{Buffer}. \var{B} takes 256 bytes memory, and \var{BP} only takes 4 bytes of memory (enough to keep an adress in memory). {\em Remark:} \fpk treats pointers much the same way as C does. This means that you can treat a pointer to some type as being an array of this type. The pointer then points to the zeroeth element of this array. Thus the following pointer declaration \begin{verbatim} Var p : ^Longint; \end{verbatim} Can be considered equivalent to the following array declaration: \begin{verbatim} Var p : array[0..Infinity] of Longint; \end{verbatim} The reference \verb+P^+ is then the same as \var{p[0]}. The following program illustrates this maybe more clear: \begin{CodEx} \begin{verbatim} program PointerArray; var i : longint; p : ^longint; pp : array[0..100] of longint; begin for i:=0 to 100 do pp[i]:=i; { Fill array } p:=@pp[0]; { Let p point to pp } for i:=0 to 100 do if p[i]<>pp[i] then writeln ('Ohoh, problem !') end. \end{verbatim} \end{CodEx} \fpk doesn't support pointer arithmetic as C does, however. \subsection{Procedural types} \fpk has support for procedural types, although it differs from the Turbo Pascal implementation of them. The type declaration remains the same. The two following examples are valid type declarations: \begin{verbatim} Type TOneArg = Procedure (Var X : integer); TNoArg = Function : Real; var proc : TOneArg; func : TNoArg; \end{verbatim} Given these declarations, the following assignments are valid: \begin{verbatim} Procedure printit (Var X : Integer); begin writeln (x); end; ... P:=@printit; Func:=@Pi; \end{verbatim} From this example, the difference with Turbo Pascal is clear: In Turbo Pascal it isn't necessary to use the address operator (\var{@}) when assigning a procedural type variable, whereas in \fpk it is required. \subsection{Records} \fpk supports records. The prototype type definition of a record is: \begin{verbatim} Type RecType = Record Element1 : type1; Element2,Element3 : type2; ... Elementn ; Typen; end; \end{verbatim} Variant records are also supported: \begin{verbatim} Type RecType = Record Element1 : type1; Case [PivotElmt:] Type Identifier of Value1 : (VarElt1, Varelt2 : Vartype1); Value2 : (VarElt3, Varelt4 : Vartype2); end; \end{verbatim} The variant part must be last in the record. The optional \var{PivotElmt} can be used to see which variant is active at a certain time. {\em Remark:} If you want to read a typed file with records, produced by a Turbo Pascal program, then chances are that you will not succeed in reading that file correctly. The reason for this is that by default, elements of a record are aligned at 2-byte boundaries, for performance reasons. This default behaviour can be changed with the \var{\{\$PackRecords n\}} switch. Possible values for \var{n} are 1, 2 and 4. This switch tells the compiler to align elements of a record on 1,2 or 4 byte boundaries. Take a look at the following program: \begin{CodEx} \begin{verbatim} Program PackRecordsDemo; type {$PackRecords 2} Trec1 = Record A : byte; B : Word; end; {$PACKRECORDS 1} Trec2 = Record A : Byte; B : Word; end; begin Writeln ('Size Trec1 : ',SizeOf(Trec1)); Writeln ('Size Trec2 : ',SizeOf(Trec2)); end. \end{verbatim} \end{CodEx} The output of this program will be : \begin{verbatim} Size Trec1 : 4 Size Trec2 : 3 \end{verbatim} And this is as expected. In \var{Trec1}, each of the elements \var{A} and \var{B} takes 2 bytes of memory, and in \var{Trec1}, \var{A} takes only 1 byte of memory. As from version 0.9.3 (a developers' version), \fpk supports also the 'packed record', this is a record where all the elements are byte-aligned. Thus the two following declarations are equivalent: \begin{verbatim} {$PACKRECORDS 1} Trec2 = Record A : Byte; B : Word; end; {$PACKRECORDS 2} \end{verbatim} and \begin{verbatim} Trec2 = Packed Record A : Byte; B : Word; end; \end{verbatim} Note the \var{\{\$PACKRECORDS 2\}} after the first declaration ! \subsection{Set types} \fpk supports the set types as in Turbo Pascal. The prototype of a set declaration is: \begin{verbatim} SetType = Set of TargetType; \end{verbatim} Each of the elements of \var{SetType} must be of type \var{TargetType}. \var{TargetType} can be any ordinal type with a range between \var{0} and \var{255}. A set can contain maximally \var{255} elements. The following is a valid set declaration: \begin{verbatim} Type Days = (Mon, Tue, Wed, Thu, Fri, Sqt, Sun); Var WeekDays : Set of days; \end{verbatim} Given this set declaration, the follwing assignment is legal: \begin{verbatim} WeekDays := [ Mon, Tue, Wed, Thu, Fri]; \end{verbatim} The operators for manipulations of sets are listed in \seet{SetOps}. \begin{FPKltable}{lr}{Set Manipulation operators}{SetOps} Operation & Operator \\ \hline Union & + \\ Difference & - \\ Intersection & * \\ \hline \end{FPKltable} You can compare two sets with the \var{<>} and \var{=} operators, but not (yet) with the \var{<} and \var{>} operators. From compiler version 0.9.5, the compiler stores small sets (less than 32 elements) in a longint, if the type range allows it. This allows for faster processing and decreases program size. \subsection{Enumeration types} Enumeration types are supported in \fpk. On top of the Turbo Pascal implementation, \fpk allows the following C-style extension of the enumeration type. \begin{verbatim} Type EnumType = (one, two, three, forty := 40); \end{verbatim} As a result, the ordinal number of \var{forty} is \var{40}, and not \var{4}, as it would be when the \var{'= 40'} wasn't present. When specifying such an enumeration type, it is important to keep in mind that you should keep initialized set elements in ascending order. The following will produce a compiler error: \begin{verbatim} Type EnumType = (one, two, three, forty := 40, thirty:=30); \end{verbatim} It is necessary to keep \var{forty} and \var{Thirty} in the correct order. {\em Remark :} You cannot use the \var{Pred} and \var{Succ} functions on this kind of enumeration types. If you try to do that, you'll get a compiler error. \section{Constants} Just as in Turbo Pascal, \fpk supports both normal and typed constants. \subsection{Ordinary constants} Ordinary constants declarations are no different from the TP implementation. You can only declare constants of the following types: \var{Ordinal types}, \var{Real types}, \var{Char}, and \var{String}. The following are all valid constant declarations: \begin{verbatim} Const e = 2.7182818; { Real type constant. } a = 2; { Integer type constant. } c = '4'; { Character type constant. } s = 'This is a constant string'; {String type constant.} \end{verbatim} Assigning a value to a constant is not permitted. Thus, given the previous declaration, the following will result in a compiler error: \begin{verbatim} s:='some other string'; \end{verbatim} \subsection{Typed constants} Typed constants serve to provide a program with initialized variables. Contrary to ordinary constants, they may be assigned to at run-time. The difference with normal variables is that their value is initialised when the program starts, whereas normal variables must be initialised explicitly. The prototype of a typed constant declaration is: \begin{verbatim} Const SomeConst : SomeType = SomeValue; \end{verbatim} After that, the constant \var{SomeConst} will be of type \var{SomeType}, and have initial value \var{SomeValue}. Given the declaration: \begin{verbatim} Const S : String = 'This is a typed constant string'; \end{verbatim} The following is a valid assignment: \begin{verbatim} S:='Result : '+Func; \end{verbatim} Where \var{Func} is a function that returns a \var{String}. Typed constants also allow you to initialize arrays and records. For arrays, the initial elements must be specified, surrounded by round brackets, and separated by commas. The number of elements must be exactly the same as number of elements in the declaration of the type. As an example: \begin{verbatim} Const tt : array [1..3] of string[20] = ('ikke','gij', 'hij'); ti : array [1..3] of longint = (1,2,3); \end{verbatim} For constant records, you should specify each element of the record, in the form \var{Field : Value}, separated by commas, and surrounded by round brackets. As an example: \begin{verbatim} Type Point = record X,Y : Real end; Const Origin : Point = (X:0.0 , Y:0.0); \end{verbatim} The order of the fields in a constant record needs to be the same as in the type declaration, otherwise you'll get a compile-time error. \section{Objects} \fpk supports object oriented programming. In fact, part of the compiler is written using objects. Here we present some technical questions regarding object oriented programming in \fpk. \fpk supports 2 programming models for object-oriented programming. You can choose to program object oriented using the Turbo Pascal approach, or you can prefer the Delphi approach. \subsection{The Turbo Pascal approach} In the Turbo Pascal approach, Objects should be treated as a special kind of record. The record contains all the fields that are declared in the objects definition, and pointers to the methods that are associated to the objects' type. An object is declared just as you would declare a record; except that you can now declare procedures and fuctions as of they were part of the record. Objects can ''inherit'' fields and methods from ''parent'' objects. This means that you can use these fields and methods as if the were included in the objects you declared as a ''child'' object. Furthermore, you can declare fields, procedures and functions as \var{public} or \var{private}. By default, fields and methods are \var{public}, and are exported outside the current unit. Fields or methods that are declared \var{private} are only accessible in the current unit. The prototype declaration of an object is as follows : \begin{verbatim} TObj = Object [(ParentObjectType)] [Constructor ConstructorName;] [Destructor DestructorName;] Field1 : Type1; ... Fieldn : Typen; Method1; Method2; [private PrField1 : PrType1; ... PrFieldn : PrTypen; PrMethod1; ... PrMethodn;] [public PuField1 : PuType1; .. Pufield1 : PuTypen; PuMethod1; ... PuMethodn;] end; \end{verbatim} You can repeat as many \var{private} and \var{public} blocks as you want. \var{Method}s are normal function or procedure declarations. As can be seen in the prototype object declaration, \fpk supports constructors and destructors. You are responsible for calling the destructor and constructor explicitly when using objects. \fpk supports also the extended syntax of the \var{New} and \var{Dispose} procedures. In case you want to allocate a dynamic varible of an object type, you can specify the constructor's name in the call to \var{New}. The \var{New} is implemented as a function which returns a pointer to the instantiated object. Given the following declarations : \begin{verbatim} Type TObj = object; Constructor init; ... end; Pobj = ^TObj; Var PP : Pobj; \end{verbatim} Then the following 3 calls are equivalent : \begin{verbatim} pp:=new (Pobj,Init); \end{verbatim} and \begin{verbatim} new(pp,init); \end{verbatim} and also \begin{verbatim} new (pp); pp^.init; \end{verbatim} In the last case, the compiler will issue a warning that you should use the extended syntax of \var{new} and \var{dispose} to generate instances of an object. You can ignore this warning, but it's better programming practice to use the extended syntax to create instances of an object. Similarly, the \var{Dispose} procedure accepts the name of a destructor. The destructor will then be called, before removing the object from the heap. In view of the compiler warning remark, the now following Delphi approach may be considered a more natural way of object-oriented programming. \subsection{The Delphi approach} In the Delphi approach to Object Oriented Programming, everything revolves around the concept of 'Classes'. A class can be seen as a pointer to an object, or a pointer to a record. The prototype declaration of a class is as follows : \begin{verbatim} TObj = Class [(ParentClassType)] [Constructor ConstructorName;] [Destructor DestructorName;] Field1 : Type1; ... Fieldn : Typen; Method1; Method2; [private PrField1 : PrType1; ... PrFieldn : PrTypen; PrMethod1; ... PrMethodn;] [public PuField1 : PuType1; .. Pufield1 : PuTypen; PuMethod1; ... PuMethodn;] end; \end{verbatim} You can repeat as many \var{private} and \var{public} blocks as you want. \var{Method}s are normal function or procedure declarations. As you can see, the declaration of a class is almost identical to the declaration of an object. The real difference between objects and classes is in the way they are created; Classes must be created using their constructor. Remember that A class is a pointer to an object, so when you declare a variable of some class, the compiler just allocates a pointer, not the entire object. The constructor of a class returns a pointer to an initialized instance of the object. So, to initialize an instance of some class, you do the following : \begin{verbatim} ClassVar:=ClassType.ConstructorName; \end{verbatim} {\em Remark :} \fpk doesn't support the concept of properties yet. \section{Statements controlling program flow.} \subsection{Assignments} In addition to the standard Pascal assignment operator (\var{:=}), \fpk supports some c-style constructions. All available constructs are listed in \seet{assignments}. \begin{FPKltable}{lr}{Allowed C constructs in \fpk}{assignments} Assignment & Result \\ \hline a += b & Adds \var{b} to \var{a}, and stores the result in \var{a}.\\ a -= b & Substracts \var{b} from \var{a}, and stores the result in \var{a}. \\ a *= b & Multiplies \var{a} with \var{b}, and stores the result in \var{a}. \\ a /= b & Divides \var{a} through \var{b}, and stores the result in \var{a}. \\ \hline \end{FPKltable} For these connstructs to work, you should specify the \var{-Sc} command-line switch. {\em Remark:} These constructions are just for typing convenience, they don't generate different code. \fpk also supports typed assignments. This means that an assignment statement has a definite type, and hence can be assigned to another variable. The type of the assignment \var{a:=b} is the type of \var{a} (or, in this case, of \var{b}), and this can be assigned to another variable : \var{c:=a:=b;}. To summarize: the construct \begin{verbatim} a:=b:=c; \end{verbatim} results in both \var{a} and \var{b} being assign the value of \var{c}, which may be an expression. For this construct to be allowed, it is necessary to specify the \var{-Sa4} switch on the command line. \subsection{The \var{Case} statement} \fpk supports the \var{case} statement. Its prototype is \begin{verbatim} Case Pivot of Label1 : Statement1; Label2 : Statement2; ... Labeln : Statementn; [Else AlternativeStatement] end; \end{verbatim} \var{label1} until \var{Labeln} must be known at compile-time, and can be of the following types : enumeration types, Ordinal types (except boolean), and chars. \var{Pivot} must also be one of these types. The statements \var{Statement1} etc., can be compound statements (i.e. a \var{begin..End} block). {\em Remark:} Contrary to Turbo Pascal, duplicate case labels are not allowed in \fpk, so the following code will generate an error when compiling: \begin{verbatim} Var i : integer; ... Case i of 3 : DoSomething; 1..5 : DoSomethingElse; end; \end{verbatim} The compiler will generate a \var{Duplicate case label} error when compiling this, because the 3 also appears (implicitly) in the range \var{1..5} {\em Remark:} In versions earlier than 0.9.7, there was an incompatibility here with Turbo Pascal. Where in Turbo Pascal you could do the following: \begin{verbatim} case Pivot of ... Else begin Statement1 Statement2 end; \end{verbatim} You needed to do the following in \fpk : \begin{verbatim} case Pivot of ... Else begin Statement1 Statement2 end; end; \end{verbatim} So there's an extra \var{end} keyword at the end. But from version 0.9.7 this has been fixed. \subsection{The \var{For..to/downto..do} statement} \fpk supports the \var{For} loop construction. The prototypes are: \begin{verbatim} For Counter:=Lowerbound to Upperbound Do Statement; or For Counter:=Upperbound downto Lowerbound Do Statement; \end{verbatim} \var{Statement} can be a compound statement. In the first case, if \var{Lowerbound} is larger than \var{Upperbound} then \var{Statement} will never be executed. \subsection{The \var{Goto} statement} \fpk supports the \var{goto} jump statement. Its prototype is \begin{verbatim} var jumpto : label ... Jumpto : Statement; ... Goto jumpto; ... \end{verbatim} The jump label must be defined in the same block as the \var{Goto} statement. To be able to use the \var{Goto} statement, you need to specify the \var{-Sg} compiler switch. \subsection{The \var{If..then..else} statement} The \var{If .. then .. else..} prototype is: \begin{verbatim} If Expression1 Then Statement1; or If Expression2 then Statement2 else Statement3; \end{verbatim} Be aware of the fact that the boolean expressions \var{Expression1} and \var{Expression2} will be short-cut evaluated. (Meaning that the evaluation will be stopped at the point where the outcome is known with certainty) Also, after \var{Statement2}, no semicolon (\var{;}) is alllowed. All statements can be compound statements. \subsection{The \var{Repeat..until} statement} The prototype of the \var{Repeat..until} statement is \begin{verbatim} Repeat Statement1; Statement2; Until Expression; \end{verbatim} This will execute \var{Statement1} etc. until \var{Expression} evaluates to \var{True}. Since \var{Expression} is evaluated {\em after} the execution of the statements, they are executed at least once. Be aware of the fact that the boolean expressions \var{Expression1} and \var{Expression2} will be short-cut evaluated. (Meaning that the evaluation will be stopped at the point where the outcome is known with certainty) \subsection{The \var{While..do} statement} The prototype of the \var{While..do} statement is \begin{verbatim} While Expression Do Statement; \end{verbatim} This will execute \var{Statement} as long as \var{Expression} evaluates to \var{True}. Since \var{Expression} is evaluated {\em before} the execution of \var{Statement}, it is possible that \var{Statement} isn't executed at all. \var{Statement} can be a compound statement. Be aware of the fact that the boolean expressions \var{Expression1} and \var{Expression2} will be short-cut evaluated. (Meaning that the evaluation will be stopped at the point where the outcome is known with certainty) \subsection{The \var{With} statement} The with statement serves to access the elements of a record, without having to specify the name of the record. Given the declaration: \begin{verbatim} Type Passenger = Record Name : String[30]; Flight : String[10]; end; Var TheCustomer : Passenger; \end{verbatim} The following statements are completely equivalent: \begin{verbatim} TheCustomer.Name:='Michael'; TheCustomer.Flight:='PS901'; \end{verbatim} and \begin{verbatim} With TheCustomer do begin Name:='Michael'; Flight:='PS901'; end; \end{verbatim} \subsection{Compound statements} Compound statements are a group of statements, separated by semicolons, that are surrounded by the keywords \var{Begin} and \var{End}. The Last statement doesn't need to be followed by a semicolon, although it is allowed. \section{Using functions and procedures} \fpk supports the use of functions and procedures, but with some extras: Function overloading is supported, as well as \var{Const} parameters and open arrays. {\em remark:} In the subsequent paragraph the word \var{procedure} and \var{function} will be used interchangeably. The statements made are valid for both. \subsection{Function overloading} Function overloading simply means that you can define the same function more than once, but each time with a different set of arguments. When the compiler encounters a unction call, it will look at the function parameters to decide which od the defined function This can be useful if you want to define the same function for different types. For example, if the RTL, the \var{Dec} procedure is is defined as: \begin{verbatim} ... Dec(Var I : longint;decrement : longint); Dec(Var I : longint); Dec(Var I : Byte;decrement : longint); Dec(Var I : Byte); ... \end{verbatim} When the compiler encounters a call to the dec function, it wil first search which function it should use. It therefore checks the parameters in your function call, and looks if there is a function definition which maches the specified parameter list. If the compiler finds such a function, a call is inserted to that function. If no such function is found, a compiler error is generated. \subsection{\var{Const} parameters} In addition to \var{var} parameters and normal parameters (call by value, call by reference), \fpk also supports \var{Const} parameters. You can specify a \var{Const} parameter as follows: \begin{verbatim} Function Name (Const S: Type_Of_S) : ResultType \end{verbatim} A constant argument is passed by refenence (i.e. the function or procedure receives a pointer to the passed , but you are not allowed to assign to it, this will result in a compiler error. The main use for this is reducing the stack size, hence improving performance. \subsection{Open array parameters} \fpk supports the passing of open arrays, i.e. You can declare a procedure with an array of unspecified length as a parameter, as in Delphi. The prototype declaration for open array parameters is: \begin{verbatim} Function Func ( ... [Var|Const] Ident : Array of Type ...) : ReturnType; ProcedureFunction Func (... [Var|Const] Ident : Array of Type ...); \end{verbatim} The \var{[Var|Const]} means that open parameters can be passed by reference or as a constant parameter. In a function or procedure, you can pass open arrays only to functions which are also declared with open arrays as parameters, {\em not} to functions or procedures which accept arrays of fixed length. \section{Using assembler in your code} \fpk supports the use of assembler in your code, but not inline assembler. assembly functions (i.e. functions declared with the \var{Assembler} keyword) are supported as of version 0.9.7. {\em Remark :} \fpk issues AT\&T assembly language, as understood by most unix assemblers (most notably : GNU \var{as}). Intel assembler syntax is available as of version 0.9.8 but the Intel support isn't complete in the sense that it is converted to AT\&T syntax, and some constructions aren't supported by the conversion mechanism (see \progref for more information about this). Therefore all examples of assembly language will be given in AT\&T syntax, as it is the 'native' assembly from \fpk. The following is an example of assembler inclusion in your code. \begin{verbatim} ... Statements; ... Asm Movl 0,%eax ... end; ... Statements; \end{verbatim} The assembler instructions between the \var{Asm} and \var{end} keywords will be inserted in the assembler generated by the compiler. You can still use comditionals in your assembler, the compiler will recognise it, and treat it as any other conditionals. Contrary to Turbo Pascal, it isn't possible (yet) to reference variables by their names in the assembler parts of your code. \section{Modifiers} \fpk doesn't support all Turbo Pascal modifiers, but does support a number of additional modifiers. They are used mainly for assembler and reference to C object files. \subsection{Public} The \var{Public} keyword is used to declare a function globally in a unit. This is useful if you don't want a function to be accessible from the unit file, but you do want the function to be accessible from the object file. as an example: \begin{CodEx} \begin{verbatim} Unit someunit; interface Function First : Real; Implementation Function First : Real; begin First:=0; end; Function Second : Real; [Public]; begin Second:=1; end; end. \end{verbatim} \end{CodEx} If another program or unit uses this unit, it will not be able to use the function \var{Second}, since it isn't declared in the interface part. However, it will be possible to access the function \var{Second} at the assembly-language level, by using it's mangled name (\progref). \subsection{C} The \var{C} modifier can be used to declare a function that resides in a object file generated by a C compiler. It allows you to use the function in your code, and at linking time, you must link the object file containing the \var{C} implementation of the function or procedure. As an example: \begin{CodEx} \begin{verbatim} program CmodDemo; Const P : Pchar = 'This is fun !'; Function strlen (P : Pchar) : Longint; [ C ]; begin Writeln ('Length of (',p,') : ',strlen(p)) end. \end{verbatim} \end{CodEx} When compiling this, and linking to the C-library, you will be able to call the \var{strlen} function throughout your program. {\em Remark} The parameters in our declaration of the \var{C} function should match exactly the ones in the declaration in \var{C}. S ince \var{C} is case sensitive, this means also that the name of the function must be exactly the same. \subsection{Export} Sometimes you must provide a callback function for a C library, or you want your routines to be callable from a C program. Since \fpk and C use different calling schemes for functions and procedures\footnote{More techically: In C the calling procedure must clear the stack. In \fpk, the subroutine clears the stack.}, the compiler must be told to generate code that can be called from a C routine. This is where the \var{Export} modifier comes in. Contrary to the other modifiers, it must be specified separately, as follows: \begin{verbatim} function DoSquare (X : longint) : longint; export; begin ... end; \end{verbatim} The square brackets around the modifier are not allowed in this case. {\em Remark:} You cannot call an exported function from within \fpk programs. If you try to do so, the compiler will complain when compiling your source code. If you do want to call an exported procedure from pascal, you must use a dummy function: \begin{verbatim} Procedure RealDoSomething; begin ... end; Procedure DoSomething; export; begin RealDoSomething; end; \end{verbatim} In this example, from your \fpk code, you can call the \var{RealDoSomething} procedure. If someone wants to link to your code from a C program, he can call the \var{DoSomething} procedure. Both calls will have the same effect. {\em Remark:} as of version 0.9.8, \fpk supports the Delphi \var{cdecl} modifier. This modifier works in the same way as the \var{export} modifier. More information about these modifiers can be found in the \progref, in the section on the calling mechanism and the chapter on linking. \subsection{StdCall} As of version 0.9.8, \fpk supports the Delphi \var{stdcall} modifier. This modifier does actually nothing, since the \fpk compiler by default pushes parameters from right to left on the stack, which is what the modifier does under Delphi (which pushes parameters on the stack from left to right). More information about this modifier can be found in the \progref, in the section on the calling mechanism and the chapter on linking. \subsection{Alias} The \var{Alias} modifier allows you to specify a different name for a procedure or function. This is mostly useful for referring to this procedure from assembly language constructs. As an example, consider the following program: \begin{CodEx} \begin{verbatim} Program Aliases; Procedure Printit; [Alias : 'DOIT']; begin Writeln ('In Printit (alias : "DOIT")'); end; begin asm call DOIT end; end. \end{verbatim} \end{CodEx} {\rm Remark:} the specified alias is inserted straight into the assembly code, thus it is case sensitive. The \var{Alias} modifier, combined with the \var{Public} modifier, make a powerful tool for making externally accessible object files. \subsection{[RegisterList]} This modifier list is used to indicate the registers that are modified by an assembler block in your code. The compiler stores certain results in the registers. If you modify theregisters in an assembly block, the compiler should, sometimes, be told about it. The prototype syntax of the \var{Registerlist} modifier is: \begin{verbatim} asm statements end; ['register1','register2',...,'registern']; \end{verbatim} Where \var{'register'} is one of \var{'EAX',EBX',ECX','EDX'} etc. \subsection{Unsupported Turbo Pascal modifiers} The modifiers that exist in Turbo pascal, but aren't supported by \fpk, are listed in \seet{Modifs}. \begin{FPKltable}{lr}{Unsupported modifiers}{Modifs} Modifier & Why not supported ? \\ \hline Near & \fpk is a 32-bit compiler.\\ Far & \fpk is a 32-bit compiler. \\ External & Replaced by \var{C} modifier. \\ \hline \end{FPKltable} % % System unit reference guide. % \chapter{Reference : The system unit} The system unit contains the standard supported functions of \fpk. It is the same for all platforms. Basically it is the same as the system unit provided with Borland or Turbo Pascal. Functions are listed in alphabetical order. Arguments to functions or procedures that are optional are put between square brackets. The pre-defined constants and variables are listed in the first section. The second section contains the supported functions and procedures. \section{Types, Constants and Variables} \subsection{Types} The following integer types are defined in the System unit: \begin{verbatim} shortint = -128..127; longint = $80000000..$7fffffff; integer = -32768..32767; byte = 0..255; word = 0..65535; \end{verbatim} The following Real types are declared: \begin{verbatim} double = real; {$ifdef VER0_6} extended = real; single = real; {$endif VER0_6} \end{verbatim} And the following pointer types: \begin{verbatim} pchar = ^char; ppchar = ^pchar; \end{verbatim} \subsection{Constants} The following constants for file-handling are defined in the system unit: \begin{verbatim} Const fmclosed = $D7B0; fminput = $D7B1; fmoutput = $D7B2; fminout = $D7B3; fmappend = $D7B4; filemode : byte = 2; \end{verbatim} Further, the following general-purpose constants are also defined: \begin{verbatim} const test8086 : byte = 2; { always i386 or newer } test8087 : byte = 3; { Always 387 or higher. emulated if needed. } erroraddr : pointer = nil; errorcode : word = 0; { max level in dumping on error } max_frame_dump : word = 20; \end{verbatim} \subsection{Variables} The following variables are defined and initialized in the system unit: \begin{verbatim} var output,input,stderr : text; exitproc : pointer; exitcode : word; stackbottom : longint; loweststack : longint; \end{verbatim} The variables \var{ExitProc}, \var{exitcode} are used in the \fpk exit scheme. It works similarly to the on in Turbo Pascal: When a program halts (be it through the call of the \var{Halt} function or \var{Exit} or through a run-time error), the exit mechanism checks the value of \var{ExitProc}. If this one is non-\var{Nil}, it is set to \var{Nil}, and the procedure is called. If the exit procedure exits, the value of ExitProc is checked again. If it is non-\var{Nil} then the above steps are repeated. So if you want to install your exit procedure, you should save the old value of \var{ExitProc} (may be non-\var{Nil}, since other units could have set it before you did). In your exit procedure you then restore the value of \var{ExitProc}, such that if it was non-\var{Nil} the exit-procedure can be called. The \var{ErrorAddr} and \var{ExitCode} can be used to check for error-conditions. If \var{ErrorAddr} is non-\var{Nil}, a run-time error has occurred. If so, \var{ExitCode} contains the error code. If \var{ErrorAddr} is \var{Nil}, then {ExitCode} contains the argument to \var{Halt} or 0 if the program terminated normally. \var{ExitCode} is always passed to the operating system as the exit-code of your process. \section{Functions and Procedures} \function{Abs}{(X : Every numerical type)}{Every numerical type} {\var{Abs} returns the absolute value of a variable. The result of the function has the same type as its argument, which can be any numerical type.} {None.} {\seef{Round}} \input{refex/ex1.tex} \function{Addr}{(X : Any type)}{Pointer} {\var{Addr} returns a pointer to its argument, which can be any type, or a function or procedure name. The returned pointer isn't typed. The same result can be obtained by the \var{@} operator, which can return a typed pointer (\progref). } {None} {\seef{SizeOf}} \input{refex/ex2.tex} \procedure{Append}{(Var F : Text)} {\var{Append} opens an existing file in append mode. Any data written to \var{F} will be appended to the file. If the file didn't exist, it will be created, contrary to the Turbo Pascal implementation of \var{Append}, where a file needed to exist in order to be opened by append. Only text files can be opened in append mode. } {If the file can't be created, a run-time error will be generated.} {\seep{Rewrite},\seep{Append}, \seep{Reset}} \input{refex/ex3.tex} \function{Arctan}{(X : Real)}{Real} {\var{Arctan} returns the Arctangent of \var{X}, which can be any real type. The resulting angle is in radial units.}{None}{\seef{Sin}, \seef{Cos}} \input{refex/ex4.tex} \procedure{Assign}{(Var F; Name : String)} {\var{Assign} assigns a name to \var{F}, which can be any file type. This call doesn't open the file, it just assigns a name to a file variable, and marks the file as closed.} {None.} {\seep{Reset}, \seep{Rewrite}, \seep{Append}} \input{refex/ex5.tex} \procedure{Blockread}{(Var F : File; Var Buffer; Var Count : Longint [; var Result : Longint])} {\var{Blockread} reads \var{count} or less records from file \var{F}. The result is placed in \var{Buffer}, which must contain enough room for \var{Count} records. The function cannot read partial records. If \var{Result} is specified, it contains the number of records actually read. If \var{Result} isn't specified, and less than \var{Count} records were read, a run-time error is generated. This behavior can be controlled by the \var{\{\$i\}} switch. } {If \var{Result} isn't specified, then a run-time error is generated if less than \var{count} records were read.} {\seep{Blockwrite},\seep{Reset}, \seep{Assign}} \input{refex/ex6.tex} \procedure{Blockwrite}{(Var F : File; Var Buffer; Var Count : Longint)} {\var{Blockread} writes \var{count} records from \var{buffer} to the file \var{F}. If the records couldn't be written to disk, a run-time error is generated. This behavior can be controlled by the \var{\{\$i\}} switch. } {A run-time error is generated if, for some reason, the records couldn't be written to disk.} {\seep{Blockread},\seep{Reset}, \seep{Assign}} For the example, see \seep{Blockread}. \procedure{Chdir}{(const S : string)} {\var{Chdir} changes the working directory of the process to \var{S}.} {If the directory \var{S} doesn't exist, a run-time error is generated.} {\seep{Mkdir}, \seep{Rmdir}} \input{refex/ex7.tex} \function{Chr}{(X : byte)}{Char} {\var{Chr} returns the character which has ASCII value \var{X}.} {None.} {\seef{Ord},\seep{Str}} \input{refex/ex8.tex} \procedure{Close}{(Var F : Anyfiletype)} {\var{Close} flushes the buffer of the file \var{F} and closes \var{F}. After a call to \var{Close}, data can no longer be read from or written to \var{F}. To reopen a file closed with \var{Close}, it isn't necessary to assign the file again. A call to \seep{Reset} or \seep{Rewrite} is sufficient.} {None.}{\seep{Assign}, \seep{Reset}, \seep{Rewrite}} \input{refex/ex9.tex} \function{Concat}{(S1,S2 [,S3, ... ,Sn])}{String} {\var{Concat} concatenates the strings \var{S1},\var{S2} etc. to one long string. The resulting string is truncated at a length of 255 bytes. The same operation can be performed with the \var{+} operation.} {None.} {\seef{Copy}, \seep{Delete}, \seep{Insert}, \seef{Pos}, \seef{Length}} \input{refex/ex10.tex} \function{Copy}{(Const S : String;Index : Integer;Count : Byte)}{String} {\var{Copy} returns a string which is a copy if the \var{Count} characters in \var{S}, starting at position \var{Index}. If \var{Count} is larger than the length of the string \var{S}, the result is truncated. If \var{Index} is larger than the length of the string \var{S}, then an empty string is returned.} {None.} {\seep{Delete}, \seep{Insert}, \seef{Pos}} \input{refex/ex11.tex} \function{Cos}{(X : real)}{Real} {\var{Cos} returns the cosine of \var{X}, where X is an angle, in radians.} {None.} {\seef{Arctan}, \seef{Sin}} \input{refex/ex12.tex} \Function{CSeg}{Word} {\var{CSeg} returns the Code segment register. In \fpk, it returns always a zero, since \fpk is a 32 bit compiler.} {None.} {\seef{DSeg}, \seef{Seg}, \seef{Ofs}, \seef{Ptr}} \input{refex/ex13.tex} \procedure{Dec}{(Var X : Any ordinal type[; Decrement : Longint])} {\var{Dec} decreases the value of \var{X} with \var{Decrement}. If \var{Decrement} isn't specified, then 1 is taken as a default.} {A range check can occur, or an underflow error, if you try to decrease \var{X} below its minimum value.} {\seep{Inc}} \input{refex/ex14.tex} \procedure{Delete}{(var S : string;Index : Integer;Count : Integer)} {\var{Delete} removes \var{Count} characters from string \var{S}, starting at position \var{Index}. All remaining characters are shifted \var{Count} positions to the left, and the length of the string is adjusted. } {None.} {\seef{Copy},\seef{Pos},\seep{Insert}} \input{refex/ex15.tex} \procedure{Dispose}{(P : pointer)} {\var{Dispose} releases the memory allocated with a call to \seep{New}. The pointer \var{P} must be typed. The released memory is returned to the heap.} {An error will occur if the pointer doesn't point to a location in the heap.} {\seep{New}, \seep{Getmem}, \seep{Freemem}} \input{refex/ex16.tex} \Function{DSeg}{Word} {\var{DSeg} returns the data segment register. In \fpk, it returns always a zero, since \fpk is a 32 bit compiler.} {None.} {\seef{CSeg}, \seef{Seg}, \seef{Ofs}, \seef{Ptr}} \input{refex/ex17.tex} \function{Eof}{[(F : Any file type)]}{Boolean} {\var{Eof} returns \var{True} if the file-pointer has reached the end of the file, or if the file is empty. In all other cases \var{Eof} returns \var{False}. If no file \var{F} is specified, standard input is assumed.} {None.} {\seef{Eoln}, \seep{Assign}, \seep{Reset}, \seep{Rewrite}} \input{refex/ex18.tex} \function{Eoln}{[(F : Text)]}{Boolean} {\var{Eof} returns \var{True} if the file pointer has reached the end of a line, which is demarcated by a line-feed character (ASCII value 10), or if the end of the file is reached. In all other cases \var{Eof} returns \var{False}. If no file \var{F} is specified, standard input is assumed. It can only be used on files of type \var{Text}.} {None.} {\seef{Eof}, \seep{Assign}, \seep{Reset}, \seep{Rewrite}} \input{refex/ex19.tex} \procedure{Erase}{(Var F : Any file type)} {\var{Erase} removes an unopened file from disk. The file should be assigned with \var{Assign}, but not opened with \var{Reset} or \var{Rewrite}} {A run-time error will be generated if the specified file doesn't exist.} {\seep{Assign}} \input{refex/ex20.tex} \procedure{Exit}{([Var X : return type )]} {\var{Exit} exits the current subroutine, and returns control to the calling routine. If invoked in the main program routine, exit stops the program. The optional argument \var{X} allows to specify a return value, in the case \var{Exit} is invoked in a function. The function result will then be equal to \var{X}.} {None.} {\seep{Halt}} \input{refex/ex21.tex} \function{Exp}{(Var X : real)}{Real} {\var{Exp} returns the exponent of \var{X}, i.e. the number \var{e} to the power \var{X}.} {None.}{\seef{Ln}} \input{refex/ex22.tex} \function{Filepos}{(Var F : Any file type)}{Longint} {\var{Filepos} returns the current record position of the file-pointer in file \var{F}. It cannot be invoked with a file of type \var{Text}.} {None.} {\seef{Filesize}} \input{refex/ex23.tex} \function{Filesize}{(Var F : Any file type)}{Longint} {\var{Filepos} returns the total number of records in file \var{F}. It cannot be invoked with a file of type \var{Text}. (under \linux, this also means that it cannot be invoked on pipes.) If \var{F} is empty, 0 is returned. } {None.} {\seef{Filepos}} \input{refex/ex24.tex} \procedure{Fillchar}{(Var X;Count : Longint;Value : char or byte);} {\var{Fillchar} fills the memory starting at \var{X} with \var{Count} bytes or characters with value equal to \var{Value}. } {No checking on the size of \var{X} is done.} {\seep{Fillword}, \seep{Move}} \input{refex/ex25.tex} \procedure{Fillword}{(Var X;Count : Longint;Value : Word);} {\var{Fillword} fills the memory starting at \var{X} with \var{Count} words with value equal to \var{Value}. } {No checking on the size of \var{X} is done.} {\seep{Fillword}, \seep{Move}} \input{refex/ex76.tex} \procedure{Flush}{(Var F : Text)} {\var{Flush} empties the internal buffer of file \var{F} and writes the contents to disk. The file is \textit{not} closed as a result of this call.} {If the disk is full, a run-time error will be generated.} {\seep{Close}} \input{refex/ex26.tex} \function{Frac}{(X : real)}{Real} {\var{Frac} returns the non-integer part of \var{X}.} {None.} {\seef{Round}, \seef{Int}} \input{refex/ex27.tex} \procedure{Freemem}{(Var P : pointer; Count : longint)} {\var{Freemem} releases the memory occupied by the pointer \var{P}, of size \var{Count}, and returns it to the heap. \var{P} should point to the memory allocated to a dynamical variable.} {An error will occur when \var{P} doesn't point to the heap.} {\seep{Getmem}, \seep{New}, \seep{Dispose}} \input{refex/ex28.tex} \procedure{Getdir}{(drivenr : byte;var dir : string)} {\var{Getdir} returns in \var{dir} the current directory on the drive \var{drivenr}, where {drivenr} is 1 for the first floppy drive, 3 for the first hard disk etc. A value of 0 returns the directory on the current disk. On \linux, \var{drivenr} is ignored, as there is only one directory tree.} {An error is returned under \dos, if the drive requested isn't ready.} {\seep{Chdir}} \input{refex/ex29.tex} \procedure{Getmem}{(var p : pointer;size : longint)} {\var{Getmem} reserves \var{Size} bytes memory on the heap, and returns a pointer to this memory in \var{p}. If no more memory is available, nil is returned.} {None.} {\seep{Freemem}, \seep{Dispose}, \seep{New}} For an example, see \seep{Freemem}. \procedure{Halt}{[(Errnum : byte]} {\var{Halt} stops program execution and returns control to the calling program. The optional argument \var{Errnum} specifies an exit value. If omitted, zero is returned.} {None.} {\seep{Exit}} \input{refex/ex30.tex} \function{Hi}{(X : Ordinal type)}{Word or byte} {\var{Hi} returns the high byte or word from \var{X}, depending on the size of X. If the size of X is 4, then the high word is returned. If the size is 2 then the high byte is retuned. \var{hi} cannot be invoked on types of size 1, such as byte or char.} {None} {\seef{Lo}} \input{refex/ex31.tex} \procedure{Inc}{(Var X : Any ordinal type[; Increment : Longint])} {\var{Inc} increases the value of \var{X} with \var{Increment}. If \var{Increment} isn't specified, then 1 is taken as a default.} {A range check can occur, or an overflow error, if you try to increase \var{X} over its maximum value.} {\seep{Dec}} \input{refex/ex32.tex} \procedure{Insert}{(Var Source : String;var S : String;Index : integer)} {\var{Insert} inserts string \var{S} in string \var{Source}, at position \var{Index}, shifting all characters after \var{Index} to the right. The resulting string is truncated at 255 characters, if needed.} {None.} {\seep{Delete}, \seef{Copy}, \seef{Pos}} \input{refex/ex33.tex} \function{Int}{(X : real)}{Real} {\var{Int} returns the integer part of any real \var{X}, as a real.} {None.} {\seef{Frac}, \seef{Round}} \input{refex/ex34.tex} \Function{IOresult}{Word} {IOresult contains the result of any input/output call, when the \var{\{\$i-\}} compiler directive is active, and IO checking is disabled. When the flag is read, it is reset to zero. If \var{IOresult} is zero, the operation completed successfully. If non-zero, an error occurred. The following errors can occur: \dos errors : \begin{description} \item [2\ ] File not found. \item [3\ ] Path not found. \item [4\ ] Too many open files. \item [5\ ] Access denied. \item [6\ ] Invalid file handle. \item [12\ ] Invalid file-access mode. \item [15\ ] Invalid disk number. \item [16\ ] Cannot remove current directory. \item [17\ ] Cannot rename across volumes. \end{description} I/O errors : \begin{description} \item [100\ ] Error when reading from disk. \item [101\ ] Error when writing to disk. \item [102\ ] File not assigned. \item [103\ ] File not open. \item [104\ ] File not opened for input. \item [105\ ] File not opened for output. \item [106\ ] Invalid number. \end{description} Fatal errors : \begin{description} \item [150\ ] Disk is write protected. \item [151\ ] Unknown device. \item [152\ ] Drive not ready. \item [153\ ] Unknown command. \item [154\ ] CRC check failed. \item [155\ ] Invalid drive specified.. \item [156\ ] Seek error on disk. \item [157\ ] Invalid media type. \item [158\ ] Sector not found. \item [159\ ] Printer out of paper. \item [160\ ] Error when writing to device. \item [161\ ] Error when reading from device. \item [162\ ] Hardware failure. \end{description} } {None.} {All I/O functions.} \input{refex/ex35.tex} \function{Length}{(S : String)}{Byte} {\var{Length} returns the length of the string \var{S}, which is limited to 255. If the strings \var{S} is empty, 0 is returned. {\em Note:} The length of the string \var{S} is stored in \var{S[0]}. } {None.} {\seef{Pos}} \input{refex/ex36.tex} \function{Ln}{(X : real)}{Real} { \var{Ln} returns the natural logarithm of the real parameter \var{X}. \var{X} must be positive. } {An run-time error will occur when \var{X} is negative.} {\seef{Exp}} \input{refex/ex37.tex} \function{Lo}{(O : Word or Longint)}{Byte or Word} {\var{Lo} returns the low byte of its argument if this is of type \var{Integer} or \var{Word}. It returns the low word of its argument if this is of type \var{Longint} or \var{Cardinal}.} {None.} {\seef{Ord}, \seef{Chr}} \input{refex/ex38.tex} \function{Lowercase}{(C : Char or String)}{Char or String} {\var{Lowercase} returns the lowercase version of its argument \var{C}. If its argument is a string, then the complete string is converted to lowercase. The type of the returned value is the same as the type of the argument.} {None.} {\seef{Upcase}} \input{refex/ex73.tex} \procedure{Mark}{(Var P : Pointer)} {\var{Mark} copies the current heap-pointer to \var{P}.} {None.} {\seep{Getmem}, \seep{Freemem}, \seep{New}, \seep{Dispose}, \seef{Maxavail}} \input{refex/ex39.tex} \Function{Maxavail}{Longint} {\var{Maxavail} returns the size, in bytes, of the biggest free memory block in the heap. {\em Remark:} The heap grows dynamically if more memory is needed than is available.} {None.} {\seep{Release}, \seef{Memavail},\seep{Freemem}, \seep{Getmem}} \input{refex/ex40.tex} \Function{Memavail}{Longint} {\var{Memavail} returns the size, in bytes, of the free heap memory. {\em Remark:} The heap grows dynamically if more memory is needed than is available.} {None.} {\seef{Maxavail},\seep{Freemem}, \seep{Getmem}} \input{refex/ex41.tex} \procedure{Mkdir}{(const S : string)} {\var{Chdir} creates a new directory \var{S}.} {If a parent-directory of directory \var{S} doesn't exist, a run-time error is generated.} {\seep{Chdir}, \seep{Rmdir}} For an example, see \seep{Rmdir}. \procedure{Move}{(var Source,Dest;Count : longint)} {\var{Move} moves \var{Count} bytes from \var{Source} to \var{Dest}.} {If either \var{Dest} or \var{Source} is outside the accessible memory for the process, then a run-time error will be generated. With older versions of the compiler, a segmentation-fault will occur. } {\seep{Fillword}, \seep{Fillchar}} \input{refex/ex42.tex} \procedure{New}{(Var P : Pointer[, Constructor])} {\var{New} allocates a new instance of the type pointed to by \var{P}, and puts the address in \var{P}. If P is an object, then it is possible to specify the name of the constructor with which the instance will be created.} {If not enough memory is available, \var{Nil} will be returned.} {\seep{Dispose}, \seep{Freemem}, \seep{Getmem}, \seef{Memavail}, \seef{Maxavail}} For an example, see \seep{Dispose}. \function{Odd}{(X : longint)}{Boolean} {\var{Odd} returns \var{True} if \var{X} is odd, or \var{False} otherwise.} {None.} {\seef{Abs}, \seef{Ord}} \input{refex/ex43.tex} \function{Ofs}{Var X}{Longint} {\var{Ofs} returns the offset of the address of a variable. This function is only supported for compatibility. In \fpk, it returns always the complete address of the variable, since \fpk is a 32 bit compiler. } {None.} {\seef{DSeg}, \seef{CSeg}, \seef{Seg}, \seef{Ptr}} \input{refex/ex44.tex} \function{Ord}{(X : Ordinal type)}{Byte} {\var{Ord} returns the Ordinal value of a ordinal-type variable \var{X}.} {None.} {\seef{Chr}} \input{refex/ex45.tex} \Function{Paramcount}{Longint} {\var{Paramcount} returns the number of command-line arguments. If no arguments were given to the running program, \var{0} is returned. } {None.} {\seef{Paramstr}} \input{refex/ex46.tex} \function{Paramstr}{(L : Longint)}{String} {\var{Paramstr} returns the \var{L}-th command-line argument. \var{L} must be between \var{0} and \var{Paramcount}, these values included. The zeroth argument is the name with which the program was started. } {Under Linux, command-line arguments may be longer than 255 characters. In that case, the string is truncated. If you want to access the complete string, you must use the \var{argv} pointer to access the real values of the command-line parameters.} {\seef{Paramcount}} For an example, see \seef{Paramcount}. \Function{Pi}{Real} {\var{Pi} returns the value of Pi (3.1415926535897932385).} {None.} {\seef{Cos}, \seef{Sin}} \input{refex/ex47.tex} \function{Pos}{(Const Substr : String;Const S : String)}{Byte} {\var{Pos} returns the index of \var{Substr} in \var{S}, if \var{S} contains \var{Substr}. In case \var{Substr} isn't found, \var{0} is returned. The search is case-sensitive. } {None} {\seef{Length}, \seef{Copy}, \seep{Delete}, \seep{Insert}} \input{refex/ex48.tex} \function{Ptr}{(Sel,Off : Longint)}{Pointer} {\var{Ptr} returns a pointer, pointing to the address specified by segment{Sel} and offset \var{Off}. {\em Remark 1:} In the 32-bit flat-memory model supported by \fpk, this function is obsolete.} {\em Remark 2:} The returned address is simply the offset. If you recompile the RTL with \var{-dDoMapping} defined, then the compiler returns the following : \verb|ptr:=pointer($e0000000+sel shl 4+off)| under \dos, or \verb|ptr:=pointer(sel shl 4+off)| on other OSes. {None.} {\seef{Addr}} \input{refex/ex59.tex} \function{Random}{[(L : longint)]}{Longint or Real} {\var{Random} returns a random number larger or equal to \var{0} and strictly less than \var{L}. If the argument \var{L} is omitted, a real number between 0 and 1 is returned. (0 included, 1 excluded)} {None.} {\seep{Randomize}} \input{refex/ex49.tex} \Procedure{Randomize} {\var{Randomize} initializes the random number generator of \fpk, by giving a value to \var{Randseed}, calculated with the system clock. } {None.} {\seef{Random}} For an example, see \seef{Random}. \procedure{Read}{([Var F : Any file type], V1 [, V2, ... , Vn])} {\var{Read} reads one or more values from a file \var{F}, and stores the result in \var{V1}, \var{V2}, etc.; If no file \var{F} is specified, then standard input is read. If \var{F} is of type \var{Text}, then the variables \var{V1, V2} etc. must be of type \var{Char}, \var{Integer}, \var{Real} or \var{String}. If \var{F} is a typed file, then each of the variables must be of the type specified in the declaration of \var{F}. Untyped files are not allowed as an argument.} {If no data is available, a run-time error is generated. This behavior can be controlled with the \var{\{\$i\}} compiler switch.} {\seep{Readln}, \seep{Blockread}, \seep{Write}, \seep{Blockwrite}} \input{refex/ex50.tex} \procedure{Readln}{[Var F : Text], V1 [, V2, ... , Vn])} {\var{Read} reads one or more values from a file \var{F}, and stores the result in \var{V1}, \var{V2}, etc. After that it goes to the next line in the file (defined by the \var{LineFeed (\#10)} character). If no file \var{F} is specified, then standard input is read. The variables \var{V1, V2} etc. must be of type \var{Char}, \var{Integer}, \var{Real}, \var{String} or \var{PChar}. } {If no data is available, a run-time error is generated. This behavior can be controlled with the \var{\{\$i\}} compiler switch.} {\seep{Read}, \seep{Blockread}, \seep{Write}, \seep{Blockwrite}} For an example, see \seep{Read}. \procedure{Release}{(Var P : pointer)} {\var{Release} sets the top of the Heap to the location pointed to by \var{P}. All memory at a location higher than \var{P} is marked empty.} {A run-time error will be generated if \var{P} points to memory outside the heap.} {\seep{Mark}, \seef{Memavail}, \seef{Maxavail}, \seep{Getmem}, \seep{Freemem} \seep{New}, \seep{Dispose}} For an example, see \seep{Mark}. \procedure{Rename}{(Var F : Any Filetype; Const S : String)} {\var{Rename} changes the name of the assigned file \var{F} to \var{S}. \var{F} must be assigned, but not opened.} {A run-time error will be generated if \var{F} isn't assigned, or doesn't exist.} {\seep{Erase}} \input{refex/ex77.tex} \procedure{Reset}{(Var F : Any File Type[; L : longint])} {\var{Reset} opens a file \var{F} for reading. \var{F} can be any file type. If \var{F} is an untyped or typed file, then it is opened for reading and writing. If \var{F} is an untyped file, the record size can be specified in the optional parameter \var{L}. Default a value of 128 is used.} {If the file cannot be opened for reading, then a run-time error is generated. This behavior can be changed by the \var{\{\$i\} } compiler switch.} {\seep{Rewrite}, \seep{Assign}, \seep{Close}} \input{refex/ex51.tex} \procedure{Rewrite}{(Var F : Any File Type[; L : longint])} {\var{Rewrite} opens a file \var{F} for writing. \var{F} can be any file type. If \var{F} is an untyped or typed file, then it is opened for reading and writing. If \var{F} is an untyped file, the record size can be specified in the optional parameter \var{L}. Default a value of 128 is used. if \var{Rewrite} finds a file with the same name as \var{F}, this file is truncated to length \var{0}. If it doesn't find such a file, a new file is created. } {If the file cannot be opened for writing, then a run-time error is generated. This behavior can be changed by the \var{\{\$i\} } compiler switch.} {\seep{Reset}, \seep{Assign}, \seep{Close}} \input{refex/ex52.tex} \procedure{Rmdir}{(const S : string)} {\var{Rmdir} removes the directory \var{S}.} {If \var{S} doesn't exist, or isn't empty, a run-time error is generated. } {\seep{Chdir}, \seep{Rmdir}} \input{refex/ex53.tex} \function{Round}{(X : real)}{Longint} {\var{Round} rounds \var{X} to the closest integer, which may be bigger or smaller than \var{X}.} {None.} {\seef{Frac}, \seef{Int}, \seef{Trunc}} \input{refex/ex54.tex} \procedure{Runerror}{(ErrorCode : Word)} {\var{Runerror} stops the execution of the program, and generates a run-time error \var{ErrorCode}.} {None.} {\seep{Exit}, \seep{Halt}} \input{refex/ex55.tex} \procedure{Seek}{(Var F; Count : Longint)} {\var{Seek} sets the file-pointer for file \var{F} to record Nr. \var{Count}. The first record in a file has \var{Count=0}. F can be any file type, except \var{Text}. If \var{F} is an untyped file, with no specified record size, 128 is assumed.} {A run-time error is generated if \var{Count} points to a position outside the file, or the file isn't opened.} {\seef{Eof}, \seef{SeekEof}, \seef{SeekEoln}} \input{refex/ex56.tex} \function{SeekEof}{[(Var F : text)]}{Boolean} {\var{SeekEof} returns \var{True} is the file-pointer is at the end of the file. It ignores all whitespace. Calling this function has the effect that the file-position is advanced until the first non-whitespace character or the end-of-file marker is reached. If the end-of-file marker is reached, \var{True} is returned. Otherwise, False is returned. If the parameter \var{F} is omitted, standard \var{Input} is assumed. } {A run-time error is generated if the file \var{F} isn't opened.} {\seef{Eof}, \seef{SeekEoln}, \seep{Seek}} \input{refex/ex57.tex} \function{SeekEoln}{[(Var F : text)]}{Boolean} {\var{SeekEoln} returns \var{True} is the file-pointer is at the end of the current line. It ignores all whitespace. Calling this function has the effect that the file-position is advanced until the first non-whitespace character or the end-of-line marker is reached. If the end-of-line marker is reached, \var{True} is returned. Otherwise, False is returned. The end-of-line marker is defined as \var{\#10}, the LineFeed character. If the parameter \var{F} is omitted, standard \var{Input} is assumed.} {A run-time error is generated if the file \var{F} isn't opened.} {\seef{Eof}, \seef{SeekEof}, \seep{Seek}} \input{refex/ex58.tex} \function{Seg}{Var X}{Longint} {\var{Seg} returns the segment of the address of a variable. This function is only supported for compatibility. In \fpk, it returns always 0, since \fpk is a 32 bit compiler, segments have no meaning. } {None.} {\seef{DSeg}, \seef{CSeg}, \seef{Ofs}, \seef{Ptr}} \input{refex/ex60.tex} \procedure{SetTextBuf}{(Var f : Text; Var Buf[; Size : Word])} {\var{SetTextBuf} assigns an I/O buffer to a text file. The new buffer is located at \var{Buf} and is \var{Size} bytes long. If \var{Size} is omitted, then \var{SizeOf(Buf)} is assumed. The standard buffer of any text file is 128 bytes long. For heavy I/0 operations this may prove too slow. The \var{SetTextBuf} procedure allows you to set a bigger buffer for your application, thus reducing the number of system calls, and thus reducing the load on the system resources. The maximum size of the newly assigned buffer is 65355 bytes. {\em Remark 1:} Never assign a new buffer to an opened file. You can assign a new buffer immediately after a call to \seep{Rewrite}, \seep{Reset} or \var{Append}, but not after you read from/wrote to the file. This may cause loss of data. If you still want to assign a new buffer after read/write operations have been performed, flush the file first. This will ensure that the current buffer is emptied. {\em Remark 2:} Take care that the buffer you assign is always valid. If you assign a local variable as a buffer, then after your program exits the local program block, the buffer will no longer be valid, and stack problems may occur. } {No checking on \var{Size} is done.} {\seep{Assign}, \seep{Reset}, \seep{Rewrite}, \seep{Append}} \input{refex/ex61.tex} \function{Sin}{(X : real)}{Real} {\var{Sin} returns the sine of its argument \var{X}, where \var{X} is an angle in radians.} {None.} {\seef{Cos}, \seef{Pi}, \seef{Exp}} \input{refex/ex62.tex} \function{SizeOf}{(X : Any Type)}{Longint} {\var{SizeOf} Returns the size, in bytes, of any variable or type-identifier. {\em Remark:} this isn't really a RTL function. Its result is calculated at compile-time, and hard-coded in your executable.} {None.} {\seef{Addr}} \input{refex/ex63.tex} \Function{Sptr}{Pointer} {\var{Sptr} returns the current stack pointer. }{None.}{} \input{refex/ex64.tex} \function{Sqr}{(X : Real)}{Real} {\var{Sqr} returns the square of its argument \var{X}.} {None.} {\seef{Sqrt}, \seef{Ln}, \seef{Exp}} \input{refex/ex65.tex} \function{Sqrt}{(X : Real)}{Real} {\var{Sqrt} returns the square root of its argument \var{X}, which must be positive.} {If \var{X} is negative, then a run-time error is generated.} {\seef{Sqr}, \seef{Ln}, \seef{Exp}} \input{refex/ex66.tex} \Function{SSeg}{Longint} { \var{SSeg} returns the Stack Segment. This function is only supported for compatibolity reasons, as \var{Sptr} returns the correct contents of the stackpointer.} {None.}{\seef{Sptr}} \input{refex/ex67.tex} \procedure{Str}{(Var X[:NumPlaces[:Decimals]]; Var S : String)} {\var{Str} returns a string which represents the value of X. X can be any numerical type. The optional \var{NumPLaces} and \var{Decimals} specifiers control the formatting of the string.} {None.} {\seep{Val}} \input{refex/ex68.tex} \function{Swap}{(X)}{Type of X} {\var{Swap} swaps the high and low order bytes of \var{X} if \var{X} is of type \var{Word} or \var{Integer}, or swaps the high and low order words of \var{X} if \var{X} is of type \var{Longint} or \var{Cardinal}. The return type is the type of \var{X}} {None.}{\seef{Lo}, \seef{Hi}} \input{refex/ex69.tex} \function{Trunc}{(X : real)}{Longint} {\var{Trunc} returns the integer part of \var{X}, which is always smaller than (or equal to) \var{X}.} {None.} {\seef{Frac}, \seef{Int}, \seef{Trunc}} \input{refex/ex70.tex} \procedure{Truncate}{(Var F : file)} {\var{Truncate} truncates the (opened) file \var{F} at the current file position. }{Errors are reported by IOresult.}{\seep{Append}, \seef{Filepos}, \seep{Seek}} \input{refex/ex71.tex} \function{Upcase}{(C : Char or string)}{Char or String} {\var{Upcase} returns the uppercase version of its argument \var{C}. If its argument is a string, then the complete string is converted to uppercase. The type of the returned value is the same as the type of the argument.} {None.} {\seef{Lowercase}} \input{refex/ex72.tex} \procedure{Val}{(const S : string;var V;var Code : word)} {\var{Val} converts the value represented in the string \var{S} to a numerical value, and stores this value in the variable \var{V}, which can be of type \var{Longint}, \var{real} and \var{Byte}. If the conversion isn't succesfull, then the parameter \var{Code} contains the index of the character in \var{S} which prevented the conversion. The string \var{S} isn't allow to contain spaces.} {If the conversion doesn't succeed, the value of \var{Code} indicates the position where the conversion went wrong.} {\seep{Str}} \input{refex/ex74.tex} \procedure{Write}{([Var F : Any filetype;] V1 [; V2; ... , Vn)]} {\var{Write} writes the contents of the variables \var{V1}, \var{V2} etc. to the file \var{F}. \var{F} can be a typed file, or a \var{Text} file. If \var{F} is a typed file, then the variables \var{V1}, \var{V2} etc. must be of the same type as the type in the declaration of \var{F}. Untyped files are not allowed. If the parameter \var{F} is omitted, standard output is assumed. If \var{F} is of type \var{Text}, then the necessary conversions are done such that the output of the variables is in human-readable format. This conversion is done for all numerical types. Strings are printed exactly as they are in memory, as well as \var{PChar} types. The format of the numerical conversions can be influenced through the following modifiers: \var{ OutputVariable : NumChars [: Decimals ] } This will print the value of \var{OutputVariable} with a minimum of \var{NumChars} characters, from which \var{Decimals} are reserved for the decimals. If the number cannot be represented with \var{NumChars} characters, \var{NumChars} will be increased, until the representation fits. If the representation requires less than \var{NumChars} characters then the output is filled up with spaces, to the left of the generated string, thus resulting in a right-aligned representation. If no formatting is specified, then the number is written using its natural length, with a space in front of it if it's positive, and a minus sign if it's negative. Real numbers are, by default, written in scientific notation. } {If an error occurs, a run-time error is generated. This behavior can be controlled with the \var{\{\$i\}} switch. } {\seep{Writeln}, \seep{Read}, \seep{Readln}, \seep{Blockwrite} } \procedure{Writeln}{[([Var F : Text;] [V1 [; V2; ... , Vn)]]} {\var{Writeln} does the same as \seep{Write} for text files, and emits a Carriage Return - LineFeed character pair after that. If the parameter \var{F} is omitted, standard output is assumed. If no variables are specified, a Carriage Return - LineFeed character pair is emitted, resulting in a new line in the file \var{F}. {\em Remark:} Under \linux, the Carriage Return character is omitted, as customary in Unix environments. } {If an error occurs, a run-time error is generated. This behavior can be controlled with the \var{\{\$i\}} switch. } {\seep{Write}, \seep{Read}, \seep{Readln}, \seep{Blockwrite}} \input{refex/ex75.tex} % % The index. % \printindex \end{document}