Multiplatform Programming Guide

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This page is the start of a tutorial on writing multiplatform applications with Lazarus. It will cover both the necessary precautions to ensure that a program can be easily ported and the porting process for an already existing program. Others are invited to help improve the article.

Introduction to Multiplatform Programming

How many boxes do you need?

To answer this question, you should first determine who your potential users are and how your program will be used. This question depends on where you are deploying your application.

If you are developing generic desktop software, Windows is obviously the most important platform, but also including Mac OS X and/or Linux versions can sometimes be the difference that will make your software be chosen instead of a non-cross-platform app.

The popularity of the various desktop operating systems differs by country, by the type of software used, and with the target audience, so there's no general rule. For example, Mac OS X is quite popular in North America and western Europe, while in South America Macs are mostly restricted to video and sound work.

On many contract projects only one platform is relevant, and that's not a problem. Free Pascal and Lazarus are quite capable of writing software targeted at a specific platform. You can, for example, access the full Windows API to write a well integrated Windows program.

If you're developing software that will run on a Web server, a Unix platform in one of its various flavors is commonly used. In this case, perhaps only Linux, Solaris, *BSD and other Unixes make sense as your target platforms, although you may want to add support for Windows for completeness.

Once you've mastered cross-platform development, you can usually just focus on the problem the software is designed to solve and do most of your development on whatever platform you have available or feel most comfortable with. That is, once you've addressed any cross-platform issues in your design, you can largely ignore the other platforms, much as you would when developing for a single platform. However, at some point you'll need to test deploying and running your program on the other platforms and it will be helpful to have unrestricted access to machines running the all target operating systems. If you don't want multiple physical boxes, you can look into configuring a dual-boot Windows-Linux box or running Windows and Linux on your Mac via Bootstrap or under an emulator like Parallels or VMware.

Cross-platform Programming

Working with files and folders

When working with files and folders, this is important to use non-platform specific path delimiters and line ending sequences. Here is a list of declared constants in Lazarus to be used when working with files and folders.

  • PathSep, PathSeparator: path separator when adding many paths together (';', ...)
  • PathDelim, DirectorySeparator: directory separator for each platform ('/', '\', ...)
  • LineEnding: proper line ending character sequence (#13#10 - CRLF, #10 - LF, ...)

Another important thing to be noted is the case sensitiveness of the file system. On Windows filenames are never case sensitive, while they usually are on Linux and BSD platforms. Mac OS X use case insensitive filenames by default. This can be the cause of annoying bugs, so any portable application should use consistently filenames.

The RTL file functions use the system encoding for file names. Under Windows this is one of the windows code pages, while Linux, BSD and Mac OS X usually use UTF-8. The unit FileUtil of the LCL provides file functions which takes UTF-8 strings like the rest of the LCL.

<Delphi>// AnsiToUTF8 and UTF8ToAnsi need a widestring manager under Linux, BSD, MacOSX // but normally these OS use UTF-8 as system encoding so the widestringmanager // is not needed. function NeedRTLAnsi: boolean;// true if system encoding is not UTF-8 procedure SetNeedRTLAnsi(NewValue: boolean); function UTF8ToSys(const s: string): string;// as UTF8ToAnsi but more independent of widestringmanager function SysToUTF8(const s: string): string;// as AnsiToUTF8 but more independent of widestringmanager function UTF8ToConsole(const s: string): string;// converts UTF8 string to console encoding (used by Write, WriteLn)

// file operations function FileExistsUTF8(const Filename: string): boolean; function FileAgeUTF8(const FileName: string): Longint; function DirectoryExistsUTF8(const Directory: string): Boolean; function ExpandFileNameUTF8(const FileName: string): string; function ExpandUNCFileNameUTF8(const FileName: string): string; function ExtractShortPathNameUTF8(Const FileName : String) : String; function FindFirstUTF8(const Path: string; Attr: Longint; out Rslt: TSearchRec): Longint; function FindNextUTF8(var Rslt: TSearchRec): Longint; procedure FindCloseUTF8(var F: TSearchrec); function FileSetDateUTF8(const FileName: String; Age: Longint): Longint; function FileGetAttrUTF8(const FileName: String): Longint; function FileSetAttrUTF8(const Filename: String; Attr: longint): Longint; function DeleteFileUTF8(const FileName: String): Boolean; function RenameFileUTF8(const OldName, NewName: String): Boolean; function FileSearchUTF8(const Name, DirList : String): String; function FileIsReadOnlyUTF8(const FileName: String): Boolean; function GetCurrentDirUTF8: String; function SetCurrentDirUTF8(const NewDir: String): Boolean; function CreateDirUTF8(const NewDir: String): Boolean; function RemoveDirUTF8(const Dir: String): Boolean; function ForceDirectoriesUTF8(const Dir: string): Boolean;

// environment function ParamStrUTF8(Param: Integer): string; function GetEnvironmentStringUTF8(Index: Integer): string; function GetEnvironmentVariableUTF8(const EnvVar: string): String; function GetAppConfigDirUTF8(Global: Boolean): string;

// other function SysErrorMessageUTF8(ErrorCode: Integer): String;</Delphi>

Empty file names and double path delimiters

Windows allows empty file names, while Linux, BSD and Mac OS X do not. That's why FileExistsUTF8('..\') checks under Windows in the parent directory for a file without name. Under Unix like systems like Linux, BSD and OS X the empty file is mapped to the directory and directories are treated as files. This means that FileExistsUTF8('../') under Unix checks for the existence of the parent directory, which normally results true.

For the same reason double path delimiters in file names are treated differently. Under Windows 'C:\' is not the same as 'C:\\', while under Unix like OS the paths '/usr//' is the same as '/usr/', and if '/usr' is a directory then even all three are the same. This is important when concatenating file names. For example:

<Delphi>FullFilename:=FilePath+PathDelim+ShortFilename; // can result in two PathDelims which gives different results under Windows and Linux FullFilename:=AppendPathDelim(FilePath)+ShortFilename); // creates only one PathDelim FullFilename:=TrimFilename(FilePath+PathDelim+ShortFilename); // creates only one PathDelim and do some more clean up</Delphi>

The function TrimFilename replaces double path delimiters with single ones and shorten '..' paths. For example /usr//lib/../src is trimmed to /usr/src.

If you want to know if a directory exists use DirectoryExistsUTF8.

Another common task is to check if the path part of a file name exists. You can get the path with ExtractFilePath, but this will contain the path delimiter. Under Unix like system you can simply use FileExistsUTF8 on the path. For example FileExistsUTF('/home/user/') will return true if the directory /home/user exists. Under Windows you must use the DirectoryExistsUTF8 function, but before that you must delete the path delimiter, for example with the ChompPathDelim function. Under Unix like systems the root directory is '/' and using the ChompPathDelim function will create an empty string. The function DirPathExists works like the DirectoryExistsUTF8 function, but trims the given path.

Text encoding

Text files are often encoded in the current system encoding. Under Windows this is usually one of the windows code pages, while Linux, BSD and Mac OS X usually use UTF-8. There is no 100% rule to find out which encoding a text file uses. The LCL unit lconvencoding has a function to guess the encoding:

<Delphi>function GuessEncoding(const s: string): string; function GetDefaultTextEncoding: string;</Delphi>

And it contains functions to convert from one encoding to another:

<Delphi>function ConvertEncoding(const s, FromEncoding, ToEncoding: string): string;

function UTF8BOMToUTF8(const s: string): string; // UTF8 with BOM function ISO_8859_1ToUTF8(const s: string): string; // central europe function CP1250ToUTF8(const s: string): string; // central europe function CP1251ToUTF8(const s: string): string; // cyrillic function CP1252ToUTF8(const s: string): string; // latin 1 ... function UTF8ToUTF8BOM(const s: string): string; // UTF8 with BOM function UTF8ToISO_8859_1(const s: string): string; // central europe function UTF8ToCP1250(const s: string): string; // central europe function UTF8ToCP1251(const s: string): string; // cyrillic function UTF8ToCP1252(const s: string): string; // latin 1 ...</Delphi>

For example to load a text file and convert it to UTF-8 you can use:


 sl: TStringList;
 OriginalText: String;
 TextAsUTF8: String;


   sl.LoadFromFile('sometext.txt'); // beware: this changes line endings to system line endings


And to save a text file in the system encoding you can use: <Delphi>sl.Text:=ConvertEncoding(TextAsUTF8,EncodingUTF8,GetDefaultTextEncoding); sl.SaveToFile('sometext.txt');</Delphi>

Configuration files

You can use the GetAppConfigDir function from SysUtils unit to get a suitable place to store configuration files on different system. The function has one parameter, called Global. If it is True then the directory returned is a global directory, i.e. valid for all users on the system. If the parameter Global is false, then the directory is specific for the user who is executing the program. On systems that do not support multi-user environments, these two directories may be the same.

There is also the GetAppConfigFile which will return an appropriate name for an application configuration file. You can use it like this:

ConfigFilePath := GetAppConfigFile(False) + '.conf';

Bellow are examples of the output of default path functions on different systems:

<delphi>program project1;

{$mode objfpc}{$H+}






The output on a GNU/Linux system with FPC 2.2.2. Note that using True is buggy, already fixed in 2.2.3:


You can notice that global configuration files are stored on the /etc directory and local configurations are stored on a hidden folder on the user's home directory. Directories whose name begin with a dot (.) are hidden on Linux. You can create a directory on the location returned by GetAppConfigDir and then store configuration files there.

The output on Windows XP with FPC 2.2.4 + :

C:\Documents and Settings\All Users\Application Data\project1\
C:\Documents and Settings\user\Local Settings\Application Data\project1
C:\Documents and Settings\All Users\Application Data\project1\project1.cfg
C:\Documents and Settings\user\Local Settings\Application Data\project1\project1.cfg

Notice that before FPC 2.2.4 the function was using the directory where the application was to store global configurations on Windows.

The output on Windows 98 with FPC 2.2.0:

C:\Program Files\PROJECT1
C:\Windows\Local Settings\Application Data\PROJECT1
C:\Program Files\PROJECT1\PROJECT1.cfg
C:\Windows\Local Settings\Application Data\PROJECT1\PROJECT1.cfg

The output on Mac OS X with FPC 2.2.0:


Note: The use of UPX interferes with the use of the GetAppConfigDir and GetAppConfigFile functions.

Note: In most cases config files are preference files, which should be XML files with the ending ".plist" and be stored in /Library/Preferences or ~/Library/Preferences with Names taken from the field "Bundle identifier" in the Info.plist of the application bundle. Using the Carbon calls CFPreference... is probably the easiest way to achieve this. .config files in the User directory are a violation of the programming guide lines.

Data and resource files

A very common question is where to store data files an application might need, such as Images, Music, XML files, database files, help files, etc. Unfortunately there is no cross-platform function to get the best location to look for data files. The solution is to implement differently on each platform using IFDEFs.

On older versions of Windows you can simply assume that the files are at the same directory as the executable, or at a position relative to it.

Actually, application data that the program modifies should not be put in the application's directory (e.g. C:\Program Files\) but in a specific location (see e.g. [1], under "Classify Application Data"). Windows Vista and newer actively enforce this (users only have write access to these directories when using elevation or disabling UAC) but uses a folder redirection mechanism to accommodate older, wrongly programmed applications.

Reading data from application directories would still work.

Long story short: on Windows don't store application data in the program's directory.

On most Unixes (like Linux, BSDs, Solaris, etc), application data files are located in a fixed location, that can be something like: /usr/share/app_name or /opt/app_name.

Application data that needs to be written to by the application often gets stored in places like /var/<programname>, with appropriate permissions set.

User-specific read/write config/data will normally be stored somewhere under the user's home directory (e.g. in ~/.myfancyprogram).

Mac OS X is an exception among UNIXes. There the best way to deploy applications is using an application bundle, which includes all files your software will need. Then your resource files should be located inside the bundle, so it can be moved and still continue to work normally. You need to use CoreFoundation API calls to find the location of the bundle. This path maps to


This section presents a particular solution where under Windows the data files are stored on the same directory as the executable (or any other directory based on it, like ResourcesPath + 'data' + PathDelim + 'myfile.dat'), and on Unixes it will be on a directory read from a configuration file. If no configuration file exists or it contains no info, then a constant ('/usr/share/myapp/') is utilized as the default directory.

The configuration file path is located with the GetAppConfigFile function from the Free Pascal Runtime Library.

Below is a full unit which you can use at your applications.

<delphi>unit appsettings;


{$ifdef fpc}

 {$mode delphi}{$H+}



 Classes, SysUtils, Forms, IniFiles, constants;


{ TConfigurations }
TConfigurations = class(TObject)
  function GetResourcesPath: string;
  {other settings as fields here}
  ConfigFilePath: string;
  ResourcesPath: string;
  constructor Create;
  destructor Destroy; override;
  procedure ReadFromFile(Sender: TObject);
  procedure Save(Sender: TObject);


vConfigurations: TConfigurations;


{$IFDEF Win32} uses


{$ENDIF} {$ifdef Darwin} uses




 DefaultDirectory = '/usr/share/myapp/';
 BundleResourcesDirectory = '/Contents/Resources/';
 SectionGeneral = 'General';
 SectionUnix = 'UNIX';
 IdentResourcesPath = 'ResourcesPath';

{ TConfigurations }

constructor TConfigurations.Create; begin {$ifdef win32}

ConfigFilePath := ExtractFilePath(Application.EXEName) + 'myapp.ini';

{$endif} {$ifdef Unix}

ConfigFilePath := GetAppConfigFile(False) + '.conf';


 ResourcePath := GetResourcesPath();


destructor TConfigurations.Destroy; begin

 inherited Destroy;


procedure TConfigurations.Save(Sender: TObject); var

 MyFile: TIniFile;


 MyFile := TIniFile.Create(ConfigFilePath);
   MyFile.WriteString(SectionUnix, IdentResourcesPath, ResourcesPath);


procedure TConfigurations.ReadFromFile(Sender: TObject); var

MyFile: TIniFile;


MyFile := TIniFile.Create(ConfigFilePath);
 // Here you can read other information from the config file

{$ifdef Win32}

  ResourcesPath := MyFile.ReadString(SectionUnix, IdentResourcesPath,

ExtractFilePath(Application.EXEName)); {$else}

 {$ifndef darwin}
  ResourcesPath := MyFile.ReadString(SectionUnix, IdentResourcesPath,






function TConfigurations.GetResourcesPath(): string; begin {$ifdef Darwin} var

 pathRef: CFURLRef;
 pathCFStr: CFStringRef;
 pathStr: shortstring;

{$endif} begin {$ifdef UNIX} {$ifdef Darwin}

 pathRef := CFBundleCopyBundleURL(CFBundleGetMainBundle());
 pathCFStr := CFURLCopyFileSystemPath(pathRef, kCFURLPOSIXPathStyle);
 CFStringGetPascalString(pathCFStr, @pathStr, 255, CFStringGetSystemEncoding());
 Result := pathStr + BundleResourcesDirectory;


 Result := DefaultDirectory;

{$endif} {$endif}

{$ifdef Windows}

 Result := ExtractFilePath(Application.EXEName);

{$endif} end;


vConfigurations := TConfigurations.Create;




and here is an example code of how to use that unit to get a resource file from it's correct location:

<delphi>bmp := TBitmap.Create try

 bmp.LoadFromFile(vConfigurations.ResourcesPath + 'MyBitmap.bmp');



end; </delphi>

32/64 bit

Detecting bitness at runtime

While you can control whether you compile for 32 or 64 bit with compiler defines, sometimes you want to know what bitness the operating system runs. For example, if you are running a 32 bit Lazarus program on 64 bit Windows, you might want to run an external program in a 32 bit program files directory, or you might want to give different information to users: I need this in my LazUpdater Lazarus installer to offer the user a choice of 32 and 64 bit compilers, if appropriate.

For Windows, works for me on Vista x64 with FPC x86 compiler - thanks to German Lazarus forum: <delphi> program bitness;

{$mode objfpc}{$H+} {$APPTYPE CONSOLE} uses {$IFDEF UNIX} {$IFDEF UseCThreads}

 cthreads, {$ENDIF} {$ENDIF}
 function IsWindows64: boolean;
 Detect if we are running on 64 bit Windows or 32 bit Windows,
 independently of bitness of this program.
 Original source:
 modified for FreePascal in German Lazarus forum:
   TIsWow64Process = function( // Type of IsWow64Process API fn
       Handle: Windows.THandle; var Res: Windows.BOOL): Windows.BOOL; stdcall;
   IsWow64Result: Windows.BOOL; // Result from IsWow64Process
   IsWow64Process: TIsWow64Process; // IsWow64Process fn reference
   // Try to load required function from kernel32
   IsWow64Process := TIsWow64Process(Windows.GetProcAddress(
     Windows.GetModuleHandle('kernel32'), 'IsWow64Process'));
   if Assigned(IsWow64Process) then
     // Function is implemented: call it
     if not IsWow64Process(Windows.GetCurrentProcess, IsWow64Result) then
       raise SysUtils.Exception.Create('IsWindows64: bad process handle');
     // Return result of function
     Result := IsWow64Result;
     // Function not implemented: can't be running on Wow64
     Result := False;


   if IsWindows64 then
     writeln('This operating system is 64 bit.');
     writeln('This operating system is 32 bit.');
   on E: exception do
     writeln('Could not determine bitness of operating system. Error details: ' + E.ClassName+'/'+E.Message);



Pointer / Integer Typecasts

Pointers under 64bit need 8 bytes instead of 4 on 32bit. The 'Integer' type remains for compatibility 32bit on all platforms. This means you can not typecast pointers into integers and back. FPC defines two types for this: PtrInt and PtrUInt. PtrInt is a 32bit signed integer on 32 bit platforms and a 64bit signed integer on 64bit platforms. The same for PtrUInt, but unsigned integer instead.

Use for code that should work with Delphi and FPC:

  PtrInt = integer;
  PtrUInt = cardinal;

Replace all integer(SomePointerOrObject) with PtrInt(SomePointerOrObject).


Intel platforms are little endian, that means the least significant byte comes first. For example the two bytes of a word $1234 is stored as $34 $12 on little endian systems. On big endian systems like the powerpc the two bytes of a word $1234 are stored as $12 $34. The difference is important when reading files created on other systems.

Use for code that should work on both: <delphi>{$IFDEF ENDIAN_BIG} ... {$ELSE} ... {$ENDIF}</delphi>

The opposite is ENDIAN_LITTLE.

The system unit provides plenty of endian converting functions, like SwapEndian, BEtoN (big endian to current endian), LEtoN (little endian to current endian), NtoBE (current endian to big endian) and NtoLE (current endian to little endian).

Libc and other special units

Avoid legacy units like "oldlinux" and "libc" that are not supported outside of linux/i386.


Avoid assembler.

Compiler defines

<DELPHI>{$ifdef CPU32} ...write here code for 32 bit processors {$ENDIF} {$ifdef CPU64} ...write here code for 64 bit processors {$ENDIF}</DELPHI>

Projects, packages and search paths

Lazarus projects and packages are designed for multi platforms. Normally you can simply copy the project and the required packages to another machine and compile them there. You don't need to create one project per platform.

Some advice to achieve this

The compiler creates for every unit a ppu with the same name. This ppu can be used by other projects and packages. The unit source files (e.g. unit1.pas) should not be shared. Simply give the compiler a unit output directory where to create the ppu files. The IDE does that by default, so nothing to do for you here.

Every unit file must be part of one project or package. If a unit file is only used by a single project, add it to this project. Otherwise add it to a package. If you have not yet created a package for your shared units, see here: Creating a package for your common units

Every project and every package should have disjunct directories - they should not share directories. Otherwise you must be an expert in the art of compiler search paths. If you are not an expert or if others who may use your project/package are not experts: do not share directories between projects/packages.

Platform specific units

For example the unit wintricks.pas should only be used under Windows. In the uses section use:


 Classes, SysUtils
 {$IFDEF Windows}

If the unit is part of a package, you must also select the unit in the package editor of the package and disable the Use unit checkbox.

See also Platform specific units

Platform specific search paths

When you target several platforms and access the operating system directly, then you will quickly get tired of endless IFDEF constructions. One solution that is used often in the FPC and Lazarus sources is to use include files. Create one sub directory per target. For example win32, linux, bsd, darwin. Put into each directory an include file with the same name. Then use a macro in the include path. The unit can use a normal include directive. An example for one include file for each LCL widget set:

Create one file for each widget set you want to support:


You do not need to add the files to the package or project. Add the include search path $(LCLWidgetType) to the compiler options of your package or project.

In your unit use the directive: {$I}

Here are some useful macros and common values:

  • LCLWidgetType: win32, gtk, gtk2, qt, carbon, fpgui, nogui
  • TargetOS: linux, win32, win64, wince, freebsd, netbsd, openbsd, darwin (many more)
  • TargetCPU: i386, x86_64, arm, powerpc, sparc
  • SrcOS: win, unix

You can use the $Env() macro to use environment variables.

And of course you can use combinations. For example the LCL uses:


See here the complete list of macros: IDE Macros in paths and filenames

Machine / User specific search paths

For example you have two windows machines stan and oliver. On stan your units are in C:\units and on oliver your units are in D:\path. The units belong to the package SharedStuff which is C:\units\sharedstuff.lpk on stan and D:\path\sharedstuff.lpk on oliver. Once you opened the lpk in the IDE or by lazbuild, the path is automatically stored in its configuration files (packagefiles.xml). When compiling a project that requires the package SharedStuff, the IDE and lazbuild knows where it is. So no configuration is needed.

If you have want to deploy a package over many machine or for all users of a machine (e.g. a pool for students), then you can add a lpl file in the lazarus source directory. See packager/globallinks for examples.

Locale differences

Some functions from Free Pascal, like StrToFloat behave differently depending on the current locale. For example, in the USA the decimal separator is usually ".", but in many european and south american countries it is ",". This can be a problem as sometimes it is desired to have this functions behave in a fixed way, independently from the locale. The next sections explain how to do that.


A new set of format settings which set a fixed decimal separator can be created with the following code:


 FPointSeparator, FCommaSeparator: TFormatSettings;


 // Format seetings to convert a string to a float
 FPointSeparator := DefaultFormatSettings;
 FPointSeparator.DecimalSeparator := '.';
 FPointSeparator.ThousandSeparator := '#';// disable the thousand separator
 FCommaSeparator := DefaultFormatSettings;
 FCommaSeparator.DecimalSeparator := ',';
 FCommaSeparator.ThousandSeparator := '#';// disable the thousand separator</delphi>

Latter on you can use this format settings when calling StrToFloat, like this:

<delphi>// This function works like StrToFloat, but simply tries two possible decimal separator // This will avoid an exception when the string format doesn't match the locale function AnSemantico.StringToFloat(AStr: string): Double; begin

 if Pos('.', AStr) > 0 then Result := StrToFloat(AStr, FPointSeparator)
 else Result := StrToFloat(AStr, FCommaSeparator);


Gtk2 and masking FPU exceptions

Gtk2 library changes the default value of FPU (floating point unit) exception mask. The consequence of this is that some floating point exceptions do not get raised if Gtk2 library is used by the application. That means that, if for example you develop a LCL application on Windows with win32/64 widgetset (which is Windows default) and plan to compile for Linux (where Gtk2 is default widgetset), you should keep this incompatibilities in mind.

After this forum topic and answers on this bug report it became clear that nothing can be done about this, so we must know what actually these differences are.

Therefore, let's do a test:

<pascal> uses

 ..., math,...



 FPUException: TFPUException;
 FPUExceptionMask: TFPUExceptionMask;


 FPUExceptionMask := GetExceptionMask;
 for FPUException := Low(TFPUException) to High(TFPUException) do begin
   write(FPUException, ' - ');
   if not (FPUException in FPUExceptionMask) then
     write('not ');

end. </pascal>

Our simple program will get what FPC default is:

exInvalidOp - not masked!
exDenormalized - masked!
exZeroDivide - not masked!
exOverflow - not masked!
exUnderflow - masked!
exPrecision - masked!

However, with Gtk2, only exOverflow is not masked.

The consequence is that EInvalidOp and EZeroDivide exceptions do not get raised if the application links to Gtk2 library! Normally, dividing non-zero value by zero raises EZeroDivide exception and dividing zero by zero raises EInvalidOp. For example the code like this:

<pascal> var

 X, A, B: Double;

// ...


 X := A / B;
 // code block 1


 // code block 2

end; // ... </pascal>

will take different direction when compiled in application with Gtk2 widgetset. On win widgetset, when B equals zero, an exception will get raised (EZeroDivide or EInvalidOp, depending on whether A is zero) and "code block 2" will be executed. On Gtk2 X becomes Infinity, NegInfinity, or NaN and "code block 1" will be executed.

We can think of different ways to overcome this inconsistency. Most of the time you can simply test if B equals zero and don't try the dividing in that case. However, sometimes you will need some different approach. So, take a look at the following examples:

<pascal> uses

 ..., math,...

//... var

 X, A, B: Double;
 Ind: Boolean;

// ... try

 X := A / B;
 Ind := IsInfinite(X) or IsNan(X); // with gtk2, we fall here


 Ind := True; // in windows, we fall here when B equals zero

end; if Ind then begin

 // code block 2

end else begin

 // code block 1

end; // ... </pascal>

Or: <pascal> uses

 ..., math,...

//... var

 X, A, B: Double;
 FPUExceptionMask: TFPUExceptionMask;

// ...


 FPUExceptionMask := GetFPUExceptionMask;
 SetFPUExceptionMask(FPUExceptionMask - [exInvalidOp, exZeroDivide]); // unmask
   X := A / B;
   SetFPUExceptionMask(FPUExceptionMask); // return previous masking immediately, we must not let Gtk2 internals to be called without the mask
 // code block 1


 // code block 2

end; // ... </pascal>

Be cautios, do not do something like this (call LCL with still removed mask): <pascal> try

 FPUExceptionMask := GetFPUExceptionMask;
 SetFPUExceptionMask(FPUExceptionMask - [exInvalidOp, exZeroDivide]);
   Edit1.Text := FloatToStr(A / B); // NO! Setting Edit's text goes down to widgetset internals and Gtk2 API must not be called without the mask!
 // code block 1


 // code block 2

end; // ... </pascal>

But use an auxiliary variable: <pascal> try

 FPUExceptionMask := GetFPUExceptionMask;
 SetFPUExceptionMask(FPUExceptionMask - [exInvalidOp, exZeroDivide]);
   X := A / B; // First, we set auxiliary variable X
 Edit1.Text := FloatToStr(X); // Now we can set Edit's text.
 // code block 1


 // code block 2

end; // ... </pascal>

In all situations, when developing LCL applications, it is most important to know about this and to keep in mind that some floating point operations can go different way with different widgetsets. Then you can think of an appropriate way to workaround this, but this should not go unnoticed.

Windows specific issues

Windows API Functions

Many Windows programs use the Windows API extensively. In crossplatform applications Win API functions in the Windows unit should not be used, or should be enclosed by a conditional compile (e.g. {$IFDEF MSWINDOWS} ).

Fortunately many of the commonly used Windows API functions are implemented in a multiplatform way in the unit LCLIntf. This can be a solution for programs which rely heavily on the Windows API, although the best solution is to replace these calls with true crossplatform components from the LCL. You can replace calls to GDI painting functions with calls to a TCanvas object's methods, for example.

On Unix there is no "application directory"

Many programmers are used to call ExtractFilePath(ParamStr(0)) or Application.ExeName to get the location of the executable, and then search for the necessary files for the program execution (Images, XML files, database files, etc) based on the location of the executable. This is wrong on unixes. The string on ParamStr(0) may contain a directory other than the one of the executable, and it also varies between different shell programs (sh, bash, etc).

Even if Application.ExeName could in fact know the directory where the executable is, that file could be a symbolic link, so you could get the directory of the link instead (depending on the Linux kernel version, you either get the directory of the link or of the program binary itself).

To avoid this read the sections about configuration files and data files.

Making do without Windows COM Automation

With Windows, Automation is a powerful way not only of manipulating other programs remotely but also for allowing other programs to manipulate your program. With Delphi you can make your program both an Automation client and an Automation server, meaning it can both manipulate other programs and in turn be manipulated by other programs. For examples, see Using COM Automation to interact with OpenOffice and Microsoft Office.

Unfortunately, Automation isn't available on OS X and Linux. However, you can simulate some of the functionality of Automation on OS X using AppleScript.

AppleScript is similar to Automation in some ways. For example, you can write scripts that manipulate other programs. Here's a very simple example of AppleScript that starts NeoOffice (the Mac version of

 tell application "NeoOffice"
 end tell

An app that is designed to be manipulated by AppleScript provides a "dictionary" of classes and commands that can be used with the app, similar to the classes of a Windows Automation server. However, even apps like NeoOffice that don't provide a dictionary will still respond to the commands "launch", "activate" and "quit". AppleScript can be run from the OS X Script Editor or Finder or even converted to an app that you can drop on the dock just like any app. You can also run AppleScript from your program, as in this example:


This assumes the script is in the indicated file. You can also run scripts on the fly from your app using the OS X OsaScript command:

 Shell('osascript -e '#39'tell application "NeoOffice"'#39 +
       ' -e '#39'launch'#39' -e '#39'end tell'#39);
       {Note use of #39 to single-quote the parameters}

However, these examples are just the equivalent of the following Open command:

 Shell('open -a NeoOffice');

Similarly, in OS X you can emulate the Windows shell commands to launch a web browser and launch an email client with:

 fpsystem('open -a safari ",1935,hq_en_0_141387_rArNrNrNrN,00.html"');


 fpsystem('open -a mail ""');

which assumes, fairly safely, that an OS X system will have the Safari and Mail applications installed. Of course, you should never make assumptions like this, and for the two previous examples, you can in fact just rely on OS X to do the right thing and pick the user's default web browser and email client if you instead use these variations:

 fpsystem('open ",1935,hq_en_0_141387_rArNrNrNrN,00.html"');


 fpsystem('open ""');

Do not forget to include the Unix unit in your uses clause if you use fpsystem or shell (interchangeable).

The real power of AppleScript is to manipulate programs remotely to create and open documents and automate other activities. How much you can do with a program depends on how extensive its AppleScript dictionary is (if it has one). For example, Microsoft's Office X programs are not very usable with AppleScript, whereas the newer Office 2004 programs have completely rewritten AppleScript dictionaries that compare in many ways with what's available via the Windows Office Automation servers.

While Linux shells support sophisticated command line scripting, the type of scripting is limited to what can be passed to a program on the command line. There is no single, unified way to access a program's internal classes and commands with Linux the way they are via Windows Automation and OS X AppleScript. However, individual desktop environments (GNOME/KDE) and application frameworks often provide such methods of interprocess communication. On GNOME see Bonobo Components. KDE has the KParts framework, DCOP. OpenOffice has a platform neutral API for controlling the office remotely (google OpenOffice SDK) - though you would probably have to write glue code in another language that has bindings (such as Python) to use it. In addition, some applications have "server modes" activated by special command-line options that allow them to be controlled from another process. It is also possible (Borland did it with Kylix document browser) to "embed" one top-level X application window into another using XReparentWindow (I think).

As with Windows, many OS X and Linux programs are made up of multiple library files (.dylib and .so extensions). Sometimes these libraries are designed so you can also use them in programs you write. While this can be a way of adding some of the functionality of an external program to your program, it's not really the same as running and manipulating the external program itself. Instead, your program is just linking to and using the external program's library similar to the way it would use any programming library.

See Also