Reference 12
Contents
- 1 Miscellaneous Topics
Miscellaneous Topics
ANSI Standard
Mops is fairly close to the ANSI Forth standard. If you load the file ANSI, the remaining differences are dealt with, and you should, we hope, have a conforming ANSI Forth system, implementing the CORE word set, the ERROR and ERROR EXT words, and most of the CORE EXT words. Thus ANSI standard Forth programs using these word sets should be able to run under Mops.
Note that Mops selectors are not consistent with the standard, since under the standard, word names ending with colon must be normal Forth words. We have therefore provided a value SLCTRS? which if set to false will disable selectors. The file ANSI sets this flag false. Set it back to true if you need to.
Local Sections and Temporary Objects
Local sections are an extension to the named parameter/local variable scheme. Local variables are so useful, that there could be a tendency to make definitions too long, simply because you need to keep a number of local variables around. Local sections remove this problem, since they allow local variables to have a scope which extends over several definitions. Within a local section, all words have access to the named parameters and locals.
You begin a local section with the word LOCAL
. The syntax is e.g.:
LOCAL LocName { parm1 parm2 \ loc1 loc2 loc3 -- }
The word LocName is the ‘main’ word of the local section, i.e. the one which takes the named parameters and whose entry causes any locals to be allocated. It must be the last word defined in the local section, using :LOC
and ;LOC
in place of :
and ;
. LOCAL
doesn't start the definition of this word; it functions like a forward definition. It is really a means of making the names of the parms and locals available to the compiler at the start of the local section. All the words defined between LOCAL
and the ;LOC
at the end of the main word, can access the parameters and locals. These words can be called freely from other definitions within the local section, but must not be called from outside, for obvious reasons.
We also have local sections for methods, which work in a similar manner. You declare a local section for methods with MLOCAL
instead of LOCAL
. :MLOC
commences the definition of the ‘main’ method, and ;MLOC
ends the definition of that method, and ends the local section.
Temporary objects are rather like local variables. They could also be called ‘local objects’ but the word ‘local’ is being used for enough things already, so we're calling them ’temporary’. It's the same thing, though. They are normal objects in all respects, except that they only exist within one definition (or local section), and have no storage allocated otherwise. The syntax is as in this example:
: SomeWord temp{ int anInt var aVar string aString } 123 put: anInt " hello" put: aString ... ;
You can also use the syntax
temp { ... }
with ‘temp
’ and ’{
’ as separate words, if you prefer. I tend to use both, depending on how many temporary objects I'm declaring, and how I want to format the declaration.
As you can see, within the definition you can use the temporary objects in exactly the same way as normal objects. They are actually allocated in a frame on the return stack. However you can use >R
etc freely in the definition, since I keep a separate frame pointer. Of course, the temporary objects get a classInit:
message automatically when the definition is entered and their space is allocated. They also get a release:
message automatically when the definition exits (either at the semicolon or via EXIT
). Thus if you use a temporary string as in the above example, you don't have to worry about sending it release:
to get rid of its heap storage at the end of the definition.
As with local variables, if you call a definition recursively, you will get a fresh copy of any temporary objects. The syntax for temporary objects within a local section is exactly as you would expect:
LOCAL localName { parm1 parm2 \ loc1 loc2 -- } temp{ int int1 var var1 }
The local variables here are entirely optional. A local section can have either local variables, or temporary objects, or both. (Not much point in having neither!!)
Case Statements
We provide no less than three different flavors of case statement in Mops; each of these is most suitable in a different situation.
The first is the Eaker model, and was described in the Tutorial. We'll use expr1, exprn2 and so on to mean any code that leaves one result on the stack.
expr1 CASE expr2 OF some code ENDOF expr3 OF some more code ENDOF default code comes here ENDCASE
This form of case construct compiles directly to a set of equivalent simpler operations:
expr1 expr2 OVER = IF some code ELSE expr3 OVER = IF some more code ELSE default code THEN THEN DROP
As you can see from the equivalent Forth code, If any of expr2, expr3... matches expr1, the associated code is executed and then control passes to after the whole case construct. If none match, the default code is executed. Note also that right at the end, a DROP
is done to get rid of the expr1 value — this means that the default code can be left out completely without leaving a spurious value on the stack. But if you consume the expr1 value in the default code, remember to put a dummy value on the stack to be consumed by the DROP
. Here's a (rather useless) example:
CASE 10 OF ." ten" ENDOF 12 OF ." twelve" ENDOF 13 OF ." thirteen or sixteen" ENDOF 16 OF ." thirteen or sixteen" ENDOF 20 30 RANGEOF ." twenty to thirty inclusive" ENDOF ( default ) ." something else, namely " . 0 ( to be consumed ) ENDCASE
Notice that the ENDCASE
consumes one value off the stack, and also that there's no easy way of handling different values which lead to the same action (as in 13 and 16 above).
The second type of CASE
we have in Mops is a keyed case, in which a test value is compared to succesive values in a linear list. Here's the equivalent of the above example:
CASE[ 10 ]=> ." ten" [ 12 ]=> ." twelve" [ 13 ], [ 16 ]=> ." thirteen or sixteen" [ 20 30 RANGE]=> ." twenty to thirty inclusive" DEFAULT=> ." something else, namely " . ]CASE
This format will compile to more compact code than the former example, and should execute significantly faster. The former CASE
syntax has the advantage that the test values are computed each time, so can be different on different executions, if this is what you want. If, however, your test values don't change, which is more likely, the latter CASE[
syntax is better to use, since the test values are obtained at compile time and compiled once and for all into the code. As you may gather from the syntax, compilation is turned off and on when obtaining the test values, so that for example you could put CASE[ value1 value2 + ]=>
etc. The arithmetic will take place at compile time.
You can also see that there's a straightforward way of handling different values giving the same action. You can also use RANGE],
with the expected meaning.
The third type of case we have is an indexed case. In this kind of case, a direct table lookup is done to determine the outcome. Here's our example again, with one change:
SELECT[ 10 ]=> ." ten" [ 12 ]=> ." twelve" [ 13 ], [ 16 ]=> ." thirteen or sixteen" DEFAULT=> ." something else, namely " . ]SELECT
Notice that the syntax is almost the same as for the keyed case, but that there's no equivalent of the range test. This is precisely because it uses a direct table lookup rather than a series of comparisons. Later we might implement the filling in of a range of entries in the table, in which case we could implement the range test. But we haven't done this yet.
This code is the fastest of all to execute, since one direct lookup is done on the table. However in some situations this construction may take up too much space. The table which is generated will contain two bytes for every value in the range between the highest and lowest test values. Thus in this example the table will have an entry for every integer between 10 and 16 inclusive, i.e. 7 entries, which will take 14 bytes. This would be fine, but in many situations the table would be enormous. Mops will assume that an attempt to build a table of more than 500 entries is an error, and give a message.
Recursion and Forward Referencing
You may occasionally wish to call a word from within its own definition (this is called recursion). At first glance you may think that the logical thing to do would be to simply use the word's own name. (This was actually the way things were done in Neon, the forerunner to Mops.) However you may often want to call an earlier word with the same name, in the situation where you are redefining the word to have similar but slightly changed behavior. For this reason it is now standard Forth practice to ‘hide’ the name of the current definition while it's being compiled, so that a dictionary search won't find it, but will instead find an earlier word with the same name, if there is one. This is what Mops does as well. We therefore need another way of specifying recursion, and this is done, logically enough, with the word RECURSE
. Using RECURSE
means that you are calling the current definition.
If a situation arises in which you need to reference a Mops word before it has been defined, you can use Mops' forward reference facility. Before the word can be referenced the first time, you must declare it as forward in the following manner:
forward newWord
This declares newWord as a forward referenced Mops word. Later, when you are able to define newWord, you must do so in the following manner:
:f newWord ... ;f
:f
is a special colon compiling word that resolves forward referenced definitions. It creates a headerless entry for the new word in the dictionary, and then sets the previous entry, built by FORWARD
, to branch to the new definition. This will cause all compiled references to the FORWARD
definition to actually execute the later definition. If you forget to resolve a forward reference with :f ... ;f
, you will see a message at runtime informing you of the exact nature of the unresolved forward reference.
An important example of forward referencing is the word OK?
This is used in many places in the predefined classes and modules to check the return code from file and other I/O operations:
forward I/O_ERR \ ( err# -- ) Call when there's an I/O error. : OK? \ ( rc -- ) A useful word to use after an I/O op. ?dup 0EXIT I/O_err ;
The word I/O_ERR
is not actually defined in the basic Mops dic.! You won't notice this unless there is an error code returned, in which case Mops will try to execute I/O_ERR
and give an “unresolved forward reference” error. You must therefore define I/O_ERR
in any application to handle the error in some intelligent way, and it must be defined as a :f....;f
word.
Using Resources in Mops
A resource on the Macintosh is essentially a structured database into which you can store initialization information for Toolbox objects and other data items, such as strings. Resources can improve the maintainability of your program: if you store all of the textual information for your application in a resource file, for example, it becomes very easy to convert your application to another language or change the wording of a given string. Another benefit of resources is that they shift the burden of storage for initialization values from your resident code to the dynamic heap, so your application takes up less memory space.
Toolbox Resources
There are several ways in which you can use resources with Mops. For example, Toolbox objects such as Windows generally have two methods you can summon for bringing a window alive. NEW:
relies upon values passed to the method via the stack, and is independent of resource files. GETNEW:
uses only a resource ID to find the template for the object in the currently open resource files. For instance, a Window would have a resource of type 'WIND'
('wind'
in PowerMops) from which it would get its size, visible and goAway values, etc. Note that resource templates such as those of type 'WIND'
only contain information relating to the portion of the object that the Toolbox knows about'in the case of a Window, the window record. Other parts of the object, such as the window actions, must still be initialized by the application's code. Certain objects, such as those of class Icon, get all of their data from a resource item, and simply read the resource data whenever they are called upon to do anything.
Another way to use resources is for non-Toolbox objects that have no predefined template type. For these objects, you will need to use an existing type such as STR, or define your own types using ResEdit (see Putting Together a Mops Application).
Defining and Using Resources
Mops provides an easy way to define a resource item from within your application. For instance:
resource myWind
'Type WIND 256 set: myWind
defines a resource called myWind that has type WIND and a resource ID of 256. When you need to access this resource, send the message
getnew: myWind
Resource is a subclass of Handle, so you can now obtain a pointer to the resource data with
ptr: myWind
Note that if you then do anything that might cause a heap compaction, this pointer will be wrong; but you can avoid this with the lock: method of class Handle, thus:
lock: myWind
You can open a new resource file in the following manner:
" myFile.rsrc" openResFile
This opens the resource file named ‘myFile.rsrc’ and make it the first file in the search order. All open resource files are closed automatically when your application terminates. Mops uses the file mops.rsrc for its resources during normal operation, and you can add your own resources to this file with ResEdit.
Note: At present,
openResFile
is not defined in PowerMops. You need to use Carbon function likeHOpenResFile
. For example :0 0 " myFile.rsrc" str255 0 HOpenResFile ( -- fileRefNum )
The source file QD1 includes support for cursors, icons and QuickDraw pictures via the resource interface. This makes it very easy for you to dress up your application with fancy graphics that you can create with a graphics application, and then add them to a resource file.
Clearing Nested Stacks - Become
In a non-hierarchical, non-modal environment such as the Macintosh, the user is generally free to select another menu choice or open a different window at any time. This could happen while your code is nested several levels down, listening to events. If the user selects a new menu option that leads to an entirely new part of the program and your code is already several words deep on the return stack, the routine dispatched by the menu will nest several levels more. This could continue indefinitely until your application runs out of return stack, at which point it will bomb.
You have two ways to avoid this situation. One is to create an inverted architecture for your program, such that its event loop is at the highest level, and the code always returns to that level before listening to the event queue. This implies that you can never use KEY
from within a called word, but only from the highest level. This may often be a good solution, but in other situations it may not lead to the easiest or the clearest implementation of a particular problem.
Mops gives you an alternative method by providing you with a Mops word called BECOME
. BECOME
causes Mops to erase everything that currently is on the stacks, and resets them to their normal empty values. Mops then executes the word whose name follows BECOME
in the input stream. This automatically makes that last word the highest-level word in the application. In this manner you can actually have several mini-applications within one, each callable from the other. At the point that BECOME
is executed, you can rest assured that the stacks are empty and the application is essentially at ground zero.
System Vectors
Mops uses a powerful technique called vectoring to provide maximum flexibility for the programmer. Vectoring is the name given to the process of using a global or local variable to hold the address of a Mops word. For example, let's say that you would like Mops to interpret a file from disk just as though you were typing it at the keyboard. A built-in Mops system vector, named KEYVEC
, always holds the address of the word that Mops normally uses to acquire key-board input. By changing the contents of KEYVEC
to point to a special word you define — a word that reads a single character from disk — all Mops words that accept keyboard input will then take their input from disk, instead of from the keyboard. For example:
: diskKey Here 1 read: ffcb drop \ get 1 character from disk here c@ ; \ place it on the stack " sam" name: ffcb open: ffcb . ' diskKey -> keyVec \ set KEYVEC to get chars from disk file Sam
Of course, in a real example you would have to restore the proper KEYVEC
value when EOF (end of file condition) was reached.
Mops has a full set of vectors for all critical I/O and compilation routines, allowing you to tailor the behavior of the Mops environment very easily. These vectors cannot reside in the Kernel, since that would preclude having several saved images that used different vectors. Thus, each saved image has its own set of system vectors, located near the start of the dictionary.
System vectors are slightly different to normal vectors, in that a 0 value may be stored in a system vector. This means that the default action is to be taken. Each system vector has its own predefined default word (which cannot be altered).
Here are the main system vectors and their required behaviors — there are others that are used internally in the Mops system and should not normally be changed, unless you really know what you are doing. Also there are some system vectors relating to Apple events which are discussed separately later.
KEY | ( -- char ) | gets keyboard input |
---|---|---|
EMITVEC | ( char -- ) | sends one character to the primary output device |
PEMITVEC | ( char -- ) | sends one character to the secondary output device |
CRVEC | ( -- ) | sends a carriage return to the primary output device |
PCRVEC | ( -- ) | sends a carriage return to the secondary output device |
TYPEVEC | ( addr len -- ) | sends a string to the primary output device |
PTYPEVEC | ( addr len -- ) | sends a string to the secondary output device |
ECHOVEC | ( char -- ) | handles echoing to the output device of the keys being input by ACCEPT |
ABORTVEC | ( -- ) | cleans up the stacks and notifies the user of an error. The Mops word CL3 (clean-up 3') is normally executed by this vector, and your error word should call CL3 if it is to return to the Mops interpreter |
QUITVEC | ( -- ) | this word will be executed before the interpreter enters its main loop. It should be the startup word for an installed application |
UFIND | ( -- xt true OR -- false ) | is a special purpose variant of FIND (this vector is actually called by FIND before FIND searches the Mops dictionary for an occurrence of a particular name at the top of the dictionary -- HERE. You won't have to worry about this vector unless you plan to write new compiling words for Mops |
OBJINIT | ( -- ) | initializes certain areas of the kernel at Mops startup. It normally contains the xt of SYSINIT. Should not be altered by the user |
HEADER | ( -- ) | lays down a dictionary header |
Defining and Compiling Words
Much of the Mops language is, itself, written in Mops. This seemingly unlikely loop is possible because Mops is an extensible language — meaning that you can write new words in Mops that modify or extend the basic behavior of the language itself. In a sense, every word that you write extends Mops, because it adds to the same dictionary used by the Mops system. There are three layers of extensibility in Mops:
- Vocabulary extensions
Whenever you write a new word, instantiate a new object, create a new Value, and so on, you are extending the vocabulary of words that succeeding words can use. This obviously adds more power and function to the language. - Class extensions
When you define a new class of objects, you are extending Mops in a somewhat more profound way than in a vocabulary extension. Creating a new class creates a new template for building other objects. These templates are known as defining words, because they can, themselves, define new dictionary entries. This is a powerful technique, because there is a good chance that you will be able to reuse defining words in your other applications. Eventually, you'll develop a large library of Classes, which should make your future application development much easier. - Compiler extensions
The deepest layer of extensibility is concerned with constructing the tools that create defining words. Words such as:CLASS
or:M
are specialized compiling words that can truly extend the language syntax and add entirely new features. Compilers are the inner soul of the Mops language. They create control structures (such asIF
,BEGIN
andDO
), Mops' class compilation facility, message processing, prefix operators...even colon itself is an example of a Mops compiler word. Mops' compiler words come largely from Forth.
You can use Mops for years without ever writing a compiling word. But if you are an advanced programmer and are interested in writing compiling words, the best source of ideas and learning is from the Forth community. The Forth newsgroup is comp.lang.forth, where newcomers are always welcome to ask questions. There is also a great deal of Forth literature around, although you won't usually see it in mainstream computer bookstores. It can, however, be obtained through the Forth Interest Group
Error Handling
Mops' error handling is based upon the ANSI Forth Standard, which uses the two words CATCH
and THROW
. CATCH
is used as follows:
['] someWord catch
(of course, if interpreting rather than compiling, put '
instead of [']
). The action which takes place is to execute SomeWord, and if no error occurs, push a zero on top of whatever SomeWord may have put on the stack.
By saying “if no error occurs”, we really mean that THROW
did not take an error exit. THROW
pops the top item on the stack, and if it is nonzero, it restores the stacks to where they were when the current CATCH
was called (assuming that at least one CATCH
is in effect). Then the nonzero value, assumed to be an error code, is pushed onto the stack and execution continues straight after the CATCH
. If THROW
finds a zero value on top of the stack it means no error, and execution continues normally.
From this you can see that CATCH
and THROW
provide a flexible means of unwinding out of deeply nested code if an error occurs. If CATCH
catches an error, but doesn't want to recognize that particular error code, it can simply re-THROW
it.
If no CATCH
is in effect when an error occurs, Mops takes its default error action, which is to display an error message and execute ABORT
. ABORT
sets all stacks to their empty state, and initializes other Mops system variables to a suitable value before returning.
Before it executes, ABORT
executes the System Vector ABORTVEC
, to give extra flexibility in error recovery. Mops normally installs its own error handler word in ABORTVEC
, called CL3
, which prints the current stack of load files and clears this stack. You should call CL3
if you install an error routine for use during development, although the use of CATCH
and THROW
would probably be better. For your final installed application, since much of the Mops system won't be present, the Install routine asks you to specify an error word, which will be placed in ABORTVEC
. You should provide a routine which tells the user what is happening and a suitable action to take (most likely in an Alert or Dialog box).
There are two error routines that indirectly call ABORT
— ABORT"
and ?ERROR
. ABORT"
must be followed by a space, and then a string terminated by a quote. Its action at runtime is as follows: if the top of the data stack is true (nonzero), it will print the string between the quotes and then execute abort. If false, ABORT"
returns without doing anything. For instance, the phrase
read: theFile abort" File read failed"
would check the return code from a disk read operation, and abort if it indicated an error. You can force an ABORT"
to occur with the statement TRUE ABORT" ..."
.
Embedding a lot of error strings in your code can take up unnecessary memory space, and it also makes the messages difficult to change. ?ERROR
allows you to specify the actual text for your error strings in a resource file, and takes the resource ID number of the string to print, assumed to be a resource of type 'STR ' (note the space at the end). It works conditionally in the same way as ABORT"
. For instance,
find not ?error -13
prints the string with resource ID -13
if the word in the input stream is not found, and then aborts. Mops uses ?ERROR
for most of its error messages. If you want, you can just print a resource string without executing ABORT
by using the word MSG#
. It takes a resource ID just as ?ERROR
does. All of the error words function in compilation state only. To get a list of all messages and their numbers, type
.msgs
If you want to add a new message, do it this way:
<msg number> " the text of your message" addMsg
If you want to change an existing message, you can't just use AddMsg
as above or you'll get an error — this is just as a safety check. You have to remove the existing message first, thus:
<msg number> removeMsg
If adding your own messages, please use numbers above 200
, so as not to clash with future error messages we may want to add to the Mops system.
For an error while loading with echo off, the last word in the dictionary will usually be the word that experienced an error.
The file Mops.rsrc is a resource file containing all of Mops' error messages. Whenever one of the error words executes, it checks that Mops.rsrc is open. Of course, you must have Mops.rsrc within the folder Mops ƒ, or Mops won't be able to find it.
Assertions
Assertions are provided by a number of programming languages, and are a very useful way of catching bugs. Assertions allow you, during development, to ensure that things are the way they're supposed to be at key places.
Mops assertions must come within definitions. You use them like this:
ASSERT{ <something that evaluates to a flag> }
If ASSERTIONS?
is true, this will give error 216
(‘assertion failed’) if the evaluated flag is false. If ASSERTIONS?
is false, nothing will happen – the code between ASSERT{
and }
is skipped.
ASSERTIONS?
can be defined and redefined however and whenever you like, as long as it returns a flag. ASSERT{
tests it via EVALUATE
, so the most recently defined definition will be the one that gets looked at. You can define it at the start of your project, or at the start of each source file, or more often. It's up to you. This way you can enable or disable ASSERT{
to suit whatever you're doing in your project development.
Note also, wherever you have ASSERTIONS?
defined as a constant with value false
, no code will even be compiled for the assertion test. You can use this for code that you know works, so that there's no performance penalty whatever.
Inline Definitions
You may specify that a definition or method is to be compiled inline whenever it is used. This allows faster execution. The syntax is:
: XXX inline{ <some code>} ;
The code <some code>
is stored as a string, and whenever xxx
is compiled into a definition, the string is compiled using EVALUATE
. We actually store the source text for <some code>
as a string, and EVALUATE
it. This can give very good compiled code due to our optimization, which is why we took this approach. This syntax is really equivalent to
: XXX " <some code>" evaluate ; immediate
but the syntax is probably clearer. It also has advantages when used in methods. The syntax for an inline method is as you would expect:
:m YYY: inline{ <some code>} ;m
We assume that inline code chunks will be fairly short, and are to be optimized for speed. Therefore, when compiling the inline code (on an early bind), we do not change the machine's address register which normally points to the current object's base address. A normal method entry involves saving the previous base address on the return stack and setting up the new value, then popping the previous value when we exit the method. Thus making a method inline saves significant time at the cost of a little space. The file Struct has many methods which use inline code, so if you look there you will see plenty of examples of how to do it.
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