@c gm2-internals.texi describes the internals of gm2. @c Copyright @copyright{} 2000-2023 Free Software Foundation, Inc. @c @c This is part of the GM2 manual. @c For copying conditions, see the file gcc/doc/include/fdl.texi. @chapter GNU Modula-2 Internals This document is a small step in the long journey of documenting the GNU Modula-2 compiler and how it integrates with GCC. The document is still in it's infancy. @menu * History:: How GNU Modula-2 came about. * Overview:: Overview of the structure of GNU Modula-2. * Integrating:: How the front end integrates with gcc. * Passes:: What gets processed during each pass. * Run time:: Integration of run time modules with the compiler. * Scope rules:: Clarification of some the scope rules. * Done list:: Progression of the GNU Modula-2 project. * To do list:: Outstanding issues. @end menu @node History, Overview, , Internals @section History This document is out of date and needs to be rewritten. The Modula-2 compiler sources have come from the m2f compiler which runs under GNU/Linux. The original m2f compiler was written in Modula-2 and was bootstrapped via a modified version of p2c 1.20. The m2f compiler was a recursive descent which generated quadruples as intermediate code. It also used C style calling convention wherever possible and utilized a C structure for dynamic arrays. @node Overview, Integrating, History, Internals @section Overview GNU Modula-2 uses flex and a machine generated recursive descent parser. Most of the source code is written in Modula-2 and bootstrapping is achieved via a modified version of p2c-1.20. The modified p2c-1.20 is contained in the GNU Modula-2 source tree as are a number of other tools necessary for bootstrapping. The changes to p2c include: @itemize @bullet @item allowing @code{DEFINITION MODULE FOR "C"} @item fixes to abstract data types. @item making p2c understand the 2nd Edition dialect of Modula-2. @item introducing the @code{UNQUALIFIED} keyword. @item allowing varargs (@code{...}) inside @code{DEFINITION MODULE FOR "C"} modules. @item fixing the parser to understand commented @code{FORWARD} prototypes, which are ignored by GNU Modula-2. @item fixes to the @code{CASE} syntax for 2nd Edition Modula-2. @item fixes to a @code{FOR} loop counting down to zero using a @code{CARDINAL}. @item introducing an initialization section for each implementation module. @item various porting improvements and general tidying up so that it compiles with the gcc option @code{-Wall}. @end itemize GNU Modula-2 comes with PIM and ISO style libraries. The compiler is built using PIM libraries and the source of the compiler complies with the PIM dialect together with a few @code{C} library calling extensions. The compiler is a four pass compiler. The first pass tokenizes the source code, creates scope and enumeration type symbols. All tokens are placed into a dynamic buffer and subsequent passes reread tokens and build types, quadruples and resolve hidden types. @xref{Passes, , ,}. GNU Modula-2 uses a technique of double book keeping @footnote{See the excellent tutorial by Joachim Nadler translated by Tim Josling}. @xref{Back end Access to Symbol Table, , , gcc}. The front end builds a complete symbol table and a list of quadruples. Each symbol is translated into a @code{gcc} equivalent after which each quadruple is translated into a @code{gcc} @code{tree}. @node Integrating, Passes, Overview, Internals @section How the front end integrates with gcc The M2Base and M2System modules contain base types and system types respectively they map onto GCC back-end data types. @node Passes, Run time, Integrating, Internals @section Passes This section describes the general actions of each pass. The key to building up the symbol table correctly is to ensure that the symbols are only created in the scope where they were declared. This may seem obvious (and easy) but it is complicated by two issues: firstly GNU Modula-2 does not generate @code{.sym} files and so all imported definition modules are parsed after the module is parsed; secondly the import/export rules might mean that you can see and use a symbol before it is declared in a completely different scope. Here is a brief description of the lists of symbols maintained within @code{DefImp} and @code{Module} symbols. It is these lists and actions at each pass which manipulate these lists which solve the scoping and visability of all symbols. The @code{DefImp} symbol maintains the: @code{ExportQualified}, @code{ExportUnQualified}, @code{ExportRequest}, @code{IncludeList}, @code{ImportTree}, @code{ExportUndeclared}, @code{NeedToBeImplemented}, @code{LocalSymbols}, @code{EnumerationScopeList}, @code{Unresolved}, @code{ListOfVars}, @code{ListOfProcs} and @code{ListOfModules} lists. The @code{Module} symbol maintains the: @code{LocalSymbols}, @code{ExportTree}, @code{IncludeList}, @code{ImportTree}, @code{ExportUndeclared}, @code{EnumerationScopeList}, @code{Unresolved}, @code{ListOfVars}, @code{ListOfProcs} and @code{ListOfModules} lists. Initially we discuss the lists which are common to both @code{DefImp} and @code{Module} symbols, thereafter the lists peculiar to @code{DefImp} and @code{Module} symbols are discussed. The @code{ListOfVars}, @code{ListOfProcs} and @code{ListOfModules} lists (common to both symbols) and simply contain a list of variables, procedures and inner modules which are declared with this definition/implementation or program module. The @code{LocalSymbols} list (common to both symbols) contains a complete list of symbols visible in this modules scope. The symbols in this list may have been imported or exported from an inner module. The @code{EnumerationScope} list (common to both symbols) defines all visible enumeration symbols. When this module is parsed the contents of these enumeration types are marked as visible. Internally to GNU Modula-2 these form a pseudo scope (rather like a @code{WITH} statement which temporarily makes the fields of the record visible). The @code{ExportUndeclared} list (common to both symbols) contains a list of all symbols marked as exported but are as yet undeclared. The @code{IncludeList} is (common to both symbols) contains a list of all modules imported by the @code{IMPORT modulename ;} construct. The @code{ImportTree} (common to both symbols) contains a tree of all imported identifiers. The @code{ExportQualified} and @code{ExportUnQualified} trees (only present in the @code{DefImp} symbol) contain identifiers which are marked as @code{EXPORT QUALIFIED} and @code{EXPORT UNQUALIFIED} respectively. The @code{NeedToBeImplemented} list (only present in the @code{DefImp} symbol) and contains a list of all unresolved symbols which are exported. @subsection Pass 1 During pass 1 each @code{DefImp} and @code{Module} symbol is created. These are also placed into a list of outstanding sources to be parsed. The import and export lists are recorded and each object imported is created in the module from whence it is exported and added into the imported list of the current module. Any exported objects are placed into the export list and marked as qualified or unqualified. Inner module symbols are also created and their import and export lists are also processed. An import list will result in a symbol being fetched (or created if it does not exist) from the outer scope and placed into the scope of the inner module. An export list results in each symbol being fetched or created in the current inner scope and added to the outer scope. If the symbol has not yet been declared then it is added to the current modules @code{ExportUndeclared} list. Procedure symbols are created (the parameters are parsed but no more symbols are created). Enumerated types are created, hidden types in the definition modules are marked as such. All the rest of the Modula-2 syntax is parsed but no symbols are created. @subsection Pass 2 This section discuss varient records and their representation within the front end @file{gm2/gm2-compiler/SymbolTable.mod}. Records and varient records are declared in pass 2. Ordinary records are represented by the following symbol table entries: @example TYPE this = RECORD foo: CARDINAL ; bar: CHAR ; END ; SymRecord [1] +-------------+ | Name = this | SymRecordField [2] | ListOfSons | +-------------------+ | +--------| | Name = foo | | | [2] [3]| | Parent = [1] | +-------------+ | Type = [Cardinal] | | LocalSymbols| +-------------------+ | +-----------+ | | foo bar | | +-----------+ +-------------+ SymRecordField [3] +-------------------+ | Name = bar | | Parent = [1] | | Type = [Cardinal] | +-------------------+ @end example Whereas varient records are represented by the following symbol table entries: @example TYPE this = RECORD CASE tag: CHAR OF 'a': foo: CARDINAL ; bar: CHAR | 'b': an: REAL | ELSE END END ; SymRecord [1] +-------------+ | Name = this | SymRecordField [2] | ListOfSons | +-------------------+ | +--------| | Name = tag | | | [2] [3]| | Parent = [1] | | +--------+ | Type = [CHAR] | | LocalSymbols| +-------------------+ | +-----------+ | | tag foo | | | bar an | | +-----------+ +-------------+ SymVarient [3] SymFieldVarient [4] +-------------------+ +-------------------+ | Parent = [1] | | Parent = [1] | | ListOfSons | | ListOfSons | | +--------------| | +--------------| | | [4] [5] | | | [6] [7] | +-------------------+ +-------------------+ SymFieldVarient [5] +-------------------+ | Parent = [1] | | ListOfSons | | +--------------| | | [8] | +-------------------+ SymRecordField [6] SymRecordField [7] +-------------------+ +-------------------+ | Name = foo | | Name = bar | | Parent = [1] | | Parent = [1] | | Type = [CARDINAL] | | Type = [CHAR] | +-------------------+ +-------------------+ SymRecordField [8] +-------------------+ | Name = an | | Parent = [1] | | Type = [REAL] | +-------------------+ @end example Varient records which have nested @code{CASE} statements are represented by the following symbol table entries: @example TYPE this = RECORD CASE tag: CHAR OF 'a': foo: CARDINAL ; CASE bar: BOOLEAN OF TRUE : bt: INTEGER | FALSE: bf: CARDINAL END | 'b': an: REAL | ELSE END END ; SymRecord [1] +-------------+ | Name = this | SymRecordField [2] | ListOfSons | +-------------------+ | +--------| | Name = tag | | | [2] [3]| | Parent = [1] | | +--------+ | Type = [CHAR] | | LocalSymbols| +-------------------+ | +-----------+ | | tag foo | | | bar bt bf | | | an | | +-----------+ +-------------+ ('1st CASE') ('a' selector) SymVarient [3] SymFieldVarient [4] +-------------------+ +-------------------+ | Parent = [1] | | Parent = [1] | | ListOfSons | | ListOfSons | | +--------------| | +--------------| | | [4] [5] | | | [6] [7] [8] | +-------------------+ +-------------------+ ('b' selector) SymFieldVarient [5] +-------------------+ | Parent = [1] | | ListOfSons | | +--------------| | | [9] | +-------------------+ SymRecordField [6] SymRecordField [7] +-------------------+ +-------------------+ | Name = foo | | Name = bar | | Parent = [1] | | Parent = [1] | | Type = [CARDINAL] | | Type = [BOOLEAN] | +-------------------+ +-------------------+ ('2nd CASE') SymVarient [8] +-------------------+ | Parent = [1] | | ListOfSons | | +--------------| | | [12] [13] | +-------------------+ SymRecordField [9] +-------------------+ | Name = an | | Parent = [1] | | Type = [REAL] | +-------------------+ SymRecordField [10] SymRecordField [11] +-------------------+ +-------------------+ | Name = bt | | Name = bf | | Parent = [1] | | Parent = [1] | | Type = [REAL] | | Type = [REAL] | +-------------------+ +-------------------+ (TRUE selector) (FALSE selector) SymFieldVarient [12] SymFieldVarient [13] +-------------------+ +-------------------+ | Parent = [1] | | Parent = [1] | | ListOfSons | | ListOfSons | | +--------------| | +--------------| | | [10] | | | [11] | +-------------------+ +-------------------+ @end example @subsection Pass 3 To do @subsection Pass H To do @subsection Declaration ordering This section gives a few stress testing examples and walks though the mechanics of the passes and how the lists of symbols are created. The first example contains a nested module in which an enumeration type is created and exported. A procedure declared before the nested module uses the enumeration type. @example MODULE colour ; PROCEDURE make (VAR c: colours) ; BEGIN c := yellow END make ; MODULE inner ; EXPORT colours ; TYPE colours = (red, blue, yellow, white) ; END inner ; VAR g: colours BEGIN make(g) END colour. @end example @node Run time, Scope rules, Passes, Internals @section Run time This section describes how the GNU Modula-2 compiler interfaces with the run time system. The modules which must be common to all library collections are @code{M2RTS} and @code{SYSTEM}. In the PIM library collection an implementation of @code{M2RTS} and @code{SYSTEM} exist; likewise in the ISO library and ULM library collection these modules also exist. The @code{M2RTS} module contains many of the base runtime features required by the GNU Modula-2 compiler. For example @code{M2RTS} contains the all the low level exception handling routines. These include exception handlers for run time range checks for: assignments, increments, decrements, static array access, dynamic array access, for loop begin, for loop to, for loop increment, pointer via nil, function without return, case value not specified and no exception. The @code{M2RTS} module also contains the @code{HALT} and @code{LENGTH} procedure. The ISO @code{SYSTEM} module contains a number of @code{SHIFT} and @code{ROTATE} procedures which GNU Modula-2 will call when wishing to shift and rotate multi-word set types. @subsection Exception handling This section describes how exception handling is implemented in GNU Modula-2. We begin by including a simple Modula-2 program which uses exception handling and provide the same program written in C++. The compiler will translate the Modula-2 into the equivalent trees, just like the C++ frontend. This ensures that the Modula-2 frontend will not do anything that the middle and backend cannot process, which ensures that migration through the later gcc releases will be smooth. Here is an example of Modula-2 using exception handling: @example MODULE except ; FROM libc IMPORT printf ; FROM Storage IMPORT ALLOCATE, DEALLOCATE ; PROCEDURE fly ; BEGIN printf("fly main body\n") ; IF 4 DIV ip^ = 4 THEN printf("yes it worked\n") ELSE printf("no it failed\n") END END fly ; PROCEDURE tryFlying ; BEGIN printf("tryFlying main body\n"); fly ; EXCEPT printf("inside tryFlying exception routine\n") ; IF (ip#NIL) AND (ip^=0) THEN ip^ := 1 ; RETRY END END tryFlying ; PROCEDURE keepFlying ; BEGIN printf("keepFlying main body\n") ; tryFlying ; EXCEPT printf("inside keepFlying exception routine\n") ; IF ip=NIL THEN NEW(ip) ; ip^ := 0 ; RETRY END END keepFlying ; VAR ip: POINTER TO INTEGER ; BEGIN ip := NIL ; keepFlying ; printf("all done\n") END except. @end example Now the same program implemented in GNU C++ @example #include #include // a c++ example of Modula-2 exception handling static int *ip = NULL; void fly (void) @{ printf("fly main body\n") ; if (ip == NULL) throw; if (*ip == 0) throw; if (4 / (*ip) == 4) printf("yes it worked\n"); else printf("no it failed\n"); @} /* * a C++ version of the Modula-2 example given in the ISO standard. */ void tryFlying (void) @{ again_tryFlying: printf("tryFlying main body\n"); try @{ fly() ; @} catch (...) @{ printf("inside tryFlying exception routine\n") ; if ((ip != NULL) && ((*ip) == 0)) @{ *ip = 1; // retry goto again_tryFlying; @} printf("did't handle exception here so we will call the next exception routine\n") ; throw; // unhandled therefore call previous exception handler @} @} void keepFlying (void) @{ again_keepFlying: printf("keepFlying main body\n") ; try @{ tryFlying(); @} catch (...) @{ printf("inside keepFlying exception routine\n"); if (ip == NULL) @{ ip = (int *)malloc(sizeof(int)); *ip = 0; goto again_keepFlying; @} throw; // unhandled therefore call previous exception handler @} @} main () @{ keepFlying(); printf("all done\n"); @} @end example The equivalent program in GNU C is given below. However the use of @code{setjmp} and @code{longjmp} in creating an exception handler mechanism is not used used by GNU C++ and GNU Java. The GNU exception handling ABI uses @code{TRY_CATCH_EXPR} tree nodes. Thus GNU Modula-2 generates trees which model the C++ code above, rather than the C code shown below. The code here serves as a mental model (for readers who are familiar with C but not of C++) of what is happening in the C++ code above. @example #include #include #include typedef enum jmpstatus @{ jmp_normal, jmp_retry, jmp_exception, @} jmp_status; struct setjmp_stack @{ jmp_buf env; struct setjmp_stack *next; @} *head = NULL; void pushsetjmp (void) @{ struct setjmp_stack *p = (struct setjmp_stack *) malloc (sizeof (struct setjmp_stack)); p->next = head; head = p; @} void exception (void) @{ printf("invoking exception handler\n"); longjmp (head->env, jmp_exception); @} void retry (void) @{ printf("retry\n"); longjmp (head->env, jmp_retry); @} void popsetjmp (void) @{ struct setjmp_stack *p = head; head = head->next; free (p); @} static int *ip = NULL; void fly (void) @{ printf("fly main body\n"); if (ip == NULL) @{ printf("ip == NULL\n"); exception(); @} if ((*ip) == 0) @{ printf("*ip == 0\n"); exception(); @} if ((4 / (*ip)) == 4) printf("yes it worked\n"); else printf("no it failed\n"); @} void tryFlying (void) @{ void tryFlying_m2_exception () @{ printf("inside tryFlying exception routine\n"); if ((ip != NULL) && ((*ip) == 0)) @{ (*ip) = 1; retry(); @} @} int t; pushsetjmp (); do @{ t = setjmp (head->env); @} while (t == jmp_retry); if (t == jmp_exception) @{ /* exception called */ tryFlying_m2_exception (); /* exception has not been handled, invoke previous handler */ printf("exception not handled here\n"); popsetjmp(); exception(); @} printf("tryFlying main body\n"); fly(); popsetjmp(); @} void keepFlying (void) @{ void keepFlying_m2_exception () @{ printf("inside keepFlying exception routine\n"); if (ip == NULL) @{ ip = (int *)malloc (sizeof (int)); *ip = 0; retry(); @} @} int t; pushsetjmp (); do @{ t = setjmp (head->env); @} while (t == jmp_retry); if (t == jmp_exception) @{ /* exception called */ keepFlying_m2_exception (); /* exception has not been handled, invoke previous handler */ popsetjmp(); exception(); @} printf("keepFlying main body\n"); tryFlying(); popsetjmp(); @} main () @{ keepFlying(); printf("all done\n"); @} @end example @node Scope rules, Done list, Run time, Internals @section Scope rules This section describes my understanding of the Modula-2 scope rules with respect to enumerated types. If they are incorrect please correct me by email @email{gaius@@gnu.org}. They also serve to document the behaviour of GNU Modula-2 in these cirumstances. In GNU Modula-2 the syntax for a type declaration is defined as: @example TypeDeclaration := Ident "=" Type =: Type := SimpleType | ArrayType | RecordType | SetType | PointerType | ProcedureType =: SimpleType := Qualident | Enumeration | SubrangeType =: @end example If the @code{TypeDeclaration} rule is satisfied by @code{SimpleType} and @code{Qualident} ie: @example TYPE foo = bar ; @end example then @code{foo} is said to be equivalent to @code{bar}. Thus variables, parameters and record fields declared with either type will be compatible with each other. If, however, the @code{TypeDeclaration} rule is satisfied by any alternative clause @code{ArrayType}, @code{RecordType}, @code{SetType}, @code{PointerType}, @code{ProcedureType}, @code{Enumeration} or @code{SubrangeType} then in these cases a new type is created which is distinct from all other types. It will be incompatible with all other user defined types. It also has furthur consequences in that if bar was defined as an enumerated type and foo is imported by another module then the enumerated values are also visible in this module. Consider the following modules: @example DEFINITION MODULE impc ; TYPE C = (red, blue, green) ; END impc. @end example @example DEFINITION MODULE impb ; IMPORT impc ; TYPE C = impc.C ; END impb. @end example @example MODULE impa ; FROM impb IMPORT C ; VAR a: C ; BEGIN a := red END impa. @end example Here we see that the type @code{C} defined in module @code{impb} is equivalent to the type @code{C} in module @code{impc}. Module @code{impa} imports the type @code{C} from module @code{impb} and at that point the enumeration values @code{red, blue, green} (declared in module @code{impc}) are also visible. The ISO Standand (p.41) in section 6.1.8 Import Lists states: ``Following the module heading, a module may have a sequence of import lists. An import list includes a list of the identifiers that are to be explicitly imported into the module. Explicit import of an enumeration type identifier implicitly imports the enumeration constant identifiers of the enumeration type. Imported identifiers are introduced into the module, thus extending their scope, but they have a defining occurrence that appears elsewhere. Every kind of module may include a sequence of import lists, whether it is a program module, a definition module, an implementation module or a local module. In the case of any other kind of module, the imported identifiers may be used in the block of the module.'' These statements confirm that the previous example is legal. But it prompts the question, what about implicit imports othersise known as qualified references. In section 6.10 Implicit Import and Export of the ISO Modula-2 standard it says: ``The set of identifiers that is imported or exported if an identifier is explicitly imported or exported is called the (import and export) closure of that identifier. Normally, the closure includes only the explicitly imported or exported identifier. However, in the case of the explicit import or export of an identifier of an enumeration type, the closure also includes the identifiers of the values of that type. Implicit export applies to the identifiers that are exported (qualified) from separate modules, by virtue of their being the subject of a definition module, as well as to export from a local module that uses an export list.'' Clearly this means that the following is legal: @example MODULE impd ; IMPORT impc ; VAR a: impc.C ; BEGIN a := impc.red END impd. @end example It also means that the following code is legal: @example MODULE impe ; IMPORT impb ; VAR a: impb.C ; BEGIN a := impb.red END impe. @end example And also this code is legal: @example MODULE impf ; FROM impb IMPORT C ; VAR a: C ; BEGIN a := red END impf. @end example And also that this code is legal: @example DEFINITION MODULE impg ; IMPORT impc; TYPE C = impc.C ; END impg. @end example @example IMPLEMENTATION MODULE impg ; VAR t: C ; BEGIN t := red END impg. @end example Furthermore the following code is also legal as the new type, @code{C} is declared and exported. Once exported all its enumerated fields are also exported. @example DEFINITION MODULE imph; IMPORT impc; TYPE C = impc.C; END imph. @end example Here we see that the current scope is populated with the enumeration fields @code{red, blue, green} and also it is possible to reference these values via a qualified identifier. @example IMPLEMENTATION MODULE imph; IMPORT impc; VAR a: C ; b: impc.C ; BEGIN a := impc.red ; b := red ; a := b ; b := a END imph. @end example @node Done list, To do list, Scope rules, Internals @section Done list What has been done: @itemize @bullet @item Coroutines have been implemented. The @code{SYSTEM} module in PIM-[234] now includes @code{TRANSFER}, @code{IOTRANSFER} and @code{NEWPROCESS}. This module is available in the directory @file{gm2/gm2-libs-coroutines}. Users of this module also have to link with GNU Pthreads @code{-lpth}. @item GM2 now works on the @code{opteron} 64 bit architecture. @code{make gm2.paranoid} and @code{make check-gm2} pass. @item GM2 can now be built as a cross compiler to the MinGW platform under GNU/Linux i386. @item GM2 now works on the @code{sparc} architecture. @code{make gm2.paranoid} and @code{make check-gm2} pass. @item converted the regression test suite into the GNU dejagnu format. In turn this can be grafted onto the GCC testsuite and can be invoked as @code{make check-gm2}. GM2 should now pass all regression tests. @item provided access to a few compiler built-in constants and twenty seven built-in C functions. @item definition modules no longer have to @code{EXPORT QUALIFIED} objects (as per PIM-3, PIM-4 and ISO). @item implemented ISO Modula-2 sets. Large sets are now allowed, no limits imposed. The comparison operators @code{# = <= >= < >} all behave as per ISO standard. The obvious use for large sets is @code{SET OF CHAR}. These work well with gdb once it has been patched to understand Modula-2 sets. @item added @code{DEFINITION MODULE FOR "C"} method of linking to C. Also added varargs handling in C definition modules. @item cpp can be run on definition and implementation modules. @item @samp{-fmakell} generates a temporary @code{Makefile} and will build all dependant modules. @item compiler will bootstrap itself and three generations of the compiler all produce the same code. @item the back end will generate code and assembly declarations for modules containing global variables of all types. Procedure prologue/epilogue is created. @item all loop constructs, if then else, case statements and expressions. @item nested module initialization. @item pointers, arrays, procedure calls, nested procedures. @item front end @samp{gm2} can now compile and link modules. @item the ability to insert gnu asm statements within GNU Modula-2. @item inbuilt functions, @code{SIZE}, @code{ADR}, @code{TSIZE}, @code{HIGH} etc @item block becomes and complex procedure parameters (unbounded arrays, strings). @item the front end now utilizes GCC tree constants and types and is no longer tied to a 32 bit architecture, but reflects the 'configure' target machine description. @item fixed all C compiler warnings when gcc compiles the p2c generated C with -Wall. @item built a new parser which implements error recovery. @item added mechanism to invoke cpp to support conditional compilation if required. @item all @samp{Makefile}s are generated via @samp{./configure} @end itemize @node To do list, , Done list, Internals @section To do list What needs to be done: @itemize @bullet @item ISO library implementation needs to be completed and debugged. @item Easy access to other libraries using @code{-flibs=} so that libraries can be added into the @file{/usr/.../gcc-lib/gm2/...} structure. @item improve documentation, specifically this document which should also include a synopsis of 2nd Edition Modula-2. @item modifying @file{SymbolTable.mod} to make all the data structures dynamic. @item testing and fixing bugs @end itemize