What is flat assembler g? It is an assembly engine designed as a successor of the one used in flat assembler 1, one of the recognized assemblers for x86 processors. This is a bare engine that by itself has no ability to recognize and encode instructions of any processor, however it has the ability to become an assembler for any CPU architecture. It has a macroinstruction language that is substantially improved compared to the one provided by flat assembler 1 and it allows to easily implement instruction encoders in form of customizable macroinstructions. The source code of this tool can be compiled with flat assembler 1, but it is also possible to use flat assembler g itself to compile it. The source contains clauses that include different header files depending on the assembler used. When flat assembler g compiles itself, it uses the provided set of headers that implement x86 instructions and formats with a syntax mostly compatible with flat assembler 1. The example programs for x86 architecture that come in this package are the selected samples that originally came with flat assembler 1 and they use sets of headers that implement instruction encoders and output formatters required to assemble them just like the original flat assembler did. To demonstrate how the instruction sets of different architectures may be implemented, there are some example programs for the microcontrollers, 8051 and AVR. They have been kept simple and therefore they do not provide a complete framework for programming such CPUs, though they may provide a solid base for the creation of such environments. There is also an example of assembling the JVM bytecode, which is a conversion of the sample originally created for flat assembler 1. For this reason it is somewhat crude and does not fully utilize the capabilities offered by the new engine. However it is good at visualising the structure of a class file. How does this work? The essential function of flat assembler g is to generate output defined by the instructions in the source code. Given the one line of text as shown below, the assembler would generate a single byte with the stated value: db 90h The macroinstructions can be defined to generate some specific sequences of data depending on the provided parameters. They may correspond to the instructions of chosen machine language, as in the following example, but they could as well be defined to generate other kinds of data, for various purposes. macro int number if number = 3 db 0CCh else db 0CDh, number end if end macro int 20h ; generates two bytes The assembly as seen this way may be considered a kind of interpreted language, and the assembler certainly has many characteristics of the interpreter. However it also shares certain aspects with a compiler. It is possible for an instruction to use the value which is defined later in the source and may depend on the instructions that come before that definition, as demonstrated by the following sample. macro jmpi target if target-($+2) < 80h & target-($+2) >= -80h db 0EBh db target-($+1) else db 0E9h dw target-($+2) end if end macro jmpi start db 'some data' start: The "jmpi" defined above produces the code of jump instruction as in 8086 architecture. Such code contains the relative offset of the target of a jump, stored in either single byte or 16-bit word. The relative offset is computed as a difference between the address of the target and the address of the next instruction. The special symbol "$" provides the address of current instruction and it is used to calculate the relative offset and determine whether it may fit in a single byte. Therefore the code generated by "jmpi start" in the above sample depends on the value of an address labeled as "start", and this in turn depends on the length of the output of all the instructions that precede it, including the said jump. This creates a loop of dependencies and the assembler needs to find a solution that fulfills all the constraints created by the source text. This would not be possible if assembler was just an imperative interpreter. Its language is thus in some aspects declarative. Finding a solution for such circular dependencies may resemble solving an equation, and it is even possible to construct an example where flat assembler g is indeed capable of solving one: x = (x-1)*(x+2)/2-2*(x+1) db x The circular reference has been reduced here to a single definition that references itself to construct the value. The flat assembler g is able to find a solution in this case, though in many others it may fail. The method used by this assembler is to perform multiple passes over the source text and then try to predict all the values with the knowledge gathered this way. This approach is in most cases good enough for the assembly of machine codes, but rarely suffices to solve the complex equations and the above sample is one of the exceptions. What are the means of parsing the arguments of an instruction? Not all instructions have a simple syntax like then ones in the previous examples. To aid in the processing of arguments that may contain special constructions, flat assembler g provides a few capable tools, demonstrated below on the examples that implement selected few instructions of the Z80 processor. The rules governing the use of presented features are found in the manual. When an instruction has a very small set of allowed arguments, each one of them can be treated separately with the "match" construction: macro EX? first,second match (=SP?), first match =HL?, second db 0E3h else match =IX?, second db 0DDh,0E3h else match =IY?, second db 0FDh,0E3h else err "incorrect second argument" end match else match =AF?, first match =AF'?, second db 08h else err "incorrect second argument" end match else match =DE?, first match =HL?, second db 0EBh else err "incorrect second argument" end match else err "incorrect first argument" end match end macro EX (SP),HL EX (SP),IX EX AF,AF' EX DE,HL The "?" character appears in many places to mark the names as case-insensitive and all these occurrences could be removed to further simplify the example. When the set of possible values of an argument is larger but has some regularities, the textual substitutions can be defined to replace some of the symbols with carefully chosen constructions that can then be recognized and parsed: A? equ [:111b:] B? equ [:000b:] C? equ [:001b:] D? equ [:010b:] E? equ [:011b:] H? equ [:100b:] L? equ [:101b:] macro INC? argument match [:r:], argument db 100b + r shl 3 else match (=HL?), argument db 34h else match (=IX?+d), argument db 0DDh,34h,d else match (=IY?+d), argument db 0FDh,34h,d else err "incorrect argument" end match end macro INC A INC B INC (HL) INC (IX+2) This approach has a trait that may not always be desirable: it allows to use an expression like "[:0:]" directly in an argument. But it is possible to prevent exploiting the syntax in such way by using a prefix in the "match" construction: REG.A? equ [:111b:] REG.B? equ [:000b:] REG.C? equ [:001b:] REG.D? equ [:010b:] REG.E? equ [:011b:] REG.H? equ [:100b:] REG.L? equ [:101b:] macro INC? argument match [:r:], REG.argument db 100b + r shl 3 else match (=HL?), argument db 34h else match (=IX?+d), argument db 0DDh,34h,d else match (=IY?+d), argument db 0FDh,34h,d else err "incorrect argument" end match end macro In case of an argument structured like "(IX+d)" it could sometimes be desired to allow other algebraically equivalent forms of the expression, like "(d+IX)" or "(c+IX+d)". Instead of parsing every possible variant individually, it is possible to let the assembler evaluate the expression while treating the selected symbol in a distinct way. When a symbol is declared as an "element", it has no value and when it is used in an expression, it is treated algebraically like a variable term in a polynomial. element HL? element IX? element IY? macro INC? argument match [:r:], REG.argument db 100b + r shl 3 else match (a), argument if a eq HL db 34h else if a relativeto IX db 0DDh,34h,a-IX else if a relativeto IY db 0FDh,34h,a-IY else err "incorrect argument" end if else err "incorrect argument" end match end macro INC (3*8+IX+1) virtual at IX x db ? y db ? end virtual INC (y) There is a small problem with the above macroinstruction. A parameter may contain any text and when such value is placed into an expression, it may induce erratic behavior. For example if "INC (1|0)" was processed, it would turn the "a eq HL" expression into "1|0 eq HL" and this logical expression is correct and true even though the argument was malformed. Such unfortunate side-effect is a consequence of macroinstructions operating on a simple principle of text substitution (and the best way to avoid such problems is to use CALM instead). Here, to prevent it from happening, a local variable may be used as a proxy holding the value of an argument: macro INC? argument match [:r:], REG.argument db 100b + r shl 3 else match (a), argument local value value = a if value eq HL db 34h else if value relativeto IX db 0DDh,34h,a-IX else if value relativeto IY db 0FDh,34h,a-IY else err "incorrect argument" end if else err "incorrect argument" end match end macro There is an additional advantage of such proxy variable, thanks to the fact that its value is computed before the macroinstruction begins to generate any output. When an expression contains a symbol like "$", it may give different values depending where it is calculated and the use of proxy variable ensures that the value taken is the one obtained by evaluating the argument before generating the code of an instruction. When the set of symbols allowed in expressions is larger, it is better to have a single construction to process an entire family of them. An "element" declaration may associate an additional value with a symbol and this information can then be retrieved with the "metadata" operator applied to a linear polynomial that contains given symbol as a variable. The following example is another variant of the previous macroinstruction that demonstrates the use of this feature: element register element A? : register + 111b element B? : register + 000b element C? : register + 001b element D? : register + 010b element E? : register + 011b element H? : register + 100b element L? : register + 101b element HL? element IX? element IY? macro INC? argument local value match (a), argument value = a if value eq HL db 34h else if value relativeto IX db 0DDh,34h,a-IX else if value relativeto IY db 0FDh,34h,a-IY else err "incorrect argument" end if else match any more, argument err "incorrect argument" else value = argument if value eq value element 1 & value metadata 1 relativeto register db 100b + (value metadata 1 - register) shl 3 else err "incorrect argument" end if end match end macro The "any more" pattern is there to catch any argument that contains a complex expressions consisting of more than one token. This prevents the use of syntax like "INC A+0" or "INC A+B-A". But in case of some of the instructions sets, the inclusion of such constraint may depend on a personal preference. The "value eq value element 1" condition ensures that the value does not contain any terms other than the name of a register. Even when an argument is forced to contain no more than a single token, it is still possible that is has a complex value, for instance if there were definitions like "X = A + B" or "Y = 2 * A". Both "INC X" and "INC Y" would then cause the operator "element 1" to return the value "A", which differs from the value checked in either case. If an instruction takes a variable number of arguments, a simple way to recognize its various forms is to declare an argument with "&" modifier to pass the complete contents of the arguments to "match": element CC NZ? := CC + 000b Z? := CC + 001b NC? := CC + 010b C? := CC + 011b PO := CC + 100b PE := CC + 101b P := CC + 110b M := CC + 111b macro CALL? arguments& local cc,nn match condition =, target, arguments cc = condition - CC nn = target db 0C4h + cc shl 3 else nn = arguments db 0CDh end match dw nn end macro CALL 0 CALL NC,2135h This approach also allows to handle other, more difficult cases, like when the arguments may contain commas or are delimited in different ways. How are the labels processed? A standard way of defining a label is by following its name with ":" (this also acts like a line break and any other command, including another label, may follow in the same line). Such label simply defines a symbol with the value equal to the current address, which initially is zero and increases when any bytes are added into the output. In some variants of assembly language it may be desirable to allow label to precede an instruction without an additional ":" inbetween. It is then necessary to create a labeled macroinstruction that after defining a label passes processing to the original macroinstruction with the same name: struc INC? argument .: INC argument end struc start INC A INC B This has to be done for every instruction that needs to allow this kind of syntax. A simple loop like the following one would suffice: iterate instruction, EX,INC,CALL struc instruction? argument .: instruction argument end struc end iterate Every built-in instruction that defines data already has the labeled variant. By defining a labeled instruction that has "?" in place of name it is possible to intercept every line that starts with an identifier that is not a known instruction and is therefore assumed to be a label. The following one would allow a label without ":" to begin any line in the source text (it also handles the special cases so that labels followed with ":" or with "=" and a value would still work): struc ? tail& match :, tail .: else match : instruction, tail .: instruction else match == value, tail . = value else .: tail end match end struc Obviously, it is no longer needed to define any specific labeled macrointructions when a global effect of this kind is applied. A variant should be chosen depending on the type of syntax that needs to be allowed. Intercepting even the labels defined with ":" may become useful when the value of current address requires some additional processing before being assigned to a label - for example when a processor uses addresses with a unit larger than a byte. The intercepting macroinstruction might then look like this: struc ? tail& match :, tail label . at $ shr 1 else match : instruction, tail label . at $ shr 1 instruction else . tail end match end struc The value of current address that is used to define labels may be altered with "org". If the labels need to be differentiated from absolute values, a symbol defined with "element" may be used to form an address: element CODEBASE org CODEBASE + 0 macro CALL? argument local value value = argument if value relativeto CODEBASE db 0CDh dw value - CODEBASE else err "incorrect argument" end if end macro To define labels in an address space that is not going to be reflected in the output, a "virtual" block should be declared. The following sample prepares macroinstructions "DATA" and "CODE" to switch between generating program instructions and data labels. Only the instruction codes would go to the output: element DATA DATA_OFFSET = 2000h element CODE CODE_OFFSET = 1000h macro DATA? _END virtual at DATA + DATA_OFFSET end macro macro CODE? _END org CODE + CODE_OFFSET end macro macro _END? if $ relativeto DATA DATA_OFFSET = $ - DATA end virtual else if $ relativeto CODE CODE_OFFSET = $ - CODE end if end macro postpone _END end postpone CODE The "postpone" block is used here to ensure that the "virtual" block always gets closed correctly, even if source text ends with data definitions. Within the environment prepared by the above sample any instruction would be able to distinguish data labels from the ones defined within program. For example a branching instruction could be made to accept an argument being either a label within a program or an absolute value, but to disallow any label of data: macro CALL? argument local value value = argument if value relativeto CODE db 0CDh dw value - CODE else if value relativeto 0 db 0CDh dw value else err "incorrect argument" end if end macro DATA variable db ? CODE routine: In this context either "CALL routine" or "CALL 1000h" would be allowed, while "CALL variable" would not be. When the labels have values that are not absolute numbers, it is possible to generate relocations for instructions that use them. A special "virtual" block may be used to store the offsets of values inside the program that need to be relocated when its base changes: virtual at 0 Relocations:: rw RELOCATION_COUNT end virtual RELOCATION_INDEX = 0 postpone RELOCATION_COUNT := RELOCATION_INDEX end postpone macro WORD? value if value relativeto CODE store $ - CODE : 2 at Relocations : RELOCATION_INDEX shl 1 RELOCATION_INDEX = RELOCATION_INDEX + 1 dw value - CODE else dw value end if end macro macro CALL? argument local value value = argument if value relativeto CODE | value relativeto 0 db 0CDh word value else err "incorrect argument" end if end macro The table of relocations that is created this way can then be accessed with "load". The following two lines could be used to put the table in its entirety somewhere in the output: load RELOCATIONS : RELOCATION_COUNT shl 1 from Relocations : 0 dw RELOCATIONS The "load" reads the whole table into a single string, then "dw" writes it into output (padded to multiple of a word, but in this case the string never requires such padding). For more complex types of relocations additional modifier may need to be employed. For example, if upper and lower portions of an address needed to be stored in separate places (likely across two instructions) and relocated separately, necessary modifiers could be implemented as follows: element MOD.HIGH element MOD.LOW HIGH? equ MOD.HIGH + LOW? equ MOD.LOW + macro BYTE? value if value relativeto MOD.HIGH + CODE ; register HIGH relocation db (value - MOD.HIGH - CODE) shr 8 else if value relativeto MOD.LOW + CODE ; register LOW relocation db (value - MOD.LOW - CODE) and 0FFh else if value relativeto MOD.HIGH db (value - MOD.HIGH) shr 8 else if value relativeto MOD.LOW db (value - MOD.LOW) and 0FFh else db value end if end macro The commands that would register relocation have been omitted for clarity, in this case not only offset within code but some additional information would need to registered in appropriate structures. With such preparation, relocatable units in code might be generated like: BYTE HIGH address BYTE LOW address Such approach allows to easily enable syntax with modifiers in any instruction that internally uses "byte" macroinstruction when generating code. How can multiple sections of file be generated in parallel? This assembly engine has a single main output that has to be generated sequentially. This may seem problematic when the file needs to contains distinct sections for code and data, collected from interleaved pieces that may be spread across multiple source files. There are, however, a couple of methods to handle it, all based in one way or another on forward-referencing capabilities of the assembler. A natural approach is to define contents of auxiliary section in "virtual" block and copy it to appropriate position in the output with a single operation. When a "virtual" block is labeled, it can be re-opened multiple times to append more data to it. include '8086.inc' org 100h jmp CodeSection DataSection: virtual Data:: end virtual postpone virtual Data load Data.OctetString : $ - $$ from $$ end virtual end postpone db Data.OctetString CodeSection: virtual Data Hello db "Hello!",24h end virtual mov ah,9 mov dx,Hello int 21h virtual Data ExitCode db 37h end virtual mov ah,4Ch mov al,[ExitCode] int 21h This leads to a relatively simple syntax even without help of additional macros. Another method could be to put the pieces of the section into macros and execute them all at the required position in source. A disadvantage of such approach is that tracing errors in definitions might become a bit cumbersome. The techniques that allow to easily append to a section generated in parallel can also be very useful to generate data structures like relocation tables. Instead of "store" commands used earlier when demonstrating the concept, regular data directives could be used inside a re-opened "virtual" block to create relocation records. What options are there to parse other kinds of syntax? In some cases a command that assembler needs to parse may begin with something different than a name of instruction or a label. It may be that a name is preceded by a special character, like "." or "!", or that it is an entirely different kind of construction. It is then necessary to use "macro ?" to intercept whole lines of source text and process any special syntax of such kind. For example, if it was required to allow a command written as ".CODE", it would not be possible to implement it directly as a macroinstruction, because initial dot causes the symbol to be interpreted as a local one and globally defined instruction could never be executed this way. The intercepting macroinstruction provides a solution: macro ? line& match .=CODE?, line CODE else match .=DATA?, line DATA else line end match end macro The lines that contain either ".CODE" or ".DATA" text are processed here in such a way, that they invoke the global macroinstruction with corresponding name, while all other intercepted lines are executed without changes. This method allows to filter out any special syntax and let the assembler process the regular instructions as usual. Sometimes unconventional syntax is expected only in a specific area of source text, like inside a block with defined boundaries. The parsing macroinstruction should then be applied only in this place, and removed with "purge" when the block ends: macro concise macro ? line& match =end =concise, line purge ? else match dest+==src, line ADD dest,src else match dest-==src, line SUB dest,src else match dest==src, line LD dest,src else match dest++, line INC dest else match dest--, line DEC dest else match any, line err "syntax error" end match end macro end macro concise C=0 B++ A+=2 end concise A macroinstruction defined this way does not intercept lines that contain directives controlling the flow of the assembly, like "if" or "repeat", and they can still be used freely inside such a block. This would change if the declaration was in the form "macro ?! line&". Such a variant would intercept every line with no exception. Another option to catch special commands might be to use "struc ?" to intercept only lines that do not start with a known instruction (the initial symbol is then treated as label). Since this one only tests unknown commands, it should cause less overhead on the assembly: struc (head) ? tail& match .=CODE?, head CODE tail else head tail end match end struc All these approaches hide a subtle trap. A label defined with ":" may be followed by another instruction in the same line. If that next instruction (which here becomes hidden in the "tail" parameter) is a control directive like "if", putting it inside the "else" clause is going to cause broken nesting of control blocks. A possible solution is to somehow invoke "tail" contents outside of "match" block. One way could be to call a special macro: struc (head) ? tail& local invoker match .=CODE?, head macro invoker CODE tail end macro else macro invoker head tail end macro end match invoker end struc A simpler option is to call the original line directly and when override is needed, cause it to be ignored with help of another line interceptor (disposing of itself immediately after): struc (head) ? tail& match .=CODE?, head CODE tail macro ? line& purge ? end macro end match head tail end struc However, a much better way of avoiding this kinds of pitfalls is to use CALM instructions instead of standard macros. There it is possible to process arguments and assemble the original or modified line without use of any control directives. CALM instructions also offer a much better performance, which might be especially important in case of interceptors that get called for nearly every line in source text. How to define an instruction sharing a name with one of the core directives? It may happen that a language can be in general easily implemented with macros, but it needs to include a command with the same name as one of the directives of assembler. While it is possible to override any instruction with a macro, macros themself may require an access to the original directive. To allow the same name call a different instruction depending on the context, the implemented language may be interpreted within a namespace that contains overriding macro, while all the macros requiring access to original directive would have to temporarily switch to another namespace where it has not have been overridden. This would require every such macro to pack its contents in a "namespace" block. But there is another trick, related to how texts of macro parameters or symbolic variables preserve the context under which the symbols within them should be interpreted (this includes the base namespace and the parent label for symbols starting with dot). Unlike the two mentioned occurences, the text of a macro normally does not carry such extra information, but if a macro is constructed in such way that it contains text that was once carried within a parameter to another macro or within a symbolic variable, then this text retains the information about context even when it becomes a part of a newly defined macro. For example: macro definitions end? namespace embedded struc LABEL? size match , size .: else label . : size end match end struc macro E#ND? name end namespace match any, name ENTRYPOINT := name end match macro ?! line& end macro end macro end macro definitions end start LABEL END start The parameter given to "definitions" macro may appear to do nothing, as it replaces every instance of "end" with exactly the same word - but the text that comes from the parameter is equipped with additional information about context, and this attribute is then preserved when the text becomes a part of a new macro. Thanks to that, macro "LABEL" can be used in a namespace where "end" instruction has taken a different meaning, but the instances of "end" within its body still refer to the symbol in the outer namespace. In this example the parameter has been made case-insensitive, and thus it would replace even the "END" in "macro" statement that is supposed to define a symbol in "embedded" namespace. For this reason the identifier has been split with a concatenation operator to prevent it from being recognized as parameter. This would not be necessary if the parameter was case-sensitive (as more usual). The same effect can be achieved through use of symbolic variables instead of macro parameters, with help of "match" to extract the text of a symbolic variable: define link end match end, link namespace embedded struc LABEL? size match , size .: else label . : size end match end struc macro END? name end namespace match any, name ENTRYPOINT := name end match macro ?! line& end macro end macro end match start LABEL END start This would not work without passing the text through symbolic variable, because parameters defined by control directives like "match" do not add context information to the text unless it was already there. CALM instructions allow for another approach to this kind of problems. If a customized instruction set is defined entirely in form of CALM, they may not even need an access to original control directives. However, if CALM instruction needs to assemble a directive that might not be accessible, the symbolic variable passed to "assemble" should be defined with appropriate context for the instruction symbol. How to convert a macroinstruction to CALM? A classic macroinstruction consists of lines of text that are preprocessed (by replacing names of parameters with their corresponding values) every time the instruction is called and these preprocessed lines are passed to assembly. For example this macroinstruction generates just a single line to be assembled, and it does it by replacing "number" with the text given by the only argument to the instruction: macro octet value* db value end macro A CALM instruction can be viewed as customized preprocessor, which needs to be written in a special language. It is able to use various commands to process the arguments and generate lines to be assembled. On the basic level, it is also able to simulate what standard preprocessor does - with help of "arrange" command. After preprocessing the line, it also needs to explicitly pass it to the assembly with an "assemble" command: calminstruction octet value* arrange value, =db value assemble value end calminstruction This gives the same result as the original macroinstruction, as it performs the same kind of preprocessing. However, unlike the text of macroinstruction a pattern given to "arrange" needs to explicitly state which name tokens are to be replaced with their values and which ones (prepended with "=") should be left untouched. The tokens that are copied from the pattern are stripped of any context information, just like the text of macroinstruction is normally not carrying any (while the values that came from arguments retain the recognition context in which the instruction was started). This is the most straightforward method of conversion and a simple sequence of "arrange" and "assemble" commands could be made to generate the same lines as by the original macroinstruction. But there is one exception - when a "local" command is executed by macroinstruction, it creates a preprocessed parameter with a special value that points to a symbol in the namespace unique to given instance of the instruction. macro pointer local next dd next next: end macro In case of CALM there is no such namespace available, the local namespace of a CALM instruction is shared among all its instances. Therefore, if a new unique symbol is needed every time the instruction is called, it has to be constructed manually. An obvious method might be to append a unique number to the name: global_uid = 0 calminstruction pointer compute global_uid, global_uid + 1 local command arrange command, =dd =next#global_uid assemble command arrange command, =next#global_uid: assemble command end calminstruction Here "arrange" is given a variable that has a numeric value and it has to replace it with a text. This works only when the value is a plan non-negative number, in such case "arrange" converts it to a text token that contains decimal representation of that number. The lines passed to assembly are therefore going to contains identifiers like "next#1". While incrementation of the global counter could be done by preparing a standard assembly command like "global_uid = global_uid + 1" with "arrange" and passing it to assembly, "compute" command allows to do it directly in the CALM processor. Moreover, it is then not affected by anything that alters the context of assembly. If the instruction was defined as unconditional and used inside a skipped IF block, the "compute" would still perform its task, because execution of CALM commands is - just like standard preprocessing - done independently from the main flow of the assembly. Also, references to the "global_uid" always point to the same symbol - the one that was in scope when the CALM instruction was defined and compiled. Therefore incrementing the value with "compute" is more reliable and predictable. In a similar manner, the assembly of line defining the label can be replaced with a "publish" command. Here the value of the label (which should be equal to the address after the line containing "dd" is assembled) needs to be computed first, because "publish" only performs the assignment of a value to the symbol: global_uid = 0 calminstruction pointer compute global_uid, global_uid + 1 local symbol, command arrange symbol, =next#global_uid arrange command, =dd symbol assemble command local address compute address, $ publish symbol:, address end calminstruction Because the CALM instruction itself is conditional, the "publish" inside is effectively conditional, too. Therefore it works correctly as a replacement for the assembly of line with a label. While a global counter has several advantages, it can be interfered with, so sometimes use of a local counter might be preferable. However, the local namespace of CALM instruction is not normally not accessible from outside, so it is a bit harder to give an initial value to such counter. One way could be to check whether the counter has already been initialized with some value using "take" command: calminstruction pointer local id take id, id jyes increment compute id, 0 increment: compute id, id + 1 local symbol, command arrange symbol, =next#id arrange command, =dd symbol assemble command local address compute address, $ publish symbol:, address end calminstruction But this adds commands that are executed every time the instruction is called. A better solution makes use of the ability to define custom instructions processed during the definition of CALM instruction: calminstruction calminstruction?.init? var*, val:0 compute val, val publish var, val end calminstruction calminstruction pointer local id init id, 0 compute id, id + 1 local symbol, command arrange symbol, =next#id arrange command, =dd symbol assemble command local address compute address, $ publish symbol:, address end calminstruction The custom statement "init" is called at the time when the CALM instruction is defined (it does not generate any commands to be executed by the defined instruction - it would itself have to use "assemble" commands to generate statements to be compiled). It is given the name of variable from the local scope of the CALM instruction, and it uses "publish" to assign an initial numeric value to that variable. To initialize local variable with a symbolic value, even simpler custom instruction would suffice: calminstruction calminstruction?.initsym? var*, val& publish var, val end calminstruction The text of "val" argument carries the recognition context of the definition of CALM instruction that contains the "initsym" statement, therefore it allows to prepare a text for "assemble" containing references to local symbols: calminstruction be32? value local command initsym command, dd value compute value, value bswap 4 assemble command end calminstruction Again, after this intruction is compiled, it contains just two actual commands, "compute" and "assemble", and the value of local symbol "command" is a text that is interpreted in the same local context and refers to the same symbol "value" as the "compute" does. This example also demonstrates another advantage of CALM over standard macroinstructions: its strict semantics prevent various kinds of unwanted behavior that is allowed by a simple substitution of text. The text of "value" is going to be evaluated by "compute" as a numeric sub-expression, signalling an error on any unexpected syntax. Therefore it should be favorable to process arguments entirely through CALM commands and only use "assemble" for final simple statements.