$Id: dasm.txt 327 2014-02-09 13:06:55Z adavie $ DOCUMENTATION FOR DASM, a high level macro cross assembler for: -6502 (and 6507) -68705 -6803 -HD6303 (extension of 6803) -68HC11 ABSTRACT This file contains the main documentation for DASM. It explains how to use DASM and what the supported assembler directives are. DASM's homepage is http://dasm-dillon.sourceforge.net/ since release 2.20.11. LEGALESE the DASM macro assembler (aka small systems cross assembler) Copyright (c) 1988-2002 by Matthew Dillon. Copyright (c) 1995 by Olaf "Rhialto" Seibert. Copyright (c) 2003-2008 by Andrew Davie. Copyright (c) 2008 by Peter H. Froehlich. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. PREFACE FROM MATT: Over the last year my work has included writing software to drive small single-chip microcomputers for various things (remote telemetry units, for instance). I have had need to program quite a few different processors over that time. At the beginning, I used an awful macro assembler running on an IBM-PC. I *really* wanted to do it on my Amiga. Thus the writing of this program. Feel free to suggest other similar processors for me to add to the list! The processor type is specified with a pseudo-op (see below). This assembler produces only binary output in one of three formats described below. In general, one has a master assembly file which INCLUDEs all the modules. Also provided is FTOHEX which converts an output file in one of the three formats to an intel-hex format suitable for many intelligent prom programmers (I have a GTEK). YES it's packed with features! FEATURES: -fast assembly -supports several common 8 bit processor models (NOT 8086, thank god!) -takes as many passes as needed -automatic checksum generation, special symbol '...' -several binary output formats available. Format 2 allows reverse indexed origins. -multiple segments, BSS segments (no generation), relocatable origin. -expressions, as in C but [] is used instead of () for parenthesis. (all expressions are computed with 32 bit integers) -no real limitation on label size, label values are 32 bits. -complex pseudo ops, repeat loops, macros, etc.... PREFACE FROM ANDREW (APRIL/2003) The documentation is lagging a bit behind the modifications. Essentially the information contained herein is correct, but there have been minor changes to the formatting of output data. Please see the accompanying text files in the distribution's root directory for a list of recent changes to DASM. PREFACE FROM PETER (APRIL/2008) Everything Andrew says above is still true, there have been a few sporadic updates to the documentation but no major ones, not even Olaf Seibert's changes from 1995 have been integrated, to say nothing of Thomas Mathys' F8 backend from 2004. We are urgently looking for volunteers to help with the documentation! COMMAND LINE: dasm sourcefile [options] options: -f# output format 1-3 (default 1, see below) -oname output file name (else a.out) -lname list file name (else none generated) -Lname list file name, containing all passes -sname symbol dump file name (else none generated) -v# verboseness 0-4 (default 0, see below) -d debug mode (for developers) -Dsymbol define symbol, set to 0 -Dsymbol=expression define symbol, set to expression -Msymbol=expression define symbol using EQM (same as -D) -Idir search directory for include and incbin -p# maximum number of passes -P# maximum number of passes, with fewer checks -T# symbol table sorting (default 0 = alphabetical, 1 = address/value) -E# error format (default 0 = MS, 1 = Dillon, 2 = GNU) Example: dasm master.asm -f2 -oout -llist -v3 -DVER=4 Note: A slash (/) or dash (-) must prefix options. Return Value: The assembler will return 0 on successful compilation, 1 otherwise. FORMAT OPTIONS: 1 (DEFAULT) The output file contains a two byte origin in LSB,MSB order, then data until the end of the file. Restrictions: Any instructions which generate output (within an initialized segment) must do so with an ascending PC. Initialized segments must occur in ascending order. 2 RAS (Random Access Segment) The output file contains one or more hunks. Each hunk consists of a 2 byte origin (LSB,MSB), 2 byte length (LSB,MSB), and that number of data bytes. The hunks occur in the same order as initialized segments in the assembly. There are no restrictions to segment ordering (i.e. reverse indexed ORG statements are allowed). The next hunk begins after the previous hunk's data, until the end of the file. 3 RAW (Raw) The output file contains data only (format #1 without the 2 byte header). Restrictions are the same as for format #1. Format 3 RAW (Raw format) Same as format 1, but NO header origin is generated. You get nothing but data. VERBOSE OPTIONS: 0 (default) Only warnings and errors are generated 1 -Segment list information generated after each pass -Include file names are displayed -statistics on why the assembler is going to make another pass R1,R2 reason code: R3 where R1 is the number of times the assembler encountered something requiring another pass to resolve. R2 is the number of references to unknown symbols which occured in the pass (but only R1 determines the need for another pass). R3 is a BITMASK of the reasons why another pass is required. See the end of this document for bit designations. 2 mismatches between program labels and equates are displayed on every pass (usually none occur in the first pass unless you have re-declared a symbol name). displayed information for symbols: ???? = unknown value str = symbol is a string eqm = symbol is an eqm macro (r) = symbol has been referenced (s) = symbol created with SET or EQM pseudo-op 3 Unresolved and unreferenced symbols are displayed every pass (unsorted, sorry) 4 An entire symbol list is displayed every pass to STDOUT. (unsorted, sorry) PROCESSOR MODEL: The processor model is chosen with the PROCESSOR pseudo-op and should be the first thing you do in your assembly file. Different processor models use different integer formats (see below). The word order does not effect the headers in the output files (-f1 and -f2), which are always LSB,MSB. The word ordering effects all address, word, and long generation. Only one PROCESSOR pseudo-op may be declared in the entire assembly, and should be the first thing encountered. -6502 LSB,MSB -68HC11 MSB,LSB -68705 MSB,LSB -6803 MSB,LSB -HD6303 MSB,LSB -F8 ? SEGMENTS: The SEG pseudo-op creates/sets the current segment. Each segment has it's own origin and is optionally an 'uninitialized' segment. Unitialized segments produce no output and have no restrictions. This is useful for determining the size of a certain assembly sequence without generating code, and for assigning RAM to labels. 'Initialized' segments produce output. The following should be considered when generating roms: (1) The default fill character when using ORG (and format 1 or 3) to skip forward is 00. This is a GLOBAL default and effects all segments. See ORG. (2) The default fill character for DS is 00 and is independant of the default fill character for ORG (see DS). GENERAL: Most everything is recursive. You cannot have a macro DEFINITION within a macro definition, but can nest macro calls, repeat loops, and include files. The other major feature in this assembler is the SUBROUTINE pseudo-op, which logically separates local labels (starting with a dot). This allows you to reuse label names (for example, .1 .fail) rather than think up crazy combinations of the current subroutine to keep it all unique. Almost nothing need be resolved in pass 1. The assembler will make multiple passes in an attempt to resolve the assembly (including just one pass if everything is resolved immediately). PSEUDOPS: INCLUDE "name" Include another assembly file. #if OlafIncbin [label] INCBIN "name" Include another file literally in the output. #endif #if OlafIncdir INCDIR "directory name" Add the given directory name to the list of places where INCLUDE and INCBIN search their files. First, the names are tried relative to the current directory, if that fails and the name is not an absolute pathname, the list is tried. You can optionally end the name with a /. AmigaDOS filename conventions imply that two slashes at the end of an INCDIR (dir//) indicates the parent directory, and so does an INCLUDE /filename. The command-line option -Idir is equivalent to an INCDIR directive placed before the source file. Currently the list is not cleared between passes, but each exact directory name is added to the list only once. This may change in subsequent releases. #endif [label] SEG[.U] name This sets the current segment, creating it if neccessary. If a .U extension is specified on segment creation, the segment is an UNINITIALIZED segment. The .U is not needed when going back to an already created uninitialized segment, though it makes the code more readable. [label] DC[.BWL] exp,exp,exp ... Declare data in the current segment. No output is generated if within a .U segment. Note that the byte ordering for the selected processor is used for each entry. The default size extension is a byte. #if OlafByte BYTE, WORD and LONG are synonyms for DC.B, DC.W and DC.L. #endif [label] DS[.BWL] exp[,filler] declare space (default filler is 0). Data is not generated if within an uninitialized segment. Note that the number of bytes generated is exp * entrysize (1,2, or 4) The default size extension is a byte. Note that the default filler is always 0 (has nothing to do with the ORG default filler). [label] DV[.BWL] eqmlabel exp,exp,exp.... This is equivalent to DC, but each exp in the list is passed through the symbolic expression specified by the EQM label. The expression is held in a special symbol dotdot '..' on each call to the EQM label. See EQM below [label] HEX hh hh hh.. This sets down raw HEX data. Spaces are optional between bytes. NO EXPRESSIONS are allowed. Note that you do NOT place a $ in front of the digits. This is a short form for creating tables compactly. Data is always layed down on a byte-by-byte basis. Example: HEX 1A45 45 13254F 3E12 ERR Abort assembly. [label] ORG exp[,DefaultFillVal] This pseudop sets the current origin. You can also set the global default fill character (a byte value) with this pseudoop. NOTE that no filler is generated until the first data-generating opcode/psueoop is encountered after this one. Sequences like: org 0,255 org 100,0 org 200 dc 23 will result in 200 zero's and a 23. This allows you to specify some ORG, then change your mind and specify some other (lower address) ORG without causing an error (assuming nothing is generated inbetween). Normally, DS and ALIGN are used to generate specific filler values. [label] RORG exp This activates the relocatable origin. All generated addresses, including '.', although physically placed at the true origin, will use values from the relocatable origin. While in effect both the physical origin and relocatable origin are updated. The relocatable origin can skip around (no limitations). The relocatable origin is a function of the segment. That is, you can still SEG to another segment that does not have a relocatable origin activated, do other (independant) stuff there, and then switch back to the current segment and continue where you left off. PROCESSOR model do not quote. model is one of: 6502,6803,HD6303,68705,68HC11,F8 Can only be executed once, and should be the first thing encountered by the assembler. ECHO exp,exp,exp The expressions (which may also be strings), are echoed on the screen and into the list file. [label] REND Deactivate the relocatable origin for the current segment. Generation uses the real origin for reference. [label] ALIGN N[,fill] Align the current PC to an N byte boundry. The default fill character is always 0, and has nothing to do with the default fill character specifiable in an ORG. [label] SUBROUTINE name This isn't really a subroutine, but a boundry between sets of temporary labels (which begin with a dot). Temporary label names are unique within segments of code bounded by SUBROUTINE: CHARLIE subroutine ldx #10 .1 dex bne .1 BEN subroutine ldx #20 .qq dex bne .qq Automatic temporary label boundries occur for each macro level. Usually temporary labels are used in macros and within actual subroutines (so you don't have to think up a thousand different names) symbol EQU exp #if OlafAsgn symbol = exp #endif The expression is evaluated and the result assigned to the symbol. #if OlafDotAssign If this option is enabled, you can use the common idiom of . EQU . + 3 (or . = .+3) in other words, you can assign to "." (or "*" if OlafStar is also enabled) instead of an ORG or RORG directive. More formally, a directive of the form ". EQU expr" is interpreted as if it were written " (R)ORG expr". The RORG is used if a relocatable origin is already in effect, otherwise ORG is used. Note that the first example is NOT equivalent with "DS.B 3" when the rorg is in effect. #endif symbol EQM exp The STRING representing the expression is assigned to the symbol. Occurances of the label in later expressions causes the string to be evaluated for each occurance. Also used in conjuction with the DV psuedo-op. symbol SET exp Same as EQU, but the symbol may be reassigned later. MAC name Declare a macro. lines between MAC and ENDM are the macro. You cannot recursively declare a macro. You CAN recursively use a macro (reference a macro in a macro). No label is allowed to the left of MAC or ENDM. Arguments passed to macros are referenced with: {#}. The first argument passed to a macro would thus be {1}. You should always use LOCAL labels (.name) inside macros which you use more than once. {0} represents an EXACT substitution of the ENTIRE argument line. ENDM end of macro def. NO LABEL ALLOWED ON THE LEFT! MEXIT Used in conjuction with conditionals. Exits the current macro level. [label] IFCONST exp Is TRUE if the expression result is defined, FALSE otherwise and NO error is generated if the expression is undefined. [label] IFNCONST exp Is TRUE if the expression result is undefined, FALSE otherwise and NO error is generated if the expression is undefined. [label] IF exp Is TRUE if the expression result is defined AND non-zero. Is FALSE if the expression result is defined AND zero. Neither IF or ELSE will be executed if the expression result is undefined. If the expression is undefined, another assembly pass is automatically taken. #if OlafPhase If this happens, phase errors in the next pass only will not be reported unless the verboseness is 1 or more. #endif [label] ELSE ELSE the current IF. [label] ENDIF [label] EIF Terminate an IF. ENDIF and EIF are equivalent. [label] REPEAT exp [label] REPEND Repeat code between REPEAT/REPEND 'exp' times. #if DAD if exp == 0, the code repeats forever. exp is evaluated once. If exp == 0, the repeat loop is ignored. If exp < 0, a warning "REPEAT parameter < 0 (ignored)" is generated and the repeat loop is ignored. #endif Y SET 0 REPEAT 10 X SET 0 REPEAT 10 DC X,Y X SET X + 1 REPEND Y SET Y + 1 REPEND generates an output table: 0,0 1,0 2,0 ... 9,0 0,1 1,1 2,1 ... 9,1, etc... Labels within a REPEAT/REPEND should be temporary labels with a SUBROUTINE pseudo-op to keep them unique. The Label to the left of REPEND is assigned AFTER the loop FINISHES. [label] XXX[.force] operand XXX is some mnemonic, not necessarily three characters long. The .FORCE optional extension is used to force specific addressing modes (see below). [label] LIST ON or OFF Globally turns listing on or off, starting with the current line. #if OlafList When you give LOCALON or LOCALOFF the effect is local to the current macro or included file. For a line to be listed both the global and local list switches must be on. #endif #if OlafDotop All pseudo-ops (and incidentally also the mnemonics) can be prefixed with a . for compatibility with other assemblers. So .IF is the same as IF. This works only because lone .FORCE extensions are meaningless. #endif #if OlafFreeFormat The format of each input line is free: first all leading spaces are discarded, and the first word is examined. If it does not look like a directive or opcode (as known at that point), it is taken as a label. This is sort-of nasty if you like labels with names like END. The two xxxFormat options are mutually exclusive. #endif #if OlafHashFormat With this option an initial # (after optional initial spaces) turns the next word into a directive/opcode. A ^ skips more spaces and makes the next word a label. #endif GENERAL: The label will be set to the current ORG/RORG either before or after a pseudo-op is executed. Most of the time, the label to the left of a pseudo-op is the current ORG/RORG. The following pseudo-op's labels are created AFTER execution of the pseudo-op: SEG, ORG, RORG, REND, ALIGN EXTENSIONS: FORCE extensions are used to force an addressing mode. In some cases, you can optimize the assembly to take fewer passes by telling it the addressing mode. Force extensions are also used with DS,DC, and DV to determine the element size. NOT ALL EXTENSIONS APPLY TO ALL PROCESSORS! example: lda.z charlie i -implied ind -indirect word 0 -implied 0x -implied indexing (0,x) 0y -implied indexing (0,y) b -byte address bx -byte address indexed x by -byte address indexed y w -word address wx -word address indexed x wy -word address indexed y l -longword (4 bytes) (DS/DC/DV) r -relative u -uninitialized (SEG) First character equivalent substitutions: b z d (byte, zeropage, direct) w e a (word, extended, absolute) ASSEMBLER PASSES: The assembler may have to make several passes through the source code to resolve all generation. The number of passes is not limited to two. Since this may result in an unexpected, verbose option 2, 3, and 4 have been provided to allow determination of the cause. The assembler will give up if it thinks it can't do the assembly in *any* number of passes. Error reporting could be better.... #if OlafPasses The check if another pass might resolve the source is pretty good, but not perfect. You can specify the maximum number of passes to do (default -p10), and with the -P option you can override the normal check. This allows the following contrived example to resolve in 12 passes: org 1 repeat [[x < 11] ? [x-11]] + 11 dc.b x repend x: #endif EXPRESSIONS: [] may be used to group expressions. The precedense of operators is the same as for the C language in almost all respects. Use brackets [] when you are unsure. The reason () cannot be used to group expressions is due to a conflict with the 6502 and other assembly languages. #if OlafBraKet It is possible to use () instead of [] in expressions following pseudo-ops, but not following mnemonics. So this works: if target & (pet3001 | pet4001), but this doesn't: lda #target & (pet3001 | pet4001). #endif Some operators, such as ||, can return a resolved value even if one of the expressions is not resolved. Operators are as follows: NOTE WELL! Some operations will result in non-byte values when a byte value was wanted. For example: ~1 is NOT $FF, but $FFFFFFFF. Preceding it with a < (take LSB of) will solve the problem. ALL ARITHMETIC IS CARRIED OUT IN 32 BITS. The final Result will be automatically truncated to the maximum handleable by the particular machine language (usually a word) when applied to standard mnemonics. prec UNARY 20 ~exp one's complement. 20 -exp negation 20 !exp not expression (returns 0 if exp non-zero, 1 if exp zero) 20 exp take MSB byte of an expression BINARY 19 * multiplication 19 / division 19 % mod 18 + addition 18 - subtraction 17 >>,<< shift right, shift left 16 >,>= greater, greater equal 16 <,<= smaller, smaller equal 15 == equal to. Try to use this instead of = 15 = exactly the same as == (exists compatibility) 15 != not equal to 14 & logical and 13 ^ logical xor 12 | logical or 11 && left expression is true AND right expression is true 10 || left expression is true OR right expression is true 9 ? if left expression is true, result is right expression, else result is 0. [10 ? 20] returns 20 8 [] group expressions 7 , separate expressions in list (also used in addressing mode resolution, BE CAREFUL! Note: The effect of the C conditional operator a ? b : c can be had with [a ? b - c] + c. Constants: nnn decimal 0nnn octal %nnn binary $nnn hex 'c character "cc.." string (NOT zero terminated if in DC/DS/DV) [exp]d the constant expressions is evaluated and it's decimal result turned into an ascii string. Symbols: ... -holds CHECKSUM so far (of actual-generated stuff) .. -holds evaluated value in DV pseudo op .name -represents a temporary symbol name. Temporary symbols may be reused inside MACROS and between SUBROUTINES, but may not be referenced across macros or across SUBROUTINEs. . -current program counter (as of the beginning of the instruction). name -beginning with an alpha character and containing letters, numbers, or '_'. Represents some global symbol name. #if OlafStar * -synonym for ., when not confused as an operator. #endif #if OlafDol nnn$ -temporary label, much like .name, except that defining a non-temporary label has the effect that SUBROUTINE has on .name. They are unique within macros, like .name. Note that 0$ and 00$ are distinct, as are 8$ and 010$. (mainly for compatibility with other assemblers.) #endif WHY codes: Each bit in the WHY word (verbose option 1) is a reason (why the assembler needs to do another pass), as follows: bit 0 expression in mnemonic not resolved 1 - 2 expression in a DC not resolved 3 expression in a DV not resolved (probably in DV's EQM symbol) 4 expression in a DV not resolved (could be in DV's EQM symbol) 5 expression in a DS not resolved 6 expression in an ALIGN not resolved 7 ALIGN: Relocatable origin not known (if in RORG at the time) 8 ALIGN: Normal origin not known (if in ORG at the time) 9 EQU: expression not resolved 10 EQU: value mismatch from previous pass (phase error) 11 IF: expression not resolved 12 REPEAT: expression not resolved 13 a program label has been defined after it has been referenced (forward reference) and thus we need another pass 14 a program label's value is different from that of the previous pass (phase error) Certain errors will cause the assembly to abort immediately, others will wait until the current pass is other. The remaining allow another pass to occur in the hopes the error will fix itself. VERSIONS: V2.12 -Fixed macro naming bug (macros wouldn't work if the name after the 'mac' was in upper case). V2.11 -Fixed exp bug, exp MSB (it used to be reversed). -Fixed many bugs in macros and other things -Added automatic checksumming ... no more doing checksums manually! -Added several new processors, including 6502. -Source is now 16/32 bit int compatible, and will compile on an IBM-PC (the ultimate portability test) V2.01 -can now have REPEAT/REPEND's within macros -fill field for DS.W is a word (used to be a byte fill) -fill field for DS.L is a long (used to be a byte fill)