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/*
* (C) Copyright 2002, Brian Knittel.
* You may freely use this program, but: it offered strictly on an AS-IS, AT YOUR OWN
* RISK basis, there is no warranty of fitness for any purpose, and the rest of the
* usual yada-yada. Please keep this notice and the copyright in any distributions
* or modifications.
*
* This is not a supported product, but I welcome bug reports and fixes.
* Mail to sim@ibm1130.org
*/
#define VERSION "ASM1130 CROSS ASSEMBLER V1.14"
// ---------------------------------------------------------------------------------
// ASM1130 - IBM 1130 Cross Assembler
//
// Version
// 1.14 - 2004Oct22 - Fixed problem with BSS complaining about negative
// sizes. This may be a fundamental problem with my using
// 32-bit expressions, but for now, it appears that just
// truncating the BSS size to 16 bits is sufficient to build DMS.
// 1.13 - 2004Jun05 - Fixed sign extension of constants in expressions. Statements
// like LD /FFFF were being assembled incorrectly.
// 1.12 - 2004Jun04 - Made WAIT instruction take a displacement value.
// Doesn't affect operation, but these are used as indicators
// in the IBM one-card diagnostic programs.
// Also -- should mention that the .IPL directive was
// removed some time ago. To create bootable cards,
// use -b flag to create binary output, and post-process the
// binary output with program "mkboot"
// 1.11 - 2004May22 - Added CMP, DCM, and DECS instructions for 1800,
// thanks to Kevin Everets.
// 1.10 - 2003Dec08 - Fixed opcode value for XCH instruction, thanks to
// Roger Simpson.
// 1.09 - 2003Aug03 - Added fxwrite so asm will write little-endian files
// on all CPUs.
// 1.08 - 2003Mar18 - Fixed bug that complained about valid MDX displacement of +127
// 1.07 - 2003Jan05 - Filenames are now left in lower case. SYMBOLS.SYS stays all upper case
// 1.06 - 2002May02 - Fixed bug in ebdic constants (data goes into low byte)
// First stab at adding ISS level # info, this is iffy
// 1.05 - 2002Apr24 - Made negative BSS size a warning not an error, as it
// it's looking like it happens twice in PTMASMBL.
// This version still doesn't do fixed point numbers and
// negative floats may be wrong.
// 1.04 - 2002Apr18 - Added binary (card loader format) output, removed
// interim IPL output formats and moved that to MKBOOT.
// Enhanced relocatable code handling. Added floating
// point constants, but don't know how to make fixed point
// constants yet. Made amenable to syntax variations found
// in the DMS sources. Doesn't properly handle ILS
// modules yet and ISS is probably wrong.
// 1.03 - 2002Apr10 - numerous fixes, began to add relative/absolute support
// 1.02 - 2002Feb26 - replaced "strupr" with "upcase" for compatibility
// 1.01 - 2002Feb25 - minor compiler compatibility changes
// 1.00 - 2002Feb01 - first release. Tested only under Win32.
// ---------------------------------------------------------------------------------
//
// Usage:
// asm1130 [-bvsx] [-o[file]] [-l[file]] [-rN.M] file...
//
// Description:
// -b binary output (.bin, relocatable absolute format)
// -v verbose
// -s print symbol table
// -x print cross references
// -o output file (default is name of first source file + extension .out or .bin)
// -l listing file (default is name of first source file + extension .lst)
// -y preload system symbol table SYMBOLS.SYS (from the current directory)
// -w write the system symbol table SYMBOLS.SYS in the current directory
// -W same as -w but don't prompt to confirm overwriting existing file
// -r set DMS release to release N version M, for sbrk cards
//
// Listing and symbol table output can be turned on by *LIST directives in the source, too
// Listing file default extension is .LST
//
// Input files can use strict IBM 1130 Assembler column format, or loose formatting
// with tabs, or any mix on a line-by-line basis. Input files default extension is .ASM.
//
// Strict specification is:
//
// label columns 1 - 5
// opcode 7 - 10
// tag 12
// index 13
// arguments 15 - 51
//
// Loose, indicated by presence of ascii tab character(s):
//
// label<tab>opcode<tab>index and format indicators<tab>arguments
//
// In both cases, the IBM convention that the arguments section ends with the
// first nonblank applies. This means that ".DC 1, 2, 3" assembles only the 1!
//
// Output file format is that used by the LOAD command in my 1130
// simulator. Lines are any of the following. All values are in hex:
//
// @addr load address for subsequent words is addr
// Znwords Zero the next "nwords" and increment load address by nwords.
// =addr set IAR register to address addr (a convenience)
// value load value at load address and increment load address
//
// Output file default extension is .OUT or .BIN for binary assemblies
//
// Note: this version does not handle relative assembly, and so doesn't carry
// absolute/relative indication through expression calculation.
//
// Seems to work. Was able to assemble the resident monitor OK.
// >>> Look for "bug here" though, for things to check out.
//
// Notes:
// We assume that the computer on which the assembler runs uses ANSI floating point.
// Also, the assembly of floating point values may be incorrect on non-Intel
// architectures, this needs to be investigated.
//
// org_advanced tells whether * in an expression refers to the address AFTER the
// instruction (1 or 2 words, depending on length). This is the case for opcodes
// but not all directives.
//
// Revision History
// 16Apr02 1.03 Added sector break, relocation flag output
// 02Apr02 1.02 Fixed bug in BOSC: it CAN be a short instruction.
// Added directives for 1130 and 1800 IPL output formats
// Added conditional assembly directives
// ---------------------------------------------------------------------------------
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <stdarg.h>
#include <setjmp.h>
#include <time.h>
#include <ctype.h>
#include "util_io.h"
// ---------------------------------------------------------------1------------------
// DEFINITIONS
// ---------------------------------------------------------------------------------
// I have found some IBM source code where @ and ' seem interchangable (likely due to the
// use of 026 keypunches).
// Comment out this define to make @ and ' different in symbol names, keep to make equivalent
#if defined(VMS)
# include <unistd.h> /* to pick up 'unlink' */
#endif
#define BETWEEN(v,a,b) (((v) >= (a)) && ((v) <= (b)))
#define MIN(a,b) (((a) <= (b)) ? (a) : (b))
#define MAX(a,b) (((a) >= (b)) ? (a) : (b))
#ifndef _WIN32
int strnicmp (char *a, char *b, int n);
int strcmpi (char *a, char *b);
#endif
#define FIX_ATS
#define DMSVERSION "V2M12" /* required 5 characters on sector break card col 67-71 */
#define DOLLAREXIT "/38" // hmmm, are these really fixed absolutely in all versions?
#define DOLLARDUMP "/3F"
#define SYSTEM_TABLE "SYMBOLS.SYS"
#define BOOL int
#define TRUE 1
#define FALSE 0
#define ISTV 0x33 // magic number from DMS R2V12 monitorm symbol @ISTV
#define MAXLITERALS 300
#define MAXENTRIES 14
#define LINEFORMAT " %4ld | %s"
#define LEFT_MARGIN " |"
// XXXX XXXX XXXX XXXX XXXX XXXX
// org w1 w2 w3 w4 w5
// XXXX 1111 2222 3333 4444 LLLL |
// 12345678901234567890123456789012
typedef enum {ABSOLUTE = 0, RELATIVE = 1, LIBF = 2, CALL = 3} RELOC;
typedef struct tag_symbol { // symbol table entry:
char *name; // name of symbol
int value; // value (absolute)
int pass; // defined during pass #
int defined; // definition state, see #defines below
RELOC relative; // ABSOLUTE = absolute, RELATIVE = relative
struct tag_symbol *next; // next symbol in list
struct tag_xref *xrefs; // cross references
} SYMBOL, *PSYMBOL;
#define S_UNDEFINED 0 // values of 'defined'
#define S_PROVISIONAL 1 // usually an expression with forward references
#define S_DEFINED 2 // ordering must be undef < prov < def
typedef struct tag_xref { // cross reference entry
char *fname; // filename
int lno; // line number
BOOL definition; // true = definition, false = reference
struct tag_xref *next; // next reference
} XREF, *PXREF;
typedef struct tag_expr { // expression result: absolute or relative
int value;
RELOC relative;
} EXPR;
typedef enum {PROGTYPE_ABSOLUTE = 1, PROGTYPE_RELOCATABLE = 2, PROGTYPE_LIBF = 3, PROGTYPE_CALL = 4,
PROGTYPE_ISSLIBF = 5, PROGTYPE_ISSCALL = 6, PROGTYPE_ILS = 7} PROGTYPE;
typedef enum {SUBTYPE_INCORE = 0, SUBTYPE_FORDISK = 1, SUBTYPE_ARITH = 2,
SUBTYPE_FORNONDISK = 3, SUBTYPE_FUNCTION=8} SUBTYPE;
typedef enum {INTMODE_UNSPECIFIED = 0, INTMODE_MATCHREAL = 0x0080, INTMODE_ONEWORD = 0x0090} INTMODE;
typedef enum {REALMODE_UNSPECIFIED = 0, REALMODE_STANDARD = 0x0001, REALMODE_EXTENDED = 0x0002} REALMODE;
#define OP_INDEXED 0x0300 // 1130 opcode modifier bits
#define OP_LONG 0x0400
#define OP_INDIRECT 0x0080
typedef enum {OUTMODE_LOAD, OUTMODE_1130, OUTMODE_1800, OUTMODE_BINARY} OUTMODE;
#ifdef _WIN32
# define OUTWRITEMODE "wb" // write outfile in binary mode
# define ENDLINE "\r\n" // explictly write CR/LF
#else
# define OUTWRITEMODE "w" // use native mode
# define ENDLINE "\n"
#endif
// ---------------------------------------------------------------------------------
// GLOBALS
// ---------------------------------------------------------------------------------
// command line syntax
char *usestr =
"Usage: asm1130 [-bpsvwxy8] [-o[file]] [-l[file]] [-rN.M] file...\n\n"
"-b binary (relocatable format) output; default is simulator LOAD format\n"
"-p count passes required; no assembly output is created with this flag"
"-s add symbol table to listing\n"
"-v verbose mode\n"
"-w write system symbol table as SYMBOLS.SYS\n"
"-W same as -w but do not confirm overwriting previous file\n"
"-x add cross reference table to listing\n"
"-y preload system symbol table SYMBOLS.SYS\n"
"-o set output file; default is first input file + .out or .bin\n"
"-l create listing file; default is first input file + .lst\n"
"-r set dms version to VN RM for system SBRK cards\n"
"-8 enable IBM 1800 instructions"; // (alternately, rename or link executable to asm1800.exe)
BOOL verbose = FALSE; // verbose mode flag
BOOL tabformat = FALSE; // TRUE if tabs were seen in the file
BOOL enable_1800 = FALSE; // TRUE if 1800 mode is enabled by flag or executable name
int pass; // current assembler pass (1 or 2)
char curfn[256]; // current input file name
char progname[8]; // base name of primary input file
char *outfn = NULL; // output file name
int lno; // current input file line number
BOOL preload = FALSE; // preload system symbol table
BOOL savetable = FALSE; // write system symbol table
BOOL saveprompt = TRUE; // prompt before overwriting
int nerrors = 0; // count of errors
int nwarnings = 0; // count of warnings
FILE *fin = NULL; // current input file
FILE *fout = NULL; // output file stream
OUTMODE outmode = OUTMODE_LOAD; // output file mode
int outcols = 0; // columns written in using card output
int maxiplcols = 80;
char cardid[9]; // characters used for IPL card ID
FILE *flist = NULL; // listing file stream
char *listfn = NULL; // listing filename
BOOL do_list = FALSE; // flag: create listing
BOOL passcount = FALSE; // flag: count passes only
BOOL list_on = TRUE; // listing is currently enabled
BOOL do_xref = FALSE; // cross reference listing
BOOL do_syms = FALSE; // symbol table listing
BOOL ended = FALSE; // end of current file
BOOL hasforward = FALSE; // true if there are any forward references
char listline[350]; // output listing line
BOOL line_error; // already saw an error on current line
RELOC relocate = RELATIVE; // relocatable assembly mode
BOOL assembled = FALSE; // true if any output has been generated
int nwout; // number of words written on current line
int org = 0; // output address (origin)
int org_advanced; // if TRUE, * means instruction addr+(value) during evaluation
int pta = -1; // program transfer address
BOOL cexpr = FALSE; // "C" expression syntax
PSYMBOL symbols = NULL; // the symbol table (linear search)
BOOL check_control = TRUE; // check for control cards
PROGTYPE progtype = PROGTYPE_RELOCATABLE; // program type
INTMODE intmode = INTMODE_UNSPECIFIED; // integer mode
REALMODE realmode = REALMODE_UNSPECIFIED; // real mode
int nintlevels = 0; // # of interrupt levels for ISS
int intlevel_primary = 0; // primary level for ISS and level for ILS
int intlevel_secondary = 0; // secondary level for ISS
int iss_number = 0; // ISS number
PSYMBOL entry[MAXENTRIES]; // entries for subroutines
int nentries = 0;
int ndefined_files = 0;
struct lit { // accumulated literals waiting to be output
int value; // constant value
int tagno; // constant symbol tag number (e.g. _L001)
BOOL hex; // constant was expressed in hex
BOOL even; // constant was operand of a double-width instruction (e.g. AD)
} literal[MAXLITERALS];
int n_literals = 0, lit_tag = 0;
BOOL requires_even_address; // target of current instruction
BOOL dmes_saved; // odd character left over from dmes ending in '
int dmes_savew;
char opfield[256]; // extracted operand field from source line
char dmsversion[12] = DMSVERSION; // version number for SBRK cards
const char whitespace[] = " \t"; // whitespace
int ascii_to_ebcdic_table[128] =
{
//
0x00,0x01,0x02,0x03,0x37,0x2d,0x2e,0x2f, 0x16,0x05,0x25,0x0b,0x0c,0x0d,0x0e,0x0f,
//
0x10,0x11,0x12,0x13,0x3c,0x3d,0x32,0x26, 0x18,0x19,0x3f,0x27,0x1c,0x1d,0x1e,0x1f,
// spac ! " # $ % & ' ( ) * + , - . /
0x40,0x5a,0x7f,0x7b,0x5b,0x6c,0x50,0x7d, 0x4d,0x5d,0x5c,0x4e,0x6b,0x60,0x4b,0x61,
// 0 1 2 3 4 5 6 7 8 9 : ; < = > ?
0xf0,0xf1,0xf2,0xf3,0xf4,0xf5,0xf6,0xf7, 0xf8,0xf9,0x7a,0x5e,0x4c,0x7e,0x6e,0x6f,
// @ A B C D E F G H I J K L M N O
0x7c,0xc1,0xc2,0xc3,0xc4,0xc5,0xc6,0xc7, 0xc8,0xc9,0xd1,0xd2,0xd3,0xd4,0xd5,0xd6,
// P Q R S T U V W X Y Z [ \ ] & _
0xd7,0xd8,0xd9,0xe2,0xe3,0xe4,0xe5,0xe6, 0xe7,0xe8,0xe9,0xba,0xe0,0xbb,0xb0,0x6d,
// a b c d e f g h i j k l m n o
0x79,0x81,0x82,0x83,0x84,0x85,0x86,0x87, 0x88,0x89,0x91,0x92,0x93,0x94,0x95,0x96,
// p q r s t u v w x y z { | } ~
0x97,0x98,0x99,0xa2,0xa3,0xa4,0xa5,0xa6, 0xa7,0xa8,0xa9,0xc0,0x4f,0xd0,0xa1,0x07,
};
int ascii_to_1403_table[128] =
{ /* 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f */
0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f, 0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,
0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f, 0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,0x7f,
0x7f,0x7f,0x7f,0x7f,0x62,0x7f,0x15,0x0b, 0x57,0x2f,0x23,0x6d,0x16,0x61,0x6e,0x4c,
0x49,0x40,0x01,0x02,0x43,0x04,0x45,0x46, 0x07,0x08,0x7f,0x7f,0x7f,0x4a,0x7f,0x7f,
0x7f,0x64,0x25,0x26,0x67,0x68,0x29,0x2a, 0x6b,0x2c,0x58,0x19,0x1a,0x5b,0x1c,0x5d,
0x5e,0x1f,0x20,0x0d,0x0e,0x4f,0x10,0x51, 0x52,0x13,0x54,0x7f,0x7f,0x7f,0x7f,0x7f,
0x7f,0x64,0x25,0x26,0x67,0x68,0x29,0x2a, 0x6b,0x2c,0x58,0x19,0x1a,0x5b,0x1c,0x5d,
0x5e,0x1f,0x20,0x0d,0x0e,0x4f,0x10,0x51, 0x52,0x13,0x54,0x7f,0x7f,0x7f,0x7f,0x7f
};
#include "../ibm1130_conout.h" /* conout_to_ascii_table */
#include "../ibm1130_prtwheel.h" /* 1132 printer printwheel data */
// ---------------------------------------------------------------------------------
// PROTOTYPES
// ---------------------------------------------------------------------------------
void init (int argc, char **argv);
void bail (char *msg);
void flag (char *arg);
void proc (char *fname);
void startpass (int n);
void errprintf (char *fmt, ...);
void asm_error (char *fmt, ...);
void asm_warning (char *fmt, ...);
char *astring (char *str);
PSYMBOL lookup_symbol (char *name, BOOL define);
void add_xref (PSYMBOL s, BOOL definition);
int get_symbol (char *name);
void set_symbol (char *name, int value, int known, RELOC relative);
char * gtok (char **pc, char *tok);
char *skipbl (char *c);
void sym_list (void);
void xref_list (void);
void listhdr (void);
int getexpr (char *pc, BOOL undefined_ok, EXPR *expr);
void passreport (void);
void listout (BOOL reset);
void output_literals (BOOL eof);
char *upcase (char *str);
void prep_line (char *line);
int ascii_to_hollerith (int ch);
char *detab (char *str);
void preload_symbols (void);
void save_symbols (void);
void bincard_init (void);
void bincard_writecard (char *sbrk_text);
void bincard_writedata (void);
void bincard_flush (void);
void bincard_sbrk (char *line);
void bincard_setorg (int neworg);
void bincard_writew (int word, RELOC relative);
void bincard_endcard (void);
void handle_sbrk (char *line);
void bincard_typecard (void);
void namecode (unsigned short *words, char *tok);
int signextend (int v);
// ---------------------------------------------------------------------------------
// main routine
// ---------------------------------------------------------------------------------
int main (int argc, char **argv)
{
int i, sawfile = FALSE;
init(argc, argv); // initialize, process flags
startpass(1); // first pass, process files
for (i = 1; i < argc; i++)
if (*argv[i] != '-')
proc(argv[i]), sawfile = TRUE;
if (! sawfile) // should have seen at least one file
bail(usestr);
if (passcount) {
passreport();
return 0;
}
startpass(2); // second pass, process files again
for (i = 1; i < argc; i++)
if (*argv[i] != '-')
proc(argv[i]);
if (outmode == OUTMODE_LOAD) {
if (pta >= 0) // write start address to the load file
fprintf(fout, "=%04x" ENDLINE, pta & 0xFFFF);
}
else
bincard_endcard();
if (flist) {
if (nerrors || nwarnings) { // summarize (or summarise)
if (nerrors == 0)
fprintf(flist, "There %s ", (nwarnings == 1) ? "was" : "were");
else
fprintf(flist, "\nThere %s %d error%s %s",
(nerrors == 1) ? "was" : "were", nerrors, (nerrors == 1) ? "" : "s", nwarnings ? "and " : "");
if (nwarnings > 0)
fprintf(flist, "%d warning%s ", nwarnings, (nwarnings == 1) ? "" : "s");
fprintf(flist, "in this assembly\n");
}
else
fprintf(flist, "\nThere were no errors in this assembly\n");
}
if (flist) { // finish the listing
if (pta >= 0)
fprintf(flist, "\nProgram transfer address = %04x\n", pta);
if (do_xref)
xref_list();
else if (do_syms)
sym_list();
}
if (savetable)
save_symbols();
return 0; // all done
}
// ---------------------------------------------------------------------------------
// init - initialize assembler, process command line flags
// ---------------------------------------------------------------------------------
void init (int argc, char **argv)
{
int i;
enable_1800 = strstr(argv[0], "1800") != NULL; // if "1800" appears in the executable name, enable 1800 extensions
for (i = 1; i < argc; i++) // process command line switches
if (*argv[i] == '-')
flag(argv[i]+1);
}
// ---------------------------------------------------------------------------------
// flag - process one command line switch
// ---------------------------------------------------------------------------------
void flag (char *arg)
{
int major, minor;
while (*arg) {
switch (*arg++) {
case 'o': // output (load) file name
if (! *arg)
bail(usestr);
outfn = arg;
return;
case 'p':
passcount = TRUE;
break;
case 'v': // mumble while running
verbose = TRUE;
break;
case 'x': // print cross reference table
do_xref = TRUE;
break;
case 's': // print symbol table
do_syms = TRUE;
break;
case 'l': // listing file name
listfn = (* arg) ? arg : NULL;
do_list = TRUE;
return;
case 'W':
saveprompt = FALSE;
// fall through
case 'w':
savetable = TRUE;
break;
case 'y':
preload = TRUE;
break;
case 'b':
outmode = OUTMODE_BINARY;
break;
case '8':
enable_1800 = TRUE;
break;
case 'r':
if (sscanf(arg, "%d.%d", &major, &minor) != 2)
bail(usestr);
sprintf(dmsversion, "V%01.1dM%02.2d", major, minor);
return;
default:
bail(usestr);
break;
}
}
}
// ---------------------------------------------------------------------------------
// bail - print error message on stderr (only) and exit
// ---------------------------------------------------------------------------------
void bail (char *msg)
{
fprintf(stderr, "%s\n", msg);
exit(1);
}
// ---------------------------------------------------------------------------------
// errprintf - print error message to stderr
// ---------------------------------------------------------------------------------
void errprintf (char *fmt, ...)
{
va_list args;
va_start(args, fmt); // get pointer to argument list
vfprintf(stderr, fmt, args); // write errors to terminal (stderr)
va_end(args);
}
// ---------------------------------------------------------------------------------
// asm_error - report an error to listing file and to user's console
// ---------------------------------------------------------------------------------
void asm_error (char *fmt, ...)
{
va_list args;
if (pass == 1) // only print on pass 2
return;
va_start(args, fmt); // get pointer to argument list
fprintf(stderr, "E: %s (%d): ", curfn, lno);
vfprintf(stderr, fmt, args); // write errors to terminal (stderr)
putc('\n', stderr);
if (flist != NULL && list_on) {
listout(FALSE);
line_error = TRUE;
fprintf(flist, "**** Error: ");
vfprintf(flist, fmt, args); // write errors to listing file
putc('\n', flist);
}
nerrors++;
va_end(args);
}
// ---------------------------------------------------------------------------------
// asm_warning - same but warnings are not counted
// ---------------------------------------------------------------------------------
void asm_warning (char *fmt, ...)
{
va_list args;
if (pass == 1) // only print on pass 2
return;
va_start(args, fmt); // get pointer to argument list
fprintf(stderr, "W: %s (%d): ", curfn, lno);
vfprintf(stderr, fmt, args); // write errors to terminal (stderr)
putc('\n', stderr);
if (flist != NULL && list_on) {
listout(FALSE);
line_error = TRUE;
fprintf(flist, "**** Warning: ");
vfprintf(flist, fmt, args); // write errors to listing file
putc('\n', flist);
}
nwarnings++;
}
// ---------------------------------------------------------------------------------
// sym_list - print the symbol table
// ---------------------------------------------------------------------------------
void sym_list (void)
{
PSYMBOL s;
int n = 5;
if (symbols == NULL || flist == NULL)
return;
fprintf(flist, "\n=== SYMBOL TABLE ==============================================================\n");
for (s = symbols, n = 0; s != NULL; s = s->next) {
if (n >= 5) {
putc('\n', flist);
n = 0;
}
else if (n > 0)
fprintf(flist, " ");
fprintf(flist, "%-6s ", s->name);
if (s->defined == S_DEFINED)
fprintf(flist, "%04x%s", s->value & 0xFFFF, s->relative ? "R" : " ");
else
fprintf(flist, "UUUU ");
n++;
}
fprintf(flist, "\n");
}
// ---------------------------------------------------------------------------------
// passreport - report # of passes required for assembly on the 1130
// ---------------------------------------------------------------------------------
void passreport (void)
{
PSYMBOL s;
for (s = symbols; s != NULL; s = s->next) {
if (s->defined == S_UNDEFINED || s->defined == S_PROVISIONAL) {
printf("There are undefined symbols. Cannot determine pass requirement.\n");
return;
}
}
if (hasforward)
printf("There are forward references. Two passes are required.\n");
else
printf("There are no forward references. Only one pass is required.\n");
}
// ---------------------------------------------------------------------------------
// xref_list - print the cross-reference table
// ---------------------------------------------------------------------------------
void xref_list (void)
{
int n = 0;
PXREF x;
PSYMBOL s;
if (flist == NULL || symbols == NULL)
return;
fprintf(flist, "\n=== CROSS REFERENCES ==========================================================\n");
if (symbols == NULL || flist == NULL)
return;
fprintf(flist, "Name Val Defd Referenced\n");
for (s = symbols; s != NULL; s = s->next) {
fprintf(flist, "%-5s %04x%s", s->name, s->value & 0xFFFF, s->relative ? "R" : " ");
for (x = s->xrefs; x != NULL; x = x->next)
if (x->definition)
break;
if (x == NULL)
fprintf(flist, "----");
else
fprintf(flist, " %4d", x->lno);
for (n = 0, x = s->xrefs; x != NULL; x = x->next) {
if (x->definition)
continue;
if (n >= 12) {
n = 0;
fprintf(flist, "\n ");
}
fprintf(flist, " %4d", x->lno);
n++;
}
putc('\n', flist);
}
}
// ---------------------------------------------------------------------------------
// listhdr - print a banner header in the listing file. Since it's not paginated
// at this time, this is not used often.
// ---------------------------------------------------------------------------------
void listhdr (void)
{
time_t t;
time(&t);
fprintf(flist, "%s -- %s -- %s\n", VERSION, dmsversion, ctime(&t));
}
// ---------------------------------------------------------------------------------
// astring - allocate a copy of a string
// ---------------------------------------------------------------------------------
char *astring (char *str)
{
static char *s = NULL;
if (s != NULL)
if (strcmp(s, str) == 0) // if same as immediately previous allocation
return s; // return same pointer (why did I do this?)
if ((s = malloc(strlen(str)+1)) == NULL)
bail("out of memory");
strcpy(s, str);
return s;
}
// ---------------------------------------------------------------------------------
// lookup_symbol - get pointer to a symbol.
// If define is TRUE, creates and marks 'undefined' if not previously defined.
// ---------------------------------------------------------------------------------
PSYMBOL lookup_symbol (char *name, BOOL define)
{
PSYMBOL s, n, prv = NULL;
int c;
char *at;
if (strlen(name) > 5) { // (sigh)
asm_error("Symbol '%s' is longer than 5 letters", name);
name[5] = '\0';
}
#ifdef FIX_ATS
while ((at = strchr(name, '@')) != NULL)
*at = '\'';
#endif
// search sorted list of symbols
for (s = symbols; s != NULL; prv = s, s = s->next) {
c = strcmpi(s->name, name);
if (c == 0)
return s;
if (c > 0)
break;
}
if (! define)
return NULL; // not found
if ((n = malloc(sizeof(SYMBOL))) == NULL)
bail("out of memory");
n->name = astring(name); // symbol was undefined -- add it now
n->value = 0;
n->defined = FALSE;
n->xrefs = NULL;
n->defined = FALSE;
n->next = s; // link in alpha order
if (prv == NULL) // we stopped before first item in list
symbols = n;
else
prv->next = n; // insert after item before place we stopped
return n;
}
// ---------------------------------------------------------------------------------
// add_xref - add a cross reference entry to a symbol
// ---------------------------------------------------------------------------------
void add_xref (PSYMBOL s, BOOL definition)
{
PXREF x, prv = NULL, n;
if (pass == 1 || ! do_xref) // define only during 2nd pass and only if listing was requested
return;
for (x = s->xrefs; x != NULL; prv = x, x = x->next)
if (strcmpi(x->fname, curfn) == 0 && x->lno == lno)
return; // ignore multiple refs on same line
if ((n = malloc(sizeof(XREF))) == NULL)
bail("out of memory");
n->fname = astring(curfn);
n->lno = lno;
n->definition = definition;
n->next = x; // link at end of existing list
if (prv == NULL)
s->xrefs = n;
else
prv->next = n;
}
// ---------------------------------------------------------------------------------
// get_symbol - get a symbol value, defining if necessary
// ---------------------------------------------------------------------------------
int get_symbol (char *name)
{
PSYMBOL s;
s = lookup_symbol(name, TRUE); // lookup, define if necessary
if (pass == 2) // should be defined by now
if (! s->defined)
asm_error("Symbol '%s' is undefined", name);
add_xref(s, FALSE); // note the reference
return s->value;
}
// ---------------------------------------------------------------------------------
// set_symbol - set a symbol value. Known = TRUE means we really know the value;
// FALSE means we're calculating it with forward referenced values or something like
// that.
// ---------------------------------------------------------------------------------
void set_symbol (char *name, int value, int known, RELOC relative)
{
PSYMBOL s;
char *at;
if (strlen(name) > 5) {
asm_error("Symbol '%s' is longer than 5 letters", name);
name[5] = '\0';
}
#ifdef FIX_ATS
while ((at = strchr(name, '@')) != NULL)
*at = '\'';
#endif
s = lookup_symbol(name, TRUE);
if (s->defined == S_DEFINED) // once defined, it should not change
if (s->value != value)
asm_error("Symbol '%s' %s", name, (s->pass == pass) ? "is multiply defined" : "changed between passes");
s->value = value;
s->relative = relative;
s->defined = known ? S_DEFINED : S_PROVISIONAL;
s->pass = pass;
if (! known)
hasforward = TRUE;
add_xref(s, TRUE); // record the place of definition
}
// ---------------------------------------------------------------------------------
// skipbl - return pointer to first nonblank character in string s
// ---------------------------------------------------------------------------------
char *skipbl (char *s)
{
while (*s && *s <= ' ')
s++;
return s;
}
// ---------------------------------------------------------------------------------
// gtok - extracts a whitespace-delimited token from the string pointed to by *pc;
// stores the token into the buffer tok and returns pointer to same. Returns NULL
// when there are no tokens. Best to call repeatedly with a pointer to the source
// buffer, e.g.
// char *pbuf = buf;
// while (gtok(&pbuf, token) != NULL) ...
// ---------------------------------------------------------------------------------
char * gtok (char **pc, char *tok)
{
char *s = *pc, *otok = tok;
while (*s && *s <= ' ') // skip blanks
s++;
if (! *s) { // no tokens to be found
*tok = '\0';
*pc = s;
return NULL;
}
while (*s > ' ') // save nonblanks into 'tok'
*tok++ = *s++;
*tok = '\0'; // terminate
*pc = s; // adjust caller's pointer
return otok; // return pointer to token
}
// listing format:
//
// ADDR CODE SOURCE
// 0000 0000 0000 0000 0000 | XXXXXXXXXXXXXXXXX
// ---------------------------------------------------------------------------------
// trim - remove trailing whitespace from string s
// ---------------------------------------------------------------------------------
char *trim (char *s)
{
char *os = s, *nb;
for (nb = s-1; *s; s++)
if (*s > ' ')
nb = s;
nb[1] = '\0';
return os;
}
// ---------------------------------------------------------------------------------
// listout - emit current constructed output listing line held in "listline" and
// if "reset" is true, prepare listline for second and subsequent listing lines
// for a given input statement.
// ---------------------------------------------------------------------------------
void listout (BOOL reset)
{
if (flist && list_on && ! line_error) {
trim(listline);
fputs(listline, flist);
putc('\n', flist);
if (reset)
sprintf(listline, LEFT_MARGIN, org);
}
}
// ---------------------------------------------------------------------------------
// storew - store a word in the output medium (hex or binary file). Most of the time
// writew is used. Advances the origin!
// ---------------------------------------------------------------------------------
void storew (int word, RELOC relative)
{
if (pass == 2) { // save in output (load) file.
switch (outmode) {
case OUTMODE_BINARY:
bincard_writew(word, relative);
break;
case OUTMODE_LOAD:
fprintf(fout, " %04x%s" ENDLINE, word & 0xFFFF,
(relative == ABSOLUTE) ? "" : (relative == RELATIVE) ? "R" :
(relative == LIBF) ? "L" : (relative == CALL) ? "$" : "?");
break;
default:
bail("in storew, can't happen");
}
}
if (relative != LIBF)
org++;
assembled = TRUE; // remember that we wrote something
}
// ---------------------------------------------------------------------------------
// setw - store a word value in the current listing output line in position 'pos'.
// ---------------------------------------------------------------------------------
void setw (int pos, int word, RELOC relative)
{
char tok[10], *p;
int i;
if (flist == NULL || ! list_on)
return;
sprintf(tok, "%04x", word & 0xFFFF);
for (i = 0, p = listline + 5*pos; i < 4; i++)
p[i] = tok[i];
if (relative == RELATIVE)
p[i] = 'R';
else if (relative != ABSOLUTE)
p[i] = '*';
}
// ---------------------------------------------------------------------------------
// writew - emit an assembled word value. Words are also displayed in the listing file.
// if relative is true, a relocation entry should be recorded.
// ---------------------------------------------------------------------------------
void writew (int word, RELOC relative)
{ // first, the listing stuff...
if (nwout == 0) { // on first output word, display address in column 0
setw(0, org, FALSE);
}
else if (nwout >= 4) { // if 4 words have already been written, start new line
listout(TRUE);
nwout = 0;
}
nwout++;
setw(nwout, word, relative); // display word in the listing line
storew(word, relative); // write it to the output medium
}
// ---------------------------------------------------------------------------------
// setorg - take note of new load address
// ---------------------------------------------------------------------------------
void setorg (int neworg)
{
if (pass == 2) {
setw(0, neworg, FALSE); // display in listing file in column 0
if (outmode == OUTMODE_LOAD) { // write new load address to the output file
fprintf(fout, "@%04x%s" ENDLINE, neworg & 0xFFFF, relocate ? "R" : "");
}
else {
bincard_setorg(neworg);
}
}
org = neworg;
}
// ---------------------------------------------------------------------------------
// org_even - force load address to an even address
// ---------------------------------------------------------------------------------
void org_even (void)
{
if (org & 1)
setorg(org+1);
}
// ---------------------------------------------------------------------------------
// tabtok - get the token in tab-delimited column number i, from source string c,
// saving in string 'tok'. If save is nonnull, we copy the entire remainder of
// the input string in buffer 'save' (in contrast to 'tok' which gets only the
// first whitespace delimited token).
// ---------------------------------------------------------------------------------
void tabtok (char *c, char *tok, int i, char *save)
{
*tok = '\0';
while (--i >= 0) { // skip to i'th tab-delimited field
if ((c = strchr(c, '\t')) == NULL) {
if (save) // was none
*save = '\0';
return;
}
c++;
}
while (*c == ' ') // skip leading blanks
c++;
if (save != NULL) // save copy of entire remainder
strcpy(save, c);
while (*c > ' ') { // take up to any whitespace
if (*c == '(') { // if we start with a paren, take all up to closing paren including spaces
while (*c && *c != ')')
*tok++ = *c++;
}
else if (*c == '.') { // period means literal character following
*tok++ = *c++;
if (*c)
*tok++ = *c++;
}
else
*tok++ = *c++;
}
*tok = '\0';
}
// ---------------------------------------------------------------------------------
// coltok - extract a token from string c, saving to buffer tok, by examining
// columns ifrom through ito only. If save is nonnull, the entire remainder
// of the input from ifrom to the end is saved there. In this routine
// if condense is true, we save all nonwhite characters in the column range;
// not the usual thing. This helps us coalesce the format, tag, & index things
// nto one string for the simple minded parser. If condense is FALSE, we terminate
// on the first nonblank, except that if we start with a (, we take up to ) and
// then terminate on a space.
//
// ifrom and ito on entry are column numbers, not indices; we change that right away
// ---------------------------------------------------------------------------------
void coltok (char *c, char *tok, int ifrom, int ito, BOOL condense, char *save)
{
char *otok = tok;
int i;
ifrom--;
ito--;
for (i = 0; i < ifrom; i++) {
if (c[i] == '\0') { // line ended before this column
*tok = '\0';
if (save)
*save = '\0';
return;
}
}
if (save) // save from ifrom on
strcpy(save, c+i);
if (condense) {
for (; i <= ito; i++) { // save only nonwhite characters
if (c[i] > ' ')
*tok++ = c[i];
}
}
else {
if (c[i] == ' ' && save != NULL)// if it starts with a space, it's empty
*save = '\0';
while (i <= ito) { // take up to any whitespace
if (c[i] <= ' ')
break;
else if (c[i] == '(') { // starts with paren? take to close paren
while (i <= ito && c[i]) {
if ((*tok++ = c[i++]) == ')')
break;
}
}
else if (c[i] == '.') { // period means literal character following
*tok++ = c[i++];
if (i <= ito && c[i])
*tok++ = c[i++];
}
else
*tok++ = c[i++];
}
}
*tok = '\0';
trim(otok);
}
// ---------------------------------------------------------------------------------
// opcode table
// ---------------------------------------------------------------------------------
// modifiers for the opcode definition table:
#define L "L" // long
#define X "X" // absolute displacement
#define I "I" // indirect
#define IDX "0123" // indexed (some LDX commands in the DMS source say LDX L0, so accept 0
#define E "E" // even address
#define NONE ""
#define ALL L X I IDX // hope non-Microsoft C accepts and concatenates strings like this
#define ANY "\xFF"
#define NUMS "0123456789"
#define IS_DBL 0x0001 // double word operand implies even address
#define IS_ABS 0x0002 // always uses absolute addressing mode (implied X)
#define NO_IDX 0x0004 // even with 1 or 2 modifier, this is not really indexed (for STX/LDX)
#define NO_ARGS 0x0008 // statement takes no arguments
#define IS_1800 0x0010 // 1800-only directive or instruction, flagged if 1800 mode is not enabled
#define TRAP 0x1000 // debug this instruction
struct tag_op { // OPCODE TABLE
char *mnem;
int opcode;
void (*handler)(struct tag_op *op, char *label, char *mods, char *arg);
char *mods_allowed;
char *mods_implied;
int flags;
};
// special opcode handlers
void std_op (struct tag_op *op, char *label, char *mods, char *arg);
void b_op (struct tag_op *op, char *label, char *mods, char *arg);
void bsc_op (struct tag_op *op, char *label, char *mods, char *arg);
void bsi_op (struct tag_op *op, char *label, char *mods, char *arg);
void mdx_op (struct tag_op *op, char *label, char *mods, char *arg);
void shf_op (struct tag_op *op, char *label, char *mods, char *arg);
void x_aif (struct tag_op *op, char *label, char *mods, char *arg);
void x_aifb (struct tag_op *op, char *label, char *mods, char *arg);
void x_ago (struct tag_op *op, char *label, char *mods, char *arg);
void x_agob (struct tag_op *op, char *label, char *mods, char *arg);
void x_anop (struct tag_op *op, char *label, char *mods, char *arg);
void x_abs (struct tag_op *op, char *label, char *mods, char *arg);
void x_call (struct tag_op *op, char *label, char *mods, char *arg);
void x_dsa (struct tag_op *op, char *label, char *mods, char *arg);
void x_file (struct tag_op *op, char *label, char *mods, char *arg);
void x_link (struct tag_op *op, char *label, char *mods, char *arg);
void x_libf (struct tag_op *op, char *label, char *mods, char *arg);
void x_org (struct tag_op *op, char *label, char *mods, char *arg);
void x_opt (struct tag_op *op, char *label, char *mods, char *arg);
void x_ces (struct tag_op *op, char *label, char *mods, char *arg);
void x_bes (struct tag_op *op, char *label, char *mods, char *arg);
void x_bss (struct tag_op *op, char *label, char *mods, char *arg);
void x_dc (struct tag_op *op, char *label, char *mods, char *arg);
void x_dec (struct tag_op *op, char *label, char *mods, char *arg);
void x_decs (struct tag_op *op, char *label, char *mods, char *arg);
void x_ebc (struct tag_op *op, char *label, char *mods, char *arg);
void x_end (struct tag_op *op, char *label, char *mods, char *arg);
void x_ent (struct tag_op *op, char *label, char *mods, char *arg);
void x_epr (struct tag_op *op, char *label, char *mods, char *arg);
void x_equ (struct tag_op *op, char *label, char *mods, char *arg);
void x_exit (struct tag_op *op, char *label, char *mods, char *arg);
void x_ils (struct tag_op *op, char *label, char *mods, char *arg);
void x_iss (struct tag_op *op, char *label, char *mods, char *arg);
void x_libr (struct tag_op *op, char *label, char *mods, char *arg);
void x_lorg (struct tag_op *op, char *label, char *mods, char *arg);
void x_dmes (struct tag_op *op, char *label, char *mods, char *arg);
void x_dn (struct tag_op *op, char *label, char *mods, char *arg);
void x_dump (struct tag_op *op, char *label, char *mods, char *arg);
void x_pdmp (struct tag_op *op, char *label, char *mods, char *arg);
void x_hdng (struct tag_op *op, char *label, char *mods, char *arg);
void x_list (struct tag_op *op, char *label, char *mods, char *arg);
void x_spac (struct tag_op *op, char *label, char *mods, char *arg);
void x_spr (struct tag_op *op, char *label, char *mods, char *arg);
void x_ejct (struct tag_op *op, char *label, char *mods, char *arg);
void x_trap (struct tag_op *op, char *label, char *mods, char *arg);
void x_xflc (struct tag_op *op, char *label, char *mods, char *arg);
struct tag_op ops[] = {
".OPT", 0, x_opt, NONE, NONE, 0, // non-IBM extensions
"TRAP", 0, x_trap, NONE, NONE, 0, // assembler breakpoint trap
".CES", 0, x_ces, NONE, NONE, 0, // lets us specify simulated console entry switch values for startup
"ABS", 0, x_abs, NONE, NONE, 0,
"BES", 0, x_bes, E, NONE, 0, // standard pseudo-ops
"BSS", 0, x_bss, E, NONE, 0,
"DC", 0, x_dc, NONE, NONE, 0,
"DEC", 0, x_dec, E, E, IS_DBL,
"DECS", 0, x_decs, E, E, IS_DBL, // this is an IBM 1800 directive
"DMES", 0, x_dmes, ANY, NONE, 0,
"DN", 0, x_dn, NONE, NONE, 0,
"DSA", 0, x_dsa, NONE, NONE, 0,
"DUMP", 0, x_dump, NONE, NONE, 0,
"EBC", 0, x_ebc, NONE, NONE, 0,
"EJCT", 0, x_ejct, NONE, NONE, 0,
"END", 0, x_end, NONE, NONE, 0,
"ENT", 0, x_ent, NONE, NONE, 0,
"EPR", 0, x_epr, NONE, NONE, 0,
"EQU", 0, x_equ, NONE, NONE, 0,
"EXIT", 0, x_exit, NONE, NONE, 0, // alias for call $exit since we don't have macros yet
"FILE", 0, x_file, NONE, NONE, 0,
"HDNG", 0, x_hdng, ANY, NONE, 0,
"ILS", 0, x_ils, NUMS, NONE, 0,
"ISS", 0, x_iss, NUMS, NONE, 0,
"LIBF", 0, x_libf, NONE, NONE, 0,
"LIBR", 0, x_libr, NONE, NONE, 0,
"LINK", 0, x_link, NONE, NONE, 0,
"LIST", 0, x_list, NONE, NONE, 0,
"LORG", 0, x_lorg, NONE, NONE, 0,
"ORG", 0, x_org, NONE, NONE, 0,
"PDMP", 0, x_pdmp, NONE, NONE, 0,
"SPAC", 0, x_spac, NONE, NONE, 0,
"SPR", 0, x_spr, NONE, NONE, 0,
"XFLC", 0, x_xflc, NONE, NONE, 0,
"A", 0x8000, std_op, ALL, NONE, 0, // standard addressing ops
"AD", 0x8800, std_op, ALL, NONE, IS_DBL,
"AND", 0xE000, std_op, ALL, NONE, 0,
"BSI", 0x4000, bsi_op, ALL, NONE, 0,
"CALL", 0x4000, x_call, ALL, L, 0, // alias for BSI L, or external call
"CMP", 0xB000, std_op, ALL, NONE, IS_1800, // this is an IBM 1800-only instruction
"DCM", 0xB800, std_op, ALL, NONE, IS_1800, // this is an IBM 1800-only instruction
"D" , 0xA800, std_op, ALL, NONE, 0,
"EOR", 0xF000, std_op, ALL, NONE, 0,
"LD", 0xC000, std_op, ALL, NONE, 0,
"LDD", 0xC800, std_op, ALL, NONE, IS_DBL,
"LDS", 0x2000, std_op, NONE, NONE, IS_ABS,
"LDX", 0x6000, std_op, ALL, NONE, IS_ABS|NO_IDX,
"M", 0xA000, std_op, ALL, NONE, 0,
"MDX", 0x7000, mdx_op, ALL, NONE, 0,
"MDM", 0x7000, mdx_op, L, L, 0, // like MDX L
"NOP", 0x1000, std_op, NONE, NONE, NO_ARGS,
"OR", 0xE800, std_op, ALL, NONE, 0,
"S", 0x9000, std_op, ALL, NONE, 0,
"SD", 0x9800, std_op, ALL, NONE, IS_DBL,
"STD", 0xD800, std_op, ALL, NONE, IS_DBL,
"STO", 0xD000, std_op, ALL, NONE, 0,
"STS", 0x2800, std_op, ALL, NONE, 0,
"STX", 0x6800, std_op, ALL, NONE, NO_IDX,
"WAIT", 0x3000, std_op, NONE, NONE, IS_ABS,
"XCH", 0x18D0, std_op, NONE, NONE, 0, // same as RTE 16, 18C0 + 10
"XIO", 0x0800, std_op, ALL, NONE, IS_DBL,
"BSC", 0x4800, bsc_op, ALL, NONE, 0, // branch family
"BOSC", 0x4840, bsc_op, ALL, NONE, 0, // is BOSC always long form? No.
"SKP", 0x4800, bsc_op, NONE, NONE, 0, // alias for BSC one word version
"B", 0x4800, b_op, ALL, NONE, 0, // alias for MDX or BSC L
"BC", 0x4802, std_op, ALL, L, 0, // alias for BSC L
"BN", 0x4828, std_op, ALL, L, 0, // alias for BSC L
"BNN", 0x4810, std_op, ALL, L, 0, // alias for BSC L
"BNP", 0x4808, std_op, ALL, L, 0, // alias for BSC L
"BNZ", 0x4820, std_op, ALL, L, 0, // alias for BSC L
"BO", 0x4801, std_op, ALL, L, 0, // alias for BSC L
"BOD", 0x4840, std_op, ALL, L, 0, // alias for BSC L
"BP", 0x4830, std_op, ALL, L, 0, // alias for BSC L
"BZ", 0x4818, std_op, ALL, L, 0, // alias for BSC L
"RTE", 0x18C0, shf_op, IDX X, X, 0, // shift family
"SLA", 0x1000, shf_op, IDX X, X, 0,
"SLC", 0x10C0, shf_op, IDX X, X, 0,
"SLCA", 0x1040, shf_op, IDX X, X, 0,
"SLT", 0x1080, shf_op, IDX X, X, 0,
"SRA", 0x1800, shf_op, IDX X, X, 0,
"SRT", 0x1880, shf_op, IDX X, X, 0,
"AIF", 0, x_aif, NONE, NONE, 0, // assemble if
"AIFB", 0, x_aifb, NONE, NONE, 0, // assemble if
"AGO", 0, x_ago, NONE, NONE, 0, // assemble goto
"AGOB", 0, x_agob, NONE, NONE, 0, // assemble goto
"ANOP", 0, x_anop, NONE, NONE, 0, // assemble target
NULL // end of table
};
// ---------------------------------------------------------------------------------
// addextn - apply file extension 'extn' to filename 'fname' and put result in 'outbuf'
// if outbuf is NULL, we allocate a buffer
// ---------------------------------------------------------------------------------
char *addextn (char *fname, char *extn, char *outbuf)
{
char *buf, line[500], *c;
buf = (outbuf == NULL) ? line : outbuf;
strcpy(buf, fname); // create listfn from first source filename (e.g. xxx.lst);
if ((c = strrchr(buf, '\\')) == NULL)
if ((c = strrchr(buf, '/')) == NULL)
if ((c = strrchr(buf, ':')) == NULL)
c = buf;
if ((c = strrchr(c, '.')) == NULL)
strcat(buf, extn);
else
strcpy(c, extn);
return (outbuf == NULL) ? astring(line) : outbuf;
}
// ---------------------------------------------------------------------------------
// controlcard - examine an assembler control card (* in column 1)
// ---------------------------------------------------------------------------------
BOOL controlcard (char *line)
{
if (strnicmp(line, "*LIST", 5) == 0) { // turn on listing file even if not specified on command line
do_list = list_on = TRUE;
return TRUE;
}
if (strnicmp(line, "*XREF", 5) == 0) {
do_xref = TRUE;
return TRUE;
}
if (strnicmp(line, "*PRINT SYMBOL TABLE", 19) == 0) {
do_syms = TRUE;
return TRUE;
}
if (strnicmp(line, "*SAVE SYMBOL TABLE", 18) == 0) {
savetable = TRUE;
return TRUE;
}
if (strnicmp(line, "*SYSTEM SYMBOL TABLE", 20) == 0) {
preload = TRUE;
preload_symbols();
return TRUE;
}
return FALSE;
}
// ---------------------------------------------------------------------------------
// stuff - insert characters into a line
// ---------------------------------------------------------------------------------
void stuff (char *buf, char *tok, int maxchars)
{
while (*tok) {
*buf++ = *tok++;
if (maxchars)
if (--maxchars <= 0)
break;
}
}
// ---------------------------------------------------------------------------------
// format_line - construct a source code input line from components
// ---------------------------------------------------------------------------------
void format_line (char *buf, char *label, char *op, char *mods, char *args, char *remarks)
{
int i;
if (tabformat) {
sprintf(buf, "%s\t%s\t%s\t%s\t%s", label, op, mods, args, remarks);
}
else {
for (i = 0; i < 72; i++)
buf[i] = ' ';
buf[i] = '\0';
stuff(buf+20, label, 5);
stuff(buf+26, op, 4);
stuff(buf+31, mods, 2);
stuff(buf+34, args, 72-34);
}
}
// ---------------------------------------------------------------------------------
// lookup_op - find an opcode
// ---------------------------------------------------------------------------------
struct tag_op * lookup_op (char *mnem)
{
struct tag_op *op;
int i;
for (op = ops; op->mnem != NULL; op++) {
if ((i = strcmp(op->mnem, mnem)) == 0)
return op;
if (i > 0)
break;
}
return NULL;
}
// ---------------------------------------------------------------------------------
// bincard - routines to write IBM 1130 Card object format
// ---------------------------------------------------------------------------------
unsigned short bincard[54]; // the 54 data words that can fit on a binary format card
char binflag[45]; // the relocation flags of the 45 buffered object words (0, 1, 2, 3)
int bincard_n = 0; // number of object words stored in bincard (0-45)
int bincard_seq = 0; // card output sequence number
int bincard_org = 0; // origin of current card-full
int bincard_maxaddr = 0;
BOOL bincard_first = TRUE; // TRUE when we're to write the program type card
// bincard_init - prepare a new object data output card
void bincard_init (void)
{
memset(bincard, 0, sizeof(bincard)); // clear card data
memset(binflag, 0, sizeof(binflag)); // clear relocation data
bincard_n = 0; // no data
bincard[0] = bincard_org; // store load address
bincard_maxaddr = MAX(bincard_maxaddr, bincard_org-1); // save highest address written-to (this may be a BSS)
}
// binard_writecard - emit a card. sbrk_text = NULL for normal data cards, points to comment text for sbrk card
// note: sbrk_text if not NULL MUST be a writeable buffer of at LEAST 71 characters
void bincard_writecard (char *sbrk_text)
{
unsigned short binout[80];
char ident[12];
int i, j;
if (sbrk_text != NULL) { // sbrk card has 4 binary words followed by comment text
for (j = 66; j < 71; j++) // be sure input columns 67..71 are nonblank (have version number)
if (sbrk_text[j] <= ' ')
break;
if (j < 71) // sbrk card didn't have the info, stuff in current release
for (j = 0; j < 5; j++)
sbrk_text[66+j] = dmsversion[j];
binout[0] = 0;
binout[1] = 0;
binout[2] = 0;
binout[3] = 0x1000;
sbrk_text += 5; // start at the real column 6 (after *SBRK
for (j = 5; j < 72; j++)
binout[j] = (*sbrk_text) ? ascii_to_hollerith(*sbrk_text++) : 0;
}
else { // binary card format packs 54 words into 72 columns
for (i = j = 0; i < 54; i += 3, j += 4) {
binout[j ] = ( bincard[i] & 0xFFF0);
binout[j+1] = ((bincard[i] << 12) & 0xF000) | ((bincard[i+1] >> 4) & 0x0FF0);
binout[j+2] = ((bincard[i+1] << 8) & 0xFF00) | ((bincard[i+2] >> 8) & 0x00F0);
binout[j+3] = ((bincard[i+2] << 4) & 0xFFF0);
}
}
sprintf(ident, "%08ld", ++bincard_seq); // append sequence text
memmove(ident, progname, MIN(strlen(progname), 4));
for (i = 0; i < 8; i++)
binout[j++] = ascii_to_hollerith(ident[i]);
fxwrite(binout, sizeof(binout[0]), 80, fout); // write card image
}
// binard_writedata - emit an object data card
void bincard_writedata (void)
{
unsigned short rflag = 0;
int i, j, nflag = 0;
bincard[1] = 0; // checksum
bincard[2] = 0x0A00 | bincard_n; // data card type + word count
for (i = 0, j = 3; i < bincard_n; i++) { // construct relocation indicator bitmap
if (nflag == 8) {
bincard[j++] = rflag;
rflag = 0;
nflag = 0;
}
rflag = (rflag << 2) | (binflag[i] & 3);
nflag++;
}
if (nflag > 0)
bincard[j] = rflag << (16 - 2*nflag);
bincard_writecard(FALSE); // emit the card
}
// bincard_flush - flush any pending binary data
void bincard_flush (void)
{
if (bincard_n > 0)
bincard_writedata();
bincard_init();
}
// bincard_sbrk - emit an SBRK card
void bincard_sbrk (char *line)
{
if (bincard_first)
bincard_typecard();
else
bincard_flush();
bincard_writecard(line);
}
// bincard_setorg - set the origin
void bincard_setorg (int neworg)
{
bincard_org = neworg; // set origin for next card
bincard_flush(); // flush any current data & store origin
}
// bincard_endcard - write end of program card
void bincard_endcard (void)
{
bincard_flush();
bincard[0] = (bincard_maxaddr + 2) & ~1; // effective length: add 1 to max origin, then 1 more to round up
bincard[1] = 0;
bincard[2] = 0x0F00;
bincard[3] = pta & 0xFFFF;
bincard_writecard(NULL);
}
// bincard_typecard - write the program type
void bincard_typecard (void)
{
int i;
if (! bincard_first)
return;
bincard_first = FALSE;
memset(bincard, 0, sizeof(bincard));
bincard[2] = (unsigned short) ((progtype << 8) | intmode | realmode);
// all indices not listed are documented as 'reserved'
switch (progtype) {
case PROGTYPE_ABSOLUTE:
case PROGTYPE_RELOCATABLE:
// bincard[ 4] = 0; // length of common (fortran only)
bincard[ 5] = 0x0003;
// bincard[ 6] = 0; // length of work area (fortran only)
bincard[ 8] = ndefined_files;
namecode(&bincard[9], progname);
bincard[11] = (pta < 0) ? 0 : pta;
break;
case PROGTYPE_LIBF:
case PROGTYPE_CALL:
bincard[ 5] = 3*nentries;
for (i = 0; i < nentries; i++) {
namecode(&bincard[9+3*i], entry[i]->name);
bincard[11+3*i] = entry[i]->value;
}
break;
case PROGTYPE_ISSLIBF:
case PROGTYPE_ISSCALL:
bincard[ 5] = 6+nintlevels;
namecode(&bincard[9], entry[0]->name);
bincard[11] = entry[0]->value;
bincard[12] = iss_number + ISTV; // magic number ISTV is 0x33 in DMS R2V12
bincard[13] = iss_number;
bincard[14] = nintlevels;
bincard[15] = intlevel_primary;
bincard[16] = intlevel_secondary;
bincard[29] = 1;
break;
case PROGTYPE_ILS:
bincard[ 2] = (unsigned short) (progtype << 8);
bincard[ 5] = 4;
bincard[12] = intlevel_primary;
break;
default:
bail("in bincard_typecard, can't happen");
}
bincard[1] = 0; // checksum
bincard_writecard(NULL);
bincard_init();
}
// bincard_writew - write a word to the current output card.
void bincard_writew (int word, RELOC relative)
{
if (pass != 2)
return;
if (bincard_first)
bincard_typecard();
else if (bincard_n >= 45) // flush full card buffer
bincard_flush();
binflag[bincard_n] = relative & 3; // store relocation bits and data word
bincard[9+bincard_n++] = word;
if (relative != LIBF) {
bincard_maxaddr = MAX(bincard_maxaddr, bincard_org);
bincard_org++;
}
}
// writetwo - notification that we are about to write two words which must stay together
void writetwo (void)
{
if (pass == 2 && outmode == OUTMODE_BINARY && bincard_n >= 44)
bincard_flush();
}
// handle_sbrk - handle an SBRK directive.
// This was not part of the 1130 assembler; they assembled DMS on a 360
void handle_sbrk (char *line)
{
char rline[90];
if (pass != 2)
return;
strncpy(rline, line, 81); // get a copy and pad it if necessary to 80 characters
rline[80] = '\0';
while (strlen(rline) < 80)
strcat(rline, " ");
switch (outmode) {
case OUTMODE_LOAD:
fprintf(fout, "#SBRK%s\n", trim(rline+5));
case OUTMODE_BINARY:
bincard_sbrk(rline);
break;
default:
bail("in handle_sbrk, can't happen");
}
}
// ---------------------------------------------------------------------------------
// namecode - turn a string into a two-word packed name
// ---------------------------------------------------------------------------------
void namecode (unsigned short *words, char *tok)
{
long val = 0;
int i, ch;
for (i = 0; i < 5; i++) { // pick up bits
if (*tok)
ch = *tok++;
else
ch = ' ';
val = (val << 6) | (ascii_to_ebcdic_table[ch] & 0x3F);
}
words[0] = (unsigned short) (val >> 16);
words[1] = (unsigned short) val;
}
// ---------------------------------------------------------------------------------
// parse_line - parse one input line.
// ---------------------------------------------------------------------------------
void parse_line (char *line)
{
char label[100], mnem[100], arg[200], mods[20], *c;
struct tag_op *op;
if (line[0] == '/' && line[1] == '/') // job control card? probably best to ignore it
return;
if (line[0] == '*') { // control card comment or comment in tab-format file
if (check_control) // pay attention to control cards only at top of file
if (! controlcard(line))
check_control = FALSE; // first non-control card shuts off sensitivity to them
if (strnicmp(line+1, "SBRK", 4) == 0)
handle_sbrk(line);
return;
}
check_control = FALSE; // non-control card, consider them no more
label[0] = '\0'; // prepare to extract fields
mods[0] = '\0';
mnem[0] = '\0';
arg[0] = '\0';
if (tabformat || strchr(line, '\t') != NULL) { // if input line has tabs, parse loosely
tabformat = TRUE; // this is a tab-formatted file
for (c = line; *c && *c <= ' '; c++) // find first nonblank
;
if (*c == '*' || ! *c) // ignore as a comment
return;
tabtok(line, label, 0, NULL);
tabtok(line, mnem, 1, NULL);
tabtok(line, mods, 2, NULL);
tabtok(line, arg, 3, opfield);
}
else { // if no tabs, use strict card-column format
if (line[20] == '*') // comment
return;
line[72] = '\0'; // clip off sequence
coltok(line, label, 21, 25, TRUE, NULL);
coltok(line, mnem, 27, 30, TRUE, NULL);
coltok(line, mods, 32, 33, TRUE, NULL);
coltok(line, arg, 35, 72, FALSE, opfield);
}
// I don't know where I got this idea, but it's wrong...
// if (strchr(mods, '1') || strchr(mods, '2') || strchr(mods, '3')) { // index + X means ignore X
// if ((c = strchr(mods, 'X')) != NULL)
// strcpy(c, c+1); // remove the X
// }
if (*label) // display org in any line with a label
setw(0, org, FALSE);
if (! *mnem) { // label w/o mnemonic, just define the symbol
if (*label)
set_symbol(label, org, TRUE, relocate);
return;
}
if ((op = lookup_op(mnem)) == NULL) { // look up mnemonic
if (*label)
set_symbol(label, org, TRUE, relocate);// at least define the label
asm_error("Unknown opcode '%s'", mnem);
return;
}
if (op->flags & TRAP) // assembler debugging breakpoint
x_trap(op, label, mods, arg);
if (*op->mods_allowed != '\xFF') { // validate modifiers against list of allowed characters
for (c = mods; *c; ) {
if (strchr(op->mods_allowed, *c) == NULL) {
asm_warning("Modifier '%c' not permitted", *c);
strcpy(c, c+1); // remove it and keep parsing
}
else
c++;
}
}
strcat(mods, op->mods_implied); // tack on implied modifiers
if (strchr(mods, 'I')) // indirect implies long
strcat(mods, "L");
requires_even_address = op->flags & IS_DBL;
org_advanced = strchr(mods, 'L') ? 2 : 1; // by default, * means address + 1 or 2. Sometimes it doesn't
(op->handler)(op, label, mods, arg);
if ((op->flags & IS_1800) && ! enable_1800)
asm_warning("%s is IBM 1800-specific; use the -8 command line option", op->mnem);
}
// ---------------------------------------------------------------------------------
// get one input line from current file or macro
// ---------------------------------------------------------------------------------
BOOL get_line (char *buf, int nbuf, BOOL onelevel)
{
char *retval;
if (ended) // we hit the END command
return FALSE;
// if macro active, return line from macro buffer, otherwise read from file
// do not pop end-of-macro if onelevel is TRUE
if ((retval = fgets(buf, nbuf, fin)) == NULL)
return FALSE;
lno++; // count the line
return TRUE;
}
// ---------------------------------------------------------------------------------
// proc - process one pass of one source file
// ---------------------------------------------------------------------------------
void proc (char *fname)
{
char line[256], *c;
int i;
if (strchr(fname, '.') == NULL) // if input file has no extension,
addextn(fname, ".asm", curfn); // set appropriate file extension
else
strcpy(curfn, fname); // otherwise use extension specified
// let's leave filename case alone even if it doesn't matter
//#if (defined(_WIN32) || defined(VMS))
// upcase(curfn); // only force uppercase of name on Windows and VMS
//#endif
if (progname[0] == '\0') { // pick up primary filename
if ((c = strrchr(curfn, '\\')) == NULL)
if ((c = strrchr(curfn, '/')) == NULL)
if ((c = strrchr(curfn, ':')) == NULL)
c = curfn;
strncpy(progname, c, sizeof(progname)); // take name after path
progname[sizeof(progname)-1] = '\0';
if ((c = strchr(progname, '.')) != NULL)// remove extension
*c = '\0';
}
lno = 0; // reset global input line number
ended = FALSE; // have not seen END statement
if (listfn == NULL) // if list file name is undefined,
listfn = addextn(fname, ".lst", NULL); // create from first filename
if (verbose)
fprintf(stderr, "--- Starting file %s pass %d\n", curfn, pass);
if ((fin = fopen(curfn, "r")) == NULL) {
perror(curfn); // oops
exit(1);
}
if (flist) { // put banner in listing file
strcpy(listline,"=== FILE ======================================================================");
for (i = 9, c = curfn; *c;)
listline[i++] = *c++;
listline[i] = ' ';
fputs(listline, flist);
putc('\n', flist);
list_on = TRUE;
}
// read all lines till EOF or END statement
while (get_line(line, sizeof(line), FALSE)) {
prep_line(line); // preform standard line prep
parse_line(line); // parse
listout(FALSE); // complete the listing
}
fclose(fin);
if (n_literals > 0) { // force out any pending literal constants at end of file
output_literals(TRUE);
listout(FALSE);
}
}
// ---------------------------------------------------------------------------------
// prep_line - prepare input line for parsing
// ---------------------------------------------------------------------------------
void prep_line (char *line)
{
char *c;
upcase(line); // uppercase it
nwout = 0; // number of words output so far
line_error = FALSE; // no errors on this line so far
for (c = line; *c; c++) { // truncate at newline
if (*c == '\r' || *c == '\n') {
*c = '\0';
break;
}
}
if (flist && list_on) { // construct beginning of listing line
if (tabformat)
sprintf(listline, LINEFORMAT, lno, detab(line));
else {
if (strlen(line) > 20) // get the part where the commands start
c = line+20;
else
c = "";
sprintf(listline, LINEFORMAT, lno, c);
stuff(listline, line, 20); // stuff the left margin in to the left side
}
}
}
// ---------------------------------------------------------------------------------
// opcmp - operand name comparison routine for qsort
// ---------------------------------------------------------------------------------
int opcmp (const void *a, const void *b)
{
return strcmp(((struct tag_op *) a)->mnem, ((struct tag_op *) b)->mnem);
}
// ---------------------------------------------------------------------------------
// preload_symbols - load a saved symbol table
// ---------------------------------------------------------------------------------
void preload_symbols (void)
{
FILE *fd;
char str[200], sym[20];
int v;
static BOOL preloaded_already = FALSE;
if (pass > 1 || preloaded_already)
return;
preloaded_already = TRUE;
if ((fd = fopen(SYSTEM_TABLE, "r")) == NULL) // read the system symbol tabl
perror(SYSTEM_TABLE);
else {
while (fgets(str, sizeof(str), fd) != NULL) {
if (sscanf(str, "%s %x", sym, &v) == 2)
set_symbol(sym, v, TRUE, FALSE);
}
fclose(fd);
}
}
// ---------------------------------------------------------------------------------
// save_symbols - save a symbol table
// ---------------------------------------------------------------------------------
void save_symbols (void)
{
FILE *fd;
char str[20];
PSYMBOL s;
if (relocate) {
fprintf(stderr, "Can't save symbol table unless ABS assembly\n");
return;
}
if ((fd = fopen(SYSTEM_TABLE, "r")) != NULL) {
fclose(fd);
if (saveprompt) {
printf("Overwrite system symbol table %s? ", SYSTEM_TABLE);
fgets(str, sizeof(str), stdin);
if (str[0] != 'y' && str[0] != 'Y')
return;
}
unlink(SYSTEM_TABLE);
}
if ((fd = fopen(SYSTEM_TABLE, "w")) == NULL) {
perror(SYSTEM_TABLE);
return;
}
for (s = symbols; s != NULL; s = s->next)
fprintf(fd, "%-5s %04x\n", s->name, s->value);
fclose(fd);
}
// ---------------------------------------------------------------------------------
// startpass - initialize data structures, prepare to start a pass
// ---------------------------------------------------------------------------------
void startpass (int n)
{
int nops;
struct tag_op *p;
pass = n; // reset globals: pass number
nerrors = 0; // error count
org = 0; // load address (origin)
lno = 0; // input line number
relocate = TRUE; // relocatable assembly mode
assembled = FALSE; // true if any output has been generated
list_on = do_list; // listing enable
dmes_saved = FALSE; // partial character strings output
n_literals = 0; // literal values pending output
lit_tag = 0;
if (pass == 1) { // first pass only
for (nops = 0, p = ops; p->mnem != NULL; p++, nops++) // count opcodes
;
qsort(ops, nops, sizeof(*p), opcmp); // sort the opcode table
if (preload)
preload_symbols();
}
else { // second pass only
if (outfn == NULL)
outfn = addextn(curfn, (outmode == OUTMODE_LOAD) ? ".out" : ".bin" , NULL);
if ((fout = fopen(outfn, OUTWRITEMODE)) == NULL) { // open output file
perror(outfn);
exit(1);
}
if (do_list) { // open listing file
if ((flist = fopen(listfn, "w")) == NULL) {
perror(listfn);
exit(1);
}
listhdr(); // print banner
}
}
}
// ---------------------------------------------------------------------------------
// x_dc - DC define constant directive
// ---------------------------------------------------------------------------------
void x_dc (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
// char *tok;
org_advanced = 1; // assume * means this address+1
// doesn't make sense, but I think I found DMS listings to support it
if (strchr(mods, 'E') != NULL) // force even address
org_even();
setw(0, org, FALSE); // display org in listing line
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
// just one!?
getexpr(arg, FALSE, &expr);
writew(expr.value, expr.relative); // store value
// pick up values, comma delimited
// for (tok = strtok(arg, ","); tok != NULL; tok = strtok(NULL, ",")) {
// getexpr(tok, FALSE, &expr);
// writew(expr.value, expr.relative); // store value
// }
}
// ---------------------------------------------------------------------------------
// x_dec - DEC define double word constant directive.
// ---------------------------------------------------------------------------------
// wd[0]: 8 unused bits | characteristic (= exponent+128)
// wd[1]: sign + 15 msb of mantissa in 2's complement
// wd[2]: 16 lsb of mantissa
// NOTE: these are wrong with Fixed point numbers
void convert_double_to_extended (double d, unsigned short *wd)
{
int neg, exp;
unsigned long mantissa;
unsigned char *byte = (unsigned char *) &d;
if (d == 0.) {
wd[0] = wd[1] = wd[2] = 0;
return;
}
// 7 6 5 4 0
// d = ansi real*8 SXXX XXXX XXXX MMMM MMMM MMMM MMMM MMMM ... MMMM MMMM
neg = byte[7] & 0x80;
exp = ((byte[7] & 0x7F) << 4) | ((byte[6] & 0xF0) >> 4); // extract exponent
exp -= 1023; // remove bias
exp++; // shift to account for implied 1 we added
// get 32 bits worth of mantissa. add the implied point
mantissa = 0x80000000L | ((byte[6] & 0x0F) << 27) | (byte[5] << 19) | (byte[4] << 11) | (byte[3] << 3) | ((byte[2] & 0xE0) >> 5);
if (mantissa & (0x80000000L >> 31)) // keep 31 bits, round if necessary
mantissa += (0x80000000L >> 31);
mantissa >>= (32-31); // get into low 31 bits
// now turn into IBM 1130 extended precision
exp += 128;
if (neg)
mantissa = (unsigned long) (- (long) mantissa); // two's complement
wd[0] = (unsigned short) (exp & 0xFF);
wd[1] = (unsigned short) ((neg ? 0x8000 : 0) | ((mantissa >> (31-15)) & 0x7FFF));
wd[2] = (unsigned short) (mantissa & 0xFFFF);
}
// ---------------------------------------------------------------------------------
// ---------------------------------------------------------------------------------
void convert_double_to_standard (double d, unsigned short *wd)
{
int neg, exp;
unsigned long mantissa;
unsigned char *byte = (unsigned char *) &d;
if (d == 0.) {
wd[0] = wd[1] = 0;
return;
}
// 7 6 5 4 0
// d = ansi real*8 SXXX XXXX XXXX MMMM MMMM MMMM MMMM MMMM ... MMMM MMMM
neg = byte[7] & 0x80;
exp = ((byte[7] & 0x7F) << 4) | ((byte[6] & 0xF0) >> 4); // extract exponent
exp -= 1023; // remove bias
exp++; // shift to account for implied 1 we added
// get 32 bits worth of mantissa. add the implied point
mantissa = 0x80000000L | ((byte[6] & 0x0F) << 27) | (byte[5] << 19) | (byte[4] << 11) | (byte[3] << 3) | ((byte[2] & 0xE0) >> 5);
// if (mantissa & (0x80000000L >> 23)) // keep 23 bits, round if necessary
// mantissa += (0x80000000L >> 23);
// DEBUG
// printf("%8.4lf: %08lx %d\n", d, mantissa, exp);
mantissa >>= (32-23); // get into low 23 bits
// now turn into IBM 1130 standard precision
exp += 128;
if (neg)
mantissa = (unsigned long) (- (long) mantissa); // two's complement
wd[0] = (unsigned short) ((neg ? 0x8000 : 0) | ((mantissa >> (23-15)) & 0x7FFF));
wd[1] = (unsigned short) ((mantissa & 0x00FF) << 8) | (exp & 0xFF);
// DEBUG
// printf(" D %04x%04x\n", wd[0], wd[1]);
}
// ---------------------------------------------------------------------------------
// ---------------------------------------------------------------------------------
void convert_double_to_fixed (double d, unsigned short *wd, int bexp)
{
int neg, exp, rshift;
unsigned long mantissa;
unsigned char *byte = (unsigned char *) &d;
if (d == 0.) {
wd[0] = wd[1] = 0;
return;
}
// note: we assume that this computer uses ANSI floating point
// 7 6 5 4 0
// d = ansi real*8 SXXX XXXX XXXX MMMM MMMM MMMM MMMM MMMM ... MMMM MMMM
neg = byte[7] & 0x80;
exp = ((byte[7] & 0x7F) << 4) | ((byte[6] & 0xF0) >> 4); // extract exponent
exp -= 1023; // remove bias
exp++; // shift to account for implied 1 we added
// get 32 bits worth of mantissa. add the implied point
mantissa = 0x80000000L | ((byte[6] & 0x0F) << 27) | (byte[5] << 19) | (byte[4] << 11) | (byte[3] << 3) | ((byte[2] & 0xE0) >> 5);
mantissa >>= 1; // shift it out of the sign bit
// DEBUG
// printf("%8.4lf: %08lx %d\n", d, mantissa, exp);
rshift = bexp - exp;
if (rshift > 0) {
mantissa >>= rshift;
}
else if (rshift < 0) {
mantissa >>= (-rshift);
asm_warning("Fixed point overflow");
}
if (neg)
mantissa = (unsigned long) (- (long) mantissa); // two's complement
// DEBUG
// printf(" B %08lx\n", mantissa);
wd[0] = (unsigned short) ((mantissa >> 16) & 0xFFFF); // return all of the bits; no exponent here
wd[1] = (unsigned short) (mantissa & 0xFFFF);
}
// ---------------------------------------------------------------------------------
// ---------------------------------------------------------------------------------
void getDconstant (char *tok, unsigned short *wd)
{
unsigned long l;
char *b, *fmt;
double d;
int bexp, fixed;
wd[0] = 0;
wd[1] = 0;
if (strchr(tok, '.') == NULL && strchr(tok, 'B') == NULL && strchr(tok, 'E') == NULL) {
fmt = "%ld";
if (*tok == '/') { // I don't see that this is legal but can't hurt to allow it
fmt = "%lx";
tok++;
}
if (sscanf(tok, fmt, &l) != 1) { // no decimal means it's an integer?
asm_error("Syntax error in constant");
}
else {
wd[0] = (unsigned short) ((l >> 16) & 0xFFFF); // high word
wd[1] = (unsigned short) (l & 0xFFFF); // low word
}
return;
}
fixed = 0;
if ((b = strchr(tok, 'B')) != NULL) {
fixed = 1;
bexp = atoi(b+1);
*b = '\0'; // truncate at the b
}
if (sscanf(tok, "%lg", &d) != 1) {
asm_error("Syntax error in constant");
return;
}
if (fixed)
convert_double_to_fixed(d, wd, bexp);
else
convert_double_to_standard(d, wd);
}
// ---------------------------------------------------------------------------------
// If the input value is an integer with no decimal point and no B or E,
// DEC generates a double INTEGER value.
// IBM documentation ranges from ambiguous to wrong on this point, but
// examination of the DMS microfiche supports this.
// ---------------------------------------------------------------------------------
void x_dec (struct tag_op *op, char *label, char *mods, char *arg)
{
unsigned short wd[2];
org_advanced = 2; // assume * means address after this location, since it's +1 for dc?
org_even(); // even address is implied
setw(0, org, FALSE); // display the origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
// just one!?
getDconstant(arg, wd);
writew(wd[0], FALSE); // write hiword, then loword
writew(wd[1], FALSE);
// pick up values, comma delimited
// for (tok = strtok(arg, ","); tok != NULL; tok = strtok(NULL, ",")) {
// getDconstant(tok, wd);
//
// writew(wd[0], FALSE); // write hiword, then loword
// writew(wd[1], FALSE);
}
// ---------------------------------------------------------------------------------
// DECS directive. Writes just the high word of a DEC value
// ---------------------------------------------------------------------------------
void x_decs (struct tag_op *op, char *label, char *mods, char *arg)
{
unsigned short wd[2];
org_advanced = 1; // assume * means address after this location
setw(0, org, FALSE); // display the origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
getDconstant(arg, wd);
writew(wd[0], FALSE); // write hiword ONLY
}
// ---------------------------------------------------------------------------------
// ---------------------------------------------------------------------------------
void x_xflc (struct tag_op *op, char *label, char *mods, char *arg)
{
char *tok, *b;
double d;
int bexp, fixed;
unsigned short wd[3];
org_advanced = 2; // who knows?
setw(0, org, FALSE); // display the origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
// pick up values, comma delimited
for (tok = strtok(arg, ","); tok != NULL; tok = strtok(NULL, ",")) {
bexp = 0;
if ((b = strchr(tok, 'B')) != NULL) {
bexp = atoi(b+1);
fixed = TRUE;
*b = '\0'; // truncate at the b
asm_warning("Fixed point extended floating constant?");
}
if (sscanf(tok, "%lg", &d) != 1) {
asm_error("Syntax error in constant");
d = 0.;
}
convert_double_to_extended(d, wd);
writew(wd[0], ABSOLUTE);
writew(wd[1], ABSOLUTE);
writew(wd[2], ABSOLUTE);
}
}
// ---------------------------------------------------------------------------------
// x_equ - EQU directive
// ---------------------------------------------------------------------------------
void x_equ (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
org_advanced = FALSE; // * means this address, not incremented
getexpr(arg, FALSE, &expr);
setw(0, expr.value, expr.relative); // show this as address
if (*label) // EQU is all about defining labels, better have one
set_symbol(label, expr.value, TRUE, expr.relative);
// else // IBM assembler doesn't complain about this
// asm_error("EQU without label?");
}
// ---------------------------------------------------------------------------------
// x_lorg - LORG directive -- output queued literal values
// ---------------------------------------------------------------------------------
void x_lorg (struct tag_op *op, char *label, char *mods, char *arg)
{
org_advanced = FALSE; // * means this address (not used, though)
output_literals(FALSE); // generate .DC's for queued literal values
}
// ---------------------------------------------------------------------------------
// x_abs - ABS directive
// ---------------------------------------------------------------------------------
void x_abs (struct tag_op *op, char *label, char *mods, char *arg)
{
if (assembled)
asm_error("ABS must be first statement");
relocate = ABSOLUTE;
switch (progtype) {
case PROGTYPE_ABSOLUTE:
case PROGTYPE_RELOCATABLE:
progtype = PROGTYPE_ABSOLUTE; // change program type, still assumed to be mainline
break;
case PROGTYPE_LIBF:
case PROGTYPE_CALL:
case PROGTYPE_ISSLIBF:
case PROGTYPE_ISSCALL:
case PROGTYPE_ILS:
asm_error("ABS not allowed with LIBF, ENT, ILS or ISS");
break;
default:
bail("in x_libr, can't happen");
}
}
// ---------------------------------------------------------------------------------
// x_call - ORG pseudo-op
// ---------------------------------------------------------------------------------
void x_call (struct tag_op *op, char *label, char *mods, char *arg)
{
unsigned short words[2];
static struct tag_op *bsi = NULL;
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (! *arg) {
asm_error("CALL missing argument");
return;
}
if (pass == 1) { // it will take two words in any case
org += 2;
return;
}
setw(0, org, FALSE); // display origin
if (lookup_symbol(arg, FALSE) != NULL) { // it's a defined symbol?
if (bsi == NULL)
if ((bsi = lookup_op("BSI")) == NULL)
bail("Can't find BSI op");
(bsi->handler)(bsi, "", "L", arg);
}
else {
namecode(words, arg); // emit namecode for loader
writetwo();
writew(words[0], CALL);
writew(words[1], ABSOLUTE);
}
}
// ---------------------------------------------------------------------------------
// x_org - ORG directive
// ---------------------------------------------------------------------------------
void x_org (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
org_advanced = FALSE; // * means this address
if (*label) // label is defined BEFORE the new origin is set!!!
set_symbol(label, org, TRUE, relocate);
if (getexpr(arg, FALSE, &expr) != S_DEFINED)
return;
setorg(expr.value); // set origin to this value
}
// ---------------------------------------------------------------------------------
// x_end - END directive
// ---------------------------------------------------------------------------------
void x_end (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
org_advanced = FALSE; // * means this address
if (*arg) { // they're specifing the program start address
if (getexpr(arg, FALSE, &expr) == S_DEFINED)
pta = expr.value;
}
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
setw(0, org, FALSE); // display origin
ended = TRUE; // assembly is done, stop reading file
}
// ---------------------------------------------------------------------------------
// x_ent - ENT op
// ---------------------------------------------------------------------------------
void x_ent (struct tag_op *op, char *label, char *mods, char *arg)
{
PSYMBOL s;
org_advanced = FALSE; // * means this address
if (pass < 2)
return;
// if (*label) // define label
// set_symbol(label, org, TRUE, relocate);
//
// setw(0, org, FALSE); // display origin
if (! *arg)
asm_error("No entry label specified");
else if ((s = lookup_symbol(arg, FALSE)) == NULL)
asm_error("Entry symbol %s not defined", arg);
else if (nentries >= MAXENTRIES)
asm_error("Too many entries, limit is %d", MAXENTRIES);
else
entry[nentries++] = s; // save symbol pointer
switch (progtype) {
case PROGTYPE_ABSOLUTE:
asm_error("ENT not allowed with ABS");
break;
case PROGTYPE_RELOCATABLE:
progtype = PROGTYPE_CALL;
break;
case PROGTYPE_LIBF:
case PROGTYPE_CALL:
case PROGTYPE_ISSLIBF:
case PROGTYPE_ISSCALL:
break;
case PROGTYPE_ILS:
asm_error("Can't mix ENT and ILS, can you?");
break;
default:
bail("in x_libr, can't happen");
}
}
// ---------------------------------------------------------------------------------
// declare a libf-type subprogram
// ---------------------------------------------------------------------------------
void x_libr (struct tag_op *op, char *label, char *mods, char *arg)
{
switch (progtype) {
case PROGTYPE_ABSOLUTE:
asm_error("LIBR not allowed with ABS");
break;
case PROGTYPE_RELOCATABLE:
case PROGTYPE_LIBF:
case PROGTYPE_CALL:
progtype = PROGTYPE_LIBF;
break;
case PROGTYPE_ISSLIBF:
case PROGTYPE_ISSCALL:
progtype = PROGTYPE_ISSLIBF;
break;
case PROGTYPE_ILS:
asm_error("Can't use LIBR in an ILS");
break;
default:
bail("in x_libr, can't happen");
}
}
// ---------------------------------------------------------------------------------
// x_ils - ILS directive
// ---------------------------------------------------------------------------------
void x_ils (struct tag_op *op, char *label, char *mods, char *arg)
{
switch (progtype) {
case PROGTYPE_ABSOLUTE:
asm_error("ILS not allowed with ABS");
break;
case PROGTYPE_RELOCATABLE:
case PROGTYPE_ILS:
progtype = PROGTYPE_ILS;
break;
case PROGTYPE_LIBF:
case PROGTYPE_CALL:
asm_error("Invalid placement of ILS");
break;
case PROGTYPE_ISSLIBF:
case PROGTYPE_ISSCALL:
break;
default:
bail("in x_libr, can't happen");
}
intlevel_primary = atoi(mods);
}
// ---------------------------------------------------------------------------------
// x_iss - ISS directive
// ---------------------------------------------------------------------------------
void x_iss (struct tag_op *op, char *label, char *mods, char *arg)
{
char *tok;
switch (progtype) {
case PROGTYPE_ABSOLUTE:
asm_error("ISS not allowed with ABS");
break;
case PROGTYPE_RELOCATABLE:
case PROGTYPE_CALL:
case PROGTYPE_ISSCALL:
progtype = PROGTYPE_ISSCALL;
break;
case PROGTYPE_LIBF:
case PROGTYPE_ISSLIBF:
progtype = PROGTYPE_ISSLIBF;
break;
case PROGTYPE_ILS:
asm_error("Can't mix ISS and ILS");
default:
bail("in x_libr, can't happen");
}
iss_number = atoi(mods); // get ISS number
opfield[16] = '\0'; // be sure not to look too far into this
nintlevels = 0; // # of interrupt levels for ISS
intlevel_primary = 0; // primary level for ISS and level for ILS
intlevel_secondary = 0; // secondary level for ISS
if ((tok = strtok(opfield, " ")) == NULL)
asm_error("ISS missing entry label");
else
x_ent(NULL, label, "", arg); // process as an ENT
if ((tok = strtok(NULL, " ")) != NULL) { // get associated levels
nintlevels++;
intlevel_primary = atoi(tok);
}
if ((tok = strtok(NULL, " ")) != NULL) {
nintlevels++;
intlevel_secondary = atoi(tok);
}
}
void x_spr (struct tag_op *op, char *label, char *mods, char *arg)
{
realmode = REALMODE_STANDARD;
}
void x_epr (struct tag_op *op, char *label, char *mods, char *arg)
{
realmode = REALMODE_EXTENDED;
}
void x_dsa (struct tag_op *op, char *label, char *mods, char *arg)
{
unsigned short words[2];
setw(0, org, FALSE); // display origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (! *arg) {
asm_error("DSA missing filename");
}
else {
namecode(words, arg);
writetwo();
writew(words[0], CALL); // special relocation bits here 3 and 1
writew(words[1], RELATIVE);
}
}
void x_link (struct tag_op *op, char *label, char *mods, char *arg)
{
unsigned short words[2];
char nline[128];
setw(0, org, FALSE); // display origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (! *arg) {
asm_error("LINK missing program name");
}
else {
format_line(nline, label, "CALL", "", "$LINK", "");
parse_line(nline);
namecode(words, arg);
writew(words[0], ABSOLUTE); // special relocation bits here 3 and 1
writew(words[1], ABSOLUTE);
}
}
void x_libf (struct tag_op *op, char *label, char *mods, char *arg)
{
unsigned short words[2];
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (! *arg) {
asm_error("LIBF missing argument");
return;
}
if (pass == 1) { // it will take one words in any case
org++;
return;
}
setw(0, org, FALSE); // display origin
namecode(words, arg); // emit namecode for loader
writetwo();
writew(words[0], LIBF); // this one does NOT advance org!
writew(words[1], ABSOLUTE);
}
void x_file (struct tag_op *op, char *label, char *mods, char *arg)
{
int i, n, r;
EXPR vals[5];
char *tok;
for (i = 0; i < 5; i++) {
if ((tok = strtok(arg, ",")) == NULL) {
asm_error("FILE has insufficient arguments");
return;
}
arg = NULL; // for next strtok call
if (i == 3) {
if (strcmpi(tok, "U") != 0)
asm_error("Argument 4 must be the letter U");
}
else if (getexpr(tok, FALSE, &vals[i]) == S_DEFINED) {
if (i <= 3 && vals[i].relative)
asm_error("Argument %d must be absolute", i+1);
else if (pass == 2 && vals[i].value == 0)
asm_error("Argument %d must be nonzero", i+1);
}
}
writew(vals[0].value, ABSOLUTE);
writew(vals[1].value, ABSOLUTE);
writew(vals[2].value, ABSOLUTE);
writew(vals[4].value, vals[i].relative);
writew(0, ABSOLUTE);
n = MAX(1, vals[2].value);
r = 320/n;
writew(r, ABSOLUTE);
r = MAX(1, r);
writew((16*vals[1].value)/r, ABSOLUTE);
if (pass == 2)
ndefined_files++;
}
// ---------------------------------------------------------------------------------
// x_trap - place to set a breakpoint
// ---------------------------------------------------------------------------------
void x_trap (struct tag_op *op, char *label, char *mods, char *arg)
{
// debugging breakpoint
}
// ---------------------------------------------------------------------------------
// x_ces - .CES directive (nonstandard). Specify a value for the console entry
// switches. When this program is loaded into the simulator, the switches will
// be set accordingly. Handy for bootstraps and other programs that read
// the switches.
// ---------------------------------------------------------------------------------
void x_ces (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
if (outmode != OUTMODE_LOAD) // this works only in our loader format
return;
if (getexpr(arg, FALSE, &expr) != S_DEFINED)
return;
if (pass == 2)
fprintf(fout, "S%04x" ENDLINE, expr.value & 0xFFFF);
}
// ---------------------------------------------------------------------------------
// x_bss - BSS directive - reserve space in core
// ---------------------------------------------------------------------------------
void x_bss (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
org_advanced = FALSE; // * means this address
if (! *arg) {
expr.value = 0;
expr.relative = ABSOLUTE;
}
else if (getexpr(arg, FALSE, &expr) != S_DEFINED)
return;
if (strchr(mods, 'E') != NULL) // force even address
org_even();
if (expr.relative)
asm_error("BSS size must be an absolute value");
setw(0, org, FALSE); // display origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
expr.value &= 0xFFFF; // truncate to 16 bits
if (expr.value & 0x8000)
asm_warning("Negative BSS size");
else if (expr.value > 0) {
if (outmode == OUTMODE_LOAD) {
org += expr.value; // advance the origin by appropriate number of words
if (pass == 2) // emit new load address in output file
fprintf(fout, "@%04x%s" ENDLINE, org & 0xFFFF, relocate ? "R" : "");
}
else {
org += expr.value; // advance the origin by appropriate number of words
if (pass == 2)
bincard_setorg(org);
}
}
}
// ---------------------------------------------------------------------------------
// x_bes - Block Ended by Symbol directive. Like BSS but label gets address AFTER the space, instead of first address
// ---------------------------------------------------------------------------------
void x_bes (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
org_advanced = FALSE; // * means this address
if (! *arg) { // arg field = space
expr.value = 0;
expr.relative = ABSOLUTE;
}
else if (getexpr(arg, FALSE, &expr) != S_DEFINED)
return;
if (strchr(mods, 'E') != NULL && (org & 1) != 0)
org_even(); // force even address
if (expr.relative)
asm_error("BES size must be an absolute value");
if (expr.value < 0)
asm_warning("Negative BES size");
else if (expr.value > 0) {
setw(0, org+expr.value, FALSE); // display NEW origin
if (outmode == OUTMODE_LOAD) {
org += expr.value; // advance the origin
if (pass == 2) // emit new load address in output file
fprintf(fout, "@%04x%s" ENDLINE, org & 0xFFFF, relocate ? "R" : "");
}
else {
org += expr.value; // advance the origin
bincard_setorg(org);
}
}
if (*label) // NOW define the label
set_symbol(label, org, TRUE, relocate);
}
// ---------------------------------------------------------------------------------
// x_dmes - DMES define message directive. Various encodings, none pretty.
// ---------------------------------------------------------------------------------
int dmes_wd;
int dmes_nc;
enum {CODESET_CONSOLE, CODESET_1403, CODESET_1132, CODESET_EBCDIC} dmes_cs;
void stuff_dmes (int ch, int rpt);
void x_dmes (struct tag_op *op, char *label, char *mods, char *arg)
{
int rpt;
char *c = opfield;
BOOL cont = FALSE;
if (dmes_saved) { // previous DMES had an odd character saved
dmes_wd = dmes_savew;
dmes_nc = 1; // stick it into the outbut buffer
}
else
dmes_nc = dmes_wd = 0; // clear output buffer
trim(opfield); // remove trailing blanks from rest of input line (use whole thing)
setw(0, org, FALSE); // display origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (strchr(mods, '1') != NULL) // determine the encoding scheme
dmes_cs = CODESET_1403;
else if (strchr(mods, '2') != NULL)
dmes_cs = CODESET_1132;
else if (strchr(mods, '0') != NULL || ! *mods)
dmes_cs = CODESET_CONSOLE;
else {
asm_error("Invalid printer code in tag field");
dmes_cs = CODESET_EBCDIC;
}
while (*c) { // pick up characters
if (*c == '\'') { // quote (') is the escape character
c++;
rpt = 0; // get repeat count
while (BETWEEN(*c, '0', '9')) {
rpt = rpt*10 + *c++ - '0';
}
if (rpt <= 0) // no count = insert one copy
rpt = 1;
switch (*c) { // handle escape codes
case '\'':
stuff_dmes(*c, 1);
break;
case 'E':
*c = '\0'; // end
break;
case 'X':
case 'S':
stuff_dmes(' ', rpt);
break;
case 'F':
stuff_dmes(*++c, rpt); // repeat character
break;
case ' ':
case '\0':
cont = TRUE;
*c = '\0'; // end
break;
case 'T':
if (dmes_cs != CODESET_CONSOLE) {
badcode: asm_error("Invalid ' escape for selected printer");
break;
}
stuff_dmes(0x41, -rpt); // tab
break;
case 'D':
if (dmes_cs != CODESET_CONSOLE) goto badcode;
stuff_dmes(0x11, -rpt); // backspace
break;
case 'B':
if (dmes_cs != CODESET_CONSOLE) goto badcode;
stuff_dmes(0x05, -rpt); // black
break;
case 'A':
if (dmes_cs != CODESET_CONSOLE) goto badcode;
stuff_dmes(0x09, -rpt); // red
break;
case 'R':
if (dmes_cs != CODESET_CONSOLE) goto badcode;
stuff_dmes(0x81, -rpt); // return
break;
case 'L':
if (dmes_cs != CODESET_CONSOLE) goto badcode;
stuff_dmes(0x03, -rpt); // line feed
break;
default:
asm_error("Invalid ' escape in DMES");
*c = '\0';
break;
}
}
else // just copy literal character
stuff_dmes(*c, 1);
if (*c)
c++;
}
dmes_saved = FALSE;
if (dmes_nc) { // odd number of characters
if (cont) {
dmes_saved = TRUE;
dmes_savew = dmes_wd; // save for next time
}
else
stuff_dmes(' ', 1); // pad with a space to force out even # of characters
}
}
// ---------------------------------------------------------------------------------
// stuff_dmes - insert 'rpt' copies of character 'ch' into output words
// ---------------------------------------------------------------------------------
void stuff_dmes (int ch, int rpt)
{
int nch, i; // nch is translated output value
if (rpt < 0) { // negative repeat means no translation needed
rpt = -rpt;
nch = ch;
}
else {
switch (dmes_cs) {
case CODESET_CONSOLE:
nch = 0x21;
for (i = 0; i < 256; i++) {
if (conout_to_ascii[i] == ch) {
nch = i;
break;
}
}
break;
case CODESET_EBCDIC:
nch = ascii_to_ebcdic_table[ch & 0x7F];
if (nch == 0)
nch = 0x7F;
break;
case CODESET_1403:
nch = ascii_to_1403_table[ch & 0x7F];
if (nch == 0)
nch = 0x7F;
break;
case CODESET_1132:
nch = 0x40;
for (i = 0; i < WHEELCHARS_1132; i++) {
if (codewheel1132[i].ascii == ch) {
nch = codewheel1132[i].ebcdic;
break;
}
}
break;
default:
bail("bad cs in x_dmes, can't happen");
break;
}
}
while (--rpt >= 0) { // pack them into words, output when we have two
if (dmes_nc == 0) {
dmes_wd = (nch & 0xFF) << 8;
dmes_nc = 1;
}
else {
dmes_wd |= (nch & 0xFF);
writew(dmes_wd, FALSE);
dmes_nc = 0;
}
}
}
// ---------------------------------------------------------------------------------
// x_ebc - handle EBCDIC string definition (delimited with periods)
// ---------------------------------------------------------------------------------
void x_ebc (struct tag_op *op, char *label, char *mods, char *arg)
{
char *p;
// setw(0, org, FALSE);
if (*label)
set_symbol(label, org, TRUE, relocate);
p = trim(opfield); // remove trailing blanks from rest of input line (use whole thing)
if (*p != '.') {
asm_error("EBC data must start with .");
return;
}
p++; // skip leading period
dmes_nc = dmes_wd = 0; // clear output buffer (we're borrowing the DMES packer)
dmes_cs = CODESET_EBCDIC;
while (*p && *p != '.') // store packed ebcdic
stuff_dmes(*p++, 1);
if (dmes_nc) // odd number of characters
stuff_dmes(' ', 1); // pad with a space to force out even # of characters
if (*p != '.')
asm_error("EBC missing closing .");
}
// ---------------------------------------------------------------------------------
// x_dn - define name DN directive. Pack 5 characters into two words. This by the
// way is the reason the language Forth is not Fourth.
// ---------------------------------------------------------------------------------
void x_dn (struct tag_op *op, char *label, char *mods, char *arg)
{
unsigned short words[2];
setw(0, org, FALSE); // display origin
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
namecode(words, arg);
writew(words[0], ABSOLUTE);
writew(words[1], ABSOLUTE);
}
// ---------------------------------------------------------------------------------
// x_dump - DUMP directive - pretend we saw "call $dump, call $exit"
// ---------------------------------------------------------------------------------
void x_dump (struct tag_op *op, char *label, char *mods, char *arg)
{
x_pdmp(op, label, mods, arg);
x_exit(NULL, "", "", ""); // compile "call $exit"
}
// ---------------------------------------------------------------------------------
// x_pdmp - PDMP directive - like DUMP but without the call $exit
// ---------------------------------------------------------------------------------
void x_pdmp (struct tag_op *op, char *label, char *mods, char *arg)
{
char nline[200], *tok;
EXPR addr[3];
int i;
for (i = 0, tok = strtok(arg, ","); i < 3 && tok != NULL; i++, tok = strtok(NULL, ",")) {
if (getexpr(tok, FALSE, addr+i) != S_DEFINED) {
addr[i].value = (i == 1) ? 0x3FFF : 0;
addr[i].relative = ABSOLUTE;
}
}
org_advanced = FALSE; // * means this address+1
format_line(nline, label, "BSI", "L", DOLLARDUMP, "");
parse_line(nline); // compile "call $dump"
writew(addr[2].value, ABSOLUTE); // append arguments (0, start, end address)
writew(addr[0].value, addr[0].relative);
writew(addr[1].value, addr[1].relative);
}
// ---------------------------------------------------------------------------------
// x_hdng - HDNG directive
// ---------------------------------------------------------------------------------
void x_hdng (struct tag_op *op, char *label, char *mods, char *arg)
{
char *c;
// label is not entered into the symbol table
if (flist == NULL || ! list_on) {
line_error = TRUE; // inhibit listing: don't print the HDNG statement
return;
}
line_error = TRUE; // don't print the statement
c = skipbl(opfield);
trim(c);
fprintf(flist, "\f%s\n\n", c); // print page header
}
// ---------------------------------------------------------------------------------
// x_list - LIST directive. enable or disable listing
// ---------------------------------------------------------------------------------
void x_list (struct tag_op *op, char *label, char *mods, char *arg)
{
BOOL on;
// label is not entered into the symbol table
line_error = TRUE; // don't print the LIST statement
if (flist == NULL || ! list_on) {
return;
}
if (strcmpi(arg, "ON") == 0)
on = TRUE;
else if (strcmpi(arg, "OFF") == 0)
on = FALSE;
else
on = do_list;
list_on = on;
}
// ---------------------------------------------------------------------------------
// x_spac - SPAC directive. Put blank lines in listing
// ---------------------------------------------------------------------------------
void x_spac (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
// label is not entered into the symbol table
if (flist == NULL || ! list_on) {
line_error = TRUE; // don't print the SPAC statement
return;
}
if (getexpr(arg, FALSE, &expr) != S_DEFINED)
return;
line_error = TRUE; // don't print the statement
while (--expr.value >= 0)
putc('\n', flist);
}
// ---------------------------------------------------------------------------------
// x_ejct - EJCT directive - put formfeed in listing
// ---------------------------------------------------------------------------------
void x_ejct (struct tag_op *op, char *label, char *mods, char *arg)
{
// label is not entered into the symbol table
if (flist == NULL || ! list_on) {
line_error = TRUE; // don't print the EJCT statement
return;
}
line_error = TRUE; // don't print the statement
putc('\f', flist);
}
// ---------------------------------------------------------------------------------
// basic_opcode - construct a standard opcode value from op table entry and modifier chars
// ---------------------------------------------------------------------------------
int basic_opcode (struct tag_op *op, char *mods)
{
int opcode = op->opcode; // basic code value
if (strchr(mods, '1') != 0) // indexing
opcode |= 0x0100;
else if (strchr(mods, '2') != 0)
opcode |= 0x0200;
else if (strchr(mods, '3') != 0)
opcode |= 0x0300;
if (strchr(mods, 'L')) { // two-word format
opcode |= OP_LONG;
if (strchr(mods, 'I') != 0) // and indirect to boot
opcode |= OP_INDIRECT;
}
return opcode;
}
// ---------------------------------------------------------------------------------
// std_op - assemble a vanilla opcode
// ---------------------------------------------------------------------------------
void std_op (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
int opcode = basic_opcode(op, mods);
BOOL val_ok = FALSE;
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (*arg && ! (op->flags & NO_ARGS)) { // get value argument
if (getexpr(arg, FALSE, &expr) == S_DEFINED)
val_ok = TRUE;
}
else {
expr.value = 0;
expr.relative = FALSE;
}
if (opcode & OP_LONG) { // two-word format, just write code and value
writew(opcode, FALSE);
writew(expr.value, expr.relative);
}
else { // one-word format
if (strchr(mods, 'I') != 0)
asm_error("Indirect mode not permitted on one-word instructions");
if (val_ok && ! (strchr(mods, 'X') || (op->flags & IS_ABS) || ((opcode & OP_INDEXED) && ! (op->flags & NO_IDX))))
expr.value -= (org+1); // compute displacement
if (expr.value < -128 || expr.value > 127) {// check range
asm_error("Offset of %d is too large", expr.value);
expr.value = 0;
}
writew(opcode | (expr.value & 0x00FF), FALSE);// that's the code
}
}
// ---------------------------------------------------------------------------------
// mdx_op - assemble a MDX family instruction
// ---------------------------------------------------------------------------------
void mdx_op (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR dest, incr = {0, FALSE};
int opcode = basic_opcode(op, mods);
char *tok;
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if ((tok = strtok(arg, ",")) == NULL) { // argument format is dest[,increment]
// asm_error("Destination not specified"); // seems not to be an error, IBM omits it sometimes
dest.value = 0;
dest.relative = ABSOLUTE;
}
else
getexpr(tok, FALSE, &dest); // parse the address
tok = strtok(NULL, ","); // look for second argument
if (opcode & OP_LONG) { // two word format
if (opcode & OP_INDEXED) { // format: MDX 2 dest
if (tok != NULL)
asm_error("This format takes only one argument");
}
else { // format: MDX dest,increment
if (opcode & OP_INDIRECT)
asm_error("Indirect can't be used without indexing");
if (tok == NULL) {
// asm_error("This format takes two arguments");
incr.value = 0;
incr.relative = ABSOLUTE;
}
else
getexpr(tok, FALSE, &incr);
if (incr.value < -128 || incr.value > 127) // displacement style (fixed in ver 1.08)
asm_error("Invalid increment value (8 bits signed)");
opcode |= (incr.value & 0xFF);
}
writew(opcode, ABSOLUTE);
writew(dest.value, dest.relative);
}
else { // one word format MDX val
if (tok != NULL)
asm_error("This format takes only one argument");
if (! (strchr(mods, 'X') || (opcode & OP_INDEXED)))
dest.value -= (org+1); // compute displacement
if (dest.value < -128 || dest.value > 127)
asm_error("Offset/Increment of %d is too large", dest.value);
writew(opcode | (dest.value & 0xFF), FALSE);
}
}
// ---------------------------------------------------------------------------------
// bsi_op - BSI long instruction is like a BSC L, short is standard
// ---------------------------------------------------------------------------------
void bsi_op (struct tag_op *op, char *label, char *mods, char *arg)
{
if (strchr(mods, 'L') || strchr(mods, 'I'))
bsc_op(op, label, mods, arg);
else
std_op(op, label, mods, arg);
}
// ---------------------------------------------------------------------------------
// b_op - branch; use short or long version
// --------------------------------------------------------------------------------
void b_op (struct tag_op *op, char *label, char *mods, char *arg)
{
static struct tag_op *mdx = NULL;
if (strchr(mods, 'L') || strchr(mods, 'I')) {
bsi_op(op, label, mods, arg);
return;
}
if (mdx == NULL)
if ((mdx = lookup_op("MDX")) == NULL)
bail("Can't find MDX op");
(mdx->handler)(mdx, label, mods, arg);
}
// ---------------------------------------------------------------------------------
// bsc_op - compute a BSC family instruction
// ---------------------------------------------------------------------------------
void bsc_op (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR dest;
int opcode = basic_opcode(op, mods);
char *tok, *tests;
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (opcode & OP_LONG) { // two word format
if ((tok = strtok(arg, ",")) == NULL) { // format is BSC dest[,tests]
asm_error("Destination not specified");
dest.value = 0;
dest.relative = ABSOLUTE;
}
else
getexpr(tok, FALSE, &dest);
tests = strtok(NULL, ","); // get test characters
}
else
tests = arg; // short format is BSC tests
if (tests != NULL) { // stick in the testing bits
for (; *tests; tests++) {
switch (*tests) {
// bit 0x40 is the BOSC bit
case 'Z': opcode |= 0x20; break;
case '-': opcode |= 0x10; break;
case '+':
case '&': opcode |= 0x08; break;
case 'E': opcode |= 0x04; break;
case 'C': opcode |= 0x02; break;
case 'O': opcode |= 0x01; break;
default:
asm_error("Invalid test flag: '%c'", *tests);
}
}
}
writew(opcode, ABSOLUTE); // emit code
if (opcode & OP_LONG)
writew(dest.value, dest.relative);
}
// ---------------------------------------------------------------------------------
// shf_op - assemble a shift instruction
// ---------------------------------------------------------------------------------
void shf_op (struct tag_op *op, char *label, char *mods, char *arg)
{
EXPR expr;
int opcode = basic_opcode(op, mods);
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
if (opcode & OP_INDEXED) { // shift value comes from index register
expr.value = 0;
expr.relative = ABSOLUTE;
}
else
getexpr(arg, FALSE, &expr);
if (expr.relative) {
asm_error("Shift value is a relative address");
expr.relative = ABSOLUTE;
}
if (expr.value < 0 || expr.value > 32) { // check range
asm_error("Shift count of %d is invalid", expr.value);
expr.value = 0;
}
writew(opcode | (expr.value & 0x3F), FALSE); // put shift count into displacement field
}
// ---------------------------------------------------------------------------------
// x_mdm - MDM instruction
// ---------------------------------------------------------------------------------
void x_mdm (struct tag_op *op, char *label, char *mods, char *arg)
{
int opcode = basic_opcode(op, mods);
if (*label) // define label
set_symbol(label, org, TRUE, relocate);
// oh dear: bug here
asm_error("'%s' is not yet supported", op->mnem);
}
// ---------------------------------------------------------------------------------
// x_exit - EXIT directive. Assembler manual says it treats like CALL $EXIT, but
// object code reveals the truth: jump to $EXIT, which is a small value, so we can use LDX.
// ---------------------------------------------------------------------------------
void x_exit (struct tag_op *op, char *label, char *mods, char *arg)
{
char nline[120];
format_line(nline, label, "LDX", "X", DOLLAREXIT, "");
parse_line(nline);
}
// ---------------------------------------------------------------------------------
// x_opt - .OPT directive. Nonstandard. Possible values:
//
// .OPT CEXPR - use C precedence in evaluating expressions rather than strict left-right
// ---------------------------------------------------------------------------------
void x_opt (struct tag_op *op, char *label, char *mods, char *arg)
{
char *tok;
org_advanced = FALSE; // * means this address
if (*label) {
asm_error("Label not permitted on .OPT statement");
return;
}
// look for OPT arguments
for (tok = strtok(arg, ","); tok != NULL; tok = strtok(NULL, ",")) {
if (strcmp(tok, "CEXPR") == 0) {
cexpr = TRUE; // use C expression precedence (untested)
}
else
asm_error("Unknown .OPT: '%s'", tok);
}
}
// ---------------------------------------------------------------------------------
// askip - skip input lines until a line with the target label appears
// ---------------------------------------------------------------------------------
void askip (char *target)
{
char nline[200], cur_label[20], *c;
while (get_line(nline, sizeof(nline), TRUE)) { // read next line (but don't exit a macro)
listout(FALSE); // end listing of previous input line
prep_line(nline); // preform standard line prep
strncpy(cur_label, nline, 6); // get first 5 characters
cur_label[5] = '\0';
for (c = cur_label; *c > ' '; c++) // truncate at first whitespace
;
*c = '\0';
// stop if there's a match
if ((target == NULL) ? (cur_label[0] == '\0') : strcmp(target, cur_label) == 0) {
parse_line(nline); // process this line
return;
}
}
if (target != NULL)
asm_error("Label %s not found", target);
}
// ---------------------------------------------------------------------------------
// x_aif - process conditional assembly jump
// ---------------------------------------------------------------------------------
void x_aif (struct tag_op *op, char *label, char *mods, char *arg)
{
char *target, *tok;
EXPR expr1, expr2;
BOOL istrue;
enum {OP_EQ, OP_LT, OP_GT, OP_NE, OP_LE, OP_GE} cmp_op;
// label is not entered into the symbol table
arg = skipbl(arg);
if (*arg != '(') {
asm_error("AIF operand must start with (");
return;
}
arg++; // skip the paren
// normally whitespace is never found in the arg string (see tabtok and coltok).
// However, spaces inside parens are permitted.
if ((tok = strtok(arg, whitespace)) == NULL) {
asm_error("AIF missing first expression");
return;
}
getexpr(tok, FALSE, &expr1);
if ((tok = strtok(NULL, whitespace)) == NULL) {
asm_error("AIF missing conditional operator");
return;
}
if (strcmp(tok, "EQ") == 0)
cmp_op = OP_EQ;
else if (strcmp(tok, "LT") == 0)
cmp_op = OP_LT;
else if (strcmp(tok, "GT") == 0)
cmp_op = OP_GT;
else if (strcmp(tok, "NE") == 0)
cmp_op = OP_NE;
else if (strcmp(tok, "LE") == 0)
cmp_op = OP_LE;
else if (strcmp(tok, "GE") == 0)
cmp_op = OP_GE;
else {
asm_error("AIF: %s is not a valid conditional operator", tok);
return;
}
if ((tok = strtok(NULL, ")")) == NULL) {
asm_error("AIF missing second expression");
return;
}
getexpr(tok, FALSE, &expr2);
switch (cmp_op) { // test the condition
case OP_EQ: istrue = expr1.value == expr2.value; break;
case OP_LT: istrue = expr1.value < expr2.value; break;
case OP_GT: istrue = expr1.value > expr2.value; break;
case OP_NE: istrue = expr1.value != expr2.value; break;
case OP_LE: istrue = expr1.value <= expr2.value; break;
case OP_GE: istrue = expr1.value >= expr2.value; break;
default: bail("in aif, can't happen");
}
// After the closing paren coltok and tabtok guarantee we will have no whitespace
if ((target = strtok(arg, ",")) == NULL) // get target label
asm_warning("Missing target label");
if (istrue)
askip(target); // skip to the target
}
// ---------------------------------------------------------------------------------
// x_aifb - conditional assembly jump back (macro only)
// ---------------------------------------------------------------------------------
void x_aifb (struct tag_op *op, char *label, char *mods, char *arg)
{
asm_error("aifb valid in macros only and not implemented in any case");
}
// ---------------------------------------------------------------------------------
// x_ago
// ---------------------------------------------------------------------------------
void x_ago (struct tag_op *op, char *label, char *mods, char *arg)
{
char *target;
// label is not entered into the symbol table
// handle differently in a macro
if ((target = strtok(arg, ",")) == NULL) // get target label
asm_warning("Missing target label");
askip(target); // skip to the target
}
// ---------------------------------------------------------------------------------
// ---------------------------------------------------------------------------------
void x_agob (struct tag_op *op, char *label, char *mods, char *arg)
{
asm_error("agob valid in macros only and not implemented in any case");
}
// ---------------------------------------------------------------------------------
// ---------------------------------------------------------------------------------
void x_anop (struct tag_op *op, char *label, char *mods, char *arg)
{
// label is not entered into the symbol table
// do nothing else
}
// ---------------------------------------------------------------------------------
// expression parser, borrowed from older code, no comments, sorry
// ---------------------------------------------------------------------------------
char *exprptr, *oexprptr;
#define GETNEXT (*exprptr++)
#define UNGET --exprptr
#define LETTER 0 /* character types */
#define DIGIT 1
#define ETC 2
#define ILL 3
#define SPACE 4
#define MULOP 5
#define ADDOP 6
#define EXPOP 7
int getnb (void);
void c_expr (EXPR *ap);
void c_expr_m (EXPR *ap);
void c_expr_e (EXPR *ap);
void c_expr_u (EXPR *ap);
void c_term (EXPR *ap);
int c_number (int c, int r, int nchar);
int digit (int c, int r);
int c_esc (int c);
void exprerr (int n);
void a1130_expr (EXPR *ap);
void a1130_term (EXPR *ap);
char ctype[128] = { // character types
/*^0ABCDEFG */ ILL, ILL, ILL, ILL, ILL, ILL, ILL, ILL,
/*^HIJKLMNO */ ILL, SPACE, SPACE, ILL, SPACE, SPACE, ILL, ILL,
/*^PQRSTUVW */ ILL, ILL, ILL, ILL, ILL, ILL, ILL, ILL,
/*^XYZ */ ILL, ILL, ILL, ILL, ILL, ILL, ILL, ILL,
/* !"#$%&' */ SPACE, ETC, ETC, LETTER, LETTER, MULOP, MULOP, LETTER, /* $ # @ and ' are letters here */
/* ()*+,-./ */ ETC, ETC, MULOP, ADDOP, ETC, ADDOP, ETC, MULOP,
/* 01234567 */ DIGIT, DIGIT, DIGIT, DIGIT, DIGIT, DIGIT, DIGIT, DIGIT,
/* 89:;<=>? */ DIGIT, DIGIT, ETC, ETC, MULOP, ETC, MULOP, ETC,
/* @ABCDEFG */ LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER,
/* HIJKLMNO */ LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER,
/* PQRSTUVW */ LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER,
/* XYZ[\]^_ */ LETTER, LETTER, LETTER, ETC, ETC, ETC, EXPOP, LETTER,
/* `abcdefg */ ETC, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER,
/* hijklmno */ LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER,
/* pqrstuvw */ LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER, LETTER,
/* xyz{|}~ */ LETTER, LETTER, LETTER, ETC, ADDOP, ETC, ETC, ETC
};
char *errstr[] = {
"Missing exponent", // 0
"Undefined symbol", // 1
"Division by zero", // 2
"Illegal operator", // 3
") expected", // 4
"Char expected after '", // 5
"Char expected after .", // 6
"Number expected after =", // 7
"Syntax error", // 8
"Number syntax", // 9
"Char expected after \\", // 10
"Relocation error" // 11
};
int getnb () {
int c;
if (cexpr) { // in C mode, handle normally
while (ctype[(c = GETNEXT)] == SPACE)
;
} // in 1130 mode, a space terminates the expression. Here, eat the rest
else if ((c = GETNEXT) == ' ') {
while ((c = GETNEXT) != '\0')
;
}
return c;
}
int symbest, exprerrno;
jmp_buf exprjmp;
// ---------------------------------------------------------------------------------
// getexpr
// ---------------------------------------------------------------------------------
int getexpr (char *pc, BOOL undefined_ok, EXPR *pval)
{
symbest = S_DEFINED; // assume no questionable symbols
pval->value = 0;
pval->relative = ABSOLUTE;
if (! *pc) // blank expression is same as zero, ok?
return S_DEFINED;
if (setjmp(exprjmp) != 0) { // encountered a syntax error & bailed
pval->value = 0;
pval->relative = ABSOLUTE;
return S_UNDEFINED;
}
exprptr = oexprptr = pc; // make global the buffer pointer
c_expr(pval);
if (GETNEXT) // expression should have been entirely eaten
exprerr(8); // if characters are left, it's an error
if (pval->relative < 0 || pval->relative > 1)
exprerr(11); // has to work out to an absolute or a single relative term
if (symbest == S_DEFINED) // tell how it came out
return S_DEFINED;
pval->value = 0;
pval->relative = ABSOLUTE;
return (pass == 1 && undefined_ok) ? S_PROVISIONAL : S_UNDEFINED;
}
// ---------------------------------------------------------------------------------
// output_literals - construct .DC assembler lines to assemble pending literal
// constant values that have accumulated.
// ---------------------------------------------------------------------------------
void output_literals (BOOL eof)
{
char line[120], label[12], num[20];
int i;
for (i = 0; i < n_literals; i++) { // generate DC statements for any pending literal constants
if (literal[i].even && literal[i].hex) // create the value string
sprintf(num, "/%08lx", literal[i].value);
else if (literal[i].even)
sprintf(num, "%ld", literal[i].value);
else if (literal[i].hex)
sprintf(num, "/%04x", literal[i].value & 0xFFFF);
else
sprintf(num, "%d", literal[i].value);
sprintf(label, "_L%03d", literal[i].tagno);
format_line(line, label, literal[i].even ? "DEC" : "DC", "", num, "GENERATED LITERAL CONSTANT");
if (eof) {
eof = FALSE; // at end of file, for first literal, only prepare blank line
sprintf(listline, LEFT_MARGIN, org);
}
else
listout(TRUE); // push out any pending line(s)
if (flist && list_on) // this makes stuff appear in the listing
sprintf(listline, LEFT_MARGIN " %s", detab(line));
nwout = 0;
parse_line(line); // assemble the constant definition
}
n_literals = 0; // clear list
}
// ---------------------------------------------------------------------------------
// a1130_term - extract one term of an expression
// ---------------------------------------------------------------------------------
void a1130_term (EXPR *ap)
{
PSYMBOL s;
char token[80], *t;
int c;
if (cexpr) { // use C syntax
c_term(ap);
return;
}
c = GETNEXT;
if (ctype[c] == DIGIT) { /* number */
ap->value = signextend(c_number(c,10,-1));
ap->relative = ABSOLUTE;
}
else if (c == '+') { /* unary + */
a1130_term(ap);
}
else if (c == '-') { /* unary - */
a1130_term(ap);
ap->value = - ap->value;
}
else if (c == '/') { /* / starts a hex constant */
ap->value = signextend(c_number(c,16,-1));
ap->relative = ABSOLUTE;
}
else if (c == '*') { /* asterisk alone = org */
ap->value = org + org_advanced; // here is where that offset matters!
ap->relative = relocate;
}
else if (c == '.') { /* EBCDIC constant */
c = GETNEXT;
if (c == '\0') {
UNGET;
c = ' ';
}
c = ascii_to_ebcdic_table[c];
ap->value = c; // VALUE IS IN LOW BYTE!!!
ap->relative = ABSOLUTE;
}
else if (ctype[c] == LETTER) { /* symbol */
t = token;
do {
*t++ = c;
c = GETNEXT;
} while (ctype[c] == LETTER || ctype[c] == DIGIT);
UNGET;
*t++ = '\0';
s = lookup_symbol(token, TRUE);
add_xref(s, FALSE);
ap->value = s->value;
ap->relative = s->relative;
symbest = MIN(symbest, s->defined); // this goes to lowest value (undefined < provisional < defined)
if (pass == 2 && s->defined != S_DEFINED)
exprerr(1);
}
else
exprerr(8);
}
// ---------------------------------------------------------------------------------
// signextend - sign-extend a 16-bit constant value to whatever "int" is.
// ---------------------------------------------------------------------------------
int signextend (int v)
{
v &= 0xFFFF; // clip to 16 bits (this may not be necessary, but best to be safe?)
if (v & 0x8000) // if sign bit is set
v |= ~0xFFFF; // sign extend
return v;
}
// ---------------------------------------------------------------------------------
// c_expr - evalate an expression
// ---------------------------------------------------------------------------------
void c_expr (EXPR *ap)
{
int c;
EXPR rop;
c_expr_m(ap); // get combined multiplicative terms
for (;;) { // handle +/- precedence operators
if (ctype[c=getnb()] != ADDOP) {
UNGET;
break;
}
c_expr_m(&rop); // right hand operand
switch (c) {
case '+':
ap->value += rop.value;
ap->relative += rop.relative;
break;
case '-':
ap->value -= rop.value;
ap->relative -= rop.relative;
break;
case '|':
if (ap->relative || rop.relative)
exprerr(11);
ap->value = ((long) (ap->value)) | ((long) rop.value);
break;
default:
printf("In expr, can't happen\n");
}
}
}
// ---------------------------------------------------------------------------------
// c_expr_m - get multiplicative precedence terms. Again, this is not usually used
// ---------------------------------------------------------------------------------
void c_expr_m (EXPR *ap)
{
int c;
EXPR rop;
c_expr_e(ap); // get exponential precedence term
for (;;) { // get operator
c = getnb();
if ((c=='<') || (c=='>'))
if (c != getnb()) // << or >>
exprerr(3);
if (ctype[c] != MULOP) {
UNGET;
break;
}
c_expr_e(&rop); // right hand operand
switch(c) {
case '*':
if (ap->relative && rop.relative)
exprerr(11);
ap->value *= rop.value;
ap->relative = (ap->relative || rop.relative) ? RELATIVE : ABSOLUTE;
break;
case '/':
if (rop.value == 0)
exprerr(2);
if (ap->relative || rop.relative)
exprerr(11);
ap->value /= rop.value;
break;
case '%':
if (rop.value == 0)
exprerr(2);
if (ap->relative || rop.relative)
exprerr(11);
ap->value = ((long) (ap->value)) % ((long) rop.value);
break;
case '&':
if (ap->relative || rop.relative)
exprerr(11);
ap->value = ((long) (ap->value)) & ((long) rop.value);
break;
case '>':
if (ap->relative || rop.relative)
exprerr(11);
ap->value = ((long) (ap->value)) >> ((long) rop.value);
break;
case '<':
if (ap->relative || rop.relative)
exprerr(11);
ap->value = ((long) (ap->value)) << ((long) rop.value);
break;
default:
printf("In expr_m, can't happen\n");
}
}
}
// ---------------------------------------------------------------------------------
// c_expr_e - get exponential precedence terms. Again, this is not usually used
// ---------------------------------------------------------------------------------
void c_expr_e (EXPR *ap)
{
int c, i, v;
EXPR rop;
c_expr_u(ap);
for (;;) {
c = getnb();
if (ctype[c] != EXPOP) {
UNGET;
break;
}
c_expr_u(&rop);
switch(c) {
case '^':
if (ap->relative || rop.relative)
exprerr(11);
v = ap->value;
ap->value = 1;
for (i = 0; i < rop.value; i++)
ap->value *= v;
break;
default:
printf("In expr_e, can't happen\n");
}
}
}
// ---------------------------------------------------------------------------------
// c_expr_u - get unary precedence terms. Again, this is not usually used
// ---------------------------------------------------------------------------------
void c_expr_u (EXPR *ap)
{
int c;
if ((c = getnb()) == '!') {
a1130_term(ap);
ap->value = ~ ((long)(ap->value));
if (ap->relative)
exprerr(11);
}
else if (c == '-') {
a1130_term(ap);
ap->value = - ap->value;
if (ap->relative)
exprerr(11);
}
else {
UNGET;
a1130_term(ap);
}
}
// ---------------------------------------------------------------------------------
// c_term - get basic operand or parenthesized expression. Again, this is not usually used
// ---------------------------------------------------------------------------------
void c_term (EXPR *ap)
{
int c, cc;
PSYMBOL s;
char token[80], *t;
ap->relative = ABSOLUTE; /* assume absolute */
if ((c = getnb()) == '(') { /* parenthesized expr */
c_expr(ap); /* start over at the top! */
if ((cc = getnb()) != ')')
exprerr(4);
}
else if (c == '\'') { /* single quote: char */
if ((c = GETNEXT) == '\0')
c = ' ';
ap->value = c_esc(c);
}
else if (ctype[c] == DIGIT) { /* number */
ap->value = signextend(c_number(c,10,-1));
}
else if (c == '0') { /* 0 starts a hex or octal constant */
if ((c = GETNEXT) == 'x') {
c = GETNEXT;
ap->value = signextend(c_number(c,16,-1));
}
else {
ap->value = signextend(c_number(c,8,-1));
}
}
else if (c == '*') { /* asterisk alone = org */
ap->value = org + org_advanced;
ap->relative = relocate;
}
else if (ctype[c] == LETTER) { /* symbol */
t = token;
do {
*t++ = c;
c = GETNEXT;
} while (ctype[c] == LETTER || ctype[c] == DIGIT);
UNGET;
*t++ = '\0';
s = lookup_symbol(token, TRUE);
ap->value = s->value;
ap->relative = s->relative;
add_xref(s, FALSE);
symbest = MIN(symbest, s->defined); // this goes to lowest value (undefined < provisional < defined)
if (pass == 2 && s->defined != S_DEFINED)
exprerr(1);
}
else
exprerr(8);
}
// ---------------------------------------------------------------------------------
// c_number - get a C format constant value. Again, this is not usually used
// ---------------------------------------------------------------------------------
int c_number (int c, int r, int nchar)
{
int v, n;
nchar--;
if (c == '/' && ! cexpr) { /* special radix stuff */
r = 16;
c = GETNEXT;
}
else if (r == 10 && c == '0' && cexpr) { /* accept C style 0x## also */
c = GETNEXT;
if (c == 'x') {
r = 16;
c = GETNEXT;
}
else {
r = 8;
UNGET;
c = '0';
}
}
n = 0; /* decode number */
while ((nchar-- != 0) && (v = digit(c, r)) >= 0) {
if (v >= r) /* out of range! */
exprerr(9);
n = r*n + v;
c = GETNEXT;
if (c == '.') { // maybe make it decimal?
c = GETNEXT;
break;
}
}
UNGET;
return (n);
}
// ---------------------------------------------------------------------------------
// digit - get digit value of character c in radix r
// ---------------------------------------------------------------------------------
int digit (int c, int r)
{
if (r == 16) {
if (c >= 'A' && c <= 'F')
return (c - 'A' + 10);
}
if (c >= '0' && c <= '9')
return (c - '0');
return (-1);
}
// ---------------------------------------------------------------------------------
// c_esc - handle C character escape
// ---------------------------------------------------------------------------------
int c_esc (int c)
{
if (c != '\\') /* not escaped */
return(c);
if ((c = GETNEXT) == '\0') /* must be followed by something */
exprerr(10);
if ((c >= 'A') && (c <= 'Z')) /* handle upper case */
c += 'a'-'A';
if (ctype[c] == LETTER) /* control character abbrevs */
switch (c) {
case 'b': c = '\b'; break; /* backspace */
case 'e': c = 27 ; break; /* escape */
case 'f': c = '\f'; break; /* formfeed */
case 'n': c = '\n'; break; /* newline */
case 'r': c = '\r'; break; /* return */
case 't': c = '\t'; break; /* horiz. tab */
}
else if (ctype[c] == DIGIT) { /* get character by the numbers */
c = c_number(c,8,3); /* force octal */
}
return c;
}
// ---------------------------------------------------------------------------------
// exprerr - note an expression syntax error. Longjumps back to caller with failure code
// ---------------------------------------------------------------------------------
void exprerr (int n)
{
char msg[256];
int nex = exprptr-oexprptr;
strncpy(msg, oexprptr, nex); // show where the problem was
msg[nex] = '\0';
strcat(msg, " << ");
strcat(msg, errstr[n]);
asm_error(msg);
exprerrno = n;
longjmp(exprjmp, 1);
}
/* ------------------------------------------------------------------------
* upcase - force a string to uppercase (ASCII)
* ------------------------------------------------------------------------ */
char *upcase (char *str)
{
char *s;
for (s = str; *s; s++) {
if (*s >= 'a' && *s <= 'z')
*s -= 32;
}
return str;
}
/* ------------------------------------------------------------------------
* hollerith table for IPL card ident field
* ------------------------------------------------------------------------ */
typedef struct {
int hollerith;
char ascii;
} CPCODE;
static CPCODE cardcode_029[] =
{
0x0000, ' ',
0x8000, '&', // + in 026 Fortran
0x4000, '-',
0x2000, '0',
0x1000, '1',
0x0800, '2',
0x0400, '3',
0x0200, '4',
0x0100, '5',
0x0080, '6',
0x0040, '7',
0x0020, '8',
0x0010, '9',
0x9000, 'A',
0x8800, 'B',
0x8400, 'C',
0x8200, 'D',
0x8100, 'E',
0x8080, 'F',
0x8040, 'G',
0x8020, 'H',
0x8010, 'I',
0x5000, 'J',
0x4800, 'K',
0x4400, 'L',
0x4200, 'M',
0x4100, 'N',
0x4080, 'O',
0x4040, 'P',
0x4020, 'Q',
0x4010, 'R',
0x3000, '/',
0x2800, 'S',
0x2400, 'T',
0x2200, 'U',
0x2100, 'V',
0x2080, 'W',
0x2040, 'X',
0x2020, 'Y',
0x2010, 'Z',
0x0820, ':',
0x0420, '#', // = in 026 Fortran
0x0220, '@', // ' in 026 Fortran
0x0120, '\'',
0x00A0, '=',
0x0060, '"',
0x8820, 'c', // cent
0x8420, '.',
0x8220, '<', // ) in 026 Fortran
0x8120, '(',
0x80A0, '+',
0x8060, '|',
0x4820, '!',
0x4420, '$',
0x4220, '*',
0x4120, ')',
0x40A0, ';',
0x4060, 'n', // not
0x2820, 'x', // what?
0x2420, ',',
0x2220, '%', // ( in 026 Fortran
0x2120, '_',
0x20A0, '>',
0x2060, '>',
};
int ascii_to_hollerith (int ch)
{
int i;
for (i = 0; i < sizeof(cardcode_029) / sizeof(CPCODE); i++)
if (cardcode_029[i].ascii == ch)
return cardcode_029[i].hollerith;
return 0;
}
/* ------------------------------------------------------------------------
* detab - replace tabs with spaces for listing files
* ------------------------------------------------------------------------ */
char *detab (char *instr)
{
static char outstr[256];
char *out = outstr;
int col = 0;
while (*instr) {
if (*instr == '\t') {
do {
*out++ = ' ';
col++;
}
while (col & 7);
}
else {
*out++ = *instr;
col++;
}
instr++;
}
*out = '\0';
return outstr;
}
#ifndef _WIN32
int strnicmp (char *a, char *b, int n)
{
int ca, cb;
for (;;) {
if (--n < 0) // still equal after n characters? quit now
return 0;
if ((ca = *a) == 0) // get character, stop on null terminator
return *b ? -1 : 0;
if (ca >= 'a' && ca <= 'z') // fold lowercase to uppercase
ca -= 32;
cb = *b;
if (cb >= 'a' && cb <= 'z')
cb -= 32;
if ((ca -= cb) != 0) // if different, return comparison
return ca;
a++, b++;
}
}
int strcmpi (char *a, char *b)
{
int ca, cb;
for (;;) {
if ((ca = *a) == 0) // get character, stop on null terminator
return *b ? -1 : 0;
if (ca >= 'a' && ca <= 'z') // fold lowercase to uppercase
ca -= 32;
cb = *b;
if (cb >= 'a' && cb <= 'z')
cb -= 32;
if ((ca -= cb) != 0) // if different, return comparison
return ca;
a++, b++;
}
}
#endif