NetBoot/vasm-1/vasm.c
2020-06-20 09:33:04 +08:00

1706 lines
43 KiB
C

/* vasm.c main module for vasm */
/* (c) in 2002-2020 by Volker Barthelmann */
#include <stdlib.h>
#include <stdio.h>
#include <stdarg.h>
#include "vasm.h"
#include "osdep.h"
#include "stabs.h"
#include "dwarf.h"
#define _VER "vasm 1.8h"
char *copyright = _VER " (c) in 2002-2020 Volker Barthelmann";
#ifdef AMIGA
static const char *_ver = "$VER: " _VER " " __AMIGADATE__ "\r\n";
#endif
#define SRCREADINC (64*1024) /* extend buffer in these steps when reading */
/* The resolver will run another pass over the current section as long as any
label location or atom size has changed. It gives up at MAXPASSES, which
hopefully will never happen.
During the first FASTOPTPHASE passes all instructions of a section will be
optimized at the same time. After that the resolver enters a safe mode,
where only a single instruction per pass is changed. */
#define MAXPASSES 1000
#define FASTOPTPHASE 200
source *cur_src;
char *filename,*debug_filename;
section *current_section;
char *inname,*outname,*listname,*compile_dir;
taddr inst_alignment;
int done,secname_attr,unnamed_sections,ignore_multinc,nocase,no_symbols;
int pic_check,final_pass,debug,exec_out,chklabels,warn_unalloc_ini_dat;
int nostdout;
int listena,listformfeed=1,listlinesperpage=40,listnosyms;
listing *first_listing,*last_listing,*cur_listing;
struct stabdef *first_nlist,*last_nlist;
char *output_format="test";
unsigned long long taddrmask;
taddr taddrmin,taddrmax;
char emptystr[]="";
char vasmsym_name[]="__VASM";
int num_secs;
static int produce_listing;
static char **listtitles;
static int *listtitlelines;
static int listtitlecnt;
static FILE *outfile;
static int depend,depend_all;
#define DEPEND_LIST 1
#define DEPEND_MAKE 2
struct deplist {
struct deplist *next;
char *filename;
};
static struct deplist *first_depend,*last_depend;
static char *dep_filename;
static section *first_section,*last_section;
#if NOT_NEEDED
static section *prev_sec,*prev_org;
#endif
/* MNEMOHTABSIZE should be defined by cpu module */
#ifndef MNEMOHTABSIZE
#define MNEMOHTABSIZE 0x1000
#endif
hashtable *mnemohash;
static int dwarf;
static int verbose=1,auto_import=1;
static int fail_on_warning;
static taddr sec_padding;
static struct include_path *first_incpath;
static struct source_file *first_source;
static char *output_copyright;
static void (*write_object)(FILE *,section *,symbol *);
static int (*output_args)(char *);
void leave(void)
{
section *sec;
symbol *sym;
if(outfile){
fclose(outfile);
if (errors&&outname!=NULL)
remove(outname);
}
if(debug){
fprintf(stdout,"Sections:\n");
for(sec=first_section;sec;sec=sec->next)
print_section(stdout,sec);
fprintf(stdout,"Symbols:\n");
for(sym=first_symbol;sym;sym=sym->next){
print_symbol(stdout,sym);
fprintf(stdout,"\n");
}
}
if(errors||(fail_on_warning&&warnings))
exit(EXIT_FAILURE);
else
exit(EXIT_SUCCESS);
}
/* Convert all labels from an offset-section into absolute expressions. */
static void convert_offset_labels(void)
{
symbol *sym;
for (sym=first_symbol; sym; sym=sym->next) {
if (sym->type==LABSYM && sym->sec!=NULL && (sym->sec->flags&UNALLOCATED)) {
sym->type = EXPRESSION;
sym->expr = number_expr(sym->pc);
sym->sec = NULL;
}
}
}
/* Removes all unallocated (offset) sections from the list. */
static void remove_unalloc_sects(void)
{
section *prev,*sec;
for (sec=first_section,prev=NULL; sec; sec=sec->next) {
if (sec->flags&UNALLOCATED) {
if (prev)
prev->next = sec->next;
else
first_section = sec->next;
}
else
prev = sec;
}
last_section = prev;
}
/* convert reloffs-atom into one or more space-atoms */
static void roffs_to_space(section *sec,atom *p)
{
uint8_t padding[MAXPADBYTES];
taddr space,padbytes,n;
sblock *sb = NULL;
if (eval_expr(p->content.roffs->offset,&space,sec,sec->pc) &&
(p->content.roffs->fillval==NULL ||
eval_expr(p->content.roffs->fillval,&n,sec,sec->pc))) {
space = sec->org + space - sec->pc;
if (space >= 0) {
if (p->content.roffs->fillval == NULL) {
memcpy(padding,sec->pad,MAXPADBYTES);
padbytes = sec->padbytes;
}
else
padbytes = make_padding(n,padding,MAXPADBYTES);
if (space >= padbytes) {
n = balign(sec->pc,padbytes); /* alignment is automatic */
space -= n;
sec->pc += n; /* Important! Fix the PC for new alignment. */
sb = new_sblock(number_expr(space/padbytes),padbytes,0);
memcpy(sb->fill,padding,padbytes);
p->type = SPACE;
p->content.sb = sb;
p->align = padbytes;
space %= padbytes;
if (space > 0) {
/* fill the rest with zeros */
atom *a = new_space_atom(number_expr(space),1,0);
a->next = p->next;
p->next = a;
}
}
else {
p->type = SPACE;
p->content.sb = new_sblock(number_expr(space),1,0);
}
}
else
general_error(20); /* rorg is lower than current pc */
}
else
general_error(30); /* expression must be constant */
}
/* append a new stabs (nlist) symbol/debugging definition */
static void new_stabdef(aoutnlist *nlist,section *sec)
{
struct stabdef *new = mymalloc(sizeof(struct stabdef));
new->next = NULL;
new->name.ptr = nlist->name;
new->type = nlist->type;
new->other = nlist->other;
new->desc = nlist->desc;
new->base = NULL;
if (nlist->value == NULL)
new->value = 0;
else if (!eval_expr(nlist->value,&new->value,sec,sec->pc)) {
int btype = find_base(nlist->value,&new->base,sec,sec->pc);
if (btype==BASE_ILLEGAL || btype==BASE_PCREL) {
new->base = NULL;
general_error(38); /* illegal relocation */
}
else if (new->base != NULL)
new->base->flags |= REFERENCED;
}
if (last_nlist)
last_nlist = last_nlist->next = new;
else
first_nlist = last_nlist = new;
}
/* emit internal debug info, triggered by a VASMDEBUG atom */
void vasmdebug(const char *f,section *s,atom *a)
{
if (a->next != NULL) {
a = a->next;
printf("%s: (%s+0x%llx) %2d:%lu(%u) ",
f,s->name,ULLTADDR(s->pc),a->type,(unsigned long)a->lastsize,a->changes);
print_atom(stdout,a);
putchar('\n');
}
}
static int resolve_section(section *sec)
{
taddr rorg_pc,org_pc;
int fastphase=FASTOPTPHASE;
int pass=0;
int extrapass,rorg;
size_t size;
atom *p;
do{
done=1;
rorg=0;
if (++pass>=MAXPASSES){
general_error(7,sec->name);
break;
}
extrapass=pass<=fastphase;
if(debug)
printf("resolve_section(%s) pass %d%s",sec->name,pass,
pass<=fastphase?" (fast)\n":"\n");
sec->pc=sec->org;
for(p=sec->first;p;p=p->next){
sec->pc=pcalign(p,sec->pc);
if(cur_src=p->src)
cur_src->line=p->line;
#if HAVE_CPU_OPTS
if(p->type==OPTS){
cpu_opts(p->content.opts);
}
else
#endif
if(p->type==RORG){
if(rorg)
general_error(43); /* reloc org is already set */
rorg_pc=*p->content.rorg;
org_pc=sec->pc;
sec->pc=rorg_pc;
sec->flags|=ABSOLUTE;
rorg=1;
}
else if(p->type==RORGEND&&rorg){
sec->pc=org_pc+(sec->pc-rorg_pc);
rorg_pc=0;
sec->flags&=~ABSOLUTE;
rorg=0;
}
else if(p->type==LABEL){
symbol *label=p->content.label;
if(label->type!=LABSYM)
ierror(0);
if(label->pc!=sec->pc){
if(debug)
printf("moving label %s from %lu to %lu\n",label->name,
(unsigned long)label->pc,(unsigned long)sec->pc);
done=0;
label->pc=sec->pc;
}
}
else if(p->type==VASMDEBUG)
vasmdebug("resolve_section",sec,p);
if(pass>fastphase&&!done&&p->type==INSTRUCTION){
/* entered safe mode: optimize only one instruction every pass */
sec->pc+=p->lastsize;
continue;
}
if(p->changes>MAXSIZECHANGES){
/* atom changed size too frequently, set warning flag */
if(debug)
printf("setting resolve-warning flag for atom type %d at %lu\n",
p->type,(unsigned long)sec->pc);
sec->flags|=RESOLVE_WARN;
size=atom_size(p,sec,sec->pc);
sec->flags&=~RESOLVE_WARN;
}
else
size=atom_size(p,sec,sec->pc);
if(size!=p->lastsize){
if(debug)
printf("modify size of atom type %d at %lu from %lu to %lu\n",
p->type,(unsigned long)sec->pc,(unsigned long)p->lastsize,
(unsigned long)size);
done=0;
if(pass>fastphase)
p->changes++; /* now count size modifications of atoms */
else if(size>p->lastsize)
extrapass=0; /* no extra pass, when an atom became larger */
p->lastsize=size;
}
sec->pc+=size;
}
if(rorg){
sec->pc=org_pc+(sec->pc-rorg_pc);
sec->flags&=~ABSOLUTE; /* workaround for misssing RORGEND */
}
/* Extend the fast-optimization phase, when there was no atom which
became larger than in the previous pass. */
if(extrapass) fastphase++;
}while(errors==0&&!done);
return pass;
}
static void bvunite(bvtype *dest,bvtype *src,size_t len)
{
len/=sizeof(bvtype);
for(;len>0;len--)
*dest++|=*src++;
}
static void resolve(void)
{
section *sec;
bvtype *todo;
int finished;
final_pass=0;
if(debug)
printf("resolve()\n");
for(num_secs=0, sec=first_section;sec;sec=sec->next)
sec->idx=num_secs++;
todo=mymalloc(BVSIZE(num_secs));
memset(todo,~(bvtype)0,BVSIZE(num_secs));
do{
finished=1;
for(sec=first_section;sec;sec=sec->next)
if(BTST(todo, sec->idx)){
int passes;
finished=0;
passes = resolve_section(sec);
BCLR(todo, sec->idx);
if(passes>1){
if(sec->deps)
bvunite(todo, sec->deps, BVSIZE(num_secs));
}
}
}while(!finished);
}
static void assemble(void)
{
taddr basepc,rorg_pc,org_pc;
struct dwarf_info dinfo;
int bss,rorg;
section *sec;
atom *p;
convert_offset_labels();
if(dwarf){
dinfo.version=dwarf;
dinfo.producer=cnvstr(copyright,strchr(copyright,'(')-copyright-1);
dwarf_init(&dinfo,first_incpath,first_source);
}
final_pass=1;
rorg=0;
for(sec=first_section;sec;sec=sec->next){
source *lasterrsrc=NULL;
utaddr oldpc;
int lasterrline=0,ovflw=0;
sec->pc=sec->org;
bss=strchr(sec->attr,'u')!=NULL;
for(p=sec->first;p;p=p->next){
basepc=sec->pc;
sec->pc=pcalign(p,sec->pc);
if(cur_src=p->src)
cur_src->line=p->line;
if(p->list&&p->list->atom==p){
p->list->sec=sec;
p->list->pc=sec->pc;
}
if(p->changes>MAXSIZECHANGES)
sec->flags|=RESOLVE_WARN;
/* print a warning on auto-aligned instructions or data */
if(sec->pc!=basepc){
atom *aa;
if (p->type==LABEL&&p->next!=NULL&&p->next->line==p->line)
aa=p->next; /* next atom in same line, look at it instead of label */
else
aa=p;
if (aa->type==INSTRUCTION)
general_error(50); /* instruction has been auto-aligned */
else if (aa->type==DATA||aa->type==DATADEF)
general_error(57); /* data has been auto-aligned */
}
if(p->type==RORG){
rorg_pc=*p->content.rorg;
org_pc=sec->pc;
sec->pc=rorg_pc;
sec->flags|=ABSOLUTE;
rorg=1;
}
else if(p->type==RORGEND){
if(rorg){
sec->pc=org_pc+(sec->pc-rorg_pc);
rorg_pc=0;
sec->flags&=~ABSOLUTE;
rorg=0;
}
else
general_error(44); /* reloc org was not set */
}
else if(p->type==INSTRUCTION){
dblock *db;
cur_listing=p->list;
db=eval_instruction(p->content.inst,sec,sec->pc);
if(pic_check)
do_pic_check(db->relocs);
cur_listing=0;
if(debug){
if(db->size!=(p->content.inst->code>=0?
instruction_size(p->content.inst,sec,sec->pc):0))
ierror(0);
}
if(dwarf){
if(cur_src->defsrc)
dwarf_line(&dinfo,sec,cur_src->defsrc->srcfile->index,
cur_src->defline+cur_src->line);
else
dwarf_line(&dinfo,sec,cur_src->srcfile->index,cur_src->line);
}
/*FIXME: sauber freigeben */
myfree(p->content.inst);
p->content.db=db;
p->type=DATA;
}
else if(p->type==DATADEF){
dblock *db;
cur_listing=p->list;
db=eval_data(p->content.defb->op,p->content.defb->bitsize,sec,sec->pc);
if(pic_check)
do_pic_check(db->relocs);
cur_listing=0;
/*FIXME: sauber freigeben */
myfree(p->content.defb);
p->content.db=db;
p->type=DATA;
}
else if(p->type==ROFFS)
roffs_to_space(sec,p);
#if HAVE_CPU_OPTS
else if(p->type==OPTS)
cpu_opts(p->content.opts);
#endif
else if(p->type==PRINTTEXT&&!nostdout)
printf("%s",p->content.ptext);
else if(p->type==PRINTEXPR&&!nostdout)
atom_printexpr(p->content.pexpr,sec,sec->pc);
else if(p->type==ASSERT){
assertion *ast=p->content.assert;
taddr val;
if(ast->assert_exp!=NULL) {
eval_expr(ast->assert_exp,&val,sec,sec->pc);
if(val==0)
general_error(47,ast->expstr,ast->msgstr?ast->msgstr:emptystr);
}
else /* ASSERT without expression, used for user-FAIL directives */
general_error(19,ast->msgstr?ast->msgstr:emptystr);
}
else if(p->type==NLIST)
new_stabdef(p->content.nlist,sec);
else if(p->type==VASMDEBUG)
vasmdebug("assemble",sec,p);
if(p->type==DATA&&bss){
if(lasterrsrc!=p->src||lasterrline!=p->line){
if(sec->flags&UNALLOCATED){
if(warn_unalloc_ini_dat)
general_error(54); /* initialized data in offset section */
}
else
general_error(31); /* initialized data in bss */
lasterrsrc=p->src;
lasterrline=p->line;
}
}
oldpc=sec->pc;
sec->pc+=atom_size(p,sec,sec->pc);
if((utaddr)sec->pc!=oldpc){
if((utaddr)(sec->pc-1)<oldpc||ovflw)
general_error(45); /* address space overflow */
ovflw=sec->pc==0;
}
sec->flags&=~RESOLVE_WARN;
}
/* leave RORG-mode, when section ends */
if(rorg){
sec->pc=org_pc+(sec->pc-rorg_pc);
rorg_pc=0;
sec->flags&=~ABSOLUTE;
rorg=0;
}
if(dwarf)
dwarf_end_sequence(&dinfo,sec);
}
remove_unalloc_sects();
if(dwarf)
dwarf_finish(&dinfo);
}
static void undef_syms(void)
{
symbol *sym;
for(sym=first_symbol;sym;sym=sym->next){
if (!auto_import&&sym->type==IMPORT&&!(sym->flags&(EXPORT|COMMON|WEAK)))
general_error(22,sym->name);
else if (sym->type==IMPORT&&!(sym->flags&REFERENCED))
general_error(61,sym->name);
}
}
static void fix_labels(void)
{
symbol *sym,*base;
taddr val;
for(sym=first_symbol;sym;sym=sym->next){
/* turn all absolute mode labels into absolute symbols */
if((sym->flags&ABSLABEL)&&sym->type==LABSYM){
sym->type=EXPRESSION;
sym->flags&=~(TYPE_MASK|COMMON);
sym->sec=NULL;
sym->size=NULL;
sym->align=0;
sym->expr=number_expr(sym->pc);
}
/* expressions which are based on a label are turned into a new label */
else if(sym->type==EXPRESSION){
if(!eval_expr(sym->expr,&val,NULL,0)){
if(find_base(sym->expr,&base,NULL,0)==BASE_OK){
/* turn into an offseted label symbol from the base's section */
sym->type=base->type;
sym->sec=base->sec;
sym->pc=val;
sym->align=1;
}else
general_error(53,sym->name); /* non-relocatable expr. in equate */
}
}
}
}
static void statistics(void)
{
section *sec;
unsigned long long size;
printf("\n");
for(sec=first_section;sec;sec=sec->next){
size=ULLTADDR(ULLTADDR(sec->pc)-ULLTADDR(sec->org));
printf("%s(%s%lu):\t%12llu byte%c\n",sec->name,sec->attr,
(unsigned long)sec->align,size,size==1?' ':'s');
}
}
static int init_output(char *fmt)
{
if(!strcmp(fmt,"test"))
return init_output_test(&output_copyright,&write_object,&output_args);
if(!strcmp(fmt,"elf"))
return init_output_elf(&output_copyright,&write_object,&output_args);
if(!strcmp(fmt,"bin"))
return init_output_bin(&output_copyright,&write_object,&output_args);
if(!strcmp(fmt,"srec"))
return init_output_srec(&output_copyright,&write_object,&output_args);
if(!strcmp(fmt,"vobj"))
return init_output_vobj(&output_copyright,&write_object,&output_args);
if(!strcmp(fmt,"hunk"))
return init_output_hunk(&output_copyright,&write_object,&output_args);
if(!strcmp(fmt,"aout"))
return init_output_aout(&output_copyright,&write_object,&output_args);
if(!strcmp(fmt,"hunkexe")){
exec_out=1; /* executable format */
return init_output_hunk(&output_copyright,&write_object,&output_args);
}
if(!strcmp(fmt,"tos")){
exec_out=1; /* executable format */
return init_output_tos(&output_copyright,&write_object,&output_args);
}
if(!strcmp(fmt,"xfile")){
exec_out=1; /* executable format */
return init_output_xfile(&output_copyright,&write_object,&output_args);
}
return 0;
}
static int init_main(void)
{
size_t i;
char *last;
hashdata data;
mnemohash=new_hashtable(MNEMOHTABSIZE);
i=0;
while(i<mnemonic_cnt){
data.idx=i;
last=mnemonics[i].name;
add_hashentry(mnemohash,mnemonics[i].name,data);
do{
i++;
}while(i<mnemonic_cnt&&!strcmp(last,mnemonics[i].name));
}
if(debug){
if(mnemohash->collisions)
printf("*** %d mnemonic collisions!!\n",mnemohash->collisions);
}
new_include_path(""); /* index 0: current work directory */
taddrmask=MAKEMASK(bytespertaddr<<3);
taddrmax=((utaddr)~0)>>1;
taddrmin=~taddrmax;
inst_alignment=INST_ALIGN;
return 1;
}
void set_default_output_format(char *fmt)
{
output_format=fmt;
}
static void include_main_source(void)
{
if (inname) {
char *filepart;
if ((filepart = get_filepart(inname)) != inname) {
/* main source is not in current dir., set compile-directory path */
compile_dir = cnvstr(inname,filepart-inname);
new_include_path(compile_dir);
}
else
compile_dir = NULL;
if (include_source(filepart)) {
setfilename(filepart);
setdebugname(inname);
}
}
else
general_error(15);
}
static void write_depends(FILE *f)
{
struct deplist *d = first_depend;
if (depend==DEPEND_MAKE && d!=NULL && outname!=NULL)
fprintf(f,"%s:",outname);
while (d != NULL) {
switch (depend) {
case DEPEND_LIST:
fprintf(f,"%s\n",d->filename);
break;
case DEPEND_MAKE:
if (str_is_graph(d->filename))
fprintf(f," %s",d->filename);
else
fprintf(f," \"%s\"",d->filename);
break;
default:
ierror(0);
}
d = d->next;
}
if (depend == DEPEND_MAKE)
fputc('\n',f);
}
int main(int argc,char **argv)
{
int i;
for(i=1;i<argc;i++){
if(argv[i][0]=='-'&&argv[i][1]=='F'){
output_format=argv[i]+2;
argv[i][0]=0;
}
if(!strcmp("-quiet",argv[i])){
verbose=0;
argv[i][0]=0;
}
if(!strcmp("-debug",argv[i])){
debug=1;
argv[i][0]=0;
}
}
if(!init_output(output_format))
general_error(16,output_format);
if(!init_main())
general_error(10,"main");
if(!init_symbol())
general_error(10,"symbol");
if(verbose)
printf("%s\n%s\n%s\n%s\n",copyright,cpu_copyright,syntax_copyright,output_copyright);
for(i=1;i<argc;i++){
if(argv[i][0]==0)
continue;
if(argv[i][0]!='-'){
if(inname)
general_error(11);
inname=argv[i];
continue;
}
if(!strcmp("-o",argv[i])&&i<argc-1){
if(outname)
general_error(28,argv[i]);
outname=argv[++i];
continue;
}
if(!strcmp("-L",argv[i])&&i<argc-1){
if(listname)
general_error(28,argv[i]);
listname=argv[++i];
produce_listing=1;
set_listing(1);
continue;
}
if(!strcmp("-Lnf",argv[i])){
listformfeed=0;
continue;
}
if(!strcmp("-Lns",argv[i])){
listnosyms=1;
continue;
}
if(!strncmp("-Ll",argv[i],3)){
sscanf(argv[i]+3,"%i",&listlinesperpage);
continue;
}
if(!strncmp("-D",argv[i],2)){
char *def=NULL;
expr *val;
if(argv[i][2])
def=&argv[i][2];
else if (i<argc-1)
def=argv[++i];
if(def){
char *s=def;
if(ISIDSTART(*s)){
s++;
while(ISIDCHAR(*s))
s++;
def=cnvstr(def,s-def);
if(*s=='='){
s++;
val=parse_expr(&s);
}
else
val=number_expr(1);
if(*s)
general_error(23,'D'); /* trailing garbage after option */
new_abs(def,val);
myfree(def);
continue;
}
}
}
if(!strncmp("-I",argv[i],2)){
char *path=NULL;
if(argv[i][2])
path=&argv[i][2];
else if (i<argc-1)
path=argv[++i];
if(path){
new_include_path(path);
continue;
}
}
if(!strncmp("-depend=",argv[i],8) || !strncmp("-dependall=",argv[i],11)){
depend_all=argv[i][7]!='=';
if(!strcmp("list",&argv[i][depend_all?11:8])){
depend=DEPEND_LIST;
continue;
}
else if(!strcmp("make",&argv[i][depend_all?11:8])){
depend=DEPEND_MAKE;
continue;
}
}
if(!strcmp("-depfile",argv[i])&&i<argc-1){
if(dep_filename)
general_error(28,argv[i]);
dep_filename=argv[++i];
continue;
}
if(!strcmp("-unnamed-sections",argv[i])){
unnamed_sections=1;
continue;
}
if(!strcmp("-ignore-mult-inc",argv[i])){
ignore_multinc=1;
continue;
}
if(!strcmp("-nocase",argv[i])){
nocase=1;
continue;
}
if(!strcmp("-nosym",argv[i])){
no_symbols=1;
continue;
}
if(!strncmp("-nowarn=",argv[i],8)){
int wno;
sscanf(argv[i]+8,"%i",&wno);
disable_warning(wno);
continue;
}
else if(!strcmp("-w",argv[i])){
no_warn=1;
continue;
}
else if(!strcmp("-wfail",argv[i])){
fail_on_warning=1;
continue;
}
if(!strncmp("-maxerrors=",argv[i],11)){
sscanf(argv[i]+11,"%i",&max_errors);
continue;
}
else if(!strcmp("-pic",argv[i])){
pic_check=1;
continue;
}
else if(!strncmp("-maxmacrecurs=",argv[i],14)){
sscanf(argv[i]+14,"%i",&maxmacrecurs);
continue;
}
else if(!strcmp("-unsshift",argv[i])){
unsigned_shift=1;
continue;
}
else if(!strcmp("-chklabels",argv[i])){
chklabels=1;
continue;
}
else if(!strcmp("-noialign",argv[i])){
inst_alignment=1;
continue;
}
else if(!strncmp("-dwarf",argv[i],6)){
if(argv[i][6]=='=')
sscanf(argv[i]+7,"%i",&dwarf); /* get DWARF version */
else
dwarf=3; /* default to DWARF3 */
continue;
}
else if(!strncmp("-pad=",argv[i],5)){
long long ullpadding;
sscanf(argv[i]+5,"%lli",&ullpadding);
sec_padding=(taddr)ullpadding;
continue;
}
if(cpu_args(argv[i]))
continue;
if(syntax_args(argv[i]))
continue;
if(output_args(argv[i]))
continue;
if(!strcmp("-esc",argv[i])){
esc_sequences=1;
continue;
}
if(!strcmp("-noesc",argv[i])){
esc_sequences=0;
continue;
}
if (!strncmp("-x",argv[i],2)){
auto_import=0;
continue;
}
general_error(14,argv[i]);
}
nostdout=depend&&dep_filename==NULL; /* dependencies to stdout nothing else */
include_main_source();
internal_abs(vasmsym_name);
if(!init_parse())
general_error(10,"parse");
if(!init_syntax())
general_error(10,"syntax");
if(!init_cpu())
general_error(10,"cpu");
parse();
listena=0;
if(errors==0||produce_listing)
resolve();
if(errors==0||produce_listing)
assemble();
cur_src=NULL;
if(errors==0)
undef_syms();
fix_labels();
if(produce_listing){
if(!listname)
listname="a.lst";
write_listing(listname);
}
if(errors==0){
if(depend&&dep_filename==NULL){
/* dependencies to stdout, no object output */
write_depends(stdout);
} else {
if(verbose)
statistics();
if(depend&&dep_filename!=NULL){
/* write dependencies to a named file first */
FILE *depfile = fopen(dep_filename,"w");
if (depfile){
write_depends(depfile);
fclose(depfile);
}
else
general_error(13,dep_filename);
}
/* write the object file */
if(!outname)
outname="a.out";
outfile=fopen(outname,"wb");
if(!outfile)
general_error(13,outname);
else
write_object(outfile,first_section,first_symbol);
}
}
leave();
return 0; /* not reached */
}
static void add_depend(char *name)
{
if (depend) {
struct deplist *d = first_depend;
/* check if an entry with the same file name already exists */
while (d != NULL) {
if (!strcmp(d->filename,name))
return;
d = d->next;
}
/* append new dependency record */
d = mymalloc(sizeof(struct deplist));
d->next = NULL;
if (name[0]=='.'&&(name[1]=='/'||name[1]=='\\'))
name += 2; /* skip "./" in paths */
d->filename = mystrdup(name);
if (last_depend)
last_depend = last_depend->next = d;
else
first_depend = last_depend = d;
}
}
static FILE *open_path(char *compdir,char *path,char *name,char *mode)
{
char pathbuf[MAXPATHLEN];
FILE *f;
if (strlen(compdir) + strlen(path) + strlen(name) + 1 <= MAXPATHLEN) {
strcpy(pathbuf,compdir);
strcat(pathbuf,path);
strcat(pathbuf,name);
if (f = fopen(pathbuf,mode)) {
if (depend_all || !abs_path(pathbuf))
add_depend(pathbuf);
return f;
}
}
return NULL;
}
FILE *locate_file(char *filename,char *mode,struct include_path **ipath_used)
{
struct include_path *ipath;
FILE *f;
if (abs_path(filename)) {
/* file name is absolute, then don't use any include paths */
if (f = fopen(filename,mode)) {
if (depend_all)
add_depend(filename);
if (ipath_used)
*ipath_used = NULL; /* no path used, file name was absolute */
return f;
}
}
else {
/* locate file name in all known include paths */
for (ipath=first_incpath; ipath; ipath=ipath->next) {
if ((f = open_path("",ipath->path,filename,mode)) == NULL) {
if (compile_dir && !abs_path(ipath->path) &&
(f = open_path(compile_dir,ipath->path,filename,mode)))
ipath->compdir_based = 1;
}
if (f != NULL) {
if (ipath_used)
*ipath_used = ipath;
return f;
}
}
}
general_error(12,filename);
return NULL;
}
source *include_source(char *inc_name)
{
static int srcfileidx;
char *filename,*pathpart,*filepart;
struct source_file **nptr = &first_source;
struct source_file *srcfile;
source *newsrc = NULL;
FILE *f;
filename = convert_path(inc_name);
/* check whether this source file name was already included */
while (srcfile = *nptr) {
if (!filenamecmp(srcfile->name,filename)) {
myfree(filename);
nptr = NULL; /* reuse existing source in memory */
break;
}
nptr = &srcfile->next;
}
if (nptr != NULL) {
/* allocate, locate and read a new source file */
struct include_path *ipath;
if (f = locate_file(filename,"r",&ipath)) {
char *text;
size_t size;
for (text=NULL,size=0; ; size+=SRCREADINC) {
size_t nchar;
text = myrealloc(text,size+SRCREADINC);
nchar = fread(text+size,1,SRCREADINC,f);
if (nchar < SRCREADINC) {
size += nchar;
break;
}
}
if (feof(f)) {
if (size > 0) {
text = myrealloc(text,size+2);
*(text+size) = '\n';
*(text+size+1) = '\0';
size++;
}
else {
myfree(text);
text = "\n";
size = 1;
}
srcfile = mymalloc(sizeof(struct source_file));
srcfile->next = NULL;
srcfile->name = filename;
srcfile->incpath = ipath;
srcfile->text = text;
srcfile->size = size;
srcfile->index = ++srcfileidx;
*nptr = srcfile;
cur_src = newsrc = new_source(filename,srcfile,text,size);
}
else
general_error(29,filename);
fclose(f);
}
}
else {
/* same source was already loaded before, source_file node exists */
if (ignore_multinc)
return NULL; /* ignore multiple inclusion of this source completely */
/* new source instance from existing source file */
cur_src = newsrc = new_source(srcfile->name,srcfile,srcfile->text,
srcfile->size);
}
return newsrc;
}
/* searches a section by name and attr (if secname_attr set) */
section *find_section(char *name,char *attr)
{
section *p;
if(secname_attr){
for(p=first_section;p;p=p->next){
if(!strcmp(name,p->name) && !strcmp(attr,p->attr))
return p;
}
}
else{
for(p=first_section;p;p=p->next){
if(!strcmp(name,p->name))
return p;
}
}
return 0;
}
/* create a new source text instance, which has cur_src as parent */
source *new_source(char *srcname,struct source_file *srcfile,
char *text,size_t size)
{
static unsigned long id = 0;
source *s = mymalloc(sizeof(source));
size_t i;
char *p;
/* scan the source for strange characters */
for (p=text,i=0; i<size; i++,p++) {
if (*p == 0x1a) {
/* EOF character - replace by newline and ignore rest of source */
*p = '\n';
size = i + 1;
break;
}
}
s->parent = cur_src;
s->parent_line = cur_src ? cur_src->line : 0;
s->srcfile = srcfile; /* NULL for macros and repetitions */
s->name = mystrdup(srcname);
s->text = text;
s->size = size;
s->defsrc = NULL;
s->defline = 0;
s->macro = NULL;
s->repeat = 1; /* read just once */
s->irpname = NULL;
s->cond_level = clev; /* remember level of conditional nesting */
s->num_params = -1; /* not a macro, no parameters */
s->param[0] = emptystr;
s->param_len[0] = 0;
s->id = id++; /* every source has unique id - important for macros */
s->srcptr = text;
s->line = 0;
s->bufsize = INITLINELEN;
s->linebuf = mymalloc(INITLINELEN);
#ifdef CARGSYM
s->cargexp = NULL;
#endif
#ifdef REPTNSYM
/* -1 outside of a repetition block */
s->reptn = cur_src ? cur_src->reptn : -1;
#endif
return s;
}
/* quit parsing the current source instance, leave macros, repeat loops
and restore the conditional assembly level */
void end_source(source *s)
{
if(s){
s->srcptr=s->text+s->size;
s->repeat=1;
clev=s->cond_level;
}
}
/* try to find a matching section name for the given attributes */
static char *name_from_attr(char *attr)
{
while(*attr) {
switch(*attr++) {
case 'c': return "text";
case 'd': return "data";
case 'u': return "bss";
}
}
return emptystr;
}
/* set current section, remember last */
void set_section(section *s)
{
#if NOT_NEEDED
if (current_section!=NULL && !(current_section->flags & UNALLOCATED)) {
if (current_section->flags & ABSOLUTE)
prev_org = current_section;
else
prev_sec = current_section;
}
#endif
#if HAVE_CPU_OPTS
if (s!=NULL && !(s->flags & UNALLOCATED))
cpu_opts_init(s); /* set initial cpu opts before the first atom */
#endif
current_section = s;
}
/* creates a new section with given attributes and alignment;
does not switch to this section automatically */
section *new_section(char *name,char *attr,int align)
{
section *p;
if(unnamed_sections)
name=name_from_attr(attr);
if(p=find_section(name,attr))
return p;
p=mymalloc(sizeof(*p));
p->next=0;
p->deps=0;
p->name=mystrdup(name);
p->attr=mystrdup(attr);
p->first=p->last=0;
p->align=align;
p->org=p->pc=0;
p->flags=0;
p->memattr=0;
memset(p->pad,0,MAXPADBYTES);
if(sec_padding)
p->padbytes=make_padding(sec_padding,p->pad,MAXPADBYTES);
else
p->padbytes=1;
if(last_section)
last_section=last_section->next=p;
else
first_section=last_section=p;
return p;
}
/* create a dummy code section for each new ORG directive */
section *new_org(taddr org)
{
char buf[16];
section *sec;
sprintf(buf,"seg%llx",ULLTADDR(org));
sec = new_section(buf,"acrwx",1);
sec->org = sec->pc = org;
sec->flags |= ABSOLUTE; /* absolute destination address */
return sec;
}
/* switches current section to the section with the specified name */
void switch_section(char *name,char *attr)
{
section *p;
if(unnamed_sections)
name=name_from_attr(attr);
p=find_section(name,attr);
if(!p)
general_error(2,name);
else
set_section(p);
}
/* Switches current section to an offset section. Create a new section when
it doesn't exist yet or needs a different offset. */
void switch_offset_section(char *name,taddr offs)
{
static unsigned long id;
char unique_name[14];
section *sec;
if (!name) {
if (offs != -1)
++id;
sprintf(unique_name,"OFFSET%06lu",id);
name = unique_name;
}
sec = new_section(name,"u",1);
sec->flags |= UNALLOCATED;
if (offs != -1)
sec->org = sec->pc = offs;
set_section(sec);
}
/* returns current_section or the syntax module's default section,
when undefined */
section *default_section(void)
{
section *sec = current_section;
if (!sec && defsectname && defsecttype) {
sec = new_section(defsectname,defsecttype,1);
switch_section(defsectname,defsecttype);
}
return sec;
}
#if NOT_NEEDED
/* restore last relocatable section */
section *restore_section(void)
{
if (prev_sec)
return prev_sec;
if (defsectname && defsecttype)
return new_section(defsectname,defsecttype,1);
return NULL; /* no previous section or default section defined */
}
/* restore last absolute section */
section *restore_org(void)
{
if (prev_org)
return prev_org;
return new_org(0); /* no previous org: default to ORG 0 */
}
#endif /* NOT_NEEDED */
/* end a relocated ORG block */
int end_rorg(void)
{
section *s = default_section();
if (s == NULL) {
general_error(3);
return 0;
}
if (s->flags & IN_RORG) {
add_atom(s,new_rorgend_atom());
if (s->flags & PREVABS)
s->flags |= ABSOLUTE;
else
s->flags &= ~ABSOLUTE;
s->flags &= ~IN_RORG;
return 1;
}
general_error(44); /* no Rorg block to end */
return 0;
}
/* end a relocated ORG block when currently active */
void try_end_rorg(void)
{
if (current_section!=NULL && (current_section->flags&IN_RORG))
end_rorg();
}
/* start a relocated ORG block */
void start_rorg(taddr rorg)
{
section *s = default_section();
if (s == NULL) {
general_error(3);
return;
}
if (s->flags & IN_RORG)
end_rorg(); /* we are already in a ROrg-block, so close it first */
add_atom(s,new_rorg_atom(rorg));
s->flags |= IN_RORG;
if (!(s->flags & ABSOLUTE)) {
s->flags &= ~PREVABS;
s->flags |= ABSOLUTE; /* make section absolute during the ROrg-block */
}
else
s->flags |= PREVABS;
}
void print_section(FILE *f,section *sec)
{
atom *p;
taddr pc=sec->org;
fprintf(f,"section %s (attr=<%s> align=%llu):\n",
sec->name,sec->attr,ULLTADDR(sec->align));
for(p=sec->first;p;p=p->next){
pc=pcalign(p,pc);
fprintf(f,"%8llx: ",ULLTADDR(pc));
print_atom(f,p);
fprintf(f,"\n");
pc+=atom_size(p,sec,pc);
}
}
static struct include_path *new_ipath_node(char *pathname)
{
struct include_path *new = mymalloc(sizeof(struct include_path));
new->next = NULL;
new->path = pathname;
new->compdir_based = 0;
return new;
}
struct include_path *new_include_path(char *pathname)
{
struct include_path *ipath;
char *newpath = convert_path(pathname);
pathname = append_path_delimiter(newpath); /* append '/', when needed */
myfree(newpath);
/* check if path already exists, otherwise append new node */
for (ipath=first_incpath; ipath; ipath=ipath->next) {
if (!filenamecmp(pathname,ipath->path)) {
myfree(pathname);
return ipath;
}
if (ipath->next == NULL)
return ipath->next = new_ipath_node(pathname);
}
return first_incpath = new_ipath_node(pathname);
}
void set_listing(int on)
{
listena = on && produce_listing;
}
void set_list_title(char *p,int len)
{
listtitlecnt++;
listtitles=myrealloc(listtitles,listtitlecnt*sizeof(*listtitles));
listtitles[listtitlecnt-1]=mymalloc(len+1);
strncpy(listtitles[listtitlecnt-1],p,len);
listtitles[listtitlecnt-1][len]=0;
listtitlelines=myrealloc(listtitlelines,listtitlecnt*sizeof(*listtitlelines));
listtitlelines[listtitlecnt-1]=cur_src->line;
}
static void print_list_header(FILE *f,int cnt)
{
if(cnt%listlinesperpage==0){
if(cnt!=0&&listformfeed)
fprintf(f,"\f");
if(listtitlecnt>0){
int i,t;
for(i=0,t=-1;i<listtitlecnt;i++){
if(listtitlelines[i]<=cnt+listlinesperpage)
t=i;
}
if(t>=0){
int sp=(120-strlen(listtitles[t]))/2;
while(--sp)
fprintf(f," ");
fprintf(f,"%s\n",listtitles[t]);
}
cnt++;
}
fprintf(f,"Err Line Loc. S Object1 Object2 M Source\n");
}
}
#if VASM_CPU_OIL
void write_listing(char *listname)
{
FILE *f;
int nsecs,i,cnt=0,nl;
section *secp;
listing *p;
atom *a;
symbol *sym;
taddr pc;
char rel;
if(!(f=fopen(listname,"w"))){
general_error(13,listname);
return;
}
for(nsecs=0,secp=first_section;secp;secp=secp->next)
secp->idx=nsecs++;
for(p=first_listing;p;p=p->next){
if(!p->src||p->src->id!=0)
continue;
print_list_header(f,cnt++);
if(p->error!=0)
fprintf(f,"%04d ",p->error);
else
fprintf(f," ");
fprintf(f,"%4d ",p->line);
a=p->atom;
while(a&&a->type!=DATA&&a->next&&a->next->line==a->line&&a->next->src==a->src)
a=a->next;
if(a&&a->type==DATA){
int size=a->content.db->size;
char *dp=a->content.db->data;
pc=p->pc;
fprintf(f,"%05lX %d ",(unsigned long)pc,(int)(p->sec?p->sec->idx:0));
for(i=0;i<8;i++){
if(i==4)
fprintf(f," ");
if(i<size){
fprintf(f,"%02X",(unsigned char)*dp++);
pc++;
}else
fprintf(f," ");
/* append following atoms with align 1 directly */
if(i==size-1&&i<7&&a->next&&a->next->align<=a->align&&a->next->type==DATA&&a->next->line==a->line&&a->next->src==a->src){
a=a->next;
size+=a->content.db->size;
dp=a->content.db->data;
}
}
fprintf(f," ");
if(a->content.db->relocs){
symbol *s=((nreloc *)(a->content.db->relocs->reloc))->sym;
if(s->type==IMPORT)
rel='X';
else
rel='0'+p->sec->idx;
}else
rel='A';
fprintf(f,"%c ",rel);
}else
fprintf(f," ");
fprintf(f," %-.77s",p->txt);
/* bei laengeren Daten den Rest ueberspringen */
/* Block entfernen, wenn alles ausgegeben werden soll */
if(a&&a->type==DATA&&i<a->content.db->size){
pc+=a->content.db->size-i;
i=a->content.db->size;
}
/* restliche DATA-Zeilen, wenn noetig */
while(a){
if(a->type==DATA){
int size=a->content.db->size;
char *dp=a->content.db->data+i;
if(i<size){
for(;i<size;i++){
if((i&7)==0){
fprintf(f,"\n");
print_list_header(f,cnt++);
fprintf(f," %05lX %d ",(unsigned long)pc,(int)(p->sec?p->sec->idx:0));
}else if((i&3)==0)
fprintf(f," ");
fprintf(f,"%02X",(unsigned char)*dp++);
pc++;
/* append following atoms with align 1 directly */
if(i==size-1&&a->next&&a->next->align<=a->align&&a->next->type==DATA&&a->next->line==a->line&&a->next->src==a->src){
a=a->next;
size+=a->content.db->size;
dp=a->content.db->data;
}
}
i=8-(i&7);
if(i>=4)
fprintf(f," ");
while(i--){
fprintf(f," ");
}
fprintf(f," %c",rel);
}
i=0;
}
if(a->next&&a->next->line==a->line&&a->next->src==a->src){
a=a->next;
pc=pcalign(a,pc);
if(a->type==DATA&&a->content.db->relocs){
symbol *s=((nreloc *)(a->content.db->relocs->reloc))->sym;
if(s->type==IMPORT)
rel='X';
else
rel='0'+p->sec->idx;
}else
rel='A';
}else
a=0;
}
fprintf(f,"\n");
}
fprintf(f,"\n\nSections:\n");
for(secp=first_section;secp;secp=secp->next)
fprintf(f,"%d %s\n",(int)secp->idx,secp->name);
if(!listnosyms){
fprintf(f,"\n\nSymbols:\n");
{
symbol *last=0,*cur,*symo;
for(symo=first_symbol;symo;symo=symo->next){
cur=0;
for(sym=first_symbol;sym;sym=sym->next){
if(!last||stricmp(sym->name,last->name)>0)
if(!cur||stricmp(sym->name,cur->name)<0)
cur=sym;
}
if(cur){
print_symbol(f,cur);
fprintf(f,"\n");
last=cur;
}
}
}
}
if(errors==0)
fprintf(f,"\nThere have been no errors.\n");
else
fprintf(f,"\nThere have been %d errors!\n",errors);
fclose(f);
for(p=first_listing;p;){
listing *m=p->next;
myfree(p);
p=m;
}
}
#else
void write_listing(char *listname)
{
FILE *f;
int nsecs,i,maxsrc=0;
section *secp;
listing *p;
atom *a;
symbol *sym;
taddr pc;
if(!(f=fopen(listname,"w"))){
general_error(13,listname);
return;
}
for(nsecs=1,secp=first_section;secp;secp=secp->next)
secp->idx=nsecs++;
for(p=first_listing;p;p=p->next){
char err[6];
if(p->error!=0)
sprintf(err,"E%04d",p->error);
else
sprintf(err," ");
if(p->src&&p->src->id>maxsrc)
maxsrc=p->src->id;
fprintf(f,"F%02d:%04d %s %s",(int)(p->src?p->src->id:0),p->line,err,p->txt);
a=p->atom;
pc=p->pc;
while(a){
if(a->type==DATA){
int size=a->content.db->size;
for(i=0;i<size&&i<32;i++){
if((i&15)==0)
fprintf(f,"\n S%02d:%08lX: ",(int)(p->sec?p->sec->idx:0),(unsigned long)(pc));
fprintf(f," %02X",(unsigned char)a->content.db->data[i]);
pc++;
}
if(a->content.db->relocs)
fprintf(f," [R]");
}
if(a->next&&a->next->list==a->list){
a=a->next;
pc=pcalign(a,pc);
}else
a=0;
}
fprintf(f,"\n");
}
fprintf(f,"\n\nSections:\n");
for(secp=first_section;secp;secp=secp->next)
fprintf(f,"S%02d %s\n",(int)secp->idx,secp->name);
fprintf(f,"\n\nSources:\n");
for(i=0;i<=maxsrc;i++){
for(p=first_listing;p;p=p->next){
if(p->src&&p->src->id==i){
fprintf(f,"F%02d %s\n",i,p->src->name);
break;
}
}
}
fprintf(f,"\n\nSymbols:\n");
for(sym=first_symbol;sym;sym=sym->next){
print_symbol(f,sym);
fprintf(f,"\n");
}
if(errors==0)
fprintf(f,"\nThere have been no errors.\n");
else
fprintf(f,"\nThere have been %d errors!\n",errors);
fclose(f);
for(p=first_listing;p;){
listing *m=p->next;
myfree(p);
p=m;
}
}
#endif