ack/util/led/main.c

616 lines
13 KiB
C
Raw Normal View History

1987-03-09 19:15:41 +00:00
/*
* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
* See the copyright notice in the ACK home directory, in the file "Copyright".
*/
#ifndef lint
static char rcsid[] = "$Header$";
#endif
/*
* led - linkage editor for ACK assemblers output format
*/
#include <stdio.h>
#include <out.h>
#include "const.h"
#include "debug.h"
#include "defs.h"
#include "memory.h"
#include "orig.h"
extern bool incore;
#ifndef NOSTATISTICS
int statistics;
#endif
#ifndef NDEBUG
int DEB = 0;
#endif
static initializations();
static first_pass();
static long number();
static setlign();
static setbase();
static struct outname *makename();
static pass1();
static evaluate();
static norm_commons();
static complete_sections();
static change_names();
static bool tstbit();
static second_pass();
static pass2();
#ifndef NOSTATISTICS
static do_statistics();
#endif
main(argc, argv)
int argc;
char **argv;
{
initializations(argc, argv);
first_pass(argv);
#ifndef NOSTATISTICS
1987-08-11 15:31:09 +00:00
if (statistics) do_statistics();
#endif
freeze_core();
evaluate();
beginoutput();
second_pass(argv);
endoutput();
stop();
}
#ifndef NOSTATISTICS
static
do_statistics()
{
register struct memory *m = mems;
while (m <= &mems[NMEMS-1]) {
fprintf(stderr, "mem %d: full %lx, free %lx\n",
m - mems,
(long) m->mem_full,
(long) m->mem_left);
m++;
}
}
#endif
char *progname; /* Name this program was invoked with. */
int passnumber; /* Pass we are in. */
struct outhead outhead; /* Header of final output file. */
struct outsect outsect[MAXSECT];/* Its section table. */
/* ARGSUSED */
static
initializations(argc, argv)
int argc;
char *argv[];
{
/*
* Avoid malloc()s.
*/
setbuf(stdin, (char *)NULL);
setbuf(stdout, (char *)NULL);
setbuf(stderr, (char *)NULL);
progname = argv[0];
passnumber = FIRST;
init_core();
init_symboltable();
outhead.oh_magic = O_MAGIC;
outhead.oh_stamp = O_STAMP;
}
/* ------------------------ ROUTINES OF FIRST PASS ------------------------- */
int flagword = 0; /* To store command-line options. */
char *outputname = "a.out"; /* Name of the resulting object file. */
int exitstatus = 0;
/*
* Scan the arguments.
* If the argument starts with a '-', it's a flag, else it is either
* a plain file to be loaded, or an archive.
*/
static
first_pass(argv)
register char **argv;
{
register char *argp;
int sectno;
int h;
extern int atoi();
extern char *strindex();
extern int hash();
extern struct outname *searchname();
while (*++argv) {
argp = *argv;
if (*argp != '-') {
pass1(argp);
continue;
}
/* It's a flag. */
switch (*++argp) {
case 'a':
/*
* The rest of the argument must be of the form
* `<section number>:<alignment>', where
* <section number> and <alignment> are numbers.
* <alignment> will be the alignment in the machine of
* section <section number>.
*/
sectno = atoi(++argp);
if ((argp = strindex(argp, ':')) == (char *)0)
fatal("usage: -a<section number>:<alignment>");
setlign(sectno, number(++argp));
break;
case 'b':
/*
* The rest of the argument must be of the form
* `<section number>:<base>', where <section number>
* and base are decimal numbers. <base> will be
* the base address in the machine of section
* <section number>.
*/
sectno = atoi(++argp);
if ((argp = strindex(argp, ':')) == (char *)0)
fatal("usage: -b<section number>:<base>");
setbase(sectno, number(++argp));
break;
1987-02-05 14:11:46 +00:00
case 'c':
/*
* Leave relocation information in the output, so that
* a next pass can see where relocation was done. The
* resulting output however is no longer relocatable.
1987-02-05 14:11:46 +00:00
*/
flagword &= ~RFLAG;
1987-02-05 14:11:46 +00:00
flagword |= CFLAG;
break;
#ifndef NDEBUG
case 'd':
DEB = 1;
break;
#endif
case 'o':
/*
* The `name' argument after -o is used as name
* of the led output file, instead of "a.out".
*/
if ((outputname = *++argv) == (char *)0)
fatal("-o needs filename");
break;
case 'r':
/*
* Generate relocation information in the output file
* so that it can be the subject of another led run.
* This flag also prevents final definitions from being
* given to common symbols, and suppresses the
* `Undefined:' diagnostic.
*/
if (flagword & CFLAG) break;
if (flagword & SFLAG)
warning("-r contradicts -s: -s ignored");
flagword |= RFLAG;
break;
case 's':
/*
* `Strip' the output, that is, remove the symbol table
* and relocation table to save space (but impair the
* usefullness of the debuggers). This information can
* also be removed by astrip(1).
*/
if (flagword & RFLAG)
warning("-s contradicts -r: -s ignored");
else
flagword |= SFLAG;
break;
case 'u':
/*
* Take the following argument as a symbol and enter it
* as undefined in the symbol table. This is useful for
* loading wholly from a library, since initially the
* symbol table is empty and an unresolved reference is
* needed to force the loading of the first routine.
*/
if (*++argv == (char *)0)
fatal("-u needs symbol name");
h = hash(*argv);
if (searchname(*argv, h) == (struct outname *)0)
entername(makename(*argv), h);
break;
case 'S':
statistics = 1;
break;
default:
1987-03-05 14:57:15 +00:00
warning("bad flag letter %c", *argp);
break;
}
}
}
/*
* If `s' starts with 0x/0X, it's hexadecimal,
* else if it starts with 0b/0B, it's binary,
* else if it starts with 0, it's octal,
* else it's decimal.
*/
static long
number(s)
register char *s;
{
register int digit;
register long value = 0;
register int radix = 10;
if (*s == '0') {
radix = 8;
s++;
if (*s == 'x' || *s == 'X') {
radix = 16;
s++;
} else if (*s == 'b' || *s == 'B') {
radix = 2;
s++;
}
}
while (digit = *s++) {
if (digit >= 'A' && digit <= 'F')
digit = digit - 'A' + 10;
else if (digit >= 'a' && digit <= 'f')
digit = digit - 'a' + 10;
else if (digit >= '0' && digit <= '9')
digit = digit - '0';
else
fatal("wrong digit %c", digit);
if (digit >= radix)
fatal("digit %c exceeds radix %d", digit, radix);
value = radix * value + digit;
}
return value;
}
/*
* We use one bit per section to indicate whether a base was already given or
* not. Only one base may be given. The same applies for alignments.
*/
static char basemap[MAXSECT / WIDTH];
static long sect_base[MAXSECT];
static char lignmap[MAXSECT / WIDTH];
static long sect_lign[MAXSECT];
/*
/*
* Set the alignment of section `sectno' to `lign', if this doesn't
* conflict with earlier alignment.
*/
static
setlign(sectno, lign)
register int sectno;
register long lign;
{
extern bool setbit();
if (setbit(sectno, lignmap) && sect_lign[sectno] != lign)
fatal("section has different alignments");
if (lign == (long)0)
fatal("alignment cannot be zero");
sect_lign[sectno] = lign;
}
/*
* Set the base of section `sectno' to `base', if no other base has been
* given yet.
*/
static
setbase(sectno, base)
register int sectno;
register long base;
{
extern bool setbit();
if (setbit(sectno, basemap) && sect_base[sectno] != base)
fatal("section has different bases");
sect_base[sectno] = base;
}
static struct outname *
makename(string)
char *string;
{
static struct outname namebuf;
namebuf.on_mptr = string;
namebuf.on_type = S_UND + S_EXT;
namebuf.on_valu = (long)0;
return &namebuf;
}
/*
* If `file' is a plain file, symboltable information and section sizes are
* extracted. If it is an archive it is examined to see if it defines any
* undefined symbols.
*/
static
pass1(file)
char *file;
{
if (getfile(file) == PLAIN) {
debug("%s: plain file\n", file, 0, 0, 0);
extract();
} else {
/* It must be an archive. */
debug("%s: archive\n", file, 0, 0, 0);
arch();
}
closefile(file);
}
/* ---------------- ROUTINES BETWEEN FIRST AND SECOND PASS ----------------- */
/*
* After pass 1 we know the sizes of all commons so we can give each common
* name an address within its section and we can compute the sizes of all
* sections in the machine. After this we can compute the bases of all
* sections. We then add the section bases to the values of names in
* corresponding sections.
*/
static
evaluate()
{
norm_commons();
complete_sections();
if (!(flagword&RFLAG))
change_names();
}
extern ushort NGlobals, NLocals;
/*
* Sect_comm[N] is the number of common bytes in section N.
* It is computed after pass 1.
*/
long sect_comm[MAXSECT];
/*
* If there are undefined names, we print them and we set a flag so that
* the output can be subject to another led run and we return.
* We now know how much space each common name needs. We change the value
* of the common name from the size to the address within its section,
* just like "normal" names. We also count the total size of common names
* within each section to be able to compute the final size in the machine.
*/
static
norm_commons()
{
register struct outname *name;
register int cnt;
register int und = FALSE;
name = (struct outname *)address(ALLOGLOB, (ind_t)0);
cnt = NGlobals;
while (cnt-- > 0) {
if (ISUNDEFINED(name)) {
if (!und) {
und = TRUE;
if (!(flagword & RFLAG)) {
exitstatus = 1;
fprintf(stderr, "Undefined:\n");
}
outhead.oh_flags |= HF_LINK;
if (flagword & RFLAG) break;
flagword = (flagword & ~SFLAG) | RFLAG;
}
fprintf(stderr, "\t%s\n",
address(ALLOGCHR, (ind_t)name->on_foff)
);
}
name++;
}
if (flagword & RFLAG) return;
/*
* RFLAG is off, so we need not produce relocatable output.
* We can now assign an address to common names.
* It also means that there are no undefined names.
*/
name = (struct outname *)address(ALLOGLOB, (ind_t)0);
cnt = NGlobals;
while (cnt-- > 0) {
if (!ISABSOLUTE(name) && ISCOMMON(name)) {
register long size;
register int sectindex;
size = name->on_valu; /* XXX rounding? */
sectindex = (name->on_type & S_TYP) - S_MIN;
name->on_valu =
outsect[sectindex].os_size +
sect_comm[sectindex];
sect_comm[sectindex] += size;
name->on_type &= ~S_COM;
}
name++;
}
}
struct orig relorig[MAXSECT];
/*
* Compute the offsets in file and machine that the sections will have.
* Also set the origins to 0.
*/
static
complete_sections()
{
register long base = 0;
register long foff;
1987-08-06 18:40:02 +00:00
register struct outsect *sc;
register int sectindex;
foff = SZ_HEAD + outhead.oh_nsect * SZ_SECT;
for (sectindex = 0; sectindex < outhead.oh_nsect; sectindex++) {
relorig[sectindex].org_size = (long)0;
1987-08-06 18:40:02 +00:00
sc = &outsect[sectindex];
sc->os_foff = foff;
foff += sc->os_flen;
if (flagword & RFLAG)
continue;
1987-08-06 18:40:02 +00:00
sc->os_size += sect_comm[sectindex];
sc->os_lign =
tstbit(sectindex, lignmap) ? sect_lign[sectindex] : 1;
if (tstbit(sectindex, basemap)) {
base = sect_base[sectindex];
if (sc->os_lign && base % sc->os_lign)
fatal("base not aligned");
} else if (sc->os_lign) {
1987-08-06 18:40:02 +00:00
base += sc->os_lign - 1;
base -= base % sc->os_lign;
}
1987-08-06 18:40:02 +00:00
sc->os_base = base;
base += sc->os_size;
}
}
/*
* For each name we add the base of its section to its value, unless
* the output has to be able to be linked again, as indicated by RFLAG.
*/
static
change_names()
{
register int cnt;
register struct outname *name;
name = (struct outname *)address(ALLOGLOB, (ind_t)0);
cnt = NGlobals;
while (cnt-- > 0) {
addbase(name);
name++;
}
if (!incore)
return;
/*
* Do the same with the local names.
*/
name = (struct outname *)address(ALLOLOCL, (ind_t)0);
cnt = NLocals;
while (cnt-- > 0) {
addbase(name);
name++;
}
}
#define BIT 0x01
/*
* This function sets a bit with index `indx' in string.
* It returns whether it was already set.
*/
bool
setbit(indx, string)
int indx;
char string[];
{
register int byte_index, bit_index;
register int byte;
byte_index = indx / WIDTH; /* Index of byte with bit we need. */
bit_index = indx % WIDTH; /* Index of bit we need. */
byte = string[byte_index];
byte >>= bit_index;
if (byte & BIT) return TRUE;
byte = BIT;
byte <<= bit_index;
string[byte_index] |= byte;
return FALSE;
}
/*
* This function returns whether the bit given by `indx' is set in `string'.
*/
static bool
tstbit(indx, string)
int indx;
char string[];
{
register int byte_index, bit_index;
register int byte;
byte_index = indx / WIDTH; /* Index of byte with bit we need. */
bit_index = indx % WIDTH; /* Index of bit we need. */
byte = string[byte_index];
byte >>= bit_index;
return byte & BIT;
}
/*
* Add the base of the section of a name to its value.
*/
addbase(name)
struct outname *name;
{
register int type = name->on_type & S_TYP;
register int sectindex = type - S_MIN;
if (type == S_UND || type == S_ABS)
return;
if (name->on_type & S_COM)
return;
name->on_valu += outsect[sectindex].os_base;
debug( "%s: type 0x%x, value %ld\n",
address((name->on_type & S_EXT) ? ALLOGCHR : ALLOLCHR,
(ind_t)name->on_foff
),
name->on_type, name->on_valu, 0
);
}
/* ------------------------ ROUTINES OF SECOND PASS ------------------------ */
/*
* Flags have already been processed, so we ignore them here.
*/
static
second_pass(argv)
char **argv;
{
passnumber = SECOND;
while (*++argv) {
if ((*argv)[0] != '-') {
pass2(*argv);
continue;
}
switch ((*argv)[1]) {
case 'o':
case 'u':
++argv;
break;
default:
break;
}
}
}
static
pass2(file)
char *file;
{
if (getfile(file) == PLAIN) {
debug("%s: plain file\n", file, 0, 0, 0);
finish();
} else {
/* It must be an archive. */
debug("%s: archive\n", file, 0, 0, 0);
arch2();
}
closefile(file);
}