ack/util/ego/share/get.c
George Koehler 36f16b0cb8 Cut down some clang warnings
Edit C code to reduce warnings from clang.  Most warnings are for
implicit declarations of functions, but some warnings want me to add
parentheses or curly braces, or to cast arguments for printf().

Make a few other changes, like declaring float_cst() in h/con_float to
be static, and using C99 bool in ego/ra/makeitems.c and
ego/share/makecldef.c.  Such changes don't silence warnings; I make
such changes while I silence warnings in the same file.  In
float_cst(), rename parameter `str` to `float_str`, so it doesn't
share a name with the global variable `str`.

Remove `const` from `newmodule(const char *)` in mach/proto/as to
silence a warning.  I wrongly added the `const` in d347207.

For warnings about implicit declarations of functions, the fix is to
declare the function before calling it.  For example, my OpenBSD
system needs <sys/wait.h> to declare wait().

In util/int, add "whatever.h" to declare more functions.  Remove old
declarations from "mem.h", to prefer the newer declarations of the
same functions in "data.h" and "stack.h".
2019-10-30 18:36:38 -04:00

535 lines
12 KiB
C

/* $Id$ */
/*
* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
* See the copyright notice in the ACK home directory, in the file "Copyright".
*/
/* S H A R E D F I L E
*
* G E T . C
*/
#include <stdio.h>
#include <em_spec.h>
#include <em_mnem.h>
#include <em_pseu.h>
#include <em_mes.h>
#include "types.h"
#include "def.h"
#include "debug.h"
#include "global.h"
#include "lset.h"
#include "cset.h"
#include "get.h"
#include "alloc.h"
#include "map.h"
#include "utils.h"
FILE *curinp;
block_id lastbid; /* block identifying number */
lab_id lastlabid; /* last label identifier */
/* creating new identifying numbers, i.e. numbers that did not
* appear in the input.
*/
bblock_p freshblock(void)
{
bblock_p b;
b = newbblock();
b->b_id = ++lastbid;
return b;
}
lab_id freshlabel(void)
{
curproc->p_nrlabels++;
return ++lastlabid;
}
#define getmark() getbyte()
short getshort(void) {
register int l_byte, h_byte;
l_byte = getbyte();
h_byte = getbyte();
if ( h_byte>=128 ) h_byte -= 256 ;
return l_byte | (h_byte*256) ;
}
offset getoff(void) {
register long l;
register int h_byte;
l = getbyte();
l |= ((unsigned) getbyte())*256 ;
l |= getbyte()*256L*256L ;
h_byte = getbyte() ;
if ( h_byte>=128 ) h_byte -= 256 ;
return l | (h_byte*256L*256*256L) ;
}
STATIC int getint(void)
{
/* Read an integer from the input file. This routine is
* only used when reading a bitvector-set. We expect an
* integer to be either a short or a long.
*/
if (sizeof(int) == sizeof(short)) {
return getshort();
} else {
assert (sizeof(int) == sizeof(offset));
return getoff();
}
}
/* getptable */
STATIC void *getloop(loop_id id)
{
/* Map a loop identifier onto a loop struct.
* If no struct was alocated yet for this identifier then
* allocate one now and update the loop-map table.
*/
assert (id > 0 && id <=lplength);
if (lpmap[id] == (loop_p) 0) {
lpmap[id] = newloop();
lpmap[id]->lp_id = id;
}
return (lpmap[id]);
}
STATIC void *getblock(block_id id)
{
/* Map a basic block identifier onto a block struct
* If no struct was alocated yet for this identifier then
* allocate one now and update the block-map table.
*/
assert (id >= 0 && id <=blength);
if (id == 0) return (bblock_p) 0;
if (bmap[id] == (bblock_p) 0) {
bmap[id] = newbblock();
bmap[id]->b_id = id;
}
return (bmap[id]);
}
STATIC lset getlset(void *(*p)(short))
{
/* Read a 'long' set. Such a set is represented externally
* as a sequence of identifying numbers terminated by a 0.
* The procedural parameter p maps such a number onto a
* pointer to a struct (bblock_p, loop_p etc.).
*/
lset s;
int id;
s = Lempty_set();
while ((id = getshort()) != 0) {
Ladd( (*p) (id), &s);
}
return s;
}
STATIC cset getcset()
{
/* Read a 'compact' set. Such a set is represented externally
* a row of bytes (its bitvector) preceded by its length.
*/
cset s;
register short i;
s = Cempty_set(getshort());
for (i = 0; i <= DIVWL(s->v_size-1);i++) {
s->v_bits[i] = getint();
}
return s;
}
proc_p getptable(const char *pname)
{
short i;
proc_p head, p, *pp;
short all;
if ((curinp = fopen(pname,"r")) == NULL) {
error("cannot open %s",pname);
}
plength = getshort(); /* table is preceded by its length */
assert(plength >= 0);
assert(plength < 1000); /* See if its a reasonable number */
pmap = (proc_p *) newmap(plength); /* allocate the pmap table */
all = getshort();
head = (proc_p) 0;
pp = &head;
for (i = 0; i < plength; i++) {
if (feof(curinp)) {
error("unexpected eof %s", pname);
}
p = newproc();
p->p_id = getshort();
assert(p->p_id > 0 && p->p_id <= plength);
pmap[p->p_id] = p;
p->p_flags1 = getbyte();
if (p->p_flags1 & PF_BODYSEEN) {
p->p_nrlabels = getshort();
p->p_localbytes = getoff();
p->p_nrformals = getoff();
if (all) {
p->p_change = newchange();
p->p_change->c_ext = getcset();
p->p_change->c_flags = getshort();
p->p_use = newuse();
p->p_use->u_flags = getshort();
p->p_calling = getcset();
}
}
*pp = p;
pp = &(p->p_next);
}
fclose(curinp);
OUTTRACE("have read proc table of length %d",plength);
return head; /* pointer to first structure of list */
}
/* getdtable */
dblock_p getdtable(const char *dname)
{
/* Read the data block table. Every data block may
* have a list of objects and a list of values (arguments),
* each of which is also represented by a structure.
* So the input file contains a mixture of dblock,
* obj and arg records, each one having its own
* attributes. A mark indicates which one comes next.
* We assume that the syntactic structure of the input
* is correct.
*/
dblock_p head, d = 0, *dp = &head;
obj_p obj, *op = 0;
arg_p arg, *ap = 0;
/* dp, op an ap tell how the next dblock/obj/arg
* has to be linked.
*/
int n;
head = (dblock_p) 0;
if ((curinp = fopen(dname,"r")) == NULL) {
error("cannot open %s", dname);
}
olength = getshort();
assert(olength >= 0);
assert(olength < 5000); /* See if its a reasonable number */
/* total number of objects */
omap = (obj_p *) newmap(olength); /* allocate omap table */
while (TRUE) {
n = getmark();
if (feof(curinp)) break;
switch(n) {
case MARK_DBLOCK:
d = *dp = newdblock();
op = &d->d_objlist;
ap = &d->d_values;
dp = &d->d_next;
d->d_id = getshort();
d->d_pseudo = getbyte();
d->d_size = getoff();
d->d_fragmnr = getshort();
d->d_flags1 = getbyte();
break;
case MARK_OBJ:
obj = *op = newobject();
op = &obj->o_next;
obj->o_dblock = d;
obj->o_id = getshort();
assert(obj->o_id >0);
assert(obj->o_id <= olength);
omap[obj->o_id] = obj;
obj->o_size = getoff();
obj->o_off = getoff();
break;
case MARK_ARG:
arg = *ap = newarg(ARGOFF);
ap = &arg->a_next;
arg->a_a.a_offset = getoff();
break;
default:
assert(FALSE);
}
}
OUTTRACE("have read data table, %d objects",olength);
return head;
}
/* getbblocks */
STATIC void argstring(short length, argb_p abp)
{
while (length--) {
if (abp->ab_index == NARGBYTES)
abp = abp->ab_next = newargb();
abp->ab_contents[abp->ab_index++] = getbyte();
}
}
STATIC arg_p readargs(void)
{
/* Read a list of arguments and allocate structures
* for them. Return a pointer to the head of the list.
*/
arg_p head, arg, *ap;
byte t;
short length;
ap = &head;
for (;;) {
/* every argument list is terminated by an
* ARGCEND byte in Intermediate Code.
*/
t = getbyte();
if (t == (byte) ARGCEND) {
return head;
}
arg = *ap = newarg(t);
ap = &arg->a_next;
switch((short) t) {
case ARGOFF:
arg->a_a.a_offset = getoff();
break;
case ARGINSTRLAB:
arg->a_a.a_instrlab = getshort();
break;
case ARGOBJECT:
arg->a_a.a_obj = omap[getshort()];
/* Read an object identifier (o_id)
* and use the omap table to obtain
* a pointer to the rigth obj struct.
*/
break;
case ARGPROC:
arg->a_a.a_proc = pmap[getshort()];
/* Read a procedure identifier (p_id) */
break;
case ARGSTRING:
length = getshort();
argstring(length, &arg->a_a.a_string);
break;
case ARGICN:
case ARGUCN:
case ARGFCN:
length = getshort();
arg->a_a.a_con.ac_length = length;
/* size of the constant */
argstring(getshort(),
&arg->a_a.a_con.ac_con);
break;
default:
assert(FALSE);
}
}
}
line_p read_line(proc_p *p_out)
{
/* Read a line of EM code (i.e. one instruction)
* and its arguments (if any).
* In Intermediate Code, the first byte is the
* instruction code and the second byte denotes the kind
* of operand(s) that follow.
*/
line_p lnp;
byte instr;
instr = getbyte();
if (feof(curinp)) return (line_p) 0;
lnp = newline(getbyte());
linecount++;
lnp->l_instr = instr;
switch(TYPE(lnp)) {
/* read the operand(s) */
case OPSHORT:
SHORT(lnp) = getshort();
break;
case OPOFFSET:
OFFSET(lnp) = getoff();
break;
case OPINSTRLAB:
INSTRLAB(lnp) = getshort();
if ((instr & BMASK) == op_lab) {
/* defining occurrence of an
* instruction label.
*/
lmap[INSTRLAB(lnp)] = lnp;
}
break;
case OPOBJECT:
OBJ(lnp) = omap[getshort()];
break;
case OPPROC:
PROC(lnp) = pmap[getshort()];
if ((instr & BMASK) == ps_pro) {
/* enter new procedure: allocate a
* label map and a label-block map table.
*/
*p_out = PROC(lnp);
llength = (*p_out)->p_nrlabels;
lmap = (line_p *) newmap(llength);
/* maps lab_id to line structure */
lbmap = (bblock_p *) newmap(llength);
/* maps lab_id to bblock structure */
lastlabid = llength;
}
break;
case OPLIST:
ARG(lnp) = readargs();
break;
default:
assert(TYPE(lnp) == OPNO);
}
return lnp;
}
void message(line_p lnp)
{
/* See if lnp is some useful message.
* (e.g. a message telling that a certain local variable
* will never be referenced indirectly, so it may be put
* in a register. If so, add it to the mesregs set.)
*/
assert(ARG(lnp)->a_type == ARGOFF);
switch((int) aoff(ARG(lnp),0)) {
case ms_reg:
if (ARG(lnp)->a_next != (arg_p) 0) {
/* take only "mes 3" with further arguments */
Ladd((Lelem_t) lnp,&mesregs);
}
break;
case ms_err:
error("ms_err encountered");
case ms_opt:
error("ms_opt encountered");
case ms_emx:
ws = aoff(ARG(lnp),1);
ps = aoff(ARG(lnp),2);
break;
}
}
line_p getlines(FILE *lf, int n, proc_p *p_out, bool collect_mes)
{
/* Read n lines of EM text and doubly link them.
* Also process messages.
*/
line_p head, *pp, l, lprev;
curinp = lf; /* EM input file */
pp = &head;
lprev = (line_p) 0;
while (n--) {
l = *pp = read_line(p_out);
PREV(l) = lprev;
pp = &l->l_next;
lprev = l;
if (collect_mes && INSTR(l) == ps_mes) {
message(l);
}
}
*pp = (line_p) 0;
return head;
}
bool getunit(FILE *gf, FILE *lf, short *kind_out, bblock_p *g_out,
line_p *l_out, proc_p *p_out, bool collect_mes)
{
/* Read control flow graph (gf) and EM text (lf) of the next procedure.
* A pointer to the proctable entry of the read procedure is
* returned via p_out.
* This routine also constructs the bmap and lpmap tables.
* Note that we allocate structs for basic blocks and loops
* at their first reference rather than at when we read them.
*/
int n,i;
bblock_p head, *pp, b;
loop_p lp;
curinp = gf;
blength = getshort(); /* # basic blocks in this procedure */
if (feof(curinp)) return FALSE;
if (blength == 0) {
/* data unit */
*kind_out = LDATA;
n = getshort();
*l_out = getlines(lf,n,p_out,collect_mes);
return TRUE;
}
*kind_out = LTEXT;
bmap = (bblock_p *) newmap(blength); /* maps block_id on bblock_p */
lplength = getshort(); /* # loops in this procedure */
lpmap = (loop_p *) newmap(lplength); /* maps loop_id on loop_p */
/* Read the basic blocks and the EM text */
pp = &head; /* we use a pointer-to-a-pointer to link the structs */
for (i = 0; i < blength; i++) {
b = getblock(getshort());
n = getshort(); /* #instructions in the block */
b->b_succ = getlset(getblock);
b->b_pred = getlset(getblock);
b->b_idom = getblock(getshort());
b->b_loops = getlset(getloop);
b->b_flags = getshort();
b->b_start = getlines(lf,n,p_out,collect_mes); /* read EM text */
*pp = b;
pp = &b->b_next;
curinp = gf;
}
lastbid = blength; /* last block_id */
/* read the information about loops */
curproc->p_loops = Lempty_set();
for (i = 0; i < lplength; i++) {
lp = getloop(getshort());
lp->lp_level = getshort(); /* nesting level */
lp->lp_entry = getblock(getshort()); /* entry block of the loop */
lp->lp_end = getblock(getshort()); /* tail of back edge of loop */
Ladd((Lelem_t)lp,&curproc->p_loops);
}
*g_out = head;
return TRUE;
}