gno/kern/gno/sys.c
1998-02-02 08:20:59 +00:00

1250 lines
32 KiB
C

/* $Id: sys.c,v 1.1 1998/02/02 08:19:05 taubert Exp $ */
#pragma optimize 79
segment "KERN2 ";
/*
sys.c
GS/IX Kernel routines for process control
Copyright 1991-1998, Procyon, Inc.
Jawaid Bazyar and Derek Taubert
*/
#include "conf.h"
#include "proc.h"
#include "kernel.h"
#include "gno.h"
#include "kvm.h"
#include "sys.h"
#include "/lang/orca/libraries/orcacdefs/stdio.h"
#include "/lang/orca/libraries/orcacdefs/string.h"
#include "/lang/orca/libraries/orcacdefs/stdlib.h"
#include <loader.h>
#include <memory.h>
#include <gsos.h>
#include <shell.h>
#include <texttool.h>
#include <misctool.h>
#include <sys/errno.h>
#include <sys/times.h>
extern kernelStructPtr kp;
/* signal context record */
typedef struct ctxt {
word ctx_A;
word ctx_X;
word ctx_Y;
word ctx_state;
word ctx_D;
byte ctx_B;
byte ctx_B1;
word ctx_P;
word ctx_S1;
longword ctx_PC;
} ctxt, *ctxtPtr;
struct GSString1K {
Word length; /* Number of Chars in text field */
char text[1024];
} ;
typedef struct GSString1K GSString1K, *GSString1KPtr;
struct ResultBuf1K {
Word bufSize;
GSString1K bufString;
} ;
typedef struct ResultBuf1K ResultBuf1K, *ResultBuf1KPtr;
/*
this is the info kept per-process on what sorts of shit the process
expects for I/O. This is similar to a special case of user.h fd table
including only the stdin/stdout fds (0-2).
*/
typedef struct ttyinf {
word InANDMask;
word InORMask;
word OutANDMask;
word OutORMask;
word ErrANDMask;
word ErrORMask;
word InDeviceType;
word OutDeviceType;
word ErrDeviceType;
longword InSlot;
longword OutSlot;
longword ErrSlot;
word dummy;
} ttyinf;
#define NPGRP 32
pgrp pgrpInfo[NPGRP];
typedef struct ttyInfo {
word pgrp;
} ttyInfo;
extern ttyStruct;
ttyInfo *ttys = (ttyInfo *) &ttyStruct;
#define isbadpgrp(p) ((p < 0) || (p >= NPGRP))
static word hiWord(longword w)
{
word h;
asm {
lda w+2
sta h
}
return h;
}
static word loWord(longword w)
{
word l;
asm {
lda w
sta l
}
return l;
}
void *kmalloc(size_t size)
{
handle h;
word p_uid;
void *x;
/* $$$ p_uid = kp->procTable[Kgetpid()].userID; */
p_uid = PROC->userID;
h = NewHandle(size, p_uid, 0xC008, NULL);
if (toolerror()) {
fprintf(stderr, "kmalloc:%04X\n",toolerror());
return NULL;
}
x = *h;
return x;
}
void *pmalloc(size_t size, word p_uid)
{
handle h;
void *x;
h = NewHandle(size, p_uid, 0xC008, NULL);
if (toolerror()) {
fprintf(stderr, "pmalloc:%04X\n",toolerror());
return NULL;
}
x = *h;
return x;
}
int kfree(void *mem)
{
handle h;
if (h = (FindHandle(mem) == NULL)) return SYSERR;
DisposeHandle(h);
return (OK);
}
static int findEmptyProc(void)
{
int i;
for (i = 0; i < NPROC; i++)
if (kp->procTable[i].processState == procUNUSED) return i;
return -1;
}
#if 0
int isbadpid( int pid )
{
int mpid;
mpid = mapPID(pid);
if (mpid == -1) return SYSERR;
else return SYSOK;
}
#endif
static int createProc(word stack, word dp, longword process)
{
int p;
disableps();
/* printf("creating process stack=%04X, dp=%04X, addr=%08lX\n",
stack, dp, process); */
p = findEmptyProc();
if (p == -1) { enableps(); return SYSERR; }
kp->procTable[p].processState = procSUSPENDED;
kp->procTable[p].parentpid = Kgetpid();
kp->procTable[p].irq_S = stack;
kp->procTable[p].irq_D = dp;
kp->procTable[p].irq_PC = (word) process;
kp->procTable[p].irq_B =
kp->procTable[p].irq_K = (process >> 16);
kp->procTable[p].irq_P = 4; /* interrupts must be OFF you putz */
/* assign child same TTY as parent */
kp->procTable[p].ttyID = PROC->ttyID;
/* $$$ kp->procTable[Kgetpid()].ttyID; */
enableps();
return p;
}
#if 0
#define BUSY_FLAG ((byte *)0xE100FFl)
int _ready(int pid, int resch)
{
int mpid;
unsigned x;
mpid = mapPID(pid);
if (mpid == -1) return SYSERR;
disableps();
if (kp->procTable[mpid].processState != procUNUSED)
kp->procTable[mpid].processState = procREADY;
if (resch) {
asm {
php
sei
}
x = *BUSY_FLAG;
*BUSY_FLAG = 0;
_resched();
*BUSY_FLAG = x;
asm {
plp
}
}
enableps();
return OK;
}
#endif
/*
* Allocates a new file descriptor in this process. If the fd table is
* full, resizes the table and proceeds with the allocation.
* allocFD does NOT adjust the fdCount field, as it's possible that
* we must unallocate the fd later due to an error and it saves
* a bit of code. (i.e. the caller must inc fdCount)
*/
fdentryPtr allocFD(int *fdn)
{
fdtablePtr ft;
int i,j;
unsigned s;
/* $$$ ft = kp->procTable[Kgetpid()].openFiles; */
ft = PROC->openFiles;
j = 0; /* change this when tables are dynamically allocated */
disableps();
retry:
while (j < ft->fdTableSize) {
if (ft->fds[j].refNum == 0) {
ft->fds[j].refNum = -1; /* just to make this item look allocated */
enableps();
if (fdn != NULL) *fdn = j+1;
return &(ft->fds[j]);
} else j++;
}
ft->fdTableSize += 32;
i = ft->fdTableSize;
ft = realloc(ft,sizeof(fdtable) + sizeof(fdentry)*(i-1));
/* zero out the new entries */
memset(&ft->fds[i-32],0,sizeof(fdentry)*32);
PROC->openFiles = ft;
goto retry;
}
struct rc {
int rn;
int rt;
int cn;
};
#ifdef NOTDEFINED
void printFDS(fdtablePtr f)
{
int i;
struct rc *r;
extern struct rc *FINDREFNUM(int,int);
fputc('[',stderr);
for (i = 0; i < 32; i++) {
if (f->fds[i].refNum) {
fprintf(stderr,"(%d ",i);
switch (f->fds[i].refType) {
case rtGSOS: fprintf(stderr,"GSOS "); break;
case rtPIPE: fprintf(stderr,"PIPE "); break;
case rtTTY : fprintf(stderr,"TTY "); break;
default : fprintf(stderr,"%d ",f->fds[i].refType);
}
fprintf(stderr,"%d/%d ", f->fds[i].refNum,f->fds[i].refLevel);
r = FINDREFNUM(f->fds[i].refType,f->fds[i].refNum);
if (r == NULL) fprintf(stderr,"!!)");
else fprintf(stderr,"%d)",r->cn);
}
}
fputc(']',stderr); fputc('\n',stderr);
}
#endif
#pragma databank 1
void endproc(void)
{
/*
* printfs in here won't work with quiting orca/c progs because ~C_SHUTDOWN
* closes ALL open file descriptors
*/
/* printf("end of process %d\n",Kgetpid()); */
/* $$$ kp->procTable[Kgetpid()].flags |= FL_NORMTERM; */
PROC->flags |= FL_NORMTERM;
/* kill(kp->procTable[Kgetpid()].flpid,9); */
Kkill(&errno, 9, PROC->flpid);
/* not reached */
PANIC("ENDPROC KILL OVERRUN");
}
int CommonQuit(char *pname, int flag)
{
/*struct pentry *p = &kp->procTable[Kgetpid()];*/
char *pcopy;
quitStack *qs;
GSString255Ptr gp;
enableps();
if (flag & 0x4000) PROC->flags |= FL_RESTART;
if (pname && *pname) {
if (flag & 0x8000) {
gp = (GSString255Ptr) LGetPathname2(PROC->userID,1);
qs = malloc(gp->length+5);
qs->next = PROC->returnStack;
memcpy(qs->data,gp->text,gp->length);
qs->data[gp->length] = 0;
PROC->returnStack = qs;
}
pcopy = kmalloc(strlen(pname)+1);
strcpy(pcopy,pname); nfree(pname);
Kexecve(&errno,pcopy,pcopy);
}
else {
if ((qs = PROC->returnStack) != NULL) {
pcopy = kmalloc(strlen(qs->data)+1);
strcpy(pcopy,qs->data);
PROC->returnStack = qs->next; nfree(qs);
Kexecve(&errno,pcopy,pcopy);
} else Kkill(&errno, 9, PROC->flpid);
}
disableps();
return 0x27;
}
#pragma toolparms 1
/* subr is the address to begin the process at */
pascal int KERNSetGNOQuitRec(word pCount,GSString255Ptr pathname, word flags, int *ERRNO)
{
extern QuitRecGS quitParms;
quitParms.pCount = pCount;
quitParms.pathname = pathname;
quitParms.flags = flags;
}
int KERNgetpid()
/* get the process id of currently executing process */
{
/*$$$ return( kp->procTable[kp->truepid].flpid ); */
return (PROC->flpid);
}
int KERNgetppid(int *ERRNO)
/* get the pid of the process' parent */
{
return (kp->procTable[PROC->parentpid].flpid);
}
int KERNgetpgrp(int *ERRNO, int pid)
/* get the pgrp field for a specified process */
{
int mpid;
mpid = mapPID(pid);
if (mpid == -1) { *ERRNO = ESRCH; return -1; }
return( kp->procTable[mpid].pgrp );
}
int KERNsetpgrp(int *ERRNO, int pgrp, int pid)
{
int mpid;
int pp;
mpid = mapPID(pid);
if (mpid == -1) { *ERRNO = ESRCH; return -1; }
if (isbadpgrp(pgrp)) { *ERRNO = ESRCH; return -1; }
if (kp->procTable[mpid].pgrp != pgrp)
{
if (pgrp != 0) pgrpInfo[pgrp-2].pgrpref++;
if ((pp = kp->procTable[mpid].pgrp) != 0)
pgrpInfo[pp-2].pgrpref--;
}
return 0;
}
int KERNgetuid(int *ERRNO)
{
return (PROC->p_uid);
/* $$$ return (kp->procTable[Kgetpid()].p_uid); */
}
int KERNgeteuid(int *ERRNO)
{
return (PROC->p_euid);
/* $$$ return (kp->procTable[Kgetpid()].p_euid); */
}
int KERNgetgid(int *ERRNO)
{
return (PROC->p_gid);
/* $$$ return (kp->procTable[Kgetpid()].p_gid); */
}
int KERNgetegid(int *ERRNO)
{
return (PROC->p_egid);
/* $$$ return (kp->procTable[Kgetpid()].p_egid); */
}
int KERNsetreuid(int *ERRNO, int ruid, int euid)
{
if (ruid == -1) ruid = PROC->p_uid;
if (euid == -1) euid = PROC->p_euid;
if ((PROC->p_uid != 0) &&
(((euid != PROC->p_uid) && (euid != PROC->p_euid))
|| ((ruid != PROC->p_euid) && (ruid != PROC->p_uid)))) {
*ERRNO = EPERM;
return -1;
}
PROC->p_uid = ruid;
PROC->p_euid = euid;
return 0;
}
int KERNsetuid(int *ERRNO, int uid)
{
/* $$$ struct pentry *p;
p = &(kp->procTable[Kgetpid()]); */
if ((PROC->p_uid == 0) || (uid == PROC->p_uid) || (uid == PROC->p_euid)) {
PROC->p_uid = uid;
PROC->p_euid = uid;
return 0;
}
*ERRNO = EPERM;
return -1;
}
int KERNsetregid(int *ERRNO, int rgid, int egid)
{
if (rgid == -1) rgid = PROC->p_gid;
if (egid == -1) egid = PROC->p_egid;
if ((PROC->p_uid != 0) &&
(((egid != PROC->p_gid) && (egid != PROC->p_egid))
|| ((rgid != PROC->p_egid) && (rgid != PROC->p_gid)))) {
*ERRNO = EPERM;
return -1;
}
PROC->p_gid = rgid;
PROC->p_egid = egid;
return 0;
}
int KERNsetgid(int *ERRNO, int gid)
{
/* $$$ struct pentry *p;
p = &(kp->procTable[Kgetpid()]); */
if ((PROC->p_uid == 0) || (gid == PROC->p_gid) || (gid == PROC->p_egid)) {
PROC->p_gid = gid;
PROC->p_egid = gid;
return 0;
}
*ERRNO = EPERM;
return -1;
}
int KERNtimes(int *ERRNO, struct tms *buffer)
{
/* $$$ buffer->tms_utime = kp->procTable[Kgetpid()].ticks;
buffer->tms_cutime = kp->procTable[Kgetpid()].childTicks;
buffer->tms_stime = buffer->tms_cstime = 0l; */
buffer->tms_utime = PROC->ticks;
buffer->tms_cutime = PROC->childTicks;
/* a->i1 = a->i2 = b BROKEN in C 2.0.3 */
#if 0
buffer->tms_stime = buffer->tms_cstime = 0l;
#else
buffer->tms_stime = 0l; buffer->tms_cstime = 0l;
#endif
return 0;
}
#pragma toolparms 0
char *a_strncpy_max(char *s, word max_len)
{
word l;
char *x;
if (s == NULL) return NULL;
while ((l < max_len) && (s[l] != 0))
l++;
x = malloc(l+1);
strncpy(x,s,l);
x[l] = 0;
return x;
}
int commonFork(void (*funcptr)(), word stackSize, int prio, char *name,
word *argv, int *ERRNO)
{
word dPageAddr, buffSize,nargs;
int newID,newPID,parentPID;
int flpid;
longword *ret;
handle fstack;
struct pentry *parent,*child;
word state;
byte statereg,slot;
int i,j,k;
extern void endproc2(void);
extern void FORKInitGlob(void);
extern void IncRefnum(int,int);
extern void incPipe(int,int);
extern int allocPID(void);
/* printf("address = %08lX\n",subr); */
if (kp->gsosDebug & 16) fprintf(stderr, "fork(%06lX)\n",funcptr);
newID = GetNewID(0x1000);
fstack = NewHandle((long) stackSize,newID | 0x0100,0xC105, NULL);
if (toolerror()) { *ERRNO = ENOMEM; return -1; }
dPageAddr = (word) *fstack;
buffSize = stackSize;
/* calculate the # of bytes of parameters */
nargs = (*argv) * 2;
ret = (longword *) (dPageAddr+buffSize-4-nargs);
/* place this first, or it'll clobber some parameters */
*ret = ((longword) endproc2)-1; /* go to endproc when process is done */
/* if they're passing in params, copy them to the target stack */
if (nargs)
memcpy( (((byte *) ret)+3), argv+1, nargs);
disableps();
newPID = createProc(dPageAddr+buffSize-5-nargs,dPageAddr, (longword) funcptr);
if (newPID == SYSERR) {
*ERRNO = EAGAIN; DisposeHandle(fstack);
enableps(); return -1;
}
child = &(kp->procTable[newPID]);
parent = PROC; /* $$$ &(kp->procTable[Kgetpid()]); */
child->parentpid = Kgetpid();
child->irq_A = newID;
child->irq_X =
child->irq_Y = 0;
child->userID = newID;
if (name != NULL) {
name = a_strncpy_max(name,128);
child->args = malloc(strlen(name)+9);
strcpy(child->args,"BYTEWRKS");
strcat(child->args,name);
nfree(name);
} else child->args = NULL;
/* make sure we keep the pgrp refcount up to date */
child->pgrp = parent->pgrp;
if (child->pgrp != 0) pgrpInfo[child->pgrp-2].pgrpref++;
child->siginfo = malloc(sizeof(struct sigrec));
memcpy(child->siginfo, parent->siginfo, sizeof(struct sigrec));
child->waitq = NULL;
i = sizeof(fdentry)*(parent->openFiles->fdTableSize-1);
child->openFiles = malloc(sizeof(fdtable)+i);
memcpy(child->openFiles, parent->openFiles, sizeof(fdtable)+i);
child->prefix = malloc(33*sizeof(GSString255Ptr));
for (i = 0; i < 33; i++) {
if (parent->prefix[i] != NULL) {
child->prefix[i] =
malloc( ((GSString255Ptr) parent->prefix[i])->length+2 );
copygsstr(child->prefix[i],parent->prefix[i]);
} else child->prefix[i] = NULL;
}
child->LInfo = parent->LInfo;
child->ticks = 0l;
child->childTicks = 0l;
child->flags = FL_FORKED | FL_COMPLIANT;
child->ttyID = parent->ttyID;
child->executeHook = parent->executeHook;
child->returnStack = NULL;
child->p_uid = parent->p_uid;
child->p_gid = parent->p_gid;
child->p_euid = parent->p_euid;
child->p_egid = parent->p_egid;
child->SANEwap = parent->SANEwap;
child->lastTool = parent->lastTool; /* actually the resource app number */
asm {
lda 0xE0C035
sta state
sep #0x30
lda 0xE0C02D
sta slot
lda 0xE0C068
sta statereg
rep #0x30
}
child->irq_state = state;
child->irq_SLTROM = slot;
child->irq_STATEREG = statereg;
child->alarmCount = 0l;
child->t2StackPtr = 0;
child->processState = procNEW; /* brand new! */
parentPID = Kgetpid();
asm {
ldy newPID
ldx parentPID
jsl FORKInitGlob
}
/* make sure the system knows about all of our new copies of those
file descriptors we inherited */
i = child->openFiles->fdCount; k = 0;
while (i) {
if (j = child->openFiles->fds[k].refNum) {
if (child->openFiles->fds[k].refType == rtPIPE)
incPipe(child->openFiles->fds[k].refFlags,j);
IncRefnum(child->openFiles->fds[k].refType,j);
i--;
}
k++;
if (k > child->openFiles->fdTableSize)
PANIC("BAD FILE DESCRIPTOR TABLE");
}
child->flpid = allocPID();
kp->numProcs++;
enableps();
return child->flpid;
}
#pragma toolparms 1
int KERNfork(int *ERRNO,void *subr)
{
word nargs = 0;
return commonFork((void *)subr, 1024, 0, NULL, &nargs, ERRNO);
}
pascal int KERNfork2(void (*funcptr)(), word stackSize, int prio,
char *name, word *argv, int *ERRNO)
{
return commonFork(funcptr, stackSize, prio, name, argv, ERRNO);
}
typedef struct GetUserPathRec {
int pCount;
int fileSysID;
int commandNum;
GSString255Ptr prefixPtr;
} GetUserPathRec;
/*
* This MUST be in a function by itself so the PROC-> dereference will have
* an allocated DP to use.
*/
static void kill_self(void)
{
Kkill(&errno, 9, PROC->flpid);
}
int KERNexecve(int *ERRNO, char *cmdline, char *filename)
{
union {
InitialLoadOutputRec il;
RestartOutRec r;
} il_out;
#define il_rec il_out.il
#define r_rec il_out.r
int e;
word newID;
GSString255Ptr pfn;
ResultBuf1KPtr resBuf;
int ind;
longword *ret;
handle fstack;
int *optionList;
char **ourPFhand;
char *args,*argscopy;
int i,j;
struct pentry *p;
ExpandPathRecGS ep;
PrefixRecGS sp;
FileInfoRecGS fi;
int ssf = 0,restart,force_norest = 0;
word oldUserID, oldFlags, newStack;
extern ctxt ctxtstuff;
extern GSString255Ptr __C2GSMALLOC(char *);
extern void endproc2(void);
extern void execveHook(void);
extern void disableBuf(void);
extern void enableBuf(void);
/* always disableps() when screwing with process tables */
disableps();
if (kp->gsosDebug & 16) fprintf(stderr,"execve(%s,%s)\n",filename,cmdline);
p = PROC; /* $$$ &(kp->procTable[Kgetpid()]);*//* aaaaaaaaaaarrrgghhh!!!!! */
/* Don't do anything with the file tables- we simply pass them on to the
new process */
/* turn the input path into a GSString255 */
pfn = __C2GSMALLOC(filename);
/* do an ExpandPath on the input path */
resBuf = malloc(sizeof(ResultBuf1K));
ep.pCount = 2;
ep.inputPath = pfn;
resBuf->bufSize = 1024;
ep.outputPath = (ResultBuf255Ptr) resBuf;
ExpandPathGS(&ep);
restart = 1;
newID = GetUserID2((Pointer)&resBuf->bufString);
if (toolerror() == 0x1101) {
/* allocate a new UserID for the program */
newID = GetNewID(0x1000);
restart = 0;
} else {
/* if the 'newID' is being used by a process, force another copy from disk */
for (i = 0; i < NPROC; i++) {
if (kp->procTable[i].processState != procUNUSED)
if (kp->procTable[i].userID == newID) {
newID = GetNewID(0x1000);
restart = 0; force_norest = 1;
break;
}
}
}
if (restart) {
r_rec = Restart(newID);
} else {
il_rec = InitialLoad2(newID, (Pointer)&resBuf->bufString, 1, 1);
}
if ((e = toolerror())) {
switch(e) {
case volNotFound:
case pathNotFound:
case fileNotFound:
*ERRNO = ENOENT;
break;
default:
*ERRNO = EIO;
break;
}
nfree(resBuf);
enableps();
return -1;
}
/* get info about the executable so we know how to set up the environment */
optionList = malloc(48l); /* should be large enough for everything */
fi.pCount = 8;
fi.pathname = (GSString255Ptr) &(resBuf->bufString);
fi.optionList = (void *) optionList;
optionList[0] = 48;
GetFileInfoGS(&fi);
/* if the executable had no defined stack segment, create 1K by default */
if (il_rec.buffSize == 0) { /* no stack/dp segment- create one */
fstack = NewHandle(4096l,newID,0xC015, NULL);
il_rec.dPageAddr = (word) *fstack;
il_rec.buffSize = 4096;
}
/* S16s (and others) get no command line arguments, but we should put
their name in the process table anyway */
if (cmdline != NULL) {
size_t len = strlen(cmdline)+11;
/* build the command line by tacking the shellid() onto the real
line */
args = (char *) malloc(len);
strcpy(args,"BYTEWRKS");
strcat(args, cmdline);
args[((word)(len-1))] = 0; /* Orca 2.0 does this for compat */
argscopy = pmalloc(len,newID);
memcpy(argscopy,args,len);
} else args = argscopy = NULL;
/* tricky- shove the address of our generic RTL-exiting shutdown routine
onto the process stack so we can always keep track of processes */
ret = (longword *) (il_rec.dPageAddr+il_rec.buffSize-4);
*ret = ((longword) endproc2)-1; /* go to endproc when process is done */
/* set up the registers to point to the command line/shell id combo */
if (p->args) nfree(p->args); /* free the args string of the old executable */
p->args = args;
if (fi.fileType != 0xB5) argscopy = NULL;
ctxtstuff.ctx_A = newID;
ctxtstuff.ctx_X = hiWord((longword) argscopy);
ctxtstuff.ctx_Y = loWord((longword) argscopy);
newStack = ctxtstuff.ctx_S1 = il_rec.dPageAddr+il_rec.buffSize-5;
ctxtstuff.ctx_D = il_rec.dPageAddr;
ctxtstuff.ctx_B = ctxtstuff.ctx_B1 = (((longword) il_rec.startAddr) >> 16);
ctxtstuff.ctx_PC = (longword) il_rec.startAddr;
oldUserID = p->userID;
oldFlags = p->flags;
p->userID = newID;
p->ticks = 0l;
p->flags = FL_COMPLIANT;
if (force_norest) p->flags |= FL_NORESTART;
p->SANEwap = 0; /* reset to the 'not started up' state */
p->lastTool = 0x401E; /* reset res app to standard */
/* is program compliant? */
if (fi.auxType == 0xDC00l) {
p->flags &= (~FL_COMPLIANT); /* turn off compliance flag */
disableBuf(); /* disablebuf now turns off the cursor */
}
/*
* Set up the prefixes for the new process image
*/
/* modify prefixes 1 and 9 to point to the directory the appl. is in */
ourPFhand = PROC->prefix; /* $$$ kp->procTable[Kgetpid()].prefix; */
nfree(ourPFhand[0]); /* the '@' prefix */
nfree(ourPFhand[1+1]); nfree(ourPFhand[9+1]);
/* set Prefixes 1 and 9 to the directory the executable is in */
for (ind = resBuf->bufString.length-1; ind > 0; ind--)
if (resBuf->bufString.text[ind] == ':') {
resBuf->bufString.length = ind+1; break; /* +1 -> snag the colon */
} /* there will always be one */
ourPFhand[9+1] = malloc(resBuf->bufString.length+2);
copygsstr(ourPFhand[9+1],&resBuf->bufString);
if (optionList[2] == 0x0D) { /* app is on AppleShare volume - set '@' */
GetUserPathRec gp;
gp.pCount = 3; gp.fileSysID = 0x0D; gp.commandNum = 8;
FSTSpecific(&gp);
ourPFhand[0] = malloc(gp.prefixPtr->length+3);
copygsstr(ourPFhand[0],gp.prefixPtr);
ourPFhand[0][gp.prefixPtr->length+2] = ':';
((GSString255Ptr)ourPFhand[0])->length++;
} else {
ourPFhand[0] = malloc(resBuf->bufString.length+2);
copygsstr(ourPFhand[0],&resBuf->bufString);
}
/* if prefix 1 would be longer than 64 chars, set it to the NULL prefix */
if (resBuf->bufString.length > 64) resBuf->bufString.length = 0;
ourPFhand[2] = malloc(resBuf->bufString.length+2);
copygsstr(ourPFhand[2],&resBuf->bufString);
nfree(pfn);
nfree(resBuf);
nfree(optionList);
/* If we're launching a S16 application, copy prefix 0 to prefix 8 */
if (fi.fileType == 0xB3) {
pfn = (GSString255Ptr) ourPFhand[0+1];
pfn = malloc(pfn->length+2);
copygsstr(pfn,ourPFhand[0+1]);
nfree(ourPFhand[8+1]);
ourPFhand[8+1] = (char *)pfn;
}
/* Ignored/blocked signals remain ignored/blocked, but caught signals
are reset to their default state */
for (i = 0; i < 32; i++) {
if (p->siginfo->v_signal[i] != SIG_IGN)
p->siginfo->v_signal[i] = SIG_DFL;
}
SET_STOP_FLAG(&ssf);
if (!(oldFlags & FL_COMPLIANT)) {
enableBuf();
}
if ((fi.auxType & 0xDB02) != 0xDB02)
if (oldFlags & FL_QDSTARTUP) *((byte *)0xE0C029l) &= 0x7F;
/* switch over to the new stack before we deallocate the one we're using */
asm {
lda newStack
tcs
}
if ((fi.auxType == 0xDC00) && (p->ttyID != 3)) {
fprintf(stderr, "Program can only run on console.\n");
if (oldFlags & FL_FORKED) {
DisposeAll(oldUserID); /* process was fork()ed, don't USD */
DeleteID(oldUserID);
} else {
UserShutDown(oldUserID,
((oldFlags & FL_RESTART) && !(oldFlags & FL_NORESTART)) ? 0x4000 : 0);
}
/* don't use any local variables beyond this point */
/* STACK REPAIR MUST BE OFF TO CALL kill_self() */
kill_self();
/* not reached */
PANIC("EXECVE KILL OVERRUN");
} else {
if (oldFlags & FL_FORKED) {
DisposeAll(oldUserID); /* process was fork()ed, don't USD */
DeleteID(oldUserID);
} else {
UserShutDown(oldUserID,
((oldFlags & FL_RESTART) && !(oldFlags & FL_NORESTART)) ? 0x4000 : 0);
}
/* don't use any local variables beyond this point */
}
asm {
jmp >execveHook
}
}
/* open the kernel to access the process structures */
kvmt *KERNkvm_open(int *ERRNO)
{
kvmt *newk;
newk = (kvmt *) kmalloc(sizeof(kvmt));
if (newk == NULL) { *ERRNO = ENOMEM; return NULL;}
Kkvmsetproc(ERRNO, newk);
return newk;
}
SYSCALL KERNkvm_close(int *ERRNO,kvmt *k)
{
if (kfree(k)) return SYSERR;
return (OK);
}
struct pentry *KERNkvmgetproc(int *ERRNO, int pid, kvmt *kd)
{
int mpid;
mpid = mapPID(pid);
if (mpid == -1) { *ERRNO = ESRCH; return NULL; }
memcpy(&(kd->kvm_pent), &(kp->procTable[mpid]), sizeof(struct pentry));
kd->pid = pid;
kd->kvm_pent.parentpid = kp->procTable[kp->procTable[mpid].parentpid].flpid;
return &(kd->kvm_pent);
}
struct pentry *KERNkvmnextproc(int *ERRNO, kvmt *kd)
{
int i;
int mpid;
if (kd->procIndex < NPROC)
{
memcpy(&(kd->kvm_pent), &(kp->procTable[kd->procIndex]),
sizeof(struct pentry));
kd->pid = kd->kvm_pent.flpid;
mpid = mapPID(kd->pid);
kd->kvm_pent.parentpid =
kp->procTable[kp->procTable[mpid].parentpid].flpid;
i = kd->procIndex+1;
while ((i < NPROC) && (kp->procTable[i].processState == procUNUSED))
i++;
kd->procIndex = i;
return &kd->kvm_pent;
}
else return NULL;
}
int KERNkvmsetproc(int *ERRNO,kvmt *kd)
{
int i;
for (i = 0; i < NPROC; i++)
if (kp->procTable[i].processState != procUNUSED) {
kd->procIndex = i;
return OK;
}
return SYSERR;
}
int KERNtcnewpgrp(int *ERRNO, int fdtty)
{
unsigned i,devNum,ttyPgrp;
fdentryPtr tty;
extern fdentryPtr getFDptr(int);
tty = getFDptr(fdtty);
if ((tty == NULL) || (tty->refNum == 0)) { *ERRNO = EBADF; return -1; }
if (tty->refType != rtTTY) { *ERRNO = ENOTTY; return -1; }
devNum = tty->refNum-1;
disableps();
for (i = 0; i < NPGRP; i++)
if (!pgrpInfo[i].pgrpref) break;
if (i == NPGRP) { enableps(); return -1; }
/* we're leaving a PTY, decrement the refcount */
if (ttyPgrp = ttys[devNum].pgrp)
pgrpInfo[ttyPgrp-2].pgrpref--;
if (kp->gsosDebug & 16)
fprintf(stderr, "tcnewpgrp- TTY:%d pgrp:%d\n",devNum,i+2);
ttys[devNum].pgrp = i+2;
pgrpInfo[i].pgrpref++;
enableps();
return 0;
}
int KERNsettpgrp(int *ERRNO, int fdtty)
{
int p,pid = Kgetpid();
int pp,devNum;
fdentryPtr tty;
extern fdentryPtr getFDptr(int);
tty = getFDptr(fdtty);
if ((tty == NULL) || (tty->refNum == 0)) { *ERRNO = EBADF; return -1; }
if (tty->refType != rtTTY) { *ERRNO = ENOTTY; return -1; }
devNum = tty->refNum-1;
p = ttys[devNum].pgrp;
if (kp->gsosDebug & 16)
fprintf(stderr, "settpgrp pid: %d, oldpgrp: %d, ",
PROC->flpid, PROC->pgrp);
/* $$$ kp->procTable[pid].flpid,
kp->procTable[pid].pgrp); */
disableps();
/* $$$ if (kp->procTable[pid].pgrp != p) */
if (PROC->pgrp != p)
{
if (p != 0) pgrpInfo[p-2].pgrpref++;
/* $$$ if ((pp = kp->procTable[pid].pgrp) != 0) */
if ((pp = PROC->pgrp) != 0)
pgrpInfo[pp-2].pgrpref--;
}
if (kp->gsosDebug & 16) fprintf(stderr,"newpgrp: %d\n",p);
/* $$$ kp->procTable[pid].pgrp = p; */
PROC->pgrp = p;
enableps();
}
int KERNtctpgrp(int *ERRNO, int pid, int fdtty)
{
int p,mpid,devNum;
fdentryPtr tty;
extern fdentryPtr getFDptr(int);
/* should check pid to be sure it's == getpid or a child of it */
mpid = mapPID(pid);
if (mpid == -1) { *ERRNO = ESRCH; return -1; }
/*
if (!((mpid == Kgetpid()) || (kp->procTable[mpid].parentpid == Kgetpid())))
{ *ERRNO = ERANGE; return -1; }
*/
tty = getFDptr(fdtty);
if ((tty == NULL) || (tty->refNum == 0)) { *ERRNO = EBADF; return -1; }
devNum = tty->refNum-1;
if (tty->refType != rtTTY) { *ERRNO = ENOTTY; return -1; }
disableps();
p = kp->procTable[mpid].pgrp;
if (p != ttys[devNum].pgrp) {
if (p != 0) pgrpInfo[p-2].pgrpref++;
if (ttys[devNum].pgrp != 0)
pgrpInfo[ttys[devNum].pgrp-2].pgrpref--;
}
if (kp->gsosDebug & 16)
fprintf(stderr,"tctpgrp TTY:%d pid:%d pgrp:%d\n",devNum,pid,p);
ttys[devNum].pgrp = p;
enableps();
}
int KERNsetdebug(int code)
{
int old;
if (kp->gsosDebug & 16) fprintf(stderr,"setdebug %d\n",code);
if ((code < 0) || (code > 63)) return SYSERR;
old = kp->gsosDebug;
kp->gsosDebug = code;
return old;
}
void *KERNsetsystemvector(void * execvec)
{
void *x;
x = PROC->executeHook;
PROC->executeHook = execvec;
/* $$$ x = kp->procTable[Kgetpid()].executeHook;
kp->procTable[Kgetpid()].executeHook = execvec; */
return x;
}
#ifdef NOTDEFINED
struct pipest {
handle bufferH; /* the pipe data handle */
word in; /* write pointer */
word out; /* read pointer */
word qflags;
word RrnCount; /* Why? Because special stuff has to */
word WrnCount; /* happen in strange conditions */
int accessSem;
int readSem;
int writeSem;
int writeStatus;
}
#endif
/* filedes[0] is read only, filedes[1] is write only */
int KERNpipe(int *ERRNO, int filedes[2])
{
fdentryPtr pread,pwrite;
int fdread,fdwrite;
fdtablePtr ft;
int pipen;
extern int newPipe(void);
if (kp->gsosDebug & 16) printf("pipe(%06lX)\n",filedes);
/* $$$ ft = kp->procTable[Kgetpid()].openFiles; */
pipen = newPipe();
pread = allocFD(&fdread);
if (pread == NULL) { *ERRNO = EMFILE; disposePipe(pipen); return -1; }
pwrite = allocFD(&fdwrite);
ft = PROC->openFiles; /* deref pointer after calls to allocFD */
if (pwrite == NULL) {
pread->refNum = 0; /* deallocate the read file descriptor */
*ERRNO = EMFILE;
disposePipe(pipen);
return -1;
}
disableps();
filedes[0] = fdread; filedes[1] = fdwrite;
/* a->i1 = a->i2 = b BROKEN in C 2.0.3 */
#if 0
pread->refNum = pwrite->refNum = pipen;
pread->refType = pwrite->refType = rtPIPE;
pread->refLevel = pwrite->refLevel = ft->fdLevel | ft->fdLevelMode;
pwrite->NLenableMask = pread->NLenableMask = 0;
#else
pread->refNum = pipen; pwrite->refNum = pipen;
pread->refType = rtPIPE; pwrite->refType = rtPIPE;
pwrite->refLevel = ft->fdLevel | ft->fdLevelMode;
pread->refLevel = pwrite->refLevel;
pwrite->NLenableMask = 0; pread->NLenableMask = 0;
#endif
pread->refFlags = rfPIPEREAD;
pwrite->refFlags = rfPIPEWRITE;
AddRefnum(rtPIPE,pipen);
IncRefnum(rtPIPE,pipen);
ft->fdCount += 2; /* we opened two new files */
enableps();
return 0;
}
int KERNdup(int *ERRNO, int filedes)
{
/* $$$ struct pentry *p; */
fdtablePtr ft;
fdentryPtr newFD,oldFD;
int nfd;
int i,j,fd;
extern void IncRefnum(int,int);
disableps();
/* $$$ p = &(kp->procTable[Kgetpid()]); */
fd = filedes-1;
ft = PROC->openFiles;
if ((filedes < 1) || (filedes > 32) ||
(ft->fds[fd].refNum == 0)) {
*ERRNO = EBADF;
enableps();
return -1;
}
newFD = allocFD(&nfd);
ft = PROC->openFiles;
if (newFD == NULL) { *ERRNO = EMFILE; enableps(); return -1; }
oldFD = &(ft->fds[fd]);
memcpy(newFD,oldFD,sizeof(fdentry));
IncRefnum(newFD->refType,newFD->refNum);
if (newFD->refType == rtPIPE)
incPipe(newFD->refFlags,newFD->refNum);
ft->fdCount++; /* we created a new one... */
enableps();
return nfd;
}
int KERNdup2(int *ERRNO, int filedes2, int filedes)
{
/* $$$ struct pentry *p; */
fdtablePtr ft;
fdentryPtr newFD,oldFD;
int i,j,fd,fd2;
extern void IncRefnum(int,int);
int cl[2];
disableps();
/* $$$ p = &(kp->procTable[Kgetpid()]); */
ft = PROC->openFiles;
fd = filedes-1; fd2 = filedes2-1;
newFD = &(ft->fds[fd2]); oldFD = &(ft->fds[fd]);
if ((filedes < 1) || (filedes2 < 1) || (filedes > 32) || (filedes2 > 32) ||
(oldFD->refNum == 0)) {
*ERRNO = EBADF;
enableps();
return -1;
}
/* if they're duping a file to itself, pretend we did it */
if (fd == fd2) {
enableps(); return 0;
}
if (newFD->refNum) {
cl[0] = 1; cl[1] = filedes2;
CloseGS(cl);
}
memcpy(newFD,oldFD,sizeof(fdentry));
IncRefnum(newFD->refType,newFD->refNum);
if (newFD->refType == rtPIPE)
incPipe(newFD->refFlags,newFD->refNum);
ft->fdCount++; /* we created a new one... */
enableps();
return 0;
}
#pragma databank 0
#pragma toolparms 0