V9/sys/sys/vmsys.c
/* vmsys.c 4.11 81/04/23 */
#include "../h/param.h"
#include "../h/systm.h"
#include "../h/dir.h"
#include "../h/user.h"
#include "../h/proc.h"
/*#include "../h/reg.h"*/
#include "../h/file.h"
#include "../h/inode.h"
#include "../h/vm.h"
#include "../h/buf.h"
#include "../machine/pte.h"
#include "../h/cmap.h"
/*#include "../h/mtpr.h"*/
#include "../h/vlimit.h"
#include "../h/trace.h"
#include "../h/vadvise.h"
vfork()
{
fork1(1);
}
resuba()
{
#ifdef vax
if (suser())
ubareset(u.u_arg[0]);
#endif
}
futz()
{
}
int both;
vadvise()
{
register struct a {
int anom;
} *uap;
register struct proc *rp = u.u_procp;
int oanom = rp->p_flag & SUANOM;
register struct pte *pte;
register struct cmap *c;
register int i;
uap = (struct a *)u.u_ap;
#ifdef TRACE
trace(TR_VADVISE, uap->anom, u.u_procp->p_pid);
#endif
rp->p_flag &= ~(SSEQL|SUANOM);
switch (uap->anom) {
case VA_ANOM:
rp->p_flag |= SUANOM;
break;
case VA_SEQL:
rp->p_flag |= SSEQL;
break;
}
if (both || (oanom && (rp->p_flag & SUANOM) == 0)) {
for (i = 0; i < rp->p_dsize; i += CLSIZE) {
pte = dptopte(rp, i);
if (pte->pg_v) {
c = &cmap[pgtocm(pte->pg_pfnum)];
if (c->c_lock)
continue;
#ifndef vax
ptesync(u.u_procp, dptov(u.u_procp, i));
#endif
pte->pg_v = 0;
if (anycl(pte, pg_m))
pte->pg_m = 1;
distcl(pte);
}
}
#ifdef vax
mtpr(TBIA, 0);
#endif
#ifdef sun
#include "../machine/mmu.h"
setusercontext(KCONTEXT);
u.u_procp->p_flag |= SPTECHG;
#endif
}
}
vtimes()
{
register struct a {
struct vtimes *par_vm;
struct vtimes *ch_vm;
} *uap = (struct a *)u.u_ap;
if (uap->par_vm) {
if (copyout((caddr_t)&u.u_vm, (caddr_t)uap->par_vm,
sizeof(struct vtimes)) < 0)
u.u_error = EFAULT;
}
if (uap->ch_vm == 0)
return;
if (copyout((caddr_t)&u.u_cvm, (caddr_t)uap->ch_vm,
sizeof(struct vtimes)) < 0)
u.u_error = EFAULT;
}
vmsadd(vp, wp)
register struct vtimes *vp, *wp;
{
vp->vm_utime += wp->vm_utime;
vp->vm_stime += wp->vm_stime;
vp->vm_nswap += wp->vm_nswap;
vp->vm_idsrss += wp->vm_idsrss;
vp->vm_ixrss += wp->vm_ixrss;
if (vp->vm_maxrss < wp->vm_maxrss)
vp->vm_maxrss = wp->vm_maxrss;
vp->vm_majflt += wp->vm_majflt;
vp->vm_minflt += wp->vm_minflt;
vp->vm_inblk += wp->vm_inblk;
vp->vm_oublk += wp->vm_oublk;
}
/*
* Affect per-process limits.
* To just return old limit, specify negative new limit.
*/
vlimit()
{
register struct a {
unsigned which;
int limit;
} *uap;
uap = (struct a *)u.u_ap;
if (uap->which > NLIMITS) {
u.u_error = EINVAL;
return;
}
u.u_r.r_val1 = u.u_limit[uap->which];
if (uap->limit < 0)
return;
switch (uap->which) {
case LIM_DATA:
if (uap->limit > ctob(MAXDSIZ))
uap->limit = ctob(MAXDSIZ);
break;
case LIM_TEXT:
if (uap->limit > ctob(MAXTSIZ))
uap->limit = ctob(MAXTSIZ);
break;
case LIM_STACK:
if (uap->limit > ctob(MAXSSIZ))
uap->limit = ctob(MAXSSIZ);
break;
}
if (u.u_limit[LIM_NORAISE] && uap->limit > u.u_limit[uap->which] &&
!suser()) {
u.u_error = EACCES;
return;
}
u.u_limit[uap->which] = uap->limit;
if (uap->which == LIM_MAXRSS)
u.u_procp->p_maxrss = uap->limit/NBPG;
}
#ifdef TRACE
int nvualarm;
vtrace()
{
register struct a {
int request;
int value;
} *uap;
int vdoualarm();
uap = (struct a *)u.u_ap;
switch (uap->request) {
case VTR_DISABLE: /* disable a trace point */
case VTR_ENABLE: /* enable a trace point */
if (uap->value < 0 || uap->value >= TR_NFLAGS)
u.u_error = EINVAL;
else {
u.u_r.r_val1 = traceflags[uap->value];
traceflags[uap->value] = uap->request;
}
break;
case VTR_VALUE: /* return a trace point setting */
if (uap->value < 0 || uap->value >= TR_NFLAGS)
u.u_error = EINVAL;
else
u.u_r.r_val1 = traceflags[uap->value];
break;
case VTR_UALARM: /* set a real-time ualarm, less than 1 min */
if (uap->value <= 0 || uap->value > 60 * hz ||
nvualarm > 5)
u.u_error = EINVAL;
else {
nvualarm++;
timeout(vdoualarm, (caddr_t)u.u_procp->p_pid,
uap->value);
}
break;
case VTR_STAMP:
trace(TR_STAMP, uap->value, 0);
break;
}
}
vdoualarm(arg)
int arg;
{
register struct proc *p;
p = pfind(arg);
if (p)
psignal(p, 16);
nvualarm--;
}
#endif