int
machine_init(struct statics * statics)
{
ulong ptr;
if ((kmem = open(KMEM, O_RDONLY)) == -1)
{
perror(KMEM);
return -1;
}
if ((mem = open(MEM, O_RDONLY)) == -1)
{
perror(MEM);
return -1;
}
/* get the list of symbols we want to access in the kernel */
if (nlist(VMUNIX, nlst) == -1)
{
fprintf(stderr, "pg_top: nlist failed\n");
return -1;
}
/* make sure they were all found */
/*
* ZZ if (check_nlist(nlst) > 0) return -1;
*/
proca = nlst[X_PROC].n_value;
/* get the symbol values out of kmem */
(void) getkval(nlst[X_CUR_CPU].n_value, (int *) (&cur_cpu), sizeof(cur_cpu),
nlst[X_CUR_CPU].n_name);
(void) getkval(nlst[X_HZ].n_value, (int *) (&Hz), sizeof(Hz),
nlst[X_HZ].n_name);
(void) getkval(nlst[X_V].n_value, (int *) (&v), sizeof(v),
nlst[X_V].n_name);
/* this is used in calculating WCPU -- calculate it ahead of time */
logcpu = log(fabs(loaddouble(cur_cpu)));
/* allocate space for proc structure array and array of pointers */
bytes = v.v_proc * sizeof(struct proc);
pbase = (struct proc *) malloc(bytes);
pref = (struct proc **) malloc(v.v_proc * sizeof(struct proc *));
if (pbase == (struct proc *) NULL || pref == (struct proc **) NULL)
{
fprintf(stderr, "pg_top: cannot allocate sufficient memory\n");
return -1;
}
/* fill in the statics information */
statics->procstate_names = procstatenames;
statics->cpustate_names = cpustatenames;
statics->memory_names = memorynames;
statics->order_names = ordernames; /* hops */
return 0;
}
void
get_system_info(struct system_info *si)
{
int load_avg[3];
struct sysinfo s_info;
struct vmker m_info;
int i;
double total = 0;
/* get the load avarage array */
getkval(avenrun_offset, (caddr_t)load_avg, sizeof load_avg, "avenrun");
/* get the sysinfo structure */
getkval(sysinfo_offset, (caddr_t)&s_info, sizeof s_info, "sysinfo");
/* get vmker structure */
getkval(vmker_offset, (caddr_t)&m_info, sizeof m_info, "vmker");
/* convert load avarages to doubles */
for (i = 0; i < 3; i++)
si->load_avg[i] = (double)load_avg[i]/65536.0;
/* calculate cpu state in percentages */
for (i = 0; i < CPU_NTIMES; i++) {
cp_old[i] = cp_time[i];
cp_time[i] = s_info.cpu[i];
cp_diff[i] = cp_time[i] - cp_old[i];
total += cp_diff[i];
}
total = total/1000.0; /* top itself will correct this */
for (i = 0; i < CPU_NTIMES; i++) {
cpu_states[i] = cp_diff[i] / total;
}
/* calculate memory statistics, scale 4K pages to megabytes */
#define PAGE_TO_MB(a) ((a)*4/1024)
memory_stats[M_REAL] = PAGE_TO_MB(m_info.totalmem);
memory_stats[M_REALFREE] = PAGE_TO_MB(m_info.freemem);
memory_stats[M_BUFFERS] = PAGE_TO_MB(m_info.numperm);
swap_stats[M_VIRTUAL] = PAGE_TO_MB(m_info.totalvmem);
swap_stats[M_VIRTFREE] = PAGE_TO_MB(m_info.freevmem);
/* runnable processes */
process_states[0] = s_info.runque - old_runque;
old_runque = s_info.runque;
si->cpustates = cpu_states;
si->memory = memory_stats;
si->swap = swap_stats;
}
void
get_system_info (struct system_info *si)
{
long avenrun[3];
struct sysinfo sysinfo;
struct vmtotal total;
struct anoninfo anoninfo;
static time_t cp_old[CPUSTATES];
static time_t cp_diff[CPUSTATES]; /* for cpu state percentages */
register int i;
getsysinfo(&sysinfo);
/* convert cp_time counts to percentages */
(void) percentages (CPUSTATES, cpu_states, sysinfo.cpu, cp_old, cp_diff);
/* Find total CPU utilization, as a fraction of 1. */
total_cpu = (cpu_states[CPU_USER] + cpu_states[CPU_KERNEL]) / 1000.0;
/* get mpid -- process id of last process */
(void) getkval (mpid_offset, &(si->last_pid), sizeof (si->last_pid),
"mpid");
/* get load average array */
(void) getkval (avenrun_offset, (int *) avenrun, sizeof (avenrun), "avenrun");
/* convert load averages to doubles */
for (i = 0; i < 3; i++)
si->load_avg[i] = loaddouble (avenrun[i]);
/* get total -- systemwide main memory usage structure */
(void) getkval (total_offset, (int *) (&total), sizeof (total), "total");
/* convert memory stats to Kbytes */
memory_stats[0] = pagetok (total.t_rm);
memory_stats[1] = pagetok (total.t_arm);
memory_stats[2] = pagetok (total.t_free);
(void) getkval (anoninfo_offset, (int *) (&anoninfo), sizeof (anoninfo),
"anoninfo");
memory_stats[3] = pagetok (anoninfo.ani_max - anoninfo.ani_free);
memory_stats[4] = pagetok (anoninfo.ani_max - anoninfo.ani_resv);
/* set arrays and strings */
si->cpustates = cpu_states;
si->memory = memory_stats;
}
struct region *
get_region(void *ptr)
{
static struct region reg;
long addr = (long) ptr;
(void) getkval(addr, (struct region *) (®),
sizeof(struct region), "region");
return ®
}
void
get_system_info(struct system_info * si)
{
int i;
int avenrun[3];
struct rminfo realmem;
struct sysinfo sysinfo;
static time_t cp_old[CPU_STATES];
static time_t cp_diff[CPU_STATES]; /* for cpu state percentages */
off_t fswap; /* current free swap in blocks */
off_t tswap; /* total swap in blocks */
(void) getkval(avenrun_offset, (int *) avenrun, sizeof(avenrun), "avenrun");
for (i = 0; i < 3; i++)
{
si->load_avg[i] = loaddouble(avenrun[i]);
si->load_avg[i] /= 1024.0;
}
if ((numcpus = sysmp(MP_NPROCS)) == -1)
{
perror("sysmp(MP_NPROCS)");
return;
}
if (sysmp(MP_SAGET, MPSA_RMINFO, &realmem, sizeof(realmem)) == -1)
{
perror("sysmp(MP_SAGET,MPSA_RMINFO, ...)");
return;
}
swapctl(SC_GETFREESWAP, &fswap);
swapctl(SC_GETSWAPTOT, &tswap);
memory_stats[0] = pagetok(realmem.physmem);
memory_stats[1] = pagetok(realmem.availrmem);
memory_stats[2] = pagetok(realmem.freemem);
memory_stats[3] = tswap / 2;
memory_stats[4] = fswap / 2;
if (sysmp(MP_SAGET, MPSA_SINFO, &sysinfo, sizeof(struct sysinfo)) == -1)
{
perror("sysmp(MP_SAGET,MPSA_SINFO)");
return;
}
(void) percentages(CPU_STATES, cpu_states, sysinfo.cpu, cp_old, cp_diff);
si->cpustates = cpu_states;
si->memory = memory_stats;
si->last_pid = -1;
return;
}
void
get_system_info(struct system_info * si)
{
long total;
/* get process id of the last process */
(void) getkval(nlst[X_MPID].n_value, &(si->last_pid),
sizeof(si->last_pid),
nlst[X_MPID].n_name);
/* get the cp_time array */
(void) getkval(nlst[X_SYSINFO].n_value, (int *) cp_time, sizeof(cp_time),
nlst[X_SYSINFO].n_name);
/* convert cp_time counts to persentages */
total = percentages(CPUSTATES, cpu_states, cp_time, cp_old, cp_diff);
/* sum memory statistics */
(void) getkval(nlst[X_PHYSMEM].n_value, &memory_stats[0],
sizeof(memory_stats[0]), nlst[X_PHYSMEM].n_name);
(void) getkval(nlst[X_MAXMEM].n_value, &memory_stats[1],
sizeof(memory_stats[1]), nlst[X_MAXMEM].n_name);
(void) getkval(nlst[X_FREEMEM].n_value, &memory_stats[2],
sizeof(memory_stats[2]), nlst[X_FREEMEM].n_name);
(void) getkval(nlst[X_AVAILRMEM].n_value, &memory_stats[3],
sizeof(memory_stats[3]), nlst[X_AVAILRMEM].n_name);
(void) getkval(nlst[X_AVAILSMEM].n_value, &memory_stats[4],
sizeof(memory_stats[4]), nlst[X_AVAILSMEM].n_name);
(void) getkval(nlst[X_NSWAP].n_value, &memory_stats[5],
sizeof(memory_stats[5]), nlst[X_NSWAP].n_name);
memory_stats[0] = bytetok(ctob(memory_stats[0])); /* clicks -> bytes */
memory_stats[1] = bytetok(ctob(memory_stats[1])); /* clicks -> bytes */
memory_stats[2] = bytetok(ctob(memory_stats[2])); /* clicks -> bytes */
memory_stats[3] = bytetok(memory_stats[3] * NBPP); /* # bytes per page */
memory_stats[4] = bytetok(memory_stats[4] * NBPP); /* # bytes per page */
memory_stats[5] = bytetok(memory_stats[5] * NBPSCTR); /* # bytes per sector */
/* set arrays and strings */
/*
* Note: we keep memory_stats as an unsigned long to avoid sign extension
* problems when shifting in bytetok. But the module interface requires an
* array of signed longs. So we just cast the pointer here and hope for
* the best. --wnl
*/
si->cpustates = cpu_states;
si->memory = (long *) memory_stats;
tab_avenrun(si->load_avg); /* philiph */
}
/*
* Initialize globals, get kernel offsets and stuff...
*/
machine_init(struct statics *statics)
{
time_t uptime, now;
struct tms tbuf;
if ((kmem = open(KMEM, O_RDONLY)) == -1) {
perror(KMEM);
return -1;
}
/* get kernel symbol offsets */
if (knlist(nlst, 5, sizeof(struct nlist)) != 0) {
perror("knlist");
return -1;
}
avenrun_offset = nlst[X_AVENRUN].n_value;
sysinfo_offset = nlst[X_SYSINFO].n_value;
vmker_offset = nlst[X_VMKER].n_value;
proc_offset = nlst[X_PROC].n_value;
v_offset = nlst[X_V].n_value;
getkval(v_offset, (caddr_t)&v_info, sizeof v_info, "v");
ncpus = v_info.v_ncpus; /* number of cpus */
nprocs = PROCMASK(PIDMAX);
if (nprocs > 1024) nprocs = 1024;
ptsize = nprocs * sizeof (struct proc);
p_proc = (struct proc *)malloc(ptsize);
p_info = (struct procsinfo *)malloc(nprocs * sizeof (struct procsinfo));
pref = (struct procsinfo **)malloc(nprocs * sizeof (struct procsinfo *));
if (!p_proc || !p_info || !pref) {
fprintf(stderr, "top: not enough memory\n");
return -1;
}
/* set boot time */
now = time(NULL);
uptime = times(&tbuf) / HZ;
statics->boottime = now - uptime;
statics->procstate_names = procstatenames;
statics->cpustate_names = cpustatenames;
statics->memory_names = memorynames;
statics->order_names = ordernames;
statics->swap_names = swapnames;
return(0);
}
static double get_cpu_load()
{
kernel_fd_type kernel_fd;
long address = 0;
static long cpu_time[CPUSTATES];
static long cpu_old[CPUSTATES];
static long cpu_diff[CPUSTATES];
double cpu_states[CPUSTATES];
double cpu_load;
if (sge_get_kernel_fd(&kernel_fd)
&& sge_get_kernel_address("cp_time", &address)) {
getkval(address, (void*)&cpu_time, sizeof(cpu_time), "cp_time");
percentages(CPUSTATES, cpu_states, cpu_time, cpu_old, cpu_diff);
cpu_load = cpu_states[0] + cpu_states[1] + cpu_states[2];
if (cpu_load < 0.0) {
cpu_load = -1.0;
}
} else {
cpu_load = -1.0;
}
return cpu_load;
}
getu(register struct proc *p, struct user *u)
{
register int nbytes, n;
struct task task;
struct utask utask;
struct uthread thread;
/*
* Check if the process is currently loaded or swapped out. The way we
* get the u area is totally different for the two cases. For this
* application, we just don't bother if the process is swapped out.
*/
/* NEXTSTEP proc.h
* One structure allocated per active
* process. It contains all data needed
* about the process while the
* process may be swapped out.
* Other per process data (user.h)
* is swapped with the process.
*/
if ((p->p_flag & SLOAD) == 0) {
/* User info is always in core.
* #ifdef DOSWAP
* if (lseek(swap, (long)dtob(p->p_swaddr), 0) == -1) {
* perror("lseek(swap)");
* return(-1);
* }
* if (read(swap, (char *) u, sizeof(struct user)) != sizeof(struct user)) {
* perror("read(swap)");
* return(-1);
* }
* return (1);
* #else
*/
return(-1);
/*#endif
*/
}
/*
* Process is currently in memory, we hope!
*/
if(!getkval(p->task, (int *)&task, sizeof(struct task), "task")) {
#ifdef DEBUG
perror("getkval(p->task)");
#endif
/* we can't seem to get to it, so pretend it's swapped out */
return(-1);
}
if(!getkval(task.u_address, (int *)&utask, sizeof(struct utask), "task.u_address")) {
#ifdef DEBUG
perror("getkval(task->utask)");
#endif
/* we can't seem to get to it, so pretend it's swapped out */
return(-1);
}
/* Copy utask and uthread info into struct user *u */
/* This is incomplete. Only copied info needed. */
u->u_procp = utask.uu_procp;
u->u_ar0 = utask.uu_ar0;
u->u_ru = utask.uu_ru;
strcpy(u->u_comm, utask.uu_comm);
nbytes = strlen(u->u_comm);
for(n=nbytes; n<MAXCOMLEN; n++)
u->u_comm[n] = ' ';
u->u_comm[MAXCOMLEN] = '\0';
return(0);
}
caddr_t get_process_info(struct system_info *si,
struct process_select *sel,
int (*compare)())
{
int i, j;
int total_procs;
int active_procs;
struct proc *pp;
struct task_basic_info taskInfo;
struct thread_basic_info threadInfo;
kern_return_t thread_status;
kern_return_t task_status;
int threadCount;
/* these are copied out of sel for speed */
int show_idle;
int show_system;
int show_uid;
int show_command;
/* get a pointer to the states summary array */
si->procstates = process_states;
/* set up flags which define what we are going to select */
show_idle = sel->idle;
show_system = sel->system;
show_uid = sel->uid != -1;
show_command = sel->command != NULL;
(void) getkval(nlst[X_PROC].n_value, (int *)(&proc), sizeof(proc),
nlst[X_PROC].n_un.n_name);
/* count up process states and get pointers to interesting procs */
total_procs = 0;
active_procs = 0;
memset((char *)process_states, 0, sizeof(process_states));
i = 0;
j = 0;
do {
if(i == 0) {
/* read first proc structure */
(void) getkval(proc, (int *)&pbase[i], sizeof(struct proc), "first proc");
} else {
(void) getkval(pp->p_nxt, (int *)&pbase[i], sizeof(struct proc), "nxt proc");
}
pp = &pbase[i];
thread_status = thread_stats(pp->p_pid, &threadInfo, &threadCount);
task_status = task_stats(pp->p_pid, &taskInfo);
/*
* Process slots that are actually in use have a non-zero
* status field. Processes with SSYS set are system
* processes---these get ignored unless show_sysprocs is set.
*/
if (pp->p_stat != 0 &&
(show_system || ((pp->p_flag & SSYS) == 0)))
{
total_procs++;
/* Using thread info for process states. */
/* process_states[pp->p_stat]++; */
if(thread_status==KERN_SUCCESS)
process_states[threadInfo.run_state]++;
if ((pp->p_stat != SZOMB) &&
(show_idle || (pp->p_stat == SRUN)) &&
(!show_uid || pp->p_uid == (uid_t)sel->uid))
{
pref[j].p_self = pp;
if(thread_status==KERN_SUCCESS)
{
pref[j].run_state = threadInfo.run_state;
pref[j].flags = threadInfo.flags;
pref[j].p_pctcpu = threadInfo.cpu_usage;
pref[j].p_cptime = threadInfo.user_time.seconds +
threadInfo.system_time.seconds;
pref[j].cur_priority = threadInfo.cur_priority;
pref[j].nthreads = threadCount;
} else {
pref[j].run_state = 0;
pref[j].flags = 0;
pref[j].p_pctcpu = 0;
pref[j].p_cptime = 0;
}
/* Get processes memory usage and cputime */
if(task_status==KERN_SUCCESS)
{
pref[j].p_rsize = taskInfo.resident_size/1024;
pref[j].p_vsize = taskInfo.virtual_size/1024;
} else {
pref[j].p_rsize = 0;
pref[j].p_vsize = 0;
}
active_procs++;
j++;
}
}
i++;
} while(pp->p_nxt != 0);
pref[j].p_self = NULL; /* End list of processes with NULL */
/* if requested, sort the "interesting" processes */
if (compare != NULL)
{
qsort((char *)pref, active_procs, sizeof(struct proc_unix), compare);
}
/* remember active and total counts */
si->p_total = total_procs;
si->p_active = pref_count = active_procs;
/* pass back a handle */
handle.list = pref;
handle.count = active_procs;
handle.current = 0;
return((caddr_t)&handle);
}
get_system_info(struct system_info *si)
{
long avenrun[3];
long total;
/* get the cp_time array */
(void) getkval(cp_time_offset, (int *)cp_time, sizeof(cp_time),
"_cp_time");
/* get load average array */
(void) getkval(avenrun_offset, (int *)avenrun, sizeof(avenrun),
"_avenrun");
/* get mpid -- process id of last process */
(void) getkval(mpid_offset, &(si->last_pid), sizeof(si->last_pid),
"_mpid");
/* convert load averages to doubles */
{
register int i;
for(i=0; i<3; i++)
si->load_avg[i] = ((double)avenrun[i])/LSCALE;
}
/* convert cp_time counts to percentages */
total = percentages(CPUSTATES, cpu_states, cp_time, cp_old, cp_diff);
/* sum memory statistics */
{
/* get total -- systemwide main memory usage structure */
/* Does not work on NeXT system. Use vm_statistics() for paging info. */
/* struct vmtotal total;
* (void) getkval(total_offset, (int *)(&total), sizeof(total),
* "_total");
*/
/* convert memory stats to Kbytes */
/* memory_stats[0] = -1;
* memory_stats[1] = pagetok(total.t_arm);
* memory_stats[2] = pagetok(total.t_rm);
* memory_stats[3] = -1;
* memory_stats[4] = pagetok(total.t_avm);
* memory_stats[5] = pagetok(total.t_vm);
* memory_stats[6] = -1;
* memory_stats[7] = pagetok(total.t_free);
*/
kern_return_t status;
unsigned int count=HOST_BASIC_INFO_COUNT;
status = vm_statistics(task_self(), &vm_stats);
#ifdef DEBUG
if(status != KERN_SUCCESS)
mach_error("An error calling vm_statistics()!", status);
#endif
status = host_info(host_self(), HOST_BASIC_INFO, (host_info_t)&host_stats, &count);
#ifdef DEBUG
if(status != KERN_SUCCESS)
mach_error("An error calling host_info()!", status);
#endif
/* convert memory stats to Kbytes */
memory_stats[0] = pagetok(host_stats.memory_size / vm_stats.pagesize);
memory_stats[1] = pagetok(vm_stats.active_count);
memory_stats[2] = pagetok(vm_stats.inactive_count);
memory_stats[3] = pagetok(vm_stats.wire_count);
memory_stats[4] = pagetok(vm_stats.free_count);
if (swappgsin < 0)
{
memory_stats[5] = 1;
memory_stats[6] = 1;
} else {
memory_stats[5] = pagetok(((vm_stats.pageins - swappgsin)));
memory_stats[6] = pagetok(((vm_stats.pageouts - swappgsout)));
}
swappgsin = vm_stats.pageins;
swappgsout = vm_stats.pageouts;
}
/* set arrays and strings */
si->cpustates = cpu_states;
si->memory = memory_stats;
}
machine_init(struct statics *statics)
{
register int i = 0;
register int pagesize;
if ((kmem = open(KMEM, O_RDONLY)) == -1) {
perror(KMEM);
return(-1);
}
if ((mem = open(MEM, O_RDONLY)) == -1) {
perror(MEM);
return(-1);
}
#ifdef DOSWAP
if ((swap = open(SWAP, O_RDONLY)) == -1) {
perror(SWAP);
return(-1);
}
#endif
/* get the list of symbols we want to access in the kernel */
(void) nlist(VMUNIX, nlst);
if (nlst[0].n_type == 0)
{
fprintf(stderr, "top: nlist failed\n");
return(-1);
}
/* make sure they were all found */
if (i > 0 && check_nlist(nlst) > 0)
{
return(-1);
}
/* get the symbol values out of kmem */
(void) getkval(nlst[X_PROC].n_value, (int *)(&proc), sizeof(proc),
nlst[X_PROC].n_un.n_name);
(void) getkval(nlst[X_NPROC].n_value, &nproc, sizeof(nproc),
nlst[X_NPROC].n_un.n_name);
(void) getkval(nlst[X_HZ].n_value, (int *)(&hz), sizeof(hz),
nlst[X_HZ].n_un.n_name);
/* (void) getkval(nlst[X_CCPU].n_value, (int *)(&ccpu), sizeof(ccpu),
* nlst[X_CCPU].n_un.n_name);
*/
/* stash away certain offsets for later use */
mpid_offset = nlst[X_MPID].n_value;
avenrun_offset = nlst[X_AVENRUN].n_value;
total_offset = nlst[X_TOTAL].n_value;
cp_time_offset = nlst[X_CP_TIME].n_value;
/* this is used in calculating WCPU -- calculate it ahead of time */
/* ccpu = mach_load_avg();
* logcpu = log((double)(ccpu)/LOAD_SCALE);
*/
/* allocate space for proc structure array and array of pointers */
bytes = nproc * sizeof(struct proc);
pbase = (struct proc *)malloc(bytes);
pref = (struct proc_unix *)malloc((nproc+1) * sizeof(struct proc_unix *));
/* Just in case ... */
if (pbase == (struct proc *)NULL || pref == (struct proc_unix *)NULL)
{
fprintf(stderr, "top: can't allocate sufficient memory\n");
return(-1);
}
/* get the page size with "getpagesize" and calculate pageshift from it */
pagesize = getpagesize();
pageshift = ceil(log(pagesize)/log(2.0));
/* we only need the amount of log(2)1024 for our conversion */
pageshift -= LOG1024;
/* fill in the statics information */
statics->procstate_names = procstatenames;
statics->cpustate_names = cpustatenames;
statics->memory_names = memorynames;
/* all done! */
return(0);
}
caddr_t
get_process_info(struct system_info * si,
struct process_select * sel,
int idx)
{
register int i;
register int total_procs;
register int active_procs;
register struct proc **prefp;
register struct proc *pp;
/* set up flags of what we are going to select */
/* these are copied out of sel for simplicity */
int show_idle = sel->idle;
int show_system = sel->system;
int show_uid = sel->uid != -1;
int show_command = sel->command != NULL;
/* read all the proc structures in one fell swoop */
(void) getkval(proca, (int *) pbase, bytes, "proc array");
/* get a pointer to the states summary array */
si->procstates = process_states;
/* count up process states and get pointers to interesting procs */
total_procs = active_procs = 0;
memset((char *) process_states, 0, sizeof(process_states));
prefp = pref;
for (pp = pbase, i = 0; i < v.v_proc; pp++, i++)
{
/*
* Place pointers to each valid proc structure in pref[]. Process
* slots that are actually in use have a non-zero status field.
* Processes with SSYS set are system processes -- these are ignored
* unless show_system is set.
*/
if (pp->p_stat && (show_system || ((pp->p_flag & SSYS) == 0)))
{
total_procs++;
process_states[pp->p_stat]++;
if ((pp->p_stat != SZOMB) &&
(show_idle || (pp->p_stat == SRUN) || (pp->p_stat == SONPROC)) &&
(!show_uid || pp->p_uid == (ushort) sel->uid))
{
*prefp++ = pp;
active_procs++;
}
}
}
/* if requested, sort the "interesting" processes */
qsort((char *) pref, active_procs, sizeof(struct proc *), proc_compares[idx]);
/* remember active and total counts */
SI_TOTAL(si) = total_procs;
SI_ACTIVE(si) = pref_len = active_procs;
/* pass back a handle */
handle.next_proc = pref;
handle.remaining = active_procs;
return ((caddr_t) & handle);
}
caddr_t
get_process_info(struct system_info *si, struct process_select *sel, int compare_index)
{
int i, nproc;
int ptsize_util;
int active_procs = 0, total_procs = 0;
struct procsinfo *pp, **p_pref = pref;
unsigned long pctcpu;
pid_t procsindex = 0;
struct proc *p;
si->procstates = process_states;
curtime = time(0);
/* get the procsinfo structures of all running processes */
nproc = getprocs(p_info, sizeof (struct procsinfo), NULL, 0,
&procsindex, nprocs);
if (nproc < 0) {
perror("getprocs");
quit(1);
}
/* the swapper has no cmd-line attached */
strcpy(p_info[0].pi_comm, "swapper");
/* get proc table */
ptsize_util = (PROCMASK(p_info[nproc-1].pi_pid)+1) * sizeof(struct proc);
getkval(proc_offset, (caddr_t)p_proc, ptsize_util, "proc");
memset(process_states, 0, sizeof process_states);
/* build a list of pointers to processes to show. walk through the
* list of procsinfo structures instead of the proc table since the
* mapping of procsinfo -> proctable is easy, the other way around
* is cumbersome
*/
for (pp = p_info, i = 0; i < nproc; pp++, i++) {
p = &p_proc[PROCMASK(pp->pi_pid)];
/* AIX marks all runnable processes as ACTIVE. We want to know
which processes are sleeping, so check used cpu ticks and adjust
status field accordingly
*/
if (p->p_stat == SACTIVE && p->p_cpticks == 0)
p->p_stat = SIDL;
if (pp->pi_state && (sel->system || ((pp->pi_flags & SKPROC) == 0))) {
total_procs++;
process_states[p->p_stat]++;
if ( (pp->pi_state != SZOMB) &&
(sel->idle || p->p_cpticks != 0 || (p->p_stat == SACTIVE))
&& (sel->uid == -1 || pp->pi_uid == (uid_t)sel->uid)) {
*p_pref++ = pp;
active_procs++;
}
}
}
/* the pref array now holds pointers to the procsinfo structures in
* the p_info array that were selected for display
*/
/* sort if requested */
if (si->p_active)
qsort((char *)pref, active_procs, sizeof (struct procsinfo *),
proc_compares[compare_index]);
si->last_pid = -1; /* no way to figure out last used pid */
si->p_total = total_procs;
si->p_active = pref_len = active_procs;
handle.next_proc = pref;
handle.remaining = active_procs;
return((caddr_t)&handle);
}
caddr_t
get_process_info(
struct system_info * si,
struct process_select * sel,
int x)
{
register int i;
register int total_procs;
register int active_procs;
register struct prpsinfo **prefp;
register struct prpsinfo *pp;
/* these are copied out of sel for speed */
int show_idle;
int show_system;
int show_uid;
/* Get current number of processes */
(void) getkval(nproc_offset, (int *) (&nproc), sizeof(nproc), "nproc");
/* read all the proc structures */
getptable(pbase);
/* get a pointer to the states summary array */
si->procstates = process_states;
/* set up flags which define what we are going to select */
show_idle = sel->idle;
show_system = sel->system;
show_uid = sel->uid != -1;
/* count up process states and get pointers to interesting procs */
total_procs = 0;
active_procs = 0;
(void) memset(process_states, 0, sizeof(process_states));
prefp = pref;
for (pp = pbase, i = 0; i < nproc; pp++, i++)
{
/*
* Place pointers to each valid proc structure in pref[]. Process
* slots that are actually in use have a non-zero status field.
* Processes with SSYS set are system processes---these get ignored
* unless show_sysprocs is set.
*/
if (pp->pr_state != 0 &&
(show_system || ((pp->pr_flag & SSYS) == 0)))
{
total_procs++;
process_states[pp->pr_state]++;
if ((!pp->pr_zomb) &&
(show_idle || (pp->pr_state == SRUN) || (pp->pr_state == SONPROC)) &&
(!show_uid || pp->pr_uid == (uid_t) sel->uid))
{
*prefp++ = pp;
active_procs++;
}
}
}
/* if requested, sort the "interesting" processes */
qsort((char *) pref, active_procs, sizeof(struct prpsinfo *), proc_compare);
/* remember active and total counts */
si->p_total = total_procs;
si->p_active = active_procs;
/* pass back a handle */
handle.next_proc = pref;
handle.remaining = active_procs;
return ((caddr_t) & handle);
}
void
get_system_info(struct system_info * si)
{
long avenrun[3];
struct sysinfo sysinfo;
static struct sysinfo *mpinfo = NULL; /* array, per-processor
* sysinfo structures. */
struct vmtotal total;
struct anoninfo anoninfo;
static long cp_old[CPUSTATES];
static long cp_diff[CPUSTATES]; /* for cpu state percentages */
static int num_cpus;
static int fd_cpu = 0;
register int i;
if (use_stats == 1)
{
if (fd_cpu == 0)
{
if ((fd_cpu = open("/stats/cpuinfo", O_RDONLY)) == -1)
{
(void) fprintf(stderr, "%s: Open of /stats/cpuinfo failed\n", myname);
quit(2);
}
if (read(fd_cpu, &num_cpus, sizeof(int)) != sizeof(int))
{
(void) fprintf(stderr, "%s: Read of /stats/cpuinfo failed\n", myname);
quit(2);
}
close(fd_cpu);
}
if (mpinfo == NULL)
{
mpinfo = (struct sysinfo *) calloc(num_cpus, sizeof(mpinfo[0]));
if (mpinfo == NULL)
{
(void) fprintf(stderr, "%s: can't allocate space for per-processor sysinfos\n", myname);
quit(12);
}
}
/* Read the per cpu sysinfo structures into mpinfo struct. */
read_sysinfos(num_cpus, mpinfo);
/* Add up all of the percpu sysinfos to get global sysinfo */
sysinfo_data(num_cpus, &sysinfo, mpinfo);
}
else
{
(void) getkval(sysinfo_offset, &sysinfo, sizeof(struct sysinfo), "sysinfo");
}
/* convert cp_time counts to percentages */
(void) percentages(CPUSTATES, cpu_states, sysinfo.cpu, cp_old, cp_diff);
/* get mpid -- process id of last process */
(void) getkval(mpid_offset, &(si->last_pid), sizeof(si->last_pid),
"mpid");
/* get load average array */
(void) getkval(avenrun_offset, (int *) avenrun, sizeof(avenrun), "avenrun");
/* convert load averages to doubles */
for (i = 0; i < 3; i++)
si->load_avg[i] = loaddouble(avenrun[i]);
/* get total -- systemwide main memory usage structure */
(void) getkval(total_offset, (int *) (&total), sizeof(total), "total");
/* convert memory stats to Kbytes */
memory_stats[0] = pagetok(total.t_rm);
memory_stats[1] = pagetok(total.t_arm);
memory_stats[2] = pagetok(total.t_free);
(void) getkval(anoninfo_offset, (int *) (&anoninfo), sizeof(anoninfo),
"anoninfo");
memory_stats[3] = pagetok(anoninfo.ani_max - anoninfo.ani_free);
memory_stats[4] = pagetok(anoninfo.ani_max - anoninfo.ani_resv);
/* set arrays and strings */
si->cpustates = cpu_states;
si->memory = memory_stats;
}
int
machine_init(struct statics * statics)
{
static struct var v;
/* fill in the statics information */
statics->procstate_names = procstatenames;
statics->cpustate_names = cpustatenames;
statics->memory_names = memorynames;
/* get the list of symbols we want to access in the kernel */
if (nlist(UNIX, nlst))
{
(void) fprintf(stderr, "Unable to nlist %s\n", UNIX);
return (-1);
}
/* make sure they were all found */
if (check_nlist(nlst) > 0)
return (-1);
/* open kernel memory */
if ((kmem = open(KMEM, O_RDONLY)) == -1)
{
perror(KMEM);
return (-1);
}
/* get the symbol values out of kmem */
/* NPROC Tuning parameter for max number of processes */
(void) getkval(nlst[X_V].n_value, &v, sizeof(struct var), nlst[X_V].n_name);
nproc = v.v_proc;
/* stash away certain offsets for later use */
mpid_offset = nlst[X_MPID].n_value;
nproc_offset = nlst[X_NPROC].n_value;
avenrun_offset = nlst[X_AVENRUN].n_value;
anoninfo_offset = nlst[X_ANONINFO].n_value;
total_offset = nlst[X_TOTAL].n_value;
/* JJ this may need to be changed */
sysinfo_offset = nlst[X_SYSINFO].n_value;
/* allocate space for proc structure array and array of pointers */
bytes = nproc * sizeof(struct prpsinfo);
pbase = (struct prpsinfo *) malloc(bytes);
pref = (struct prpsinfo **) malloc(nproc * sizeof(struct prpsinfo *));
/* Just in case ... */
if (pbase == (struct prpsinfo *) NULL || pref == (struct prpsinfo **) NULL)
{
(void) fprintf(stderr, "%s: can't allocate sufficient memory\n", myname);
return (-1);
}
if (!(proc_dir = opendir(PROCFS)))
{
(void) fprintf(stderr, "Unable to open %s\n", PROCFS);
return (-1);
}
if (chdir(PROCFS))
{ /* handy for later on when we're reading it */
(void) fprintf(stderr, "Unable to chdir to %s\n", PROCFS);
return (-1);
}
/* all done! */
return (0);
}
int
machine_init (struct statics *statics)
{
int i;
static struct var v;
/* fill in the statics information */
statics->procstate_names = procstatenames;
statics->cpustate_names = cpustatenames;
statics->memory_names = memorynames;
/* get the list of symbols we want to access in the kernel */
if (nlist (UNIX, nlst))
{
(void) fprintf (stderr, "Unable to nlist %s\n", UNIX);
return (-1);
}
/* make sure they were all found */
if (check_nlist (nlst) > 0)
return (-1);
/* open kernel memory */
if ((kmem = open (KMEM, O_RDONLY)) == -1)
{
perror (KMEM);
return (-1);
}
/* Open the sar driver device node. */
if ((sar = open(SAR, O_RDONLY)) == -1)
{
perror (SAR);
return (-1);
}
/* get the symbol values out of kmem */
/* NPROC Tuning parameter for max number of processes */
(void) getkval (nlst[X_V].n_value, &v, sizeof (struct var), nlst[X_V].n_name);
nproc = v.v_proc;
/* stash away certain offsets for later use */
mpid_offset = nlst[X_MPID].n_value;
nproc_offset = nlst[X_NPROC].n_value;
avenrun_offset = nlst[X_AVENRUN].n_value;
anoninfo_offset = nlst[X_ANONINFO].n_value;
total_offset = nlst[X_TOTAL].n_value;
/* allocate space for proc structure array and array of pointers */
bytes = nproc * sizeof (struct prpsinfo);
pbase = (struct prpsinfo *) malloc (bytes);
pref = (struct prpsinfo **) malloc (nproc * sizeof (struct prpsinfo *));
/* Just in case ... */
if (pbase == (struct prpsinfo *) NULL || pref == (struct prpsinfo **) NULL)
{
(void) fprintf (stderr, "%s: can't allocate sufficient memory\n", myname);
return (-1);
}
if (!(procdir = opendir (PROCFS)))
{
(void) fprintf (stderr, "Unable to open %s\n", PROCFS);
return (-1);
}
if (chdir (PROCFS))
{ /* handy for later on when we're reading it */
(void) fprintf (stderr, "Unable to chdir to %s\n", PROCFS);
return (-1);
}
/* Set up the pointers to the sysinfo data area. */
spa.uvcp = (caddr_t) &cpu_state[0];
spa.uvsp = (caddr_t) &cpu_sysinfo[0];
timedata.lnext = &timedata;
timedata.llast = &timedata;
for (i = 0; i < HASHSZ; i++) {
hash[i].hnext = (timedata_t *)&hash[i];
hash[i].hlast = (timedata_t *)&hash[i];
}
/* all done! */
return (0);
}
