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qps-packaging/src/proc.cpp

2256 lines
62 KiB

// proc.cpp for Linux
//
// This program is free software. See the file COPYING for details.
// Author: Mattias Engdeg?rd, 1997-1999
// Oliver
/*
LWP (Light Weight Process): just thread, mainly used in Solaris
Task : thread and process in Linux
NPTL(Native POSIX Thread Library)
TGID thread group leader's pid
*/
#include <stdio.h>
#include <string.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/syscall.h>
#include <dirent.h>
#include <fcntl.h>
#include <time.h>
#include <sched.h> // sched_rr_get_interval(pid, &ts);
#include <libgen.h> // basename()
#include <unistd.h> // sysconf() POSIX.1-2001
#include <sys/time.h>
//#include <sys/param.h> //HZ defined, no more used.
//#include "misc.h" // x_atoi() , userName() ,groupname()
#include "proc.h"
#include "uidstr.h"
#include "ttystr.h"
#include "wchan.h"
#ifdef GTK
#include "detail_gtk.h"
#else
#include "details.h" //qt
#endif
#include "proc_common.cpp" // COMMON code !!!!
#define PROCDIR "/proc" // hmmm
bool flag_SMPsim = false; // SMP simulation
extern int flag_thread_ok;
extern bool flag_schedstat;
extern bool flag_show_thread;
extern bool flag_devel;
int pagesize;
int Proc::update_msec = 1024;
// socket states, from <linux/net.h> and touched to avoid name collisions
enum
{
SSFREE = 0, /* not allocated */
SSUNCONNECTED, /* unconnected to any socket */
SSCONNECTING, /* in process of connecting */
SSCONNECTED, /* connected to socket */
SSDISCONNECTING /* in process of disconnecting */
};
#define QPS_SCHED_AFFINITY ok
#ifdef QPS_SCHED_AFFINITY
#ifndef SYS_sched_setaffinity
#define SYS_sched_setaffinity 241
#endif
#ifndef SYS_sched_getaffinity
#define SYS_sched_getaffinity 242
#endif
// Needed for some glibc
int qps_sched_setaffinity(pid_t pid, unsigned int len, unsigned long *mask)
{
return syscall(SYS_sched_setaffinity, pid, len, mask);
};
int qps_sched_getaffinity(pid_t pid, unsigned int len, unsigned long *mask)
{
return syscall(SYS_sched_getaffinity, pid, len, mask);
};
#endif
/*
Thread Problems.
pthread_exit()
*/
struct proc_info_
{
int proc_id;
char flag;
char type;
int files;
} proc_info; // TESTING
struct list_files_
{
int proc_id;
int flag;
char *filename; // path + filename
} list_files; // TESTING
// read() the number of bytes read is returned (zero indicates end of file)
// return the number of bytes read if ok, -1 if failed
inline int read_file(char *name, char *buf, int max)
{
int fd = open(name, O_RDONLY);
if (fd < 0)
return -1;
int r = read(fd, buf, max);
close(fd);
// buf[r]=0;
return r;
}
// Description : read proc files
// return 0 : if error occurs.
char buffer_proc[1024 * 4]; // enough..maybe
char *read_proc_file(const char *fname, int pid = -1, int tgid = -1,
int *size = NULL)
{
static int max_size = 0;
char path[256];
int r;
if (pid < 0)
sprintf(path, "/proc/%s", fname);
else
{
if (tgid > 0)
sprintf(path, "/proc/%d/task/%d/%s", tgid, pid, fname);
else
sprintf(path, "/proc/%d/%s", pid, fname);
}
if (strcmp(fname, "exe") == 0)
{
if ((r = readlink(path, buffer_proc, sizeof(buffer_proc) - 1)) >= 0)
{
buffer_proc[r] = 0; // safer
return buffer_proc;
}
else
return 0;
}
int fd = open(path, O_RDONLY);
if (fd < 0)
return 0;
r = read(fd, buffer_proc, sizeof(buffer_proc) - 1); // return 0 , -1 ,
if (r < 0)
return 0;
if (max_size < r)
max_size = r;
if (size != 0)
*size = r;
buffer_proc[r] = 0; // safer
return buffer_proc;
// note: not work fgets(sbuf, sizeof(64), fp) why???
}
char *read_proc_file2(char *r_path, const char *fname, int *size = NULL)
{
static int max_size = 0;
char path[256];
int r;
// strcpy(path,r_path);
sprintf(path, "%s/%s", r_path, fname);
if (strcmp(fname, "exe") == 0)
{
if ((r = readlink(path, buffer_proc, sizeof(buffer_proc) - 1)) >= 0)
{
buffer_proc[r] = 0; // safer
return buffer_proc;
}
else
return 0;
}
int fd = open(path, O_RDONLY);
if (fd < 0)
return 0;
r = read(fd, buffer_proc,
sizeof(buffer_proc) - 1); // return 0 , -1 , read_count
if (r < 0)
return 0;
if (max_size < r)
max_size = r;
if (size != 0)
*size = r;
buffer_proc[r] = 0; // safer
close(fd);
return buffer_proc;
// note: not work fgets(sbuf, sizeof(64), fp) why???
}
// TEST CODE , Bottleneck
// Description: read /proc/PID/fd/* check opened file, count opened files
// this fuction will be called when every update.
// Return Value :
int proc_pid_fd(const int pid)
{
char path[256];
char buffer[256], fname[256];
DIR *d;
int fdnum;
int len, path_len;
sprintf(path, "/proc/%d/fd", pid);
path_len = strlen(path);
d = opendir(path);
if (!d)
{
// this happend when the process died already or Zombie process
// printf("Qps : read fail !! /proc/%d/fd !!! kernel bug ?
// \n",pid);
return false;
}
struct dirent *e;
while ((e = readdir(d)) != 0)
{
if (e->d_name[0] == '.')
continue; // skip "." and ".."
path[path_len] = '/';
path[path_len + 1] = 0;
strcat(path, e->d_name);
len = readlink(path, fname, sizeof(fname) - 1);
if (len > 0)
{
fname[len] = 0;
// printf("DEBUG: %s[%s]\n",path,fname);
// if (strcmp(fname,"/dev/null")==0 ) continue;
}
/// num_opened_files++;
// strcpy(p, e->d_name);
// fdnum = atoi(p);
// read_fd(fdnum, path);
}
closedir(d);
return true;
}
// new process created
Procinfo::Procinfo(Proc *system_proc, int process_id, int thread_id) : refcnt(1)
{
first_run = true;
clone = false;
proc = system_proc;
if (thread_id < 0) //
{
pid = process_id;
tgid = process_id; // thread group leader's id
}
else
{
pid = thread_id;
tgid = process_id; // thread group leader's id
}
ppid = 0; // no parent
selected = false;
hidekids = false;
envblock = 0; //!!
table_child_seq = -1;
child_seq_prev = -1;
lastchild = 0;
generation = -1;
detail = 0;
/// per_cpu_times = 0; not yet
size = 0;
resident = 0;
trs = 0;
drs = 0;
stack = 0;
share = 0;
mem = 0;
io_read_prev = 0; // **
io_write_prev = 0;
io_read = 0; // **
io_write = 0; // **
// tgid=0;
pcpu = 0;
pmem = 0;
old_utime = 0; // this must be current utime !
old_wcpu = 0;
command = "noname";
tty = 0;
nice = 0;
starttime = 0;
state = 'Z';
cutime = utime = 0;
nthreads = 0; /* number of threads */
hashstr[0] = 0;
hashlen = 0;
}
Procinfo::~Procinfo()
{
if (!clone)
{
void watchdog_check_if_finish(QString cmd, Procinfo * p);
watchdog_check_if_finish(command, this);
if (detail)
{
// printf("~Procinfo() : pid=%d\n",pid);
detail->process_gone();
detail = 0;
}
// if(environ) delete environ;
if (envblock)
free(envblock); /// double free , SEGFAULT
}
// fd_files.squeeze();
// maps.squeeze();
/*
if(maps) {
maps->purge();
delete maps;
}
if(fd_files) {
fd_files->purge();
delete fd_files;
}
*/
// if(children)
// { children->clear(); delete children; }
/// delete[] per_cpu_times;
}
// miscellaneous static initializations
void Proc::init_static()
{
// socks.setAutoDelete(true);
/// usocks.setAutoDelete(true);
pagesize = sysconf(_SC_PAGESIZE); // same getpagesize() in <unistd.h>
// printf("pagesize=%d, %d\n",getpagesize(),
// sysconf(_SC_PAGESIZE)); //4027
}
// tricky function...(by fasthyun@magicn.com)
// Description :
// let's deal thread as normal process!
// read /proc/PID/task/* and add to Proc::procs[]
int Proc::read_pid_tasks(int pid)
{
char path[256];
struct dirent *e;
int thread_pid;
int thread_n = 0;
Procinfo *pi = 0;
sprintf(path, "/proc/%d/task", pid);
DIR *d = opendir(path);
if (!d)
return -1; // process dead already!
while ((e = readdir(d)) != 0)
{
if (e->d_name[0] == '.')
continue; // skip "." , ".."
thread_pid = atoi(e->d_name);
if (pid == thread_pid)
continue; // skip
pi = procs.value(thread_pid, NULL);
if (pi == NULL)
{
pi = new Procinfo(this, pid, thread_pid);
procs.insert(thread_pid, pi);
}
if (pi->readproc() >= 0)
{
pi->generation = current_gen;
// if(pid!=thread_pid)
// pi->cmdline="(thread)";
}
thread_n++;
}
closedir(d);
return thread_n;
}
// update wcpu,%cpu field
void Procinfo::calculate_cpu() //
{
}
// using cache for Speed up
int Procinfo::hashcmp(char *sbuf)
{
int statlen;
statlen = strlen(sbuf);
if (statlen > sizeof(hashstr))
{
// some user reported 265byte.
printf("Qps BUG: hashstr shortage statlen(%d) > hashstr(%lu), "
"report this "
"message to fasthyun@magicn.com \n",
statlen, sizeof(hashstr));
abort();
}
else if (statlen == hashlen)
{
if (memcmp(hashstr, sbuf, statlen) == 0)
{
pcpu = 0;
// 1. I am a sleeping process
// printf("[%d] sleep process \n",pid);
return 1;
}
}
memcpy(hashstr, sbuf, statlen); // to back
hashlen = statlen;
return 0;
}
int mini_sscanf(const char *s, const char *fmt, ...);
// Description : read /proc/PID/* or read /proc/PID/task/*
// be called every refresh() time.
// return -1 means the process already dead !
int Procinfo::readproc()
{
char cmdbuf[MAX_CMD_LEN];
char path[64];
int len;
char *sbuf; // should be enough to acommodate /proc/PID/stat
char *buf;
int x_pid; // just pid
int i_tty; //
long stime, cstime;
// Note : /proc/PID/* is not same /proc/task/PID/*
if (isThread()) // flag_thread_ok
{
sprintf(path, "/proc/%d/task/%d", tgid, pid);
}
else
sprintf(path, "/proc/%d", pid);
if (first_run)
{
// Note: COMMAND(?) , TGID, UID , COMMAND_LINE never
// change !
old_wcpu = wcpu = pcpu = 0.0;
// read /proc/PID/status
if ((buf = read_proc_file2(path, "status")) == 0)
return -1;
// Note: Process_name from
// 1.status (15 chars-name)
// 2.stat (15 chars-name, pass)
// 3.cmdline : full name (sometimes have null, Thread
// can't use
// cmdline)
// 4.exe : full name (frequently this does not exist,
// thread can't use
// exe)
// 5.comm : 15 chars ?
//
// Note:
// 1. thread's name_max is 15 chars
if (mini_sscanf(buf, "Name: %S\n", cmdbuf) == 0)
return -1;
else
{
command = cmdbuf;
if (command.contains("kthread"))
hidekids = true; // kthread, kthreadd ,
// ///Procinfo::qps_pid=pid;
}
if (mini_sscanf(buf, "Tgid: %d ", &tgid) == 0)
return -1;
if (mini_sscanf(buf, "Uid: %d %d %d %d", &uid, &euid, &suid, &fsuid) !=
4)
return -1;
if (mini_sscanf(buf, "Gid: %d %d %d %d", &gid, &egid, &sgid, &fsgid) !=
4)
return -1;
username = userName(uid, euid);
groupname = groupName(gid, egid);
int bug = 0;
char cmdline_cmd[4096]; // some cmdline very large! ex)chrome
// read /proc/pid/cmdline
int size;
cmdline_cmd[0] = 0;
// anyone can read [cmdline]
if ((buf = read_proc_file2(path, "cmdline", &size)) == 0)
return -1;
else
{
// printf("DEBUG: size=%d \n",size);
int cmdlen = strlen(buf);
if (cmdlen == 0)
{
// 1. kthread
// printf("Qps:debug no_cmdline pid=%d\n",pid );
cmdline = "";
}
// for non-ascii locale language
// cmdline = codec->toUnicode(cmdbuf,strlen(cmdbuf));
else
{
// change 0x00,0xA to ' '
for (int i = 0; i < size - 1; i++) // OVERFLOW
if (buf[i] == 0 or buf[i] == 0x0A)
buf[i] = ' ';
cmdline = buf;
strcpy(cmdline_cmd, buf);
}
}
// VERY COMPLEX CODE
// because Command's MAX_length is only 15, so sometimes
// cmd_name truncated,
// we should guess ...
//
// The solution is...
// 1.check [exe] file ( only owner can read it)
// 2.check [cmdline] ( anyone can read it )
// 3.check [comm]
//
if (command.size() == 15)
{
// only root & owner can read [exe] link
/*
if((buf= read_proc_file2(path,"exe")) !=0 )
{
// printf("Qps:debug %s\n",buf );
if(strlen(basename(buf))>15 and
strncmp(qPrintable(command),basename(buf),15)==0
)
command=basename(buf); // no
memory leak !
else ;// just use command
//printf("Qps:debug %s\n",buf );
} */
if (true) // guess the full name of the command
{
// Use /proc/PID/cmdline, comm, status
// ex)
// /usr/lib/chromium/chromium --option1
// --option2
// python /usr/lib/system-service-d
// pam: gdm-password
// hald-addon-input: Listing On /dev~
//
char *p;
p = strstr(cmdline_cmd, ": "); // cut the options !
if (p != 0)
*p = 0;
p = strchr(cmdline_cmd, ' '); // cut the options !
if (p != 0)
*p = 0;
// printf("Qps:debug %s\n",cmdline_cmd );
char *pstart = strstr(basename(cmdline_cmd), cmdbuf);
if (pstart != 0)
{
command = pstart; // copy
/// printf("Qps:debug2
/// %s\n",basename(cmdline_cmd));
}
}
}
if (isThread())
cmdline = command + " (thread)";
if (flag_devel and bug)
{
// command.append("^");
cmdline += " ^ Qps: may be a wrong commandline ";
}
void watchdog_check_if_start(QString cmd, Procinfo * ps);
watchdog_check_if_start(command, this); // segfault possible.
first_run = false;
}
if (flag_schedstat == true)
{
// if no change then return. twice faster !
// MAX_256 bytes check...?
// 2.6.9 upper only and some system no has
if ((sbuf = read_proc_file2(path, "schedstat")) == 0)
return -1;
if (hashcmp(sbuf))
return 1; // no change
}
// read /proc/PID/stat
if ((sbuf = read_proc_file2(path, "stat")) == 0)
return -1;
if (flag_schedstat == false) // if no change then return. twice faster !
{
if (hashcmp(sbuf))
return 1;
}
/// if (proc_pid_fd(pid)== true) ; // bottleneck !!
/*
Not all values from /proc/#/stat are interesting; the ones left
out
have been retained in comments to see where they should go, in
case
they are needed again.
Notes :
1. man -S 5 proc
2. man -S 2 times
3. ppid can be changed when parent dead !
4. initial utime maybe 0, so %CPU field NotAnumber !!
utime: user time
stime: kernel mode tick
cutime : The number of jiffies that this process's waited-for
children have been scheduled in user mode.
#jiffies == tick
*/
unsigned int guest_utime, cguest_utime;
#if 1
char *p, *p1;
// in odd cases the name can contain spaces and '(' or ')' and numbers,
// so
// this makes
// parsing more difficult. We scan for the outermost '(' ')' to find the
// name.
p = strchr(sbuf, '(');
p1 = strrchr(sbuf, ')');
if (p == 0 || p1 == 0)
return -1;
p1++;
// we can safely use sscanf() on the rest of the string
sscanf(p1,
" %c %d %d %d %d %d"
" %lu %lu %lu %lu %lu "
"%ld %ld %ld %ld %d %d %d %*s %lu %*s %*s %*s %*s %*s %*s %*s %*s "
"%*s %*s %*s %*s %lu %*s %*s %*s %u %*s %*s %*s %u %u",
#else
// some errors will occur !
mini_sscanf(
sbuf,
"%d (%S) %c %d %d %d %d %d"
"%lu %lu %lu %lu %lu "
"%ld %ld %ld %ld %d %d %d %*s %lu %*s %*s %*s %*s %*s %*s %*s %*s "
"%*s %*s %*s %*s %lu %*s %*s %*s %u %*s %*s %*s %u %u",
&x_pid, &cmdbuf[0],
#endif
&state, &ppid, &pgrp, &session, &i_tty, &tpgid, &flags, &minflt,
&cminflt, &majflt, &cmajflt, &utime, &stime, &cutime, &cstime,
&priority, &nice, &nthreads /* number of threads v2.6 */,
/* itrealvalue */
&starttime, /* start time(static) */ // jiffes
/* vsize */
/* rss */
/* rlim, startcode, endcode, startstack kstkesp kstkeip,
signal, blocked, sigignore, sigcatch */
&wchan,
/* 0L, 0L, exit_signal */
&which_cpu
/* rt_priority, policy, delayacct_blkio_ticks */
,
&guest_utime, &cguest_utime);
starttime = proc->boot_time /* secs */ + (starttime / proc->clk_tick);
tty = (dev_t)i_tty; // hmmm
// if(tty!=0) printf("pid=%d tty =%d\n",pid,tty);
// if(guest_utime>0 or cguest_utime>0)
// printf("cmd [%s] guest_utime=%d cguest_utime
//=%d\n",qPrintable(command),guest_utime,cguest_utime);
utime += stime; // we make no user/system time distinction
cutime += cstime;
if (old_utime > 0) // check..
{
int dcpu;
dcpu = utime - old_utime; // user_time from proc
if (dcpu < 0)
{
// why.. this occurs ?
// Qps exception:[3230,firefox] dcpu=-22 utime=39268
// old_utime=39290 why
// occur?
if (flag_devel)
printf("Qps :[%d,%s] dcpu=%d utime=%ld "
"old_utime=%ld why occurs?\n",
pid, qPrintable(command), dcpu, utime, old_utime);
return 1;
}
// gettimeofday(&tv, 0); //sys/time
if (proc->dt_total > 0) // move to Proc ??
{
pcpu = 100.0 * dcpu / proc->dt_total;
if (Procview::flag_pcpu_single == true)
pcpu *= proc->num_cpus; //
}
// else too fast read again
// printf("Qps exception: dt_total=%d report to
// fasthyun@magicn.com
// \n",Proc::dt_total);
if (flag_devel and pcpu > 100) // DEBUG CODE
{
printf("Qps pcpu error: %0.0f%% [%d,%s] dt_total=%ld "
"dcpu=%d utime=%ld "
"old_utime=%ld \n",
pcpu, pid, qPrintable(command), proc->dt_total, dcpu, utime,
old_utime);
pcpu = 99.99;
}
const float a = Procview::avg_factor;
wcpu = a * old_wcpu + (1 - a) * pcpu;
}
old_tv = tv;
old_wcpu = wcpu;
old_utime = utime; // ****
// read /proc/%PID/statm - memory usage
if (1)
{
if ((buf = read_proc_file2(path, "statm")) == 0)
return -1; // kernel 2.2 ?
sscanf(buf, "%lu %lu %lu %lu %lu %lu %lu", &size, &resident, &share,
&trs, &lrs, &drs, &dt);
size *= pagesize / 1024; // total memory in kByte
resident *= pagesize / 1024;
share *= pagesize / 1024; // share
// trs ; // text(code)
// lrs ; // zero : lib, awlays zero in
// Kernel 2.6
// drs ; // data: wrong in kernel 2.6
// dt ; // zero : in Kernel 2.6
mem = resident - share;
// pmem = 100.0 * resident / proc->mem_total;
pmem = 100.0 * mem / proc->mem_total;
}
// read /proc/PID/status check !!
if ((buf = read_proc_file2(path, "status")) == 0)
return -1;
else
{
// slpavg : not supported in kernel 2.4; default value of -1
if (mini_sscanf(buf, "SleepAVG:%d", &slpavg) == 0)
slpavg = -1;
if (strstr(buf, "VmSize:"))
{
// mini_sscanf(p, "VmSize: %d",&size); // XXX
// mini_sscanf(p, "VmRSS: %d",&resident);
// mini_sscanf(sbuf, "VmLib: %d",&share);
mini_sscanf(buf, "VmData: %d", &drs); // data in kByte
mini_sscanf(buf, "VmStk: %d", &stack); // stack in kByte
mini_sscanf(buf, "VmExe: %d", &trs); // text
}
}
/*
generally
shared = RSS - ( CODE + DATA + STACK )
share= resident - trs -drs -stack;
// Defines from task_mmu.c of kernel source
total_vm==size
data = mm->total_vm - mm->shared_vm - mm->stack_vm;
swap = p->size - p->resident ;
*/
// read /proc/PID/file_io
// NOTE: 2.6.11 dont have IO file
// COMPLEX_CODE
if ((buf = read_proc_file2(path, "io")) != 0)
{
// rchar = ... not file maybe sockread
//
mini_sscanf(buf, "read_bytes:%d", &io_read);
mini_sscanf(buf, "write_bytes:%d", &io_write);
// if(io_read_prev!=0)
{
if (io_read_prev == 0)
io_read_prev = io_read;
if (io_write_prev == 0)
io_write_prev = io_write;
// NOTE: Kbps right????
io_read_KBps = (io_read - io_read_prev) /
proc->update_msec; // not accurate....
io_write_KBps = (io_write - io_write_prev) / proc->update_msec;
proc->io_byte += io_read_KBps; // test
proc->io_byte += io_write_KBps;
}
io_read_prev = io_read;
io_write_prev = io_write;
// io_read>>=10; // divide by 1024
// io_write>>=10; // divide by 1024
}
// per_cpu_times = 0; // not yet
if ((buf = read_proc_file2(path, "wchan")) != 0)
{
wchan_str = buf;
}
policy = -1; // will get it when needed
rtprio = -1; // ditto
tms = -1; // ditto
// useless ? if(detail) detail->set_procinfo(this); // BAD !!!
return 2; // return ok.
}
// just grab the load averages
// called by
void Proc::read_loadavg()
{
char path[80];
char buf[512];
int n;
strcpy(path, "/proc/loadavg");
if ((n = read_file(path, buf, sizeof(buf) - 1)) <= 0)
{
fprintf(stderr, "qps: Cannot open /proc/loadavg (make sure "
"/proc is mounted)\n");
exit(1);
}
buf[n] = '\0';
sscanf(buf, "%f %f %f", &loadavg[0], &loadavg[1], &loadavg[2]);
}
int Proc::countCpu()
{
static bool first_run = true;
char path[80];
char buf[1024 * 8]; // for SMP
int num_cpus = 0, n;
// read system status /proc/stat
strcpy(path, "/proc/stat");
// if((buf= read_proc_file("stat:)) ==0 ) return -1;
if ((n = read_file(path, buf, sizeof(buf) - 1)) <= 0)
{
printf("Qps Error: /proc/stat can't be read ! check it and "
"report to "
"fasthyun@magicn.com\n");
abort(); // return 0;
}
buf[n] = '\0';
// count (current) cpu of system
char *p;
p = strstr(buf, "cpu");
while (p < buf + sizeof(buf) - 4 && strncmp(p, "cpu", 3) == 0)
{
num_cpus++;
if (strncmp(p, "cpu0", 4) == 0)
Proc::num_cpus--;
p = strchr(p, '\n');
if (p)
p++;
}
if (flag_devel and flag_SMPsim)
{
// num_cpus=64;
int vals[] = {2, 4, 8, 16, 32};
int r = rand() % 5;
num_cpus = vals[r];
}
return num_cpus;
}
// LINUX
// Description: read common information for all processes
// return value
// -1 : too fast refresh !
int Proc::read_system() //
{
static bool first_run = true;
char path[80];
char buf[1024 * 8]; // for SMP
char *p;
int n;
if (first_run)
{
/* Version 2.4.x ? */
strcpy(path, "/proc/vmstat");
if (!stat(path, (struct stat *)buf))
flag_24_ok = false;
else
flag_24_ok = true;
/* NPTL(Native POSIX Thread Library) */
strcpy(path, "/proc/1/task");
if (!stat(path, (struct stat *)buf))
flag_thread_ok = true;
else
flag_thread_ok = false;
/* check schedstat */
strcpy(path, "/proc/1/schedstat"); // some system doesn't have
if (!stat(path, (struct stat *)buf))
flag_schedstat = true;
else
flag_schedstat = false;
strcpy(path, "/proc/stat");
if ((n = read_file(path, buf, sizeof(buf) - 1)) <= 0)
return 0;
buf[n] = '\0';
p = strstr(buf, "btime");
if (p == NULL)
{
// used
printf("Qps: A bug occurs ! [boot_time] \n");
// boot_time= current time
}
else
{
p += 6;
// sscanf(p, "%d", &Proc::boot_time); //???? why
// segfault???
sscanf(p, "%d", &boot_time);
}
// Max SMP 1024 cpus, MOVETO: COMMON
int max_cpus = 512;
cpu_times_vec = new unsigned[CPUTIMES * max_cpus]; //??? +2
old_cpu_times_vec = new unsigned[CPUTIMES * max_cpus];
// init
for (int cpu = 0; cpu < max_cpus; cpu++)
for (int i = 0; i < CPUTIMES; i++)
{
cpu_times(cpu, i) = 0;
old_cpu_times(cpu, i) = 0;
}
// first_run=false; // not yet , at the bottom of this function
}
// read system status /proc/stat
strcpy(path, "/proc/stat");
// if((buf= read_proc_file("stat:)) ==0 ) return -1;
if ((n = read_file(path, buf, sizeof(buf) - 1)) <= 0)
{
printf("Qps Error: /proc/stat can't be read ! check it and "
"report to "
"fasthyun@magicn.com\n");
abort(); // return 0;
}
buf[n] = '\0';
if (true)
{
// count (current) cpu of system
char *p;
p = strstr(buf, "cpu");
num_cpus = 0;
while (p < buf + sizeof(buf) - 4 && strncmp(p, "cpu", 3) == 0)
{
num_cpus++;
if (strncmp(p, "cpu0", 4) == 0)
Proc::num_cpus--;
p = strchr(p, '\n');
if (p)
p++;
}
if (flag_SMPsim)
{
int vals[] = {2, 4, 8, 16, 32};
int r = rand() % 5;
num_cpus = vals[r];
num_cpus = 8;
}
// Hotplugging Detection : save total_cpu
if (Proc::num_cpus != Proc::old_num_cpus)
{
// for(int i = 0; i < CPUTIMES; i++)
// cpu_times(num_cpus, i) =
// cpu_times(Proc::old_num_cpus,
// i);
Proc::old_num_cpus = Proc::num_cpus;
}
}
// backup old values : important*******
for (int cpu = 0; cpu < Proc::num_cpus + 1; cpu++)
{
for (int i = 0; i < CPUTIMES; i++)
old_cpu_times(cpu, i) = cpu_times(cpu, i);
}
/*
/proc/stat
cpu# user nice system idle iowait(2.6)
irq(2.6) sft(2.6) steal(2.6.11) guest(2.6.24)
cpu0 3350 9 535 160879
1929 105 326 5
1200
Q1: kernel 2.4 cpu0 exist ?
*/
// Total_cpu
int total_cpu = Proc::num_cpus;
unsigned user, nice, system, idle, iowait, irq, sftirq, steal, guest, nflds;
nflds = sscanf(buf, "cpu %u %u %u %u %u %u %u %u %u", &user, &nice, &system,
&idle, &iowait, &irq, &sftirq, &steal, &guest);
if (nflds > 4)
{
// kernel 2.6.x
system += (irq + sftirq);
idle += iowait;
}
if (nflds == 9)
{
system += steal;
system += guest;
}
cpu_times(Proc::num_cpus, CPUTIME_USER) = user;
cpu_times(Proc::num_cpus, CPUTIME_NICE) = nice;
cpu_times(Proc::num_cpus, CPUTIME_SYSTEM) = system;
cpu_times(Proc::num_cpus, CPUTIME_IDLE) = idle;
// DRAFT!
// num_cpus == total_cpu
//
// dt_total= user + system + nice + idle
// dt_used= user + system;
Proc::dt_used =
user - old_cpu_times(Proc::num_cpus,
CPUTIME_USER); // infobar uses this value
Proc::dt_used += system - old_cpu_times(Proc::num_cpus, CPUTIME_SYSTEM);
Proc::dt_total = dt_used + nice -
old_cpu_times(Proc::num_cpus, CPUTIME_NICE) + idle -
old_cpu_times(Proc::num_cpus, CPUTIME_IDLE);
load_cpu = (float)Proc::dt_used / Proc::dt_total; // COMMON
if (first_run)
{
// printf("\n==================== tooo fast
//=================================\n");
// printf("DEBUG:dt_total=%d
// dt_used=%d\n",Proc::dt_total,Proc::dt_used);
// return -1; // too early refresh again !!
}
if (Proc::dt_total == 0)
{
//?????
printf("Error: dt_total=0 , dt_used=%ld(%u) report to "
"fasthyun@magicn.com\n",
Proc::dt_used, old_cpu_times(Proc::num_cpus, CPUTIME_IDLE));
dt_total = 500; // more tolerable?
// abort(); // stdlib.h
}
// void watchdog_syscpu(int );
// watchdog_syscpu((user-old_cpu_times(num_cpus,CPUTIME_USER))*100/dt_total);
//// test
// if(flag_devel and flag_SMPsim )
if (flag_SMPsim)
{
// for Developer only !!!
// printf("user%d nuce%d system%d
// idle%d\n",user,nice,system,idle);
for (int cpu = 0; cpu < num_cpus; cpu++)
{
// stdlib.h, int rand();
if (dt_used != 0)
cpu_times(cpu, CPUTIME_USER) =
old_cpu_times(cpu, CPUTIME_USER) + rand() % dt_used;
else
cpu_times(cpu, CPUTIME_USER) = 0;
cpu_times(cpu, CPUTIME_NICE) = nice;
cpu_times(cpu, CPUTIME_SYSTEM) = system;
cpu_times(cpu, CPUTIME_IDLE) = idle;
}
}
else
{
// Single-CPU and SMP(Multi-CPU)
for (int cpu = 0; cpu < num_cpus; cpu++)
{
char cpu_buf[10];
sprintf(cpu_buf, "cpu%d", cpu);
if ((p = strstr(buf, cpu_buf)) != 0)
{
nflds = sscanf(p, "%*s %u %u %u %u %u %u %u %u %u",
&cpu_times(cpu, CPUTIME_USER),
&cpu_times(cpu, CPUTIME_NICE),
&cpu_times(cpu, CPUTIME_SYSTEM),
&cpu_times(cpu, CPUTIME_IDLE), &iowait, &irq,
&sftirq, &steal, &guest);
// cpu_times(cpu, CPUTIME_USER),cpu_times(cpu,
// CPUTIME_NICE),
if (nflds > 4)
{
// kernel 2.6.x
cpu_times(cpu, CPUTIME_SYSTEM) += (irq + sftirq);
cpu_times(cpu, CPUTIME_IDLE) += iowait;
}
if (nflds == 9)
{
cpu_times(cpu, CPUTIME_SYSTEM) += (steal + guest);
}
// 2.4.27-SMP bug ?
}
else
{
fprintf(stderr, "Qps: Error reading info for "
"cpu%d (/proc/stat)\n",
cpu);
abort();
}
}
}
// read memory info
strcpy(path, PROCDIR);
strcat(path, "/meminfo");
if ((n = read_file(path, buf, sizeof(buf) - 1)) <= 0)
return 0;
buf[n] = '\0';
// Skip the old /meminfo cruft, making this work in post-2.1.42 kernels
// as well. (values are now in kB)
if ((p = strstr(buf, "MemTotal:")))
sscanf(p, "MemTotal: %d kB\n", &mem_total);
if ((p = strstr(buf, "MemFree:")) != NULL)
sscanf(p, "MemFree: %d kB\n", &mem_free);
if ((p = strstr(buf, "Buffers:")) != NULL)
sscanf(p, "Buffers: %d kB\n", &mem_buffers);
if ((p = strstr(buf, "Cached:")) != NULL)
sscanf(p, "Cached: %d kB\n", &mem_cached);
p = strstr(buf, "SwapTotal:");
sscanf(p, "SwapTotal: %d kB\nSwapFree: %d kB\n", &swap_total, &swap_free);
first_run = false;
return 0;
}
int Procinfo::get_policy()
{
if (policy == -1)
policy = sched_getscheduler(pid);
return policy;
}
int Procinfo::get_rtprio()
{
if (rtprio == -1)
{
struct sched_param p;
if (sched_getparam(pid, &p) == 0)
rtprio = p.sched_priority;
}
return rtprio;
}
double Procinfo::get_tms()
{
struct timespec ts;
if (sched_rr_get_interval(pid, &ts) == -1) // POSIX
tms = -1; // should not be possible
else
{
tms = ts.tv_nsec; // nano seconds
tms /= 1000000; // mili seconds
tms += ts.tv_sec * 1000;
}
return tms;
}
unsigned long Procinfo::get_affcpu()
{
#ifdef QPS_SCHED_AFFINITY
if (qps_sched_getaffinity(pid, sizeof(unsigned long), &affcpu) == -1)
affcpu = (unsigned long)0;
#else
if (sched_getaffinity(pid, sizeof(unsigned long), (cpu_set_t *)&affcpu) ==
-1)
affcpu = (unsigned long)0;
#endif
return affcpu;
}
// Description : read /proc/PID/fd/* (SYMBOLIC LINK NAME)
/* We need to implement support for IPV6 and sctp ? */
void Procinfo::read_fd(int fdnum, char *path)
{
int len;
char buf[128];
struct stat sb;
// The fd mode is contained in the link permission bits
if (lstat(path, &sb) < 0)
return;
int mode = 0;
if (sb.st_mode & 0400)
mode |= OPEN_READ;
if (sb.st_mode & 0200)
mode |= OPEN_WRITE;
if ((len = readlink(path, buf, sizeof(buf) - 1)) > 0)
{
buf[len] = '\0';
unsigned long dev, ino;
// check socket_fd
if ((buf[0] == '[' and sscanf(buf, "[%lx]:%lu", &dev, &ino) == 2 and
dev == 0) // Linux 2.0 style
||
sscanf(buf, "socket:[%lu]", &ino) > 0) // Linux 2.1 upper
{
Sockinfo *si = NULL;
si = proc->socks.value(ino, NULL); // sock
char buf[80];
if (si)
{
printf("sock ino=%lu\n", ino);
si->pid = pid;
// a TCP or UDP socket
sock_inodes.append(new SockInode(fdnum, ino));
sprintf(buf, "%s socket %lu",
si->proto == Sockinfo::TCP ? "TCP" : "UDP", ino);
fd_files.append(new Fileinfo(fdnum, buf, mode));
return;
}
else
{
// maybe a unix domain socket?
// read_usockets();
UnixSocket *us = NULL;
us = proc->usocks.value(ino, NULL);
if (us)
{
const char *tp = "?", *st = "?";
switch (us->type)
{
case SOCK_STREAM:
tp = "stream";
break;
case SOCK_DGRAM:
tp = "dgram";
break;
}
switch (us->state)
{
case SSFREE:
st = "free";
break;
case SSUNCONNECTED:
st = "unconn";
break;
case SSCONNECTING:
st = "connecting";
break;
case SSCONNECTED:
st = "connected";
break;
case SSDISCONNECTING:
st = "disconn";
break;
}
sprintf(buf, "UNIX domain socket %lu (%s, %s) ", ino, tp,
st);
QString s = buf;
s.append(us->name);
fd_files.append(new Fileinfo(fdnum, s, mode));
return;
}
}
}
// normal filess
// assume fds will be read in increasing order
fd_files.append(new Fileinfo(fdnum, buf, mode));
}
}
// Description :
// read /PID/fd opened files
// return true if /proc/PID/fd could be read, false otherwise
// store fileinfo, and also socket inodes separately
//
// called by Detail()
bool Procinfo::read_fds()
{
char path[128], *p;
if (flag_thread_ok && flag_show_thread)
sprintf(path, "/proc/%d/task/%d/fd", pid, pid);
else
sprintf(path, "/proc/%d/fd", pid);
DIR *d = opendir(path);
if (!d)
return false;
/*
if(!sock_inodes) sock_inodes = new Svec<SockInode*>(4);
else sock_inodes->purge(); */
strcat(path, "/");
fd_files.clear(); //
struct dirent *e;
while ((e = readdir(d)) != 0)
{
char str[128];
if (e->d_name[0] == '.')
continue; // skip . and ..
int fdnum = atoi(e->d_name);
strcpy(str, path);
strcat(str, e->d_name);
// printf("str=%s\n",str);
read_fd(fdnum, str);
}
// printf("end str=\n");
closedir(d);
return true;
}
// tcp, udp
bool Proc::read_socket_list(Sockinfo::proto_t proto, const char *filename)
{
char path[80];
sprintf(path, "/proc/net/%s", filename);
FILE *f = fopen(path, "r");
if (!f)
return false;
char buf[128 * 3];
// Header
// sl local_addr rem_addr st tx_queue rx_queue tr tm->when retrnsmt
// uid
// timeout inode
Sockinfo si;
printf("read_socket_list()\n");
fgets(buf, sizeof(buf), f); // skip header
while (fgets(buf, sizeof(buf), f) != 0)
{
// Sockinfo *si = new Sockinfo;
si.pid = -1;
si.proto = proto;
unsigned local_port, rem_port, st, tr;
sscanf(buf + 6, "%x:%x %x:%x %x %x:%x %x:%x %x %d %d %d",
&si.local_addr, &local_port, &si.rem_addr, &rem_port, &st,
&si.tx_queue, &si.rx_queue, &tr, &si.tm_when, &si.rexmits,
&si.uid, &si.timeout, &si.inode);
// fix fields that aren't sizeof(int)
si.local_port = local_port;
si.rem_port = rem_port;
si.st = st;
si.tr = tr;
Sockinfo *psi;
psi = socks.value(si.inode, NULL);
if (psi == NULL)
{
printf("inode =%d \n", si.inode);
psi = new Sockinfo;
*psi = si;
socks.insert(si.inode, psi);
}
else
*psi = si;
// linear_socks.add(si);
}
fclose(f);
return true;
}
bool Proc::read_usocket_list()
{
char path[80];
strcpy(path, PROCDIR);
strcat(path, "/net/unix");
FILE *f = fopen(path, "r");
if (!f)
return false;
char buf[256];
fgets(buf, sizeof(buf), f); // skip header
while (fgets(buf, sizeof(buf), f))
{
if (buf[0])
buf[strlen(buf) - 1] = '\0'; // chomp newline
// UnixSocket *us = new UnixSocket;
UnixSocket us;
unsigned q;
unsigned type, state;
int n;
sscanf(buf, "%x: %x %x %x %x %x %ld %n",
// Num refcount protocol flags type state indoe path
&q, &q, &q /*protocol*/, &us.flags, &type, &state, &us.inode,
&n);
us.name = buf + n;
us.type = type;
us.state = state;
UnixSocket *pus;
pus = usocks.value(us.inode, NULL);
if (pus == NULL)
{
printf("inode =%lu \n", us.inode);
pus = new UnixSocket;
*pus = us;
usocks.insert(us.inode, pus);
}
else
*pus = us;
}
fclose(f);
return true;
}
void Proc::read_sockets()
{
// socks.clear();
// memory leak !!
if (!read_socket_list(Sockinfo::TCP, "tcp") ||
!read_socket_list(Sockinfo::UDP, "udp"))
return;
// remove no more socket ino
read_usocket_list();
socks_current = true;
}
void Proc::read_usockets()
{
if (usocks_current)
return;
usocks.clear();
if (!read_usocket_list())
return;
usocks_current = true;
}
void Proc::invalidate_sockets() { socks_current = usocks_current = false; }
// return true if /proc/XX/maps could be read, false otherwise
bool Procinfo::read_maps()
{
// idea: here we could readlink /proc/XX/exe to identify the executable
// when running 2.0.x
char name[80];
if (flag_thread_ok && flag_show_thread)
sprintf(name, "/proc/%d/task/%d/maps", pid, pid);
else
sprintf(name, "/proc/%d/maps", pid);
FILE *f = fopen(name, "r");
if (!f)
return false;
char line[1024]; // lines can be longer , SEGFAULT
while (fgets(line, sizeof(line), f))
{
Mapsinfo *mi = new Mapsinfo;
int n;
sscanf(line, "%lx-%lx %4c %lx %x:%x %lu%n",
// sscanf(line, "%lx-%lx %4c %lx %x:%x %n",
&mi->from, &mi->to, mi->perm, &mi->offset, &mi->major,
&mi->minor, &mi->inode, &n);
if (line[n] != '\n')
{
int len = strlen(line);
if (line[len - 1] == '\n')
line[len - 1] = '\0';
while (line[n] == ' ' && line[n])
n++;
mi->filename = line + n;
}
else if ((mi->major | mi->minor | mi->inode) == 0)
mi->filename = "(anonymous)";
maps.append(mi);
}
fclose(f);
if (maps.size() == 0)
return false;
return true;
}
// DRAFT CODE:
// return true if /proc/777/environ could be read, false otherwise
int fsize(char *fname);
bool Procinfo::read_environ()
{
int file_size = 0;
int size;
char path[256];
environ.clear(); //
if (flag_thread_ok && flag_show_thread)
sprintf(path, "/proc/%d/task/%d/environ", pid, pid);
else
sprintf(path, "/proc/%d/environ", pid);
file_size = fsize(path);
if (file_size <= 0)
return false;
envblock = (char *)malloc(file_size + 1);
size = read_file(path, envblock, file_size + 1);
if (size <= 0)
return false;
// kernel 2.6.x has a bug
if (envblock[size - 2] == 0) // how to check the bug.
{
char buf[128];
sprintf(buf, "Kernel Bug= wrong environments ! please, check "
"/proc/%d/environ !",
pid);
size = strlen(buf) + 1;
if (file_size > size)
strcpy(envblock, buf);
}
int i = 0, n = 0, v = 0;
char ch;
for (i = 0; i < size; i++)
{
ch = envblock[i];
if (ch == '=')
{
envblock[i] = 0;
v = i + 1;
}
if (ch == 0)
{
NameValue nv(&envblock[n], &envblock[v]);
environ.append(nv);
// printf("%s %s\n",&envblock[n],&envblock[v]);
n = i + 1;
}
}
if (envblock)
{
free(envblock); // refresh() // INVALID VALGRIND
envblock = 0;
}
return true;
}
// CWD,ROOT only so...
Cat_dir::Cat_dir(const char *heading, const char *explain, const char *dirname,
QString Procinfo::*member)
: Cat_string(heading, explain), dir(dirname), cache(member)
{
}
QString Cat_dir::string(Procinfo *p)
{
if ((p->*cache).isNull())
{
char path[128], buf[512];
if (flag_thread_ok && flag_show_thread)
sprintf(path, "/proc/%d/task/%d/%s", p->pid, p->pid, dir);
else
sprintf(path, "/proc/%d/%s", p->pid, dir);
int n = readlink(path, buf, sizeof(buf) - 1);
if (n < 0)
{
// Either a kernel process, or access denied.
// A hyphen is visually least disturbing here.
p->*cache = "-";
return p->*cache;
}
else if (buf[0] != '[')
{
// linux >= 2.1.x: path name directly in link
buf[n] = '\0';
p->*cache = buf;
return p->*cache;
}
// Either a Linux 2.0 link in [device]:inode form, or a Solaris
// link.
// To resolve it, we just chdir() to it and see where we end up.
// Perhaps we should change back later?
if (chdir(path) < 0)
{
p->*cache = "-"; // Most likely access denied
}
else
{
// getcwd() is fairly expensive, but this is cached
// anyway
if (!getcwd(buf, sizeof(buf)))
{
p->*cache = "(deleted)";
}
else
p->*cache = buf;
}
}
return p->*cache;
}
Cat_state::Cat_state(const char *heading, const char *explain)
: Category(heading, explain)
{
}
QString Cat_state::string(Procinfo *p)
{
QString s(" ");
int ni = p->nice;
s[0] = p->state;
s[1] = (p->resident == 0 && p->state != 'Z') ? 'W' : ' ';
s[2] = (ni > 0) ? 'N' : ((ni < 0) ? '<' : ' ');
return s;
}
// LINUX
Cat_policy::Cat_policy(const char *heading, const char *explain)
: Category(heading, explain)
{
}
QString Cat_policy::string(Procinfo *p)
{
QString s;
switch (p->get_policy())
{
case SCHED_FIFO:
s = "FI";
break; // first in, first out
case SCHED_RR:
s = "RR";
break; // round-robin
case SCHED_OTHER:
s = "TS";
break; // time-sharing
default:
s = "??";
break;
}
return s;
}
int Cat_policy::compare(Procinfo *a, Procinfo *b)
{
return b->get_policy() - a->get_policy();
}
Cat_rtprio::Cat_rtprio(const char *heading, const char *explain)
: Category(heading, explain)
{
}
QString Cat_rtprio::string(Procinfo *p)
{
QString s;
s.setNum(p->get_rtprio());
return s;
}
int Cat_rtprio::compare(Procinfo *a, Procinfo *b)
{
return b->get_rtprio() - a->get_rtprio();
}
// maybe tms COMMON
Cat_tms::Cat_tms(const char *heading, const char *explain)
: Category(heading, explain)
{
}
QString Cat_tms::string(Procinfo *p)
{
QString s;
p->tms = p->get_tms();
s.sprintf("%.3f", p->tms);
// s.sprintf("%d",p->tms);
return s;
}
int Cat_tms::compare(Procinfo *a, Procinfo *b)
{
return (int)((b->get_tms() - a->get_tms()) * 1000);
}
Cat_affcpu::Cat_affcpu(const char *heading, const char *explain)
: Category(heading, explain)
{
}
QString Cat_affcpu::string(Procinfo *p)
{
QString s;
p->affcpu = p->get_affcpu();
s.sprintf("%lx", p->affcpu);
return s;
}
/*
int Cat_affcpu::compare(Procinfo *a, Procinfo *b)
{
return (int)(b->affcpu - a->affcpu);
}
*/
// LINUX or COMMON?
Cat_time::Cat_time(const char *heading, const char *explain)
: Category(heading, explain)
{
}
QString Cat_time::string(Procinfo *p)
{
QString s;
char buff[64];
int ticks = p->utime;
int ms;
int proctick = p->proc->clk_tick;
if (Procview::flag_cumulative)
ticks += p->cutime;
int t = ticks / p->proc->clk_tick; // seconds
// COMPLEX CODE
if (t < 10)
{ // ex. 9.23s
ms = ticks / (p->proc->clk_tick / 100) % 100; // Need FIX
sprintf(buff, "%1d.%02ds", t, ms);
}
else if (t < 60)
{ // ex. 48s
sprintf(buff, "%5ds", t);
}
else if (t < 60 * 10)
{ // ex. 8.9m, 9.0m
sprintf(buff, "%2d.%1dm", t / 60, (t % 60) / 6);
}
else if (t < 60 * 60)
{ // 58m
sprintf(buff, "%5dm", t / 60);
}
else if (t < 24 * 3600)
{ //
int h = t / 3600; // 1hour = 3600 = 60m*60s
t %= 3600;
sprintf(buff, "%2d:%02d", h, t / 60);
}
else if (t < 10 * 24 * 3600)
{ //
int d = t / 86400; // 1 day = 24* 3600s
t %= 86400;
sprintf(buff, "%2d.%1dd", d, (t * 10 / (3600 * 24)));
}
else
{
int d = t / 86400; // 1 day = 24* 3600s
sprintf(buff, "%5dd", d);
}
s = buff;
return s;
}
int Cat_time::compare(Procinfo *a, Procinfo *b)
{
int at = a->utime, bt = b->utime;
if (Procview::flag_cumulative)
{
at += a->cutime;
bt += b->cutime;
}
return bt - at;
}
// LINUX ?
Cat_tty::Cat_tty(const char *heading, const char *explain)
: Cat_string(heading, explain)
{
}
QString Cat_tty::string(Procinfo *p) { return Ttystr::name(p->tty); }
Proc::Proc()
{
// Note:
categories.insert(F_PID,
new Cat_int("PID", "Process ID", 6, &Procinfo::pid));
categories.insert(F_TGID,
new Cat_int("TGID", "Task group ID ( parent of threads )",
6, &Procinfo::tgid));
categories.insert(
F_PPID, new Cat_int("PPID", "Parent process ID", 6, &Procinfo::ppid));
categories.insert(
F_PGID, new Cat_int("PGID", "Process group ID", 6, &Procinfo::pgrp));
categories.insert(F_SID,
new Cat_int("SID", "Session ID", 6, &Procinfo::session));
categories.insert(F_TTY, new Cat_tty("TTY", "Terminal"));
categories.insert(F_TPGID,
new Cat_int("TPGID", "Process group ID of tty owner", 6,
&Procinfo::tpgid));
categories.insert(
F_USER, new Cat_string("USER", "Owner (*=suid root, +=suid a user)",
&Procinfo::username));
categories.insert(F_GROUP,
new Cat_string("GROUP", "Group name (*=sgid other)",
&Procinfo::groupname));
categories.insert(F_UID,
new Cat_int("UID", "Real user ID", 6, &Procinfo::uid));
categories.insert(
F_EUID, new Cat_int("EUID", "Effective user ID", 6, &Procinfo::euid));
categories.insert(F_SUID, new Cat_int("SUID", "Saved user ID (Posix)", 6,
&Procinfo::suid));
categories.insert(F_FSUID, new Cat_int("FSUID", "File system user ID", 6,
&Procinfo::fsuid));
categories.insert(F_GID,
new Cat_int("GID", "Real group ID", 6, &Procinfo::gid));
categories.insert(
F_EGID, new Cat_int("EGID", "Effective group ID", 6, &Procinfo::egid));
categories.insert(F_SGID, new Cat_int("SGID", "Saved group ID (Posix)", 6,
&Procinfo::sgid));
categories.insert(F_FSGID, new Cat_int("FSGID", "File system group ID", 6,
&Procinfo::fsgid));
categories.insert(
F_PRI, new Cat_int("PRI", "Dynamic priority", 4, &Procinfo::priority));
categories.insert(F_NICE,
new Cat_int("NICE",
"Scheduling favour (higher -> less cpu time)",
4, &Procinfo::nice));
categories.insert(
F_NLWP, new Cat_int("NLWP", "Number of tasks(threads) in task group", 5,
&Procinfo::nthreads));
categories.insert(F_PLCY, new Cat_policy("PLCY", "Scheduling policy"));
categories.insert(
F_RPRI,
new Cat_rtprio("RPRI", "Realtime priority (0-99, more is better)"));
categories.insert(F_TMS, new Cat_tms("TMS", "Time slice in milliseconds"));
categories.insert(F_SLPAVG,
new Cat_int("%SAVG",
"Percentage average sleep time (-1 -> N/A)",
4, &Procinfo::slpavg));
categories.insert(
F_AFFCPU,
new Cat_affcpu("CPUSET",
"Affinity CPU mask (0 -> API not supported)")); // ???
categories.insert(F_MAJFLT,
new Cat_uintl("MAJFLT",
"Number of major faults (disk access)", 8,
&Procinfo::majflt));
categories.insert(F_MINFLT,
new Cat_uintl("MINFLT",
"Number of minor faults (no disk access)",
8, &Procinfo::minflt));
// Memory
categories.insert(F_SIZE,
new Cat_memory("VSIZE", "Virtual image size of process",
8, &Procinfo::size));
categories.insert(F_RSS, new Cat_memory("RSS", "Resident set size", 8,
&Procinfo::resident));
categories.insert(F_MEM, new Cat_memory("MEM", "memory usage (RSS-SHARE)",
8, &Procinfo::mem));
categories.insert(F_TRS,
new Cat_memory("TRS", "Text(code) resident set size", 8,
&Procinfo::trs));
categories.insert(
F_DRS,
new Cat_memory("DRS", "Data resident set size(malloc+global variable)",
8, &Procinfo::drs));
categories.insert(
F_STACK, new Cat_memory("STACK", "Stack size", 8, &Procinfo::stack));
categories.insert(F_SHARE,
new Cat_memory("SHARE", "Shared memory with other libs",
8, &Procinfo::share));
categories.insert(F_SWAP, new Cat_swap("SWAP", "Kbytes on swap device"));
categories.insert(
F_IOR, new Cat_memory("IO_R", "io read (file)", 8, &Procinfo::io_read));
categories.insert(F_IOW, new Cat_memory("IO_W", "io write (file)", 8,
&Procinfo::io_write));
categories.insert(F_DT,
new Cat_uintl("DT", "Number of dirty (non-written) pages",
7, &Procinfo::dt));
categories.insert(F_STAT, new Cat_state("STAT", "State of the process "));
categories.insert(F_FLAGS, new Cat_hex("FLAGS", "Process flags (hex)", 9,
&Procinfo::flags));
categories.insert(
F_WCHAN,
new Cat_wchan("WCHAN", "Kernel function where process is sleeping"));
categories.insert(
F_WCPU,
new Cat_percent("%WCPU", "Weighted percentage of CPU (30 s average)", 6,
&Procinfo::wcpu));
categories.insert(
F_CPU,
new Cat_percent("%CPU", "Percentage of CPU used since last update", 6,
&Procinfo::pcpu));
categories.insert(
F_PMEM,
new Cat_percent("%MEM", "Percentage of memory used (RSS/total mem)", 6,
&Procinfo::pmem));
categories.insert(F_START, new Cat_start("START", "Time process started"));
categories.insert(F_TIME,
new Cat_time("TIME", "Total CPU time used since start"));
categories.insert(
F_CPUNUM,
new Cat_int("CPU", "CPU the process is executing on (SMP system)", 3,
&Procinfo::which_cpu));
categories.insert(F_CMD, new Cat_string("Process Name", "the process name",
&Procinfo::command));
// categories.insert(F_PROCESSNAME, new Cat_string("Process Name",
//"the
// process name", &Procinfo::command));
categories.insert(F_CWD, new Cat_dir("CWD", "Current working directory",
"cwd", &Procinfo::cwd));
categories.insert(F_ROOT, new Cat_dir("ROOT", "Root directory of process",
"root", &Procinfo::root));
// command_line="COMMAND_LINE"; //reference to /proc/1234/cmdline
categories.insert(F_CMDLINE,
new Cat_cmdline("COMMAND_LINE",
"Command line that started the process"));
commonPostInit();
socks_current = false;
usocks_current = false;
Proc::init_static();
}
Proc::~Proc()
{
// killall procinfos
}
// COMMON for LINUX,SOLARIS
// Polling /proc/PID/*
void Proc::read_proc_all()
{
DIR *d = opendir("/proc");
struct dirent *e;
while ((e = readdir(d)) != 0)
{
if (e->d_name[0] >= '0' and e->d_name[0] <= '9')
{ // good idea !
int pid;
Procinfo *pi = NULL;
// inline int x_atoi(const char *sstr);
// pid=x_atoi(e->d_name); //if(pid<100) continue;
pid = atoi(e->d_name);
pi = procs.value(pid, NULL);
if (pi == NULL) // new process
{
pi = new Procinfo(this, pid);
procs.insert(pid, pi);
/*
Procinfo *parent;
parent =procs[pi->ppid];
if(parent)
parent->children->add(pi);
printf("Qps : parent null
pid[%d]\n",pi->pid); }
*/
}
int ret = pi->readproc();
if (ret > 0)
{
pi->generation = current_gen; // this process is alive
// printf(" [%s] %d
// %d\n",pi->command.toAscii().data(),pi->generation,current_gen);
if (flag_show_thread and flag_thread_ok)
read_pid_tasks(pid); // for threads
// add to History expect thread
if (ret == 2)
{
Procinfo *p = new Procinfo(*pi); // copy
p->clone = true;
hprocs->insert(pid, p);
}
}
else
{
// already gone. /proc/PID dead!
// later remove this process ! not yet
}
}
}
closedir(d);
}
// COMMON , redesign
Proclist Proc::getHistory(int pos)
{
Proclist l;
if (pos <= 0)
{
return l;
}
int size = history.size();
if (size > pos)
l = history[size - pos]->procs;
return l;
}
void Proc::setHistory(int tick)
{
return;
if (tick <= 0)
{
mprocs = 0;
return;
}
int size = history.size();
if (size > tick)
mprocs = &history[size - tick]->procs;
else
mprocs = 0;
}
bool Procinfo::isThread()
{
return pid != tgid; // how to check
}
// LINUX size=64
int Procview::custom_fields[] = {F_PID, F_TTY, F_USER, F_NICE,
F_SIZE, F_MEM, F_STAT, F_CPU,
F_START, F_TIME, F_CMDLINE, F_END};
// COMMON: basic field
int Procview::basic_fields[] = {F_PID, F_TTY, F_USER, F_CPUNUM,
F_STAT, F_MEM, F_CPU, F_START,
F_TIME, F_CMDLINE, F_END};
int Procview::jobs_fields[] = {F_PID, F_TGID, F_PPID, F_PGID,
F_SID, F_TPGID, F_STAT, F_UID,
F_TIME, F_CMDLINE, F_END};
int Procview::mem_fields[] = {F_PID, F_TTY, F_MAJFLT, F_MINFLT, F_SIZE,
F_RSS, F_TRS, F_DRS, F_STACK, F_SHARE,
// F_DT,
F_CMDLINE, F_END};
int Procview::sched_fields[] = {F_PID, F_TGID, F_NLWP, F_STAT, F_FLAGS,
F_PLCY, F_PRI, F_NICE, F_TMS, F_SLPAVG,
F_RPRI, F_AFFCPU, F_CPU, F_START, F_TIME,
F_CMDLINE, F_END};
void Procview::set_fields()
{
switch (viewfields)
{
case USER: // BASIC FIELD
set_fields_list(basic_fields);
break;
case JOBS:
set_fields_list(jobs_fields);
break;
case MEM:
set_fields_list(mem_fields);
break;
case SCHED:
set_fields_list(sched_fields);
break;
case CUSTOM:
set_fields_list(custom_fields);
break;
default:
printf("Error ? set_fields_list \n");
}
fieldArrange();
}
// LINUX:
// deduce whether the currently selected fields correspond to a field list
void Procview::deduce_fields()
{
return; // under development (by fasthyun@magicn.com) 2006/05/24
if (viewfields != CUSTOM)
return;
Procview::fieldstates tags[4] = {USER, JOBS, MEM, SCHED};
int *lists[4] = {basic_fields, jobs_fields, mem_fields, sched_fields};
for (int i = 0; i < 4; i++)
{
int *l = lists[i];
int j;
for (j = 0; l[j] != F_END; j++)
if (findCol(l[j]) < 0)
break;
if (l[j] == F_END && j == cats.size())
{
viewfields = tags[i];
return;
}
}
}
// move to Proc.cpp
#include <sys/utsname.h> // uname()
int get_kernel_version()
{
int version = 0;
char *p;
struct utsname uname_info;
if (uname(&uname_info) == 0) // man -S 2 uname
{
// printf("sysname =%s \n",uname_info.sysname);
if (strcasecmp(uname_info.sysname, "linux") == 0)
{
Q_UNUSED(uname_info.release[0]);
}
p = uname_info.release;
char str[32];
int major, minor, patch;
int result;
result = sscanf(p, "%d.%d.%d", &major, &minor, &patch);
if (result == 2)
{
// only read two value
patch = 0; // ex) 3.0-ARCH
}
else if (result < 3)
{
fprintf(stderr, "Qps: can't determine version, read %s \n", p);
fprintf(stderr, "please report this bug.\n");
exit(1);
}
version = major * 10000 + minor * 100 + patch;
// ex) 2.6.17 == 20617 , 2.4.8 == 20408
printf("DEBUG: version = %d\n", version);
}
else
{
fprintf(stderr, "Qps: uname() failed. (%d) \n", version);
fprintf(stderr, "please report this bug.\n");
exit(1);
}
return version;
}
void check_system_requirement()
{
int kernel_version = 0;
kernel_version = get_kernel_version();
if (kernel_version < 20600) // less 2.6
{
printf("Qps: kernel 2.4.x not supported !!!\n\n"); // because of
// 2.4.x SMP
// bugs
exit(0);
}
}