procps/top.c - busybox - Git at Google

 /*
  * A tiny 'top' utility.
  *
  * This is written specifically for the linux /proc/<PID>/stat(m)
  * files format.

  * This reads the PIDs of all processes and their status and shows
  * the status of processes (first ones that fit to screen) at given
  * intervals.
  *
  * NOTES:
  * - At startup this changes to /proc, all the reads are then
  *   relative to that.
  *
  * (C) Eero Tamminen <oak at welho dot com>
  *
  * Rewroted by Vladimir Oleynik (C) 2002 <dzo@simtreas.ru>
  */

 /* Original code Copyrights */
 /*
  * Copyright (c) 1992 Branko Lankester
  * Copyright (c) 1992 Roger Binns
  * Copyright (C) 1994-1996 Charles L. Blake.
  * Copyright (C) 1992-1998 Michael K. Johnson
  * May be distributed under the conditions of the
  * GNU Library General Public License
  */

 #include <sys/types.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <unistd.h>
 #include <string.h>
 #include <sys/ioctl.h>
 /* get page info */
 #include <asm/page.h>
 #include "busybox.h"

 //#define FEATURE_CPU_USAGE_PERCENTAGE  /* + 2k */

 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 #include <time.h>
 #include <sys/time.h>
 #include <fcntl.h>
 #include <netinet/in.h>  /* htons */
 #endif


 typedef int (*cmp_t)(procps_status_t *P, procps_status_t *Q);

 static procps_status_t *top;   /* Hehe */
 static int ntop;


 static int pid_sort (procps_status_t *P, procps_status_t *Q)
 {
     int p = P->pid;
     int q = Q->pid;

     if( p < q ) return -1;
     if( p > q ) return  1;
     return 0;
 }

 static int mem_sort (procps_status_t *P, procps_status_t *Q)
 {
     long p = P->rss;
     long q = Q->rss;

     if( p > q ) return -1;
     if( p < q ) return  1;
     return 0;
 }

 #ifdef FEATURE_CPU_USAGE_PERCENTAGE

 #define sort_depth 3
 static cmp_t sort_function[sort_depth];

 static int pcpu_sort (procps_status_t *P, procps_status_t *Q)
 {
     int p = P->pcpu;
     int q = Q->pcpu;

     if( p > q ) return -1;
     if( p < q ) return  1;
     return 0;
 }

 static int time_sort (procps_status_t *P, procps_status_t *Q)
 {
     long p = P->stime;
     long q = Q->stime;

     p += P->utime;
     q += Q->utime;
     if( p > q ) return -1;
     if( p < q ) return  1;
     return 0;
 }

 int mult_lvl_cmp(void* a, void* b) {
     int i, cmp_val;

     for(i = 0; i < sort_depth; i++) {
 	cmp_val = (*sort_function[i])(a, b);
 	if (cmp_val != 0)
 	    return cmp_val;
     }
     return 0;
 }

 /* This structure stores some critical information from one frame to
    the next. mostly used for sorting. Added cumulative and resident fields. */
 struct save_hist {
     int ticks;
     int pid;
     int utime;
     int stime;
 };

 /*
  * Calculates percent cpu usage for each task.
  */

 static struct save_hist *save_history;

 static unsigned long Hertz;

 /***********************************************************************
  * Some values in /proc are expressed in units of 1/HZ seconds, where HZ
  * is the kernel clock tick rate. One of these units is called a jiffy.
  * The HZ value used in the kernel may vary according to hacker desire.
  * According to Linus Torvalds, this is not true. He considers the values
  * in /proc as being in architecture-dependant units that have no relation
  * to the kernel clock tick rate. Examination of the kernel source code
  * reveals that opinion as wishful thinking.
  *
  * In any case, we need the HZ constant as used in /proc. (the real HZ value
  * may differ, but we don't care) There are several ways we could get HZ:
  *
  * 1. Include the kernel header file. If it changes, recompile this library.
  * 2. Use the sysconf() function. When HZ changes, recompile the C library!
  * 3. Ask the kernel. This is obviously correct...
  *
  * Linus Torvalds won't let us ask the kernel, because he thinks we should
  * not know the HZ value. Oh well, we don't have to listen to him.
  * Someone smuggled out the HZ value. :-)
  *
  * This code should work fine, even if Linus fixes the kernel to match his
  * stated behavior. The code only fails in case of a partial conversion.
  *
  */

 #define FILE_TO_BUF(filename, fd) do{                           \
     if (fd == -1 && (fd = open(filename, O_RDONLY)) == -1) {    \
 	bb_perror_msg_and_die("/proc not be mounted?");            \
     }                                                           \
     lseek(fd, 0L, SEEK_SET);                                    \
     if ((local_n = read(fd, buf, sizeof buf - 1)) < 0) {        \
 	bb_perror_msg_and_die("%s", filename);                     \
     }                                                           \
     buf[local_n] = '\0';                                        \
 }while(0)

 #define FILE_TO_BUF2(filename, fd) do{                          \
     lseek(fd, 0L, SEEK_SET);                                    \
     if ((local_n = read(fd, buf, sizeof buf - 1)) < 0) {        \
 	bb_perror_msg_and_die("%s", filename);                     \
     }                                                           \
     buf[local_n] = '\0';                                        \
 }while(0)

 static void init_Hertz_value(void) {
   unsigned long user_j, nice_j, sys_j, other_j;  /* jiffies (clock ticks) */
   double up_1, up_2, seconds;
   unsigned long jiffies, h;
   char buf[80];
   int uptime_fd = -1;
   int stat_fd = -1;

   long smp_num_cpus = sysconf(_SC_NPROCESSORS_CONF);

   if(smp_num_cpus<1) smp_num_cpus=1;
   do {
     int local_n;

     FILE_TO_BUF("uptime", uptime_fd);
     up_1 = strtod(buf, 0);
     FILE_TO_BUF("stat", stat_fd);
     sscanf(buf, "cpu %lu %lu %lu %lu", &user_j, &nice_j, &sys_j, &other_j);
     FILE_TO_BUF2("uptime", uptime_fd);
     up_2 = strtod(buf, 0);
   } while((long)( (up_2-up_1)*1000.0/up_1 )); /* want under 0.1% error */

   close(uptime_fd);
   close(stat_fd);

   jiffies = user_j + nice_j + sys_j + other_j;
   seconds = (up_1 + up_2) / 2;
   h = (unsigned long)( (double)jiffies/seconds/smp_num_cpus );
   /* actual values used by 2.4 kernels: 32 64 100 128 1000 1024 1200 */
   switch(h){
   case   30 ...   34 :  Hertz =   32; break; /* ia64 emulator */
   case   48 ...   52 :  Hertz =   50; break;
   case   58 ...   62 :  Hertz =   60; break;
   case   63 ...   65 :  Hertz =   64; break; /* StrongARM /Shark */
   case   95 ...  105 :  Hertz =  100; break; /* normal Linux */
   case  124 ...  132 :  Hertz =  128; break; /* MIPS, ARM */
   case  195 ...  204 :  Hertz =  200; break; /* normal << 1 */
   case  253 ...  260 :  Hertz =  256; break;
   case  295 ...  304 :  Hertz =  300; break; /* 3 cpus */
   case  393 ...  408 :  Hertz =  400; break; /* normal << 2 */
   case  495 ...  504 :  Hertz =  500; break; /* 5 cpus */
   case  595 ...  604 :  Hertz =  600; break; /* 6 cpus */
   case  695 ...  704 :  Hertz =  700; break; /* 7 cpus */
   case  790 ...  808 :  Hertz =  800; break; /* normal << 3 */
   case  895 ...  904 :  Hertz =  900; break; /* 9 cpus */
   case  990 ... 1010 :  Hertz = 1000; break; /* ARM */
   case 1015 ... 1035 :  Hertz = 1024; break; /* Alpha, ia64 */
   case 1095 ... 1104 :  Hertz = 1100; break; /* 11 cpus */
   case 1180 ... 1220 :  Hertz = 1200; break; /* Alpha */
   default:
     /* If 32-bit or big-endian (not Alpha or ia64), assume HZ is 100. */
     Hertz = (sizeof(long)==sizeof(int) || htons(999)==999) ? 100UL : 1024UL;
   }
 }

 static void do_stats(void)
 {
     struct timeval t;
     static struct timeval oldtime;
     struct timezone timez;
     float elapsed_time;

     procps_status_t *cur;
     int total_time, i, n;
     static int prev_count;
     int systime, usrtime, pid;

     struct save_hist *New_save_hist;

     /*
      * Finds the current time (in microseconds) and calculates the time
      * elapsed since the last update.
      */
     gettimeofday(&t, &timez);
     elapsed_time = (t.tv_sec - oldtime.tv_sec)
 	+ (float) (t.tv_usec - oldtime.tv_usec) / 1000000.0;
     oldtime.tv_sec  = t.tv_sec;
     oldtime.tv_usec = t.tv_usec;

     New_save_hist  = alloca(sizeof(struct save_hist)*ntop);
     /*
      * Make a pass through the data to get stats.
      */
     for(n = 0; n < ntop; n++) {
 	cur = top + n;

 	/*
 	 * Calculate time in cur process.  Time is sum of user time
 	 * (usrtime) plus system time (systime).
 	 */
 	systime = cur->stime;
 	usrtime = cur->utime;
 	pid = cur->pid;
 	total_time = systime + usrtime;
 	New_save_hist[n].ticks = total_time;
 	New_save_hist[n].pid = pid;
 	New_save_hist[n].stime = systime;
 	New_save_hist[n].utime = usrtime;

 	/* find matching entry from previous pass */
 	for (i = 0; i < prev_count; i++) {
 	    if (save_history[i].pid == pid) {
 		total_time -= save_history[i].ticks;
 		systime -= save_history[i].stime;
 		usrtime -= save_history[i].utime;
 		break;
 	    }
 	}

 	/*
 	 * Calculate percent cpu time for cur task.
 	 */
 	i = (total_time * 10 * 100/Hertz) / elapsed_time;
 	if (i > 999)
 	    i = 999;
 	cur->pcpu = i;

     }

     /*
      * Save cur frame's information.
      */
     free(save_history);
     save_history = memcpy(xmalloc(sizeof(struct save_hist)*n), New_save_hist,
 						sizeof(struct save_hist)*n);
     prev_count = n;
     qsort(top, n, sizeof(procps_status_t), (void*)mult_lvl_cmp);
 }
 #else
 static cmp_t sort_function;
 #endif /* FEATURE_CPU_USAGE_PERCENTAGE */

 /* display generic info (meminfo / loadavg) */
 static unsigned long display_generic(void)
 {
 	FILE *fp;
 	char buf[80];
 	float avg1, avg2, avg3;
 	unsigned long total, used, mfree, shared, buffers, cached;
 	unsigned int needs_conversion = 1;

 	/* read memory info */
 	fp = bb_xfopen("meminfo", "r");

 	/*
 	 * Old kernels (such as 2.4.x) had a nice summary of memory info that
 	 * we could parse, however this is gone entirely in 2.6. Try parsing
 	 * the old way first, and if that fails, parse each field manually.
 	 *
 	 * First, we read in the first line. Old kernels will have bogus
 	 * strings we don't care about, whereas new kernels will start right
 	 * out with MemTotal:
 	 * 				-- PFM.
 	 */
 	if (fscanf(fp, "MemTotal: %lu %s\n", &total, buf) != 2) {
 		fgets(buf, sizeof(buf), fp);	/* skip first line */

 		fscanf(fp, "Mem: %lu %lu %lu %lu %lu %lu",
 		   &total, &used, &mfree, &shared, &buffers, &cached);
 	} else {
 		/*
 		 * Revert to manual parsing, which incidentally already has the
 		 * sizes in kilobytes. This should be safe for both 2.4 and
 		 * 2.6.
 		 */
 		needs_conversion = 0;

 		fscanf(fp, "MemFree: %lu %s\n", &mfree, buf);

 		/*
 		 * MemShared: is no longer present in 2.6. Report this as 0,
 		 * to maintain consistent behavior with normal procps.
 		 */
 		if (fscanf(fp, "MemShared: %lu %s\n", &shared, buf) != 2)
 			shared = 0;

 		fscanf(fp, "Buffers: %lu %s\n", &buffers, buf);
 		fscanf(fp, "Cached: %lu %s\n", &cached, buf);

 		used = total - mfree;
 	}
 	fclose(fp);

 	/* read load average */
 	fp = bb_xfopen("loadavg", "r");
 	if (fscanf(fp, "%f %f %f", &avg1, &avg2, &avg3) != 3) {
 		bb_error_msg_and_die("failed to read '%s'", "loadavg");
 	}
 	fclose(fp);

 	if (needs_conversion) {
 		/* convert to kilobytes */
 		used /= 1024;
 		mfree /= 1024;
 		shared /= 1024;
 		buffers /= 1024;
 		cached /= 1024;
 		total /= 1024;
 	}

 	/* output memory info and load average */
 	/* clear screen & go to top */
 	printf("\e[H\e[J" "Mem: "
 	       "%ldK used, %ldK free, %ldK shrd, %ldK buff, %ldK cached\n",
 	       used, mfree, shared, buffers, cached);
 	printf("Load average: %.2f, %.2f, %.2f    "
 			"(State: S=sleeping R=running, W=waiting)\n",
 	       avg1, avg2, avg3);
 	return total;
 }


 /* display process statuses */
 static void display_status(int count, int col)
 {
 	procps_status_t *s = top;
 	char rss_str_buf[8];
 	unsigned long total_memory = display_generic();

 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 	/* what info of the processes is shown */
 	printf("\n\e[7m  PID USER     STATUS   RSS  PPID %%CPU %%MEM COMMAND\e[0m\n");
 #else
 	printf("\n\e[7m  PID USER     STATUS   RSS  PPID %%MEM COMMAND\e[0m\n");
 #endif

 	while (count--) {
 		char *namecmd = s->short_cmd;
 		int pmem;

 		pmem = 1000.0 * s->rss / total_memory;
 		if (pmem > 999) pmem = 999;

 		if(s->rss > 10*1024)
 			sprintf(rss_str_buf, "%6ldM", s->rss/1024);
 		else
 			sprintf(rss_str_buf, "%7ld", s->rss);
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 		printf("%5d %-8s %s  %s %5d %2d.%d %2u.%u ",
 			s->pid, s->user, s->state, rss_str_buf, s->ppid,
 			s->pcpu/10, s->pcpu%10, pmem/10, pmem%10);
 #else
 		printf("%5d %-8s %s  %s %5d %2u.%u ",
 			s->pid, s->user, s->state, rss_str_buf, s->ppid,
 			pmem/10, pmem%10);
 #endif
 			if(strlen(namecmd) > col)
 				namecmd[col] = 0;
 			printf("%s\n", namecmd);
 		s++;
 	}
 }

 static void clearmems(void)
 {
 	free(top);
 	top = 0;
 	ntop = 0;
 }

 #if defined CONFIG_FEATURE_USE_TERMIOS
 #include <termios.h>
 #include <sys/time.h>
 #include <signal.h>


 static struct termios initial_settings;

 static void reset_term(void)
 {
 	tcsetattr(0, TCSANOW, (void *) &initial_settings);
 #ifdef CONFIG_FEATURE_CLEAN_UP
 	clearmems();
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 	free(save_history);
 #endif
 #endif /* CONFIG_FEATURE_CLEAN_UP */
 }

 static void sig_catcher (int sig)
 {
 	reset_term();
 }
 #endif /* CONFIG_FEATURE_USE_TERMIOS */


 int top_main(int argc, char **argv)
 {
 	int opt, interval, lines, col;
 #if defined CONFIG_FEATURE_USE_TERMIOS
 	struct termios new_settings;
 	struct timeval tv;
 	fd_set readfds;
 	unsigned char c;
 	struct sigaction sa;
 #endif /* CONFIG_FEATURE_USE_TERMIOS */

 	/* Default update rate is 5 seconds */
 	interval = 5;

 	/* do normal option parsing */
 	while ((opt = getopt(argc, argv, "d:")) > 0) {
 	    switch (opt) {
 		case 'd':
 		    interval = atoi(optarg);
 		    break;
 		default:
 		    bb_show_usage();
 	    }
 	}

 	/* Default to 25 lines - 5 lines for status */
 	lines = 25 - 5;
 	/* Default CMD format size */
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 	col = 35 - 6;
 #else
 	col = 35;
 #endif
 	/* change to /proc */
 	if (chdir("/proc") < 0) {
 		bb_perror_msg_and_die("chdir('/proc')");
 	}
 #if defined CONFIG_FEATURE_USE_TERMIOS
 	tcgetattr(0, (void *) &initial_settings);
 	memcpy(&new_settings, &initial_settings, sizeof(struct termios));
 	new_settings.c_lflag &= ~(ISIG | ICANON); /* unbuffered input */
 	/* Turn off echoing */
 	new_settings.c_lflag &= ~(ECHO | ECHONL);

 	signal (SIGTERM, sig_catcher);
 	sigaction (SIGTERM, (struct sigaction *) 0, &sa);
 	sa.sa_flags |= SA_RESTART;
 	sa.sa_flags &= ~SA_INTERRUPT;
 	sigaction (SIGTERM, &sa, (struct sigaction *) 0);
 	sigaction (SIGINT, &sa, (struct sigaction *) 0);
 	tcsetattr(0, TCSANOW, (void *) &new_settings);
 	atexit(reset_term);

 	get_terminal_width_height(0, &col, &lines);
 	if (lines > 4) {
 	    lines -= 5;
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 	    col = col - 80 + 35 - 6;
 #else
 	    col = col - 80 + 35;
 #endif
 	}
 #endif /* CONFIG_FEATURE_USE_TERMIOS */
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 	sort_function[0] = pcpu_sort;
 	sort_function[1] = mem_sort;
 	sort_function[2] = time_sort;
 #else
 	sort_function = mem_sort;
 #endif
 	while (1) {
 		/* read process IDs & status for all the processes */
 		procps_status_t * p;

 #ifdef CONFIG_SELINUX
 		while ((p = procps_scan(0, 0, NULL) ) != 0) {
 #else
 		while ((p = procps_scan(0)) != 0) {
 #endif
 			int n = ntop;

 			top = xrealloc(top, (++ntop)*sizeof(procps_status_t));
 			memcpy(top + n, p, sizeof(procps_status_t));
 		}
 		if (ntop == 0) {
 		bb_perror_msg_and_die("scandir('/proc')");
 	}
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 		if(!Hertz) {
 			init_Hertz_value();
 			do_stats();
 			sleep(1);
 			clearmems();
 			continue;
 	}
 		do_stats();
 #else
 		qsort(top, ntop, sizeof(procps_status_t), (void*)sort_function);
 #endif
 		opt = lines;
 		if (opt > ntop) {
 			opt = ntop;
 		}
 		/* show status for each of the processes */
 		display_status(opt, col);
 #if defined CONFIG_FEATURE_USE_TERMIOS
 		tv.tv_sec = interval;
 		tv.tv_usec = 0;
 		FD_ZERO (&readfds);
 		FD_SET (0, &readfds);
 		select (1, &readfds, NULL, NULL, &tv);
 		if (FD_ISSET (0, &readfds)) {
 			if (read (0, &c, 1) <= 0) {   /* signal */
 		return EXIT_FAILURE;
 	}
 			if(c == 'q' || c == initial_settings.c_cc[VINTR])
 				return EXIT_SUCCESS;
 			if(c == 'M') {
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 				sort_function[0] = mem_sort;
 				sort_function[1] = pcpu_sort;
 				sort_function[2] = time_sort;
 #else
 				sort_function = mem_sort;
 #endif
 			}
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 			if(c == 'P') {
 				sort_function[0] = pcpu_sort;
 				sort_function[1] = mem_sort;
 				sort_function[2] = time_sort;
 			}
 			if(c == 'T') {
 				sort_function[0] = time_sort;
 				sort_function[1] = mem_sort;
 				sort_function[2] = pcpu_sort;
 			}
 #endif
 			if(c == 'N') {
 #ifdef FEATURE_CPU_USAGE_PERCENTAGE
 				sort_function[0] = pid_sort;
 #else
 				sort_function = pid_sort;
 #endif
 			}
 		}
 #else
 		sleep(interval);
 #endif                                  /* CONFIG_FEATURE_USE_TERMIOS */
 		clearmems();
 	}

 	return EXIT_SUCCESS;
 }
	/*
	* A tiny 'top' utility.
	*
	* This is written specifically for the linux /proc/<PID>/stat(m)
	* files format.

	* This reads the PIDs of all processes and their status and shows
	* the status of processes (first ones that fit to screen) at given
	* intervals.
	*
	* NOTES:
	* - At startup this changes to /proc, all the reads are then
	* relative to that.
	*
	* (C) Eero Tamminen <oak at welho dot com>
	*
	* Rewroted by Vladimir Oleynik (C) 2002 <dzo@simtreas.ru>
	*/

	/* Original code Copyrights */
	/*
	* Copyright (c) 1992 Branko Lankester
	* Copyright (c) 1992 Roger Binns
	* Copyright (C) 1994-1996 Charles L. Blake.
	* Copyright (C) 1992-1998 Michael K. Johnson
	* May be distributed under the conditions of the
	* GNU Library General Public License
	*/

	#include <sys/types.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <unistd.h>
	#include <string.h>
	#include <sys/ioctl.h>
	/* get page info */
	#include <asm/page.h>
	#include "busybox.h"

	//#define FEATURE_CPU_USAGE_PERCENTAGE /* + 2k */

	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	#include <time.h>
	#include <sys/time.h>
	#include <fcntl.h>
	#include <netinet/in.h> /* htons */
	#endif


	typedef int (cmp_t)(procps_status_t P, procps_status_t *Q);

	static procps_status_t top; / Hehe */
	static int ntop;


	static int pid_sort (procps_status_t P, procps_status_t Q)
	{
	int p = P->pid;
	int q = Q->pid;

	if( p < q ) return -1;
	if( p > q ) return 1;
	return 0;
	}

	static int mem_sort (procps_status_t P, procps_status_t Q)
	{
	long p = P->rss;
	long q = Q->rss;

	if( p > q ) return -1;
	if( p < q ) return 1;
	return 0;
	}

	#ifdef FEATURE_CPU_USAGE_PERCENTAGE

	#define sort_depth 3
	static cmp_t sort_function[sort_depth];

	static int pcpu_sort (procps_status_t P, procps_status_t Q)
	{
	int p = P->pcpu;
	int q = Q->pcpu;

	if( p > q ) return -1;
	if( p < q ) return 1;
	return 0;
	}

	static int time_sort (procps_status_t P, procps_status_t Q)
	{
	long p = P->stime;
	long q = Q->stime;

	p += P->utime;
	q += Q->utime;
	if( p > q ) return -1;
	if( p < q ) return 1;
	return 0;
	}

	int mult_lvl_cmp(void* a, void* b) {
	int i, cmp_val;

	for(i = 0; i < sort_depth; i++) {
	cmp_val = (*sort_function[i])(a, b);
	if (cmp_val != 0)
	return cmp_val;
	}
	return 0;
	}

	/* This structure stores some critical information from one frame to
	the next. mostly used for sorting. Added cumulative and resident fields. */
	struct save_hist {
	int ticks;
	int pid;
	int utime;
	int stime;
	};

	/*
	* Calculates percent cpu usage for each task.
	*/

	static struct save_hist *save_history;

	static unsigned long Hertz;

	/***********************************************************************
	* Some values in /proc are expressed in units of 1/HZ seconds, where HZ
	* is the kernel clock tick rate. One of these units is called a jiffy.
	* The HZ value used in the kernel may vary according to hacker desire.
	* According to Linus Torvalds, this is not true. He considers the values
	* in /proc as being in architecture-dependant units that have no relation
	* to the kernel clock tick rate. Examination of the kernel source code
	* reveals that opinion as wishful thinking.
	*
	* In any case, we need the HZ constant as used in /proc. (the real HZ value
	* may differ, but we don't care) There are several ways we could get HZ:
	*
	* 1. Include the kernel header file. If it changes, recompile this library.
	* 2. Use the sysconf() function. When HZ changes, recompile the C library!
	* 3. Ask the kernel. This is obviously correct...
	*
	* Linus Torvalds won't let us ask the kernel, because he thinks we should
	* not know the HZ value. Oh well, we don't have to listen to him.
	* Someone smuggled out the HZ value. :-)
	*
	* This code should work fine, even if Linus fixes the kernel to match his
	* stated behavior. The code only fails in case of a partial conversion.
	*
	*/

	#define FILE_TO_BUF(filename, fd) do{ \
	if (fd == -1 && (fd = open(filename, O_RDONLY)) == -1) { \
	bb_perror_msg_and_die("/proc not be mounted?"); \
	} \
	lseek(fd, 0L, SEEK_SET); \
	if ((local_n = read(fd, buf, sizeof buf - 1)) < 0) { \
	bb_perror_msg_and_die("%s", filename); \
	} \
	buf[local_n] = '\0'; \
	}while(0)

	#define FILE_TO_BUF2(filename, fd) do{ \
	lseek(fd, 0L, SEEK_SET); \
	if ((local_n = read(fd, buf, sizeof buf - 1)) < 0) { \
	bb_perror_msg_and_die("%s", filename); \
	} \
	buf[local_n] = '\0'; \
	}while(0)

	static void init_Hertz_value(void) {
	unsigned long user_j, nice_j, sys_j, other_j; /* jiffies (clock ticks) */
	double up_1, up_2, seconds;
	unsigned long jiffies, h;
	char buf[80];
	int uptime_fd = -1;
	int stat_fd = -1;

	long smp_num_cpus = sysconf(_SC_NPROCESSORS_CONF);

	if(smp_num_cpus<1) smp_num_cpus=1;
	do {
	int local_n;

	FILE_TO_BUF("uptime", uptime_fd);
	up_1 = strtod(buf, 0);
	FILE_TO_BUF("stat", stat_fd);
	sscanf(buf, "cpu %lu %lu %lu %lu", &user_j, &nice_j, &sys_j, &other_j);
	FILE_TO_BUF2("uptime", uptime_fd);
	up_2 = strtod(buf, 0);
	} while((long)( (up_2-up_1)1000.0/up_1 )); / want under 0.1% error */

	close(uptime_fd);
	close(stat_fd);

	jiffies = user_j + nice_j + sys_j + other_j;
	seconds = (up_1 + up_2) / 2;
	h = (unsigned long)( (double)jiffies/seconds/smp_num_cpus );
	/* actual values used by 2.4 kernels: 32 64 100 128 1000 1024 1200 */
	switch(h){
	case 30 ... 34 : Hertz = 32; break; /* ia64 emulator */
	case 48 ... 52 : Hertz = 50; break;
	case 58 ... 62 : Hertz = 60; break;
	case 63 ... 65 : Hertz = 64; break; /* StrongARM /Shark */
	case 95 ... 105 : Hertz = 100; break; /* normal Linux */
	case 124 ... 132 : Hertz = 128; break; /* MIPS, ARM */
	case 195 ... 204 : Hertz = 200; break; /* normal << 1 */
	case 253 ... 260 : Hertz = 256; break;
	case 295 ... 304 : Hertz = 300; break; /* 3 cpus */
	case 393 ... 408 : Hertz = 400; break; /* normal << 2 */
	case 495 ... 504 : Hertz = 500; break; /* 5 cpus */
	case 595 ... 604 : Hertz = 600; break; /* 6 cpus */
	case 695 ... 704 : Hertz = 700; break; /* 7 cpus */
	case 790 ... 808 : Hertz = 800; break; /* normal << 3 */
	case 895 ... 904 : Hertz = 900; break; /* 9 cpus */
	case 990 ... 1010 : Hertz = 1000; break; /* ARM */
	case 1015 ... 1035 : Hertz = 1024; break; /* Alpha, ia64 */
	case 1095 ... 1104 : Hertz = 1100; break; /* 11 cpus */
	case 1180 ... 1220 : Hertz = 1200; break; /* Alpha */
	default:
	/* If 32-bit or big-endian (not Alpha or ia64), assume HZ is 100. */
	Hertz = (sizeof(long)==sizeof(int) \|\| htons(999)==999) ? 100UL : 1024UL;
	}
	}

	static void do_stats(void)
	{
	struct timeval t;
	static struct timeval oldtime;
	struct timezone timez;
	float elapsed_time;

	procps_status_t *cur;
	int total_time, i, n;
	static int prev_count;
	int systime, usrtime, pid;

	struct save_hist *New_save_hist;

	/*
	* Finds the current time (in microseconds) and calculates the time
	* elapsed since the last update.
	*/
	gettimeofday(&t, &timez);
	elapsed_time = (t.tv_sec - oldtime.tv_sec)
	+ (float) (t.tv_usec - oldtime.tv_usec) / 1000000.0;
	oldtime.tv_sec = t.tv_sec;
	oldtime.tv_usec = t.tv_usec;

	New_save_hist = alloca(sizeof(struct save_hist)*ntop);
	/*
	* Make a pass through the data to get stats.
	*/
	for(n = 0; n < ntop; n++) {
	cur = top + n;

	/*
	* Calculate time in cur process. Time is sum of user time
	* (usrtime) plus system time (systime).
	*/
	systime = cur->stime;
	usrtime = cur->utime;
	pid = cur->pid;
	total_time = systime + usrtime;
	New_save_hist[n].ticks = total_time;
	New_save_hist[n].pid = pid;
	New_save_hist[n].stime = systime;
	New_save_hist[n].utime = usrtime;

	/* find matching entry from previous pass */
	for (i = 0; i < prev_count; i++) {
	if (save_history[i].pid == pid) {
	total_time -= save_history[i].ticks;
	systime -= save_history[i].stime;
	usrtime -= save_history[i].utime;
	break;
	}
	}

	/*
	* Calculate percent cpu time for cur task.
	*/
	i = (total_time * 10 * 100/Hertz) / elapsed_time;
	if (i > 999)
	i = 999;
	cur->pcpu = i;

	}

	/*
	* Save cur frame's information.
	*/
	free(save_history);
	save_history = memcpy(xmalloc(sizeof(struct save_hist)*n), New_save_hist,
	sizeof(struct save_hist)*n);
	prev_count = n;
	qsort(top, n, sizeof(procps_status_t), (void*)mult_lvl_cmp);
	}
	#else
	static cmp_t sort_function;
	#endif /* FEATURE_CPU_USAGE_PERCENTAGE */

	/* display generic info (meminfo / loadavg) */
	static unsigned long display_generic(void)
	{
	FILE *fp;
	char buf[80];
	float avg1, avg2, avg3;
	unsigned long total, used, mfree, shared, buffers, cached;
	unsigned int needs_conversion = 1;

	/* read memory info */
	fp = bb_xfopen("meminfo", "r");

	/*
	* Old kernels (such as 2.4.x) had a nice summary of memory info that
	* we could parse, however this is gone entirely in 2.6. Try parsing
	* the old way first, and if that fails, parse each field manually.
	*
	* First, we read in the first line. Old kernels will have bogus
	* strings we don't care about, whereas new kernels will start right
	* out with MemTotal:
	* -- PFM.
	*/
	if (fscanf(fp, "MemTotal: %lu %s\n", &total, buf) != 2) {
	fgets(buf, sizeof(buf), fp); /* skip first line */

	fscanf(fp, "Mem: %lu %lu %lu %lu %lu %lu",
	&total, &used, &mfree, &shared, &buffers, &cached);
	} else {
	/*
	* Revert to manual parsing, which incidentally already has the
	* sizes in kilobytes. This should be safe for both 2.4 and
	* 2.6.
	*/
	needs_conversion = 0;

	fscanf(fp, "MemFree: %lu %s\n", &mfree, buf);

	/*
	* MemShared: is no longer present in 2.6. Report this as 0,
	* to maintain consistent behavior with normal procps.
	*/
	if (fscanf(fp, "MemShared: %lu %s\n", &shared, buf) != 2)
	shared = 0;

	fscanf(fp, "Buffers: %lu %s\n", &buffers, buf);
	fscanf(fp, "Cached: %lu %s\n", &cached, buf);

	used = total - mfree;
	}
	fclose(fp);

	/* read load average */
	fp = bb_xfopen("loadavg", "r");
	if (fscanf(fp, "%f %f %f", &avg1, &avg2, &avg3) != 3) {
	bb_error_msg_and_die("failed to read '%s'", "loadavg");
	}
	fclose(fp);

	if (needs_conversion) {
	/* convert to kilobytes */
	used /= 1024;
	mfree /= 1024;
	shared /= 1024;
	buffers /= 1024;
	cached /= 1024;
	total /= 1024;
	}

	/* output memory info and load average */
	/* clear screen & go to top */
	printf("\e[H\e[J" "Mem: "
	"%ldK used, %ldK free, %ldK shrd, %ldK buff, %ldK cached\n",
	used, mfree, shared, buffers, cached);
	printf("Load average: %.2f, %.2f, %.2f "
	"(State: S=sleeping R=running, W=waiting)\n",
	avg1, avg2, avg3);
	return total;
	}


	/* display process statuses */
	static void display_status(int count, int col)
	{
	procps_status_t *s = top;
	char rss_str_buf[8];
	unsigned long total_memory = display_generic();

	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	/* what info of the processes is shown */
	printf("\n\e[7m PID USER STATUS RSS PPID %%CPU %%MEM COMMAND\e[0m\n");
	#else
	printf("\n\e[7m PID USER STATUS RSS PPID %%MEM COMMAND\e[0m\n");
	#endif

	while (count--) {
	char *namecmd = s->short_cmd;
	int pmem;

	pmem = 1000.0 * s->rss / total_memory;
	if (pmem > 999) pmem = 999;

	if(s->rss > 10*1024)
	sprintf(rss_str_buf, "%6ldM", s->rss/1024);
	else
	sprintf(rss_str_buf, "%7ld", s->rss);
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	printf("%5d %-8s %s %s %5d %2d.%d %2u.%u ",
	s->pid, s->user, s->state, rss_str_buf, s->ppid,
	s->pcpu/10, s->pcpu%10, pmem/10, pmem%10);
	#else
	printf("%5d %-8s %s %s %5d %2u.%u ",
	s->pid, s->user, s->state, rss_str_buf, s->ppid,
	pmem/10, pmem%10);
	#endif
	if(strlen(namecmd) > col)
	namecmd[col] = 0;
	printf("%s\n", namecmd);
	s++;
	}
	}

	static void clearmems(void)
	{
	free(top);
	top = 0;
	ntop = 0;
	}

	#if defined CONFIG_FEATURE_USE_TERMIOS
	#include <termios.h>
	#include <sys/time.h>
	#include <signal.h>


	static struct termios initial_settings;

	static void reset_term(void)
	{
	tcsetattr(0, TCSANOW, (void *) &initial_settings);
	#ifdef CONFIG_FEATURE_CLEAN_UP
	clearmems();
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	free(save_history);
	#endif
	#endif /* CONFIG_FEATURE_CLEAN_UP */
	}

	static void sig_catcher (int sig)
	{
	reset_term();
	}
	#endif /* CONFIG_FEATURE_USE_TERMIOS */


	int top_main(int argc, char **argv)
	{
	int opt, interval, lines, col;
	#if defined CONFIG_FEATURE_USE_TERMIOS
	struct termios new_settings;
	struct timeval tv;
	fd_set readfds;
	unsigned char c;
	struct sigaction sa;
	#endif /* CONFIG_FEATURE_USE_TERMIOS */

	/* Default update rate is 5 seconds */
	interval = 5;

	/* do normal option parsing */
	while ((opt = getopt(argc, argv, "d:")) > 0) {
	switch (opt) {
	case 'd':
	interval = atoi(optarg);
	break;
	default:
	bb_show_usage();
	}
	}

	/* Default to 25 lines - 5 lines for status */
	lines = 25 - 5;
	/* Default CMD format size */
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	col = 35 - 6;
	#else
	col = 35;
	#endif
	/* change to /proc */
	if (chdir("/proc") < 0) {
	bb_perror_msg_and_die("chdir('/proc')");
	}
	#if defined CONFIG_FEATURE_USE_TERMIOS
	tcgetattr(0, (void *) &initial_settings);
	memcpy(&new_settings, &initial_settings, sizeof(struct termios));
	new_settings.c_lflag &= ~(ISIG \| ICANON); /* unbuffered input */
	/* Turn off echoing */
	new_settings.c_lflag &= ~(ECHO \| ECHONL);

	signal (SIGTERM, sig_catcher);
	sigaction (SIGTERM, (struct sigaction *) 0, &sa);
	sa.sa_flags \|= SA_RESTART;
	sa.sa_flags &= ~SA_INTERRUPT;
	sigaction (SIGTERM, &sa, (struct sigaction *) 0);
	sigaction (SIGINT, &sa, (struct sigaction *) 0);
	tcsetattr(0, TCSANOW, (void *) &new_settings);
	atexit(reset_term);

	get_terminal_width_height(0, &col, &lines);
	if (lines > 4) {
	lines -= 5;
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	col = col - 80 + 35 - 6;
	#else
	col = col - 80 + 35;
	#endif
	}
	#endif /* CONFIG_FEATURE_USE_TERMIOS */
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	sort_function[0] = pcpu_sort;
	sort_function[1] = mem_sort;
	sort_function[2] = time_sort;
	#else
	sort_function = mem_sort;
	#endif
	while (1) {
	/* read process IDs & status for all the processes */
	procps_status_t * p;

	#ifdef CONFIG_SELINUX
	while ((p = procps_scan(0, 0, NULL) ) != 0) {
	#else
	while ((p = procps_scan(0)) != 0) {
	#endif
	int n = ntop;

	top = xrealloc(top, (++ntop)*sizeof(procps_status_t));
	memcpy(top + n, p, sizeof(procps_status_t));
	}
	if (ntop == 0) {
	bb_perror_msg_and_die("scandir('/proc')");
	}
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	if(!Hertz) {
	init_Hertz_value();
	do_stats();
	sleep(1);
	clearmems();
	continue;
	}
	do_stats();
	#else
	qsort(top, ntop, sizeof(procps_status_t), (void*)sort_function);
	#endif
	opt = lines;
	if (opt > ntop) {
	opt = ntop;
	}
	/* show status for each of the processes */
	display_status(opt, col);
	#if defined CONFIG_FEATURE_USE_TERMIOS
	tv.tv_sec = interval;
	tv.tv_usec = 0;
	FD_ZERO (&readfds);
	FD_SET (0, &readfds);
	select (1, &readfds, NULL, NULL, &tv);
	if (FD_ISSET (0, &readfds)) {
	if (read (0, &c, 1) <= 0) { /* signal */
	return EXIT_FAILURE;
	}
	if(c == 'q' \|\| c == initial_settings.c_cc[VINTR])
	return EXIT_SUCCESS;
	if(c == 'M') {
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	sort_function[0] = mem_sort;
	sort_function[1] = pcpu_sort;
	sort_function[2] = time_sort;
	#else
	sort_function = mem_sort;
	#endif
	}
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	if(c == 'P') {
	sort_function[0] = pcpu_sort;
	sort_function[1] = mem_sort;
	sort_function[2] = time_sort;
	}
	if(c == 'T') {
	sort_function[0] = time_sort;
	sort_function[1] = mem_sort;
	sort_function[2] = pcpu_sort;
	}
	#endif
	if(c == 'N') {
	#ifdef FEATURE_CPU_USAGE_PERCENTAGE
	sort_function[0] = pid_sort;
	#else
	sort_function = pid_sort;
	#endif
	}
	}
	#else
	sleep(interval);
	#endif /* CONFIG_FEATURE_USE_TERMIOS */
	clearmems();
	}

	return EXIT_SUCCESS;
	}