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freebsd/contrib/top/display.c
John Baldwin 2e52fb92ff Add a new line to top that provides a brief summary of the ZFS ARC memory
usage on hosts using ZFS.  The new line displays the total amount of RAM
used by the ARC along with the size of MFU, MRU, anonymous (in flight),
headers, and other (miscellaneous) sub-categories.  The line is not
displayed on systems that are not using ZFS.

Reviewed by:	avg, fs@
MFC after:	3 days
2012-06-27 18:08:48 +00:00

1372 lines
27 KiB
C

/*
* Top users/processes display for Unix
* Version 3
*
* This program may be freely redistributed,
* but this entire comment MUST remain intact.
*
* Copyright (c) 1984, 1989, William LeFebvre, Rice University
* Copyright (c) 1989, 1990, 1992, William LeFebvre, Northwestern University
*
* $FreeBSD$
*/
/*
* This file contains the routines that display information on the screen.
* Each section of the screen has two routines: one for initially writing
* all constant and dynamic text, and one for only updating the text that
* changes. The prefix "i_" is used on all the "initial" routines and the
* prefix "u_" is used for all the "updating" routines.
*
* ASSUMPTIONS:
* None of the "i_" routines use any of the termcap capabilities.
* In this way, those routines can be safely used on terminals that
* have minimal (or nonexistant) terminal capabilities.
*
* The routines are called in this order: *_loadave, i_timeofday,
* *_procstates, *_cpustates, *_memory, *_message, *_header,
* *_process, u_endscreen.
*/
#include "os.h"
#include <ctype.h>
#include <time.h>
#include <sys/time.h>
#include "screen.h" /* interface to screen package */
#include "layout.h" /* defines for screen position layout */
#include "display.h"
#include "top.h"
#include "top.local.h"
#include "boolean.h"
#include "machine.h" /* we should eliminate this!!! */
#include "utils.h"
#ifdef DEBUG
FILE *debug;
#endif
/* imported from screen.c */
extern int overstrike;
static int lmpid = 0;
static int last_hi = 0; /* used in u_process and u_endscreen */
static int lastline = 0;
static int display_width = MAX_COLS;
#define lineindex(l) ((l)*display_width)
char *printable();
/* things initialized by display_init and used thruout */
/* buffer of proc information lines for display updating */
char *screenbuf = NULL;
static char **procstate_names;
static char **cpustate_names;
static char **memory_names;
static char **arc_names;
static char **swap_names;
static int num_procstates;
static int num_cpustates;
static int num_memory;
static int num_swap;
static int *lprocstates;
static int *lcpustates;
static int *lmemory;
static int *lswap;
static int num_cpus;
static int *cpustate_columns;
static int cpustate_total_length;
static int cpustates_column;
static enum { OFF, ON, ERASE } header_status = ON;
static int string_count();
static void summary_format();
static void line_update();
int x_lastpid = 10;
int y_lastpid = 0;
int x_loadave = 33;
int x_loadave_nompid = 15;
int y_loadave = 0;
int x_procstate = 0;
int y_procstate = 1;
int x_brkdn = 15;
int y_brkdn = 1;
int x_mem = 5;
int y_mem = 3;
int x_arc = 5;
int y_arc = 4;
int x_swap = 6;
int y_swap = 4;
int y_message = 5;
int x_header = 0;
int y_header = 6;
int x_idlecursor = 0;
int y_idlecursor = 5;
int y_procs = 7;
int y_cpustates = 2;
int Header_lines = 7;
int display_resize()
{
register int lines;
/* first, deallocate any previous buffer that may have been there */
if (screenbuf != NULL)
{
free(screenbuf);
}
/* calculate the current dimensions */
/* if operating in "dumb" mode, we only need one line */
lines = smart_terminal ? screen_length - Header_lines : 1;
if (lines < 0)
lines = 0;
/* we don't want more than MAX_COLS columns, since the machine-dependent
modules make static allocations based on MAX_COLS and we don't want
to run off the end of their buffers */
display_width = screen_width;
if (display_width >= MAX_COLS)
{
display_width = MAX_COLS - 1;
}
/* now, allocate space for the screen buffer */
screenbuf = (char *)malloc(lines * display_width);
if (screenbuf == (char *)NULL)
{
/* oops! */
return(-1);
}
/* return number of lines available */
/* for dumb terminals, pretend like we can show any amount */
return(smart_terminal ? lines : Largest);
}
int display_updatecpus(statics)
struct statics *statics;
{
register int *lp;
register int lines;
register int i;
/* call resize to do the dirty work */
lines = display_resize();
if (pcpu_stats)
num_cpus = statics->ncpus;
else
num_cpus = 1;
cpustates_column = 5; /* CPU: */
if (num_cpus != 1)
cpustates_column += 2; /* CPU 0: */
for (i = num_cpus; i > 9; i /= 10)
cpustates_column++;
/* fill the "last" array with all -1s, to insure correct updating */
lp = lcpustates;
i = num_cpustates * num_cpus;
while (--i >= 0)
{
*lp++ = -1;
}
return(lines);
}
int display_init(statics)
struct statics *statics;
{
register int lines;
register char **pp;
register int *ip;
register int i;
lines = display_updatecpus(statics);
/* only do the rest if we need to */
if (lines > -1)
{
/* save pointers and allocate space for names */
procstate_names = statics->procstate_names;
num_procstates = string_count(procstate_names);
lprocstates = (int *)malloc(num_procstates * sizeof(int));
cpustate_names = statics->cpustate_names;
swap_names = statics->swap_names;
num_swap = string_count(swap_names);
lswap = (int *)malloc(num_swap * sizeof(int));
num_cpustates = string_count(cpustate_names);
lcpustates = (int *)malloc(num_cpustates * sizeof(int) * statics->ncpus);
cpustate_columns = (int *)malloc(num_cpustates * sizeof(int));
memory_names = statics->memory_names;
num_memory = string_count(memory_names);
lmemory = (int *)malloc(num_memory * sizeof(int));
arc_names = statics->arc_names;
/* calculate starting columns where needed */
cpustate_total_length = 0;
pp = cpustate_names;
ip = cpustate_columns;
while (*pp != NULL)
{
*ip++ = cpustate_total_length;
if ((i = strlen(*pp++)) > 0)
{
cpustate_total_length += i + 8;
}
}
}
/* return number of lines available */
return(lines);
}
i_loadave(mpid, avenrun)
int mpid;
double *avenrun;
{
register int i;
/* i_loadave also clears the screen, since it is first */
clear();
/* mpid == -1 implies this system doesn't have an _mpid */
if (mpid != -1)
{
printf("last pid: %5d; ", mpid);
}
printf("load averages");
for (i = 0; i < 3; i++)
{
printf("%c %5.2f",
i == 0 ? ':' : ',',
avenrun[i]);
}
lmpid = mpid;
}
u_loadave(mpid, avenrun)
int mpid;
double *avenrun;
{
register int i;
if (mpid != -1)
{
/* change screen only when value has really changed */
if (mpid != lmpid)
{
Move_to(x_lastpid, y_lastpid);
printf("%5d", mpid);
lmpid = mpid;
}
/* i remembers x coordinate to move to */
i = x_loadave;
}
else
{
i = x_loadave_nompid;
}
/* move into position for load averages */
Move_to(i, y_loadave);
/* display new load averages */
/* we should optimize this and only display changes */
for (i = 0; i < 3; i++)
{
printf("%s%5.2f",
i == 0 ? "" : ", ",
avenrun[i]);
}
}
i_timeofday(tod)
time_t *tod;
{
/*
* Display the current time.
* "ctime" always returns a string that looks like this:
*
* Sun Sep 16 01:03:52 1973
* 012345678901234567890123
* 1 2
*
* We want indices 11 thru 18 (length 8).
*/
if (smart_terminal)
{
Move_to(screen_width - 8, 0);
}
else
{
fputs(" ", stdout);
}
#ifdef DEBUG
{
char *foo;
foo = ctime(tod);
fputs(foo, stdout);
}
#endif
printf("%-8.8s\n", &(ctime(tod)[11]));
lastline = 1;
}
static int ltotal = 0;
static char procstates_buffer[MAX_COLS];
/*
* *_procstates(total, brkdn, names) - print the process summary line
*
* Assumptions: cursor is at the beginning of the line on entry
* lastline is valid
*/
i_procstates(total, brkdn)
int total;
int *brkdn;
{
register int i;
/* write current number of processes and remember the value */
printf("%d processes:", total);
ltotal = total;
/* put out enough spaces to get to column 15 */
i = digits(total);
while (i++ < 4)
{
putchar(' ');
}
/* format and print the process state summary */
summary_format(procstates_buffer, brkdn, procstate_names);
fputs(procstates_buffer, stdout);
/* save the numbers for next time */
memcpy(lprocstates, brkdn, num_procstates * sizeof(int));
}
u_procstates(total, brkdn)
int total;
int *brkdn;
{
static char new[MAX_COLS];
register int i;
/* update number of processes only if it has changed */
if (ltotal != total)
{
/* move and overwrite */
#if (x_procstate == 0)
Move_to(x_procstate, y_procstate);
#else
/* cursor is already there...no motion needed */
/* assert(lastline == 1); */
#endif
printf("%d", total);
/* if number of digits differs, rewrite the label */
if (digits(total) != digits(ltotal))
{
fputs(" processes:", stdout);
/* put out enough spaces to get to column 15 */
i = digits(total);
while (i++ < 4)
{
putchar(' ');
}
/* cursor may end up right where we want it!!! */
}
/* save new total */
ltotal = total;
}
/* see if any of the state numbers has changed */
if (memcmp(lprocstates, brkdn, num_procstates * sizeof(int)) != 0)
{
/* format and update the line */
summary_format(new, brkdn, procstate_names);
line_update(procstates_buffer, new, x_brkdn, y_brkdn);
memcpy(lprocstates, brkdn, num_procstates * sizeof(int));
}
}
#ifdef no_more
/*
* *_cpustates(states, names) - print the cpu state percentages
*
* Assumptions: cursor is on the PREVIOUS line
*/
/* cpustates_tag() calculates the correct tag to use to label the line */
char *cpustates_tag()
{
register char *use;
static char *short_tag = "CPU: ";
static char *long_tag = "CPU states: ";
/* if length + strlen(long_tag) >= screen_width, then we have to
use the shorter tag (we subtract 2 to account for ": ") */
if (cpustate_total_length + (int)strlen(long_tag) - 2 >= screen_width)
{
use = short_tag;
}
else
{
use = long_tag;
}
/* set cpustates_column accordingly then return result */
cpustates_column = strlen(use);
return(use);
}
#endif
i_cpustates(states)
register int *states;
{
register int i = 0;
register int value;
register char **names;
register char *thisname;
int cpu;
for (cpu = 0; cpu < num_cpus; cpu++) {
names = cpustate_names;
/* print tag and bump lastline */
if (num_cpus == 1)
printf("\nCPU: ");
else {
value = printf("\nCPU %d: ", cpu);
while (value++ <= cpustates_column)
printf(" ");
}
lastline++;
/* now walk thru the names and print the line */
while ((thisname = *names++) != NULL)
{
if (*thisname != '\0')
{
/* retrieve the value and remember it */
value = *states++;
/* if percentage is >= 1000, print it as 100% */
printf((value >= 1000 ? "%s%4.0f%% %s" : "%s%4.1f%% %s"),
(i++ % num_cpustates) == 0 ? "" : ", ",
((float)value)/10.,
thisname);
}
}
}
/* copy over values into "last" array */
memcpy(lcpustates, states, num_cpustates * sizeof(int) * num_cpus);
}
u_cpustates(states)
register int *states;
{
register int value;
register char **names;
register char *thisname;
register int *lp;
register int *colp;
int cpu;
for (cpu = 0; cpu < num_cpus; cpu++) {
names = cpustate_names;
Move_to(cpustates_column, y_cpustates + cpu);
lastline = y_cpustates + cpu;
lp = lcpustates + (cpu * num_cpustates);
colp = cpustate_columns;
/* we could be much more optimal about this */
while ((thisname = *names++) != NULL)
{
if (*thisname != '\0')
{
/* did the value change since last time? */
if (*lp != *states)
{
/* yes, move and change */
Move_to(cpustates_column + *colp, y_cpustates + cpu);
lastline = y_cpustates + cpu;
/* retrieve value and remember it */
value = *states;
/* if percentage is >= 1000, print it as 100% */
printf((value >= 1000 ? "%4.0f" : "%4.1f"),
((double)value)/10.);
/* remember it for next time */
*lp = value;
}
}
/* increment and move on */
lp++;
states++;
colp++;
}
}
}
z_cpustates()
{
register int i = 0;
register char **names;
register char *thisname;
register int *lp;
int cpu, value;
for (cpu = 0; cpu < num_cpus; cpu++) {
names = cpustate_names;
/* show tag and bump lastline */
if (num_cpus == 1)
printf("\nCPU: ");
else {
value = printf("\nCPU %d: ", cpu);
while (value++ <= cpustates_column)
printf(" ");
}
lastline++;
while ((thisname = *names++) != NULL)
{
if (*thisname != '\0')
{
printf("%s %% %s", (i++ % num_cpustates) == 0 ? "" : ", ", thisname);
}
}
}
/* fill the "last" array with all -1s, to insure correct updating */
lp = lcpustates;
i = num_cpustates * num_cpus;
while (--i >= 0)
{
*lp++ = -1;
}
}
/*
* *_memory(stats) - print "Memory: " followed by the memory summary string
*
* Assumptions: cursor is on "lastline"
* for i_memory ONLY: cursor is on the previous line
*/
char memory_buffer[MAX_COLS];
i_memory(stats)
int *stats;
{
fputs("\nMem: ", stdout);
lastline++;
/* format and print the memory summary */
summary_format(memory_buffer, stats, memory_names);
fputs(memory_buffer, stdout);
}
u_memory(stats)
int *stats;
{
static char new[MAX_COLS];
/* format the new line */
summary_format(new, stats, memory_names);
line_update(memory_buffer, new, x_mem, y_mem);
}
/*
* *_arc(stats) - print "ARC: " followed by the ARC summary string
*
* Assumptions: cursor is on "lastline"
* for i_arc ONLY: cursor is on the previous line
*/
char arc_buffer[MAX_COLS];
i_arc(stats)
int *stats;
{
if (arc_names == NULL)
return (0);
fputs("\nARC: ", stdout);
lastline++;
/* format and print the memory summary */
summary_format(arc_buffer, stats, arc_names);
fputs(arc_buffer, stdout);
}
u_arc(stats)
int *stats;
{
static char new[MAX_COLS];
if (arc_names == NULL)
return (0);
/* format the new line */
summary_format(new, stats, arc_names);
line_update(arc_buffer, new, x_arc, y_arc);
}
/*
* *_swap(stats) - print "Swap: " followed by the swap summary string
*
* Assumptions: cursor is on "lastline"
* for i_swap ONLY: cursor is on the previous line
*/
char swap_buffer[MAX_COLS];
i_swap(stats)
int *stats;
{
fputs("\nSwap: ", stdout);
lastline++;
/* format and print the swap summary */
summary_format(swap_buffer, stats, swap_names);
fputs(swap_buffer, stdout);
}
u_swap(stats)
int *stats;
{
static char new[MAX_COLS];
/* format the new line */
summary_format(new, stats, swap_names);
line_update(swap_buffer, new, x_swap, y_swap);
}
/*
* *_message() - print the next pending message line, or erase the one
* that is there.
*
* Note that u_message is (currently) the same as i_message.
*
* Assumptions: lastline is consistent
*/
/*
* i_message is funny because it gets its message asynchronously (with
* respect to screen updates).
*/
static char next_msg[MAX_COLS + 5];
static int msglen = 0;
/* Invariant: msglen is always the length of the message currently displayed
on the screen (even when next_msg doesn't contain that message). */
i_message()
{
while (lastline < y_message)
{
fputc('\n', stdout);
lastline++;
}
if (next_msg[0] != '\0')
{
standout(next_msg);
msglen = strlen(next_msg);
next_msg[0] = '\0';
}
else if (msglen > 0)
{
(void) clear_eol(msglen);
msglen = 0;
}
}
u_message()
{
i_message();
}
static int header_length;
/*
* Trim a header string to the current display width and return a newly
* allocated area with the trimmed header.
*/
char *
trim_header(text)
char *text;
{
char *s;
int width;
s = NULL;
width = display_width;
header_length = strlen(text);
if (header_length >= width) {
s = malloc((width + 1) * sizeof(char));
if (s == NULL)
return (NULL);
strncpy(s, text, width);
s[width] = '\0';
}
return (s);
}
/*
* *_header(text) - print the header for the process area
*
* Assumptions: cursor is on the previous line and lastline is consistent
*/
i_header(text)
char *text;
{
char *s;
s = trim_header(text);
if (s != NULL)
text = s;
if (header_status == ON)
{
putchar('\n');
fputs(text, stdout);
lastline++;
}
else if (header_status == ERASE)
{
header_status = OFF;
}
free(s);
}
/*ARGSUSED*/
u_header(text)
char *text; /* ignored */
{
if (header_status == ERASE)
{
putchar('\n');
lastline++;
clear_eol(header_length);
header_status = OFF;
}
}
/*
* *_process(line, thisline) - print one process line
*
* Assumptions: lastline is consistent
*/
i_process(line, thisline)
int line;
char *thisline;
{
register char *p;
register char *base;
/* make sure we are on the correct line */
while (lastline < y_procs + line)
{
putchar('\n');
lastline++;
}
/* truncate the line to conform to our current screen width */
thisline[display_width] = '\0';
/* write the line out */
fputs(thisline, stdout);
/* copy it in to our buffer */
base = smart_terminal ? screenbuf + lineindex(line) : screenbuf;
p = strecpy(base, thisline);
/* zero fill the rest of it */
memzero(p, display_width - (p - base));
}
u_process(line, newline)
int line;
char *newline;
{
register char *optr;
register int screen_line = line + Header_lines;
register char *bufferline;
/* remember a pointer to the current line in the screen buffer */
bufferline = &screenbuf[lineindex(line)];
/* truncate the line to conform to our current screen width */
newline[display_width] = '\0';
/* is line higher than we went on the last display? */
if (line >= last_hi)
{
/* yes, just ignore screenbuf and write it out directly */
/* get positioned on the correct line */
if (screen_line - lastline == 1)
{
putchar('\n');
lastline++;
}
else
{
Move_to(0, screen_line);
lastline = screen_line;
}
/* now write the line */
fputs(newline, stdout);
/* copy it in to the buffer */
optr = strecpy(bufferline, newline);
/* zero fill the rest of it */
memzero(optr, display_width - (optr - bufferline));
}
else
{
line_update(bufferline, newline, 0, line + Header_lines);
}
}
u_endscreen(hi)
register int hi;
{
register int screen_line = hi + Header_lines;
register int i;
if (smart_terminal)
{
if (hi < last_hi)
{
/* need to blank the remainder of the screen */
/* but only if there is any screen left below this line */
if (lastline + 1 < screen_length)
{
/* efficiently move to the end of currently displayed info */
if (screen_line - lastline < 5)
{
while (lastline < screen_line)
{
putchar('\n');
lastline++;
}
}
else
{
Move_to(0, screen_line);
lastline = screen_line;
}
if (clear_to_end)
{
/* we can do this the easy way */
putcap(clear_to_end);
}
else
{
/* use clear_eol on each line */
i = hi;
while ((void) clear_eol(strlen(&screenbuf[lineindex(i++)])), i < last_hi)
{
putchar('\n');
}
}
}
}
last_hi = hi;
/* move the cursor to a pleasant place */
Move_to(x_idlecursor, y_idlecursor);
lastline = y_idlecursor;
}
else
{
/* separate this display from the next with some vertical room */
fputs("\n\n", stdout);
}
}
display_header(t)
int t;
{
if (t)
{
header_status = ON;
}
else if (header_status == ON)
{
header_status = ERASE;
}
}
/*VARARGS2*/
new_message(type, msgfmt, a1, a2, a3)
int type;
char *msgfmt;
caddr_t a1, a2, a3;
{
register int i;
/* first, format the message */
(void) snprintf(next_msg, sizeof(next_msg), msgfmt, a1, a2, a3);
if (msglen > 0)
{
/* message there already -- can we clear it? */
if (!overstrike)
{
/* yes -- write it and clear to end */
i = strlen(next_msg);
if ((type & MT_delayed) == 0)
{
type & MT_standout ? standout(next_msg) :
fputs(next_msg, stdout);
(void) clear_eol(msglen - i);
msglen = i;
next_msg[0] = '\0';
}
}
}
else
{
if ((type & MT_delayed) == 0)
{
type & MT_standout ? standout(next_msg) : fputs(next_msg, stdout);
msglen = strlen(next_msg);
next_msg[0] = '\0';
}
}
}
clear_message()
{
if (clear_eol(msglen) == 1)
{
putchar('\r');
}
}
readline(buffer, size, numeric)
char *buffer;
int size;
int numeric;
{
register char *ptr = buffer;
register char ch;
register char cnt = 0;
register char maxcnt = 0;
/* allow room for null terminator */
size -= 1;
/* read loop */
while ((fflush(stdout), read(0, ptr, 1) > 0))
{
/* newline means we are done */
if ((ch = *ptr) == '\n' || ch == '\r')
{
break;
}
/* handle special editing characters */
if (ch == ch_kill)
{
/* kill line -- account for overstriking */
if (overstrike)
{
msglen += maxcnt;
}
/* return null string */
*buffer = '\0';
putchar('\r');
return(-1);
}
else if (ch == ch_erase)
{
/* erase previous character */
if (cnt <= 0)
{
/* none to erase! */
putchar('\7');
}
else
{
fputs("\b \b", stdout);
ptr--;
cnt--;
}
}
/* check for character validity and buffer overflow */
else if (cnt == size || (numeric && !isdigit(ch)) ||
!isprint(ch))
{
/* not legal */
putchar('\7');
}
else
{
/* echo it and store it in the buffer */
putchar(ch);
ptr++;
cnt++;
if (cnt > maxcnt)
{
maxcnt = cnt;
}
}
}
/* all done -- null terminate the string */
*ptr = '\0';
/* account for the extra characters in the message area */
/* (if terminal overstrikes, remember the furthest they went) */
msglen += overstrike ? maxcnt : cnt;
/* return either inputted number or string length */
putchar('\r');
return(cnt == 0 ? -1 : numeric ? atoi(buffer) : cnt);
}
/* internal support routines */
static int string_count(pp)
register char **pp;
{
register int cnt;
cnt = 0;
while (*pp++ != NULL)
{
cnt++;
}
return(cnt);
}
static void summary_format(str, numbers, names)
char *str;
int *numbers;
register char **names;
{
register char *p;
register int num;
register char *thisname;
register int useM = No;
/* format each number followed by its string */
p = str;
while ((thisname = *names++) != NULL)
{
/* get the number to format */
num = *numbers++;
/* display only non-zero numbers */
if (num > 0)
{
/* is this number in kilobytes? */
if (thisname[0] == 'K')
{
/* yes: format it as a memory value */
p = strecpy(p, format_k(num));
/* skip over the K, since it was included by format_k */
p = strecpy(p, thisname+1);
}
else
{
p = strecpy(p, itoa(num));
p = strecpy(p, thisname);
}
}
/* ignore negative numbers, but display corresponding string */
else if (num < 0)
{
p = strecpy(p, thisname);
}
}
/* if the last two characters in the string are ", ", delete them */
p -= 2;
if (p >= str && p[0] == ',' && p[1] == ' ')
{
*p = '\0';
}
}
static void line_update(old, new, start, line)
register char *old;
register char *new;
int start;
int line;
{
register int ch;
register int diff;
register int newcol = start + 1;
register int lastcol = start;
char cursor_on_line = No;
char *current;
/* compare the two strings and only rewrite what has changed */
current = old;
#ifdef DEBUG
fprintf(debug, "line_update, starting at %d\n", start);
fputs(old, debug);
fputc('\n', debug);
fputs(new, debug);
fputs("\n-\n", debug);
#endif
/* start things off on the right foot */
/* this is to make sure the invariants get set up right */
if ((ch = *new++) != *old)
{
if (line - lastline == 1 && start == 0)
{
putchar('\n');
}
else
{
Move_to(start, line);
}
cursor_on_line = Yes;
putchar(ch);
*old = ch;
lastcol = 1;
}
old++;
/*
* main loop -- check each character. If the old and new aren't the
* same, then update the display. When the distance from the
* current cursor position to the new change is small enough,
* the characters that belong there are written to move the
* cursor over.
*
* Invariants:
* lastcol is the column where the cursor currently is sitting
* (always one beyond the end of the last mismatch).
*/
do /* yes, a do...while */
{
if ((ch = *new++) != *old)
{
/* new character is different from old */
/* make sure the cursor is on top of this character */
diff = newcol - lastcol;
if (diff > 0)
{
/* some motion is required--figure out which is shorter */
if (diff < 6 && cursor_on_line)
{
/* overwrite old stuff--get it out of the old buffer */
printf("%.*s", diff, &current[lastcol-start]);
}
else
{
/* use cursor addressing */
Move_to(newcol, line);
cursor_on_line = Yes;
}
/* remember where the cursor is */
lastcol = newcol + 1;
}
else
{
/* already there, update position */
lastcol++;
}
/* write what we need to */
if (ch == '\0')
{
/* at the end--terminate with a clear-to-end-of-line */
(void) clear_eol(strlen(old));
}
else
{
/* write the new character */
putchar(ch);
}
/* put the new character in the screen buffer */
*old = ch;
}
/* update working column and screen buffer pointer */
newcol++;
old++;
} while (ch != '\0');
/* zero out the rest of the line buffer -- MUST BE DONE! */
diff = display_width - newcol;
if (diff > 0)
{
memzero(old, diff);
}
/* remember where the current line is */
if (cursor_on_line)
{
lastline = line;
}
}
/*
* printable(str) - make the string pointed to by "str" into one that is
* printable (i.e.: all ascii), by converting all non-printable
* characters into '?'. Replacements are done in place and a pointer
* to the original buffer is returned.
*/
char *printable(str)
char *str;
{
register char *ptr;
register char ch;
ptr = str;
while ((ch = *ptr) != '\0')
{
if (!isprint(ch))
{
*ptr = '?';
}
ptr++;
}
return(str);
}
i_uptime(bt, tod)
struct timeval* bt;
time_t *tod;
{
time_t uptime;
int days, hrs, mins, secs;
if (bt->tv_sec != -1) {
uptime = *tod - bt->tv_sec;
days = uptime / 86400;
uptime %= 86400;
hrs = uptime / 3600;
uptime %= 3600;
mins = uptime / 60;
secs = uptime % 60;
/*
* Display the uptime.
*/
if (smart_terminal)
{
Move_to((screen_width - 24) - (days > 9 ? 1 : 0), 0);
}
else
{
fputs(" ", stdout);
}
printf(" up %d+%02d:%02d:%02d", days, hrs, mins, secs);
}
}