/*
 *	T T C P . C
 *
 * Test TCP connection.  Makes a connection on port 2000
 * and transfers zero buffers or data copied from stdin.
 *
 * Usable on 4.2, 4.3, and 4.1a systems by defining one of
 * BSD42 BSD43 (BSD41a)
 *
 * Modified for operation under 4.2BSD, 18 Dec 84
 *      T.C. Slattery, USNA
 * Minor improvements, Mike Muuss and Terry Slattery, 16-Oct-85.
 */
#ifndef lint
static char RCSid[] = "@(#)$Header: ttcp.c,v 1.10 87/09/02 23:26:36 mike Exp $ (BRL)";
#endif

#define BSD43
/* #define BSD42 */
/* #define BSD41a */

#include <stdio.h>
#include <ctype.h>
#include <errno.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <netdb.h>
#include <sys/time.h>		/* struct timeval */

#ifdef SYSV
#include <sys/times.h>
#include <sys/param.h>
#else
#include <sys/resource.h>
#endif

struct sockaddr_in sinme;
struct sockaddr_in sinhim;
struct sockaddr_in sindum;
struct sockaddr_in frominet;

int domain, fromlen;
int fd;				/* fd of network socket */

int buflen = 1024;		/* length of buffer */
char *buf;			/* ptr to dynamic buffer */
int nbuf = 1024;		/* number of buffers to send in sinkmode */

int udp = 0;			/* 0 = tcp, !0 = udp */
int options = 0;		/* socket options */
int one = 1;                    /* for 4.3 BSD style setsockopt() */
short port = 2000;		/* TCP port number */
char *host;			/* ptr to name of host */
int trans;			/* 0=receive, !0=transmit mode */
int sinkmode;			/* 0=normal I/O, !0=sink/source mode */

struct hostent *addr;
extern int errno;

char Usage[] = "\
Usage: ttcp -t [-options] host <in\n\
	-l##	length of bufs written to network (default 1024)\n\
	-s	source a pattern to network\n\
	-n##	number of bufs written to network (-s only, default 1024)\n\
	-p##	port number to send to (default 2000)\n\
	-u	use UDP instead of TCP\n\
Usage: ttcp -r [-options] >out\n\
	-l##	length of network read buf (default 1024)\n\
	-s	sink (discard) all data from network\n\
	-p##	port number to listen at (default 2000)\n\
	-B	Only output full blocks, as specified in -l## (for TAR)\n\
	-u	use UDP instead of TCP\n\
";	

char stats[128];
double t;			/* transmission time */
long nbytes;			/* bytes on net */
int b_flag = 0;			/* use mread() */

void prep_timer();
double read_timer();
double cput, realt;		/* user, real time (seconds) */

main(argc,argv)
int argc;
char **argv;
{
	unsigned long addr_tmp;

	if (argc < 2) goto usage;

	argv++; argc--;
	while( argc>0 && argv[0][0] == '-' )  {
		switch (argv[0][1]) {

		case 'B':
			b_flag = 1;
			break;
		case 't':
			trans = 1;
			break;
		case 'r':
			trans = 0;
			break;
		case 'd':
			options |= SO_DEBUG;
			break;
		case 'n':
			nbuf = atoi(&argv[0][2]);
			break;
		case 'l':
			buflen = atoi(&argv[0][2]);
			break;
		case 's':
			sinkmode = 1;	/* source or sink, really */
			break;
		case 'p':
			port = atoi(&argv[0][2]);
			break;
		case 'u':
			udp = 1;
			break;
		default:
			goto usage;
		}
		argv++; argc--;
	}
	if(trans)  {
		/* xmitr */
		if (argc != 1) goto usage;
		bzero((char *)&sinhim, sizeof(sinhim));
		host = argv[0];
		if (atoi(host) > 0 )  {
			/* Numeric */
			sinhim.sin_family = AF_INET;
#ifdef cray
			addr_tmp = inet_addr(host);
			sinhim.sin_addr = addr_tmp;
#else
			sinhim.sin_addr.s_addr = inet_addr(host);
#endif
		} else {
			if ((addr=gethostbyname(host)) == NULL)
				err("bad hostname");
			sinhim.sin_family = addr->h_addrtype;
			bcopy(addr->h_addr,(char*)&addr_tmp, addr->h_length);
#ifdef cray
			sinhim.sin_addr = addr_tmp;
#else
			sinhim.sin_addr.s_addr = addr_tmp;
#endif cray
		}
		sinhim.sin_port = htons(port);
		sinme.sin_port = 0;		/* free choice */
	} else {
		/* rcvr */
		sinme.sin_port =  htons(port);
	}

	if( (buf = (char *)malloc(buflen)) == (char *)NULL)
		err("malloc");
	fprintf(stderr,"ttcp%s: nbuf=%d, buflen=%d, port=%d\n",
		trans?"-t":"-r",
		nbuf, buflen, port);

	if ((fd = socket(AF_INET, udp?SOCK_DGRAM:SOCK_STREAM, 0)) < 0)
		err("socket");
	mes("socket");

	if (bind(fd, &sinme, sizeof(sinme)) < 0)
		err("bind");

	if (!udp)  {
	    if (trans) {
		/* We are the client if transmitting */
		if(options)  {
#ifdef BSD42
			if( setsockopt(fd, SOL_SOCKET, options, 0, 0) < 0)
#else BSD43
			if( setsockopt(fd, SOL_SOCKET, options, &one, sizeof(one)) < 0)
#endif
				err("setsockopt");
		}
		if(connect(fd, &sinhim, sizeof(sinhim) ) < 0)
			err("connect");
		mes("connect");
	    } else {
		/* otherwise, we are the server and 
	         * should listen for the connections
	         */
		listen(fd,0);   /* allow a queue of 0 */
		if(options)  {
#ifdef BSD42
			if( setsockopt(fd, SOL_SOCKET, options, 0, 0) < 0)
#else BSD43
			if( setsockopt(fd, SOL_SOCKET, options, &one, sizeof(one)) < 0)
#endif
				err("setsockopt");
		}
		fromlen = sizeof(frominet);
		domain = AF_INET;
		if((fd=accept(fd, &frominet, &fromlen) ) < 0)
			err("accept");
		mes("accept");
	    }
	}
	prep_timer();
	errno = 0;
	if (sinkmode) {      
		register int cnt;
		if (trans)  {
			pattern( buf, buflen );
			if(udp)  (void)Nwrite( fd, buf, 4 ); /* rcvr start */
			while (nbuf-- && Nwrite(fd,buf,buflen) == buflen)
				nbytes += buflen;
			if(udp)  (void)Nwrite( fd, buf, 4 ); /* rcvr end */
		} else {
			while ((cnt=Nread(fd,buf,buflen)) > 0)  {
				static int going = 0;
				if( cnt <= 4 )  {
					if( going )
						break;	/* "EOF" */
					going = 1;
					prep_timer();
				} else
					nbytes += cnt;
			}
		}
	} else {
		register int cnt;
		if (trans)  {
			while((cnt=read(0,buf,buflen)) > 0 &&
			    Nwrite(fd,buf,cnt) == cnt)
				nbytes += cnt;
		}  else  {
			while((cnt=Nread(fd,buf,buflen)) > 0 &&
			    write(1,buf,cnt) == cnt)
				nbytes += cnt;
		}
	}
	if(errno) err("IO");
	(void)read_timer(stats,sizeof(stats));
	if(udp&&trans)  {
		(void)Nwrite( fd, buf, 4 ); /* rcvr end */
		(void)Nwrite( fd, buf, 4 ); /* rcvr end */
		(void)Nwrite( fd, buf, 4 ); /* rcvr end */
		(void)Nwrite( fd, buf, 4 ); /* rcvr end */
	}
	fprintf(stderr,"ttcp%s: %s\n", trans?"-t":"-r", stats);
	if( cput <= 0.0 )  cput = 0.001;
	if( realt <= 0.0 )  realt = 0.001;
	fprintf(stderr,"ttcp%s: %ld bytes processed\n",
		trans?"-t":"-r", nbytes );
	fprintf(stderr,"ttcp%s: %9g CPU sec  = %9g KB/cpu sec,  %9g Kbits/cpu sec\n",
		trans?"-t":"-r",
		cput,
		((double)nbytes)/cput/1024,
		((double)nbytes)*8/cput/1024 );
	fprintf(stderr,"ttcp%s: %9g real sec = %9g KB/real sec, %9g Kbits/sec\n",
		trans?"-t":"-r",
		realt,
		((double)nbytes)/realt/1024,
		((double)nbytes)*8/realt/1024 );
	exit(0);

usage:
	fprintf(stderr,Usage);
	exit(1);
}

err(s)
char *s;
{
	fprintf(stderr,"ttcp%s: ", trans?"-t":"-r");
	perror(s);
	fprintf(stderr,"errno=%d\n",errno);
	exit(1);
}

mes(s)
char *s;
{
	fprintf(stderr,"ttcp%s: %s\n", trans?"-t":"-r", s);
}

pattern( cp, cnt )
register char *cp;
register int cnt;
{
	register char c;
	c = 0;
	while( cnt-- > 0 )  {
		while( !isprint((c&0x7F)) )  c++;
		*cp++ = (c++&0x7F);
	}
}

/******* timing *********/

#ifdef SYSV
extern long time();
static long time0;
static struct tms tms0;
#else
static struct	timeval time0;	/* Time at which timeing started */
static struct	rusage ru0;	/* Resource utilization at the start */

static void prusage();
static void tvadd();
static void tvsub();
static void psecs();
#endif

/*
 *			P R E P _ T I M E R
 */
void
prep_timer()
{
#ifdef SYSV
	(void)time(&time0);
	(void)times(&tms0);
#else
	gettimeofday(&time0, (struct timezone *)0);
	getrusage(RUSAGE_SELF, &ru0);
#endif
}

/*
 *			R E A D _ T I M E R
 * 
 */
double
read_timer(str,len)
char *str;
{
#ifdef SYSV
	long now;
	struct tms tmsnow;
	char line[132];

	(void)time(&now);
	realt = now-time0;
	(void)times(&tmsnow);
	cput = tmsnow.tms_utime - tms0.tms_utime;
	cput /= HZ;
	if( cput < 0.00001 )  cput = 0.01;
	if( realt < 0.00001 )  realt = cput;
	sprintf(line,"%g CPU secs in %g elapsed secs (%g%%)",
		cput, realt,
		cput/realt*100 );
	(void)strncpy( str, line, len );
	return( cput );
#else
	/* BSD */
	struct timeval timedol;
	struct rusage ru1;
	struct timeval td;
	struct timeval tend, tstart;
	char line[132];

	getrusage(RUSAGE_SELF, &ru1);
	gettimeofday(&timedol, (struct timezone *)0);
	prusage(&ru0, &ru1, &timedol, &time0, line);
	(void)strncpy( str, line, len );

	/* Get real time */
	tvsub( &td, &timedol, &time0 );
	realt = td.tv_sec + ((double)td.tv_usec) / 1000000;

	/* Get CPU time (user+sys) */
	tvadd( &tend, &ru1.ru_utime, &ru1.ru_stime );
	tvadd( &tstart, &ru0.ru_utime, &ru0.ru_stime );
	tvsub( &td, &tend, &tstart );
	cput = td.tv_sec + ((double)td.tv_usec) / 1000000;
	if( cput < 0.00001 )  cput = 0.00001;
	return( cput );
#endif
}

#ifndef SYSV
static void
prusage(r0, r1, e, b, outp)
	register struct rusage *r0, *r1;
	struct timeval *e, *b;
	char *outp;
{
	struct timeval tdiff;
	register time_t t;
	register char *cp;
	register int i;
	int ms;

	t = (r1->ru_utime.tv_sec-r0->ru_utime.tv_sec)*100+
	    (r1->ru_utime.tv_usec-r0->ru_utime.tv_usec)/10000+
	    (r1->ru_stime.tv_sec-r0->ru_stime.tv_sec)*100+
	    (r1->ru_stime.tv_usec-r0->ru_stime.tv_usec)/10000;
	ms =  (e->tv_sec-b->tv_sec)*100 + (e->tv_usec-b->tv_usec)/10000;

#define END(x)	{while(*x) x++;}
	cp = "%Uuser %Ssys %Ereal %P %Xi+%Dd %Mmaxrss %F+%Rpf %Ccsw";
	for (; *cp; cp++)  {
		if (*cp != '%')
			*outp++ = *cp;
		else if (cp[1]) switch(*++cp) {

		case 'U':
			tvsub(&tdiff, &r1->ru_utime, &r0->ru_utime);
			sprintf(outp,"%d.%01d", tdiff.tv_sec, tdiff.tv_usec/100000);
			END(outp);
			break;

		case 'S':
			tvsub(&tdiff, &r1->ru_stime, &r0->ru_stime);
			sprintf(outp,"%d.%01d", tdiff.tv_sec, tdiff.tv_usec/100000);
			END(outp);
			break;

		case 'E':
			psecs(ms / 100, outp);
			END(outp);
			break;

		case 'P':
			sprintf(outp,"%d%%", (int) (t*100 / ((ms ? ms : 1))));
			END(outp);
			break;

		case 'W':
			i = r1->ru_nswap - r0->ru_nswap;
			sprintf(outp,"%d", i);
			END(outp);
			break;

		case 'X':
			sprintf(outp,"%d", t == 0 ? 0 : (r1->ru_ixrss-r0->ru_ixrss)/t);
			END(outp);
			break;

		case 'D':
			sprintf(outp,"%d", t == 0 ? 0 :
			    (r1->ru_idrss+r1->ru_isrss-(r0->ru_idrss+r0->ru_isrss))/t);
			END(outp);
			break;

		case 'K':
			sprintf(outp,"%d", t == 0 ? 0 :
			    ((r1->ru_ixrss+r1->ru_isrss+r1->ru_idrss) -
			    (r0->ru_ixrss+r0->ru_idrss+r0->ru_isrss))/t);
			END(outp);
			break;

		case 'M':
			sprintf(outp,"%d", r1->ru_maxrss/2);
			END(outp);
			break;

		case 'F':
			sprintf(outp,"%d", r1->ru_majflt-r0->ru_majflt);
			END(outp);
			break;

		case 'R':
			sprintf(outp,"%d", r1->ru_minflt-r0->ru_minflt);
			END(outp);
			break;

		case 'I':
			sprintf(outp,"%d", r1->ru_inblock-r0->ru_inblock);
			END(outp);
			break;

		case 'O':
			sprintf(outp,"%d", r1->ru_oublock-r0->ru_oublock);
			END(outp);
			break;
		case 'C':
			sprintf(outp,"%d+%d", r1->ru_nvcsw-r0->ru_nvcsw,
				r1->ru_nivcsw-r0->ru_nivcsw );
			END(outp);
			break;
		}
	}
	*outp = '\0';
}

static void
tvadd(tsum, t0, t1)
	struct timeval *tsum, *t0, *t1;
{

	tsum->tv_sec = t0->tv_sec + t1->tv_sec;
	tsum->tv_usec = t0->tv_usec + t1->tv_usec;
	if (tsum->tv_usec > 1000000)
		tsum->tv_sec++, tsum->tv_usec -= 1000000;
}

static void
tvsub(tdiff, t1, t0)
	struct timeval *tdiff, *t1, *t0;
{

	tdiff->tv_sec = t1->tv_sec - t0->tv_sec;
	tdiff->tv_usec = t1->tv_usec - t0->tv_usec;
	if (tdiff->tv_usec < 0)
		tdiff->tv_sec--, tdiff->tv_usec += 1000000;
}

static void
psecs(l,cp)
long l;
register char *cp;
{
	register int i;

	i = l / 3600;
	if (i) {
		sprintf(cp,"%d:", i);
		END(cp);
		i = l % 3600;
		sprintf(cp,"%d%d", (i/60) / 10, (i/60) % 10);
		END(cp);
	} else {
		i = l;
		sprintf(cp,"%d", i / 60);
		END(cp);
	}
	i %= 60;
	*cp++ = ':';
	sprintf(cp,"%d%d", i / 10, i % 10);
}
#endif

/*
 *			N R E A D
 */
Nread( fd, buf, count )
{
	struct sockaddr_in from;
	int len = sizeof(from);
	register int cnt;
	if( udp )  {
		cnt = recvfrom( fd, buf, count, 0, &from, &len );
	} else {
		if( b_flag )
			cnt = mread( fd, buf, count );	/* fill buf */
		else
			cnt = read( fd, buf, count );
	}
	return(cnt);
}

/*
 *			N W R I T E
 */
Nwrite( fd, buf, count )
{
	register int cnt;
	if( udp )  {
again:
		cnt = sendto( fd, buf, count, 0, &sinhim, sizeof(sinhim) );
		if( cnt<0 && errno == ENOBUFS )  {
			delay(18000);
			errno = 0;
			goto again;
		}
	} else {
		cnt = write( fd, buf, count );
	}
	return(cnt);
}

delay(us)
{
	struct timeval tv;

	tv.tv_sec = 0;
	tv.tv_usec = us;
	(void)select( 1, (char *)0, (char *)0, (char *)0, &tv );
	return(1);
}

/*
 *			M R E A D
 *
 * This function performs the function of a read(II) but will
 * call read(II) multiple times in order to get the requested
 * number of characters.  This can be necessary because
 * network connections don't deliver data with the same
 * grouping as it is written with.  Written by Robert S. Miles, BRL.
 */
int
mread(fd, bufp, n)
int fd;
register char	*bufp;
unsigned	n;
{
	register unsigned	count = 0;
	register int		nread;

	do {
		nread = read(fd, bufp, n-count);
		if(nread < 0)  {
			perror("ttcp_mread");
			return(-1);
		}
		if(nread == 0)
			return((int)count);
		count += (unsigned)nread;
		bufp += nread;
	 } while(count < n);

	return((int)count);
}