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/* sim_tmxr.c: Telnet terminal multiplexer library
Copyright (c) 2001-2011, Robert M Supnik
Permission is hereby granted, free of charge, to any person obtaining a
copy of this software and associated documentation files (the "Software"),
to deal in the Software without restriction, including without limitation
the rights to use, copy, modify, merge, publish, distribute, sublicense,
and/or sell copies of the Software, and to permit persons to whom the
Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
Except as contained in this notice, the name of Robert M Supnik shall not be
used in advertising or otherwise to promote the sale, use or other dealings
in this Software without prior written authorization from Robert M Supnik.
Based on the original DZ11 simulator by Thord Nilson, as updated by
Arthur Krewat.
12-Oct-12 MP Revised serial port support to not require changes to
any code in TMXR library using code. Added support
for per line listener ports and outgoing tcp connections.
02-Jun-11 MP Fixed telnet option negotiation loop with some clients
Added Option Negotiation and Debugging Support
17-Jan-11 MP Added Buffered line capabilities
16-Jan-11 MP Made option negotiation more reliable
20-Nov-08 RMS Added three new standardized SHOW routines
05-Nov-08 JDB Moved logging call after connection check in tmxr_putc_ln
03-Nov-08 JDB Added TMXR null check to tmxr_find_ldsc
07-Oct-08 JDB Added initial serial port support
30-Sep-08 JDB Reverted tmxr_find_ldsc to original implementation
27-May-08 JDB Added line connection order to tmxr_poll_conn,
added tmxr_set_lnorder and tmxr_show_lnorder
14-May-08 JDB Print device and line to which connection was made
11-Apr-07 JDB Worked around Telnet negotiation problem with QCTerm
16-Aug-05 RMS Fixed C++ declaration and cast problems
29-Jun-05 RMS Extended tmxr_dscln to support unit array devices
Fixed bug in SET LOG/NOLOG
04-Jan-04 RMS Changed TMXR ldsc to be pointer to linedesc array
Added tmxr_linemsg, circular output pointers, logging
(from Mark Pizzolato)
29-Dec-03 RMS Added output stall support
01-Nov-03 RMS Cleaned up attach routine
09-Mar-03 RMS Fixed bug in SHOW CONN
22-Dec-02 RMS Fixed bugs in IAC+IAC receive and transmit sequences
Added support for received break (all from by Mark Pizzolato)
Fixed bug in attach
31-Oct-02 RMS Fixed bug in 8b (binary) support
22-Aug-02 RMS Added tmxr_open_master, tmxr_close_master
30-Dec-01 RMS Added tmxr_fstats, tmxr_dscln, renamed tmxr_fstatus
03-Dec-01 RMS Changed tmxr_fconns for extended SET/SHOW
20-Oct-01 RMS Fixed bugs in read logic (found by Thord Nilson).
Added tmxr_rqln, tmxr_tqln
This library includes:
tmxr_poll_conn - poll for connection
tmxr_reset_ln - reset line (drops Telnet/tcp and serial connections)
tmxr_detach_ln - reset line and close per line listener and outgoing destination
tmxr_getc_ln - get character for line
tmxr_get_packet_ln - get packet from line
tmxr_get_packet_ln_ex - get packet from line with separater byte
tmxr_poll_rx - poll receive
tmxr_putc_ln - put character for line
tmxr_put_packet_ln - put packet on line
tmxr_put_packet_ln_ex - put packet on line with separator byte
tmxr_poll_tx - poll transmit
tmxr_send_buffered_data - transmit buffered data
tmxr_set_modem_control_passthru - enable modem control on a multiplexer
tmxr_clear_modem_control_passthru - disable modem control on a multiplexer
tmxr_set_port_speed_control - Declare that tmxr_set_config_line is used
tmxr_clear_port_speed_control - Declare that tmxr_set_config_line is not used
tmxr_set_line_port_speed_control - Declare that tmxr_set_config_line is used for line
tmxr_clear_line_port_speed_control - Declare that tmxr_set_config_line is not used for line
tmxr_set_get_modem_bits - set and/or get a line modem bits
tmxr_set_line_loopback - enable or disable loopback mode on a line
tmxr_get_line_loopback - returns the current loopback status of a line
tmxr_set_line_halfduplex - enable or disable halfduplex mode on a line
tmxr_get_line_halfduplex - returns the current halfduplex status of a line
tmxr_set_config_line - set port speed, character size, parity and stop bits
tmxr_open_master - open master connection
tmxr_close_master - close master connection
tmxr_attach - attach terminal multiplexor to listening port
tmxr_detach - detach terminal multiplexor to listening port
tmxr_attach_help - help routine for attaching multiplexer devices
tmxr_set_line_unit - set the unit which polls for input for a given line
tmxr_ex - (null) examine
tmxr_dep - (null) deposit
tmxr_msg - send message to socket
tmxr_linemsg - send message to line
tmxr_linemsgf - send formatted message to line
tmxr_fconns - output connection status
tmxr_fstats - output connection statistics
tmxr_set_log - enable logging for line
tmxr_set_nolog - disable logging for line
tmxr_show_log - show logging status for line
tmxr_dscln - disconnect line (SET routine)
tmxr_rqln - number of available characters for line
tmxr_tqln - number of buffered characters for line
tmxr_tpqln - number of buffered packet characters for line
tmxr_tpbusyln - transmit packet busy status for line
tmxr_set_lnorder - set line connection order
tmxr_show_lnorder - show line connection order
tmxr_show_summ - show connection summary
tmxr_show_cstat - show line connections or status
tmxr_show_lines - show number of lines
tmxr_show_open_devices - show info about all open tmxr devices
All routines are OS-independent.
This library supports the simulation of multiple-line terminal multiplexers.
It may also be used to create single-line "multiplexers" to provide
additional terminals beyond the simulation console. It may also be used to
create single-line or multi-line simulated synchronous (BiSync) devices.
Multiplexer lines may be connected to terminal emulators supporting the
Telnet protocol via sockets, or to hardware terminals via host serial
ports. Concurrent Telnet and serial connections may be mixed on a given
multiplexer.
When connecting via sockets, the simulated multiplexer is attached to a
listening port on the host system:
sim> attach MUX 23
Listening on port 23
Once attached, the listening port must be polled for incoming connections.
When a connection attempt is received, it will be associated with the next
multiplexer line in the user-specified line order, or with the next line in
sequence if no order has been specified. Individual lines may be connected
to serial ports or remote systems via TCP (telnet or not as desired), OR
they may have separate listening TCP ports.
Logging of Multiplexer Line output:
The traffic going out multiplexer lines can be logged to files. A single
line multiplexer can log it's traffic with the following command:
sim> atta MUX 23,Log=LogFileName
sim> atta MUX Connect=ser0,Log=LogFileName
Specifying a Log value for a multi-line multiplexer is specifying a
template filename. The actual file name used for each line will be
the indicated filename with _n appended (n being the line number).
Buffered Multiplexer Line:
A Multiplexer Line Buffering has been implemented. A Buffered Line will
have a copy of the last 'buffer size' bytes of output retained in a line
specific buffer. The contents of this buffer will be transmitted out any
new connection on that line when a new telnet session is established.
This capability is most useful for the Console Telnet session. When a
Console Telnet session is Buffered, a simulator will start (via BOOT CPU
or whatever is appropriate for a particular simulator) without needing to
have an active telnet connection. When a Telnet connection comes along
for the telnet port, the contents of the saved buffer (which wraps on
overflow) are presented on the telnet session as output before session
traffic. This allows the connecting telnet client to see what happened
before he connected since the likely reason he might be connecting to the
console of a background simulator is to troubleshoot unusual behavior,
the details of which may have already been sent to the console.
Serial Port support:
Serial ports may be specified as an operating system specific device names
or using simh generic serial names. simh generic names are of the form
serN, where N is from 0 thru one less than the maximum number of serial
ports on the local system. The mapping of simh generic port names to OS
specific names can be displayed using the following command:
sim> show serial
Serial devices:
ser0 COM1 (\Device\Serial0)
ser1 COM3 (Winachcf0)
sim> attach MUX Line=2,Connect=ser0
or equivalently
sim> attach MUX Line=2,Connect=COM1
An optional configuration string may be present after the port name. If
present, it must be separated from the port name with a semicolon and has
this form:
<rate>-<charsize><parity><stopbits>
where:
rate = communication rate in bits per second
charsize = character size in bits (5-8, including optional parity)
parity = parity designator (N/E/O/M/S for no/even/odd/mark/space parity)
stopbits = number of stop bits (1, 1.5, or 2)
As an example:
9600-8n1
The supported rates, sizes, and parity options are host-specific. If
a configuration string is not supplied, then the default of 9600-8N1
is used.
An attachment to a serial port with the '-V' switch will cause a
connection message to be output to the connected serial port.
This will help to confirm the correct port has been connected and
that the port settings are reasonable for the connected device.
This would be done as:
sim> attach -V MUX Connect=SerN
Line specific tcp listening ports are supported. These are configured
using commands of the form:
sim> attach MUX Line=2,port{;notelnet}
Direct computer to computer connections (Virutal Null Modem cables) may
be established using the telnet protocol or via raw tcp sockets.
sim> attach MUX Line=2,Connect=host:port{;notelnet}
Computer to computer virtual connections can be one way (as illustrated
above) or symmetric. A symmetric connection is configured by combining
a one way connection with a tcp listening port on the same line:
sim> attach MUX Line=2,Connect=host:port,listenport
When symmetric virtual connections are configured, incoming connections
on the specified listening port are checked to assure that they actually
come from the specified connection destination host system.
The command syntax for a single line device (MX) is:
sim> attach MX port{;notelnet}
sim> attach MX Connect=serN{;config}
sim> attach MX Connect=COM9{;config}
sim> attach MX Connect=host:port{;notelnet}
The command syntax for ANY multi-line device is:
sim> attach MX port{;notelnet} ; Defines the master listening port for the mux and optionally allows non-telnet (i.e. raw socket) operation for all lines.
sim> attach MX Line=n,port{;notelnet} ; Defines a line specific listen port for a particular line. Each line can have a separate listen port and the mux can have its own as well. Optionally disable telnet wire protocol (i.e. raw socket)
sim> attach MX Line=n,Connect=serN{;config} ; Connects line n to simh generic serial port N (port list visible with the sim> SHOW SERIAL command), the optional ";config" data specifies the speed, parity and stop bits for the connection
; DTR (and RTS) will be raised at attach time and will drop at detach/disconnect time
sim> attach MX Line=n,Connect=host:port{;notelnet} ; Causes a connection to be established to the designated host:port. The actual connection will happen in a non-blocking fashion and will be completed and/or re-established by the normal tmxr_poll_conn activities
All connections configured for any multiplexer device are unconfigured by:
sim> detach MX ; detaches ALL connections/ports/sessions on the MUX.
Console serial connections are achieved by:
sim> set console serial=serN{;config}
or
sim> set console serial=COM2{;config}
A line specific listening port (12366) can be specified by the following:
sim> attach MUX Line=2,12366
A line specific remote telnet (or raw tcp) destination can be specified
by the following:
sim> attach MUX Line=2,Connect=remotehost:port
If a connection to a remotehost:port wants a raw binary data channel
(instead of a telnet session) the following would be used:
sim> attach MUX Line=2,Connect=remotehost:port;notelnet
A single line multiplexor can indicate any of the above line options
without specifying a line number:
sim> attach MUX Connect=ser0;9600-8N1
sim> attach MUX 12366
sim> attach MUX Connect=remotehost:port
sim> attach MUX Connect=remotehost:port;notelnet
A multiplexor can disconnect all (telnet, serial and outgoing) previous
attachments with:
sim> detach MUX
A device emulation may choose to implement a command interface to
disconnect specific individual lines. This would usually be done via
a Unit Modifier table entry (MTAB) which dispatches the command
"SET dev DISCONNECT[=line]" to tmxr_dscln. This will cause a telnet
connection to be closed, but a serial port will normally have DTR
dropped for 500ms and raised again (thus hanging up a modem on that
serial port).
sim> set MUX disconnect=2
A line which is connected to a serial port can be manually closed by
adding the -C switch to a disconnect command.
sim> set -C MUX disconnect=2
Full Modem Control serial port support.
This library supports devices which wish to emulate full modem
control/signalling for serial ports. Any device emulation which wishes
to support this functionality for attached serial ports must call
"tmxr_set_modem_control_passthru" before any call to tmxr_attach.
This disables automatic DTR (&RTS) manipulation by this library.
Responsibility for manipulating DTR falls on the simulated operating
system. Calling tmxr_set_modem_control_passthru would usually be in
a device reset routine. It may also be called by a device attach
routine based on user specified options.
Once support for full modem control has been declared by a device
emulation for a particular TMXR device, this library will make no
direct effort to manipulate modem bits while connected to serial ports.
The "tmxr_set_get_modem_bits" API exists to allow the device emulation
layer to query and control modem signals. The "tmxr_set_config_line"
API exists to allow the device emulation layer to change port settings
(baud rate, parity and stop bits). A modem_control enabled line
merely passes the VM's port status bits, data and settings through to
and from the serial port.
The "tmxr_set_get_modem_bits" and "tmxr_set_config_line" APIs will
ONLY work on a modem control enabled TMXR device.
*/
#define NOT_MUX_USING_CODE /* sim_tmxr library define */
#include "sim_defs.h"
#include "sim_serial.h"
#include "sim_sock.h"
#include "sim_timer.h"
#include "sim_tmxr.h"
#include "scp.h"
#define MIN(a,b) (((a) < (b)) ? (a) : (b))
#include <ctype.h>
#include <math.h>
/* Telnet protocol constants - negatives are for init'ing signed char data */
/* Commands */
#define TN_IAC 0xFFu /* -1 */ /* protocol delim */
#define TN_DONT 0xFEu /* -2 */ /* dont */
#define TN_DO 0xFDu /* -3 */ /* do */
#define TN_WONT 0xFCu /* -4 */ /* wont */
#define TN_WILL 0xFBu /* -5 */ /* will */
#define TN_SB 0xFAu /* -6 */ /* sub-option negotiation */
#define TN_GA 0xF9u /* -7 */ /* go ahead */
#define TN_EL 0xF8u /* -8 */ /* erase line */
#define TN_EC 0xF7u /* -9 */ /* erase character */
#define TN_AYT 0xF6u /* -10 */ /* are you there */
#define TN_AO 0xF5u /* -11 */ /* abort output */
#define TN_IP 0xF4u /* -12 */ /* interrupt process */
#define TN_BRK 0xF3u /* -13 */ /* break */
#define TN_DATAMK 0xF2u /* -14 */ /* data mark */
#define TN_NOP 0xF1u /* -15 */ /* no operation */
#define TN_SE 0xF0u /* -16 */ /* end sub-option negot */
/* Options */
#define TN_BIN 0 /* bin */
#define TN_ECHO 1 /* echo */
#define TN_SGA 3 /* sga */
#define TN_STATUS 5 /* option status query */
#define TN_TIMING 6 /* Timing Mark */
#define TN_NAOCRD 10 /* Output Carriage-Return Disposition */
#define TN_NAOHTS 11 /* Output Horizontal Tab Stops */
#define TN_NAOHTD 12 /* Output Horizontal Tab Stop Disposition */
#define TN_NAOFFD 13 /* Output Forfeed Disposition */
#define TN_NAOVTS 14 /* Output Vertical Tab Stop */
#define TN_NAOVTD 15 /* Output Vertical Tab Stop Disposition */
#define TN_NAOLFD 16 /* Output Linefeed Disposition */
#define TN_EXTEND 17 /* Extended Ascii */
#define TN_LOGOUT 18 /* Logout */
#define TN_BM 19 /* Byte Macro */
#define TN_DET 20 /* Data Entry Terminal */
#define TN_SENDLO 23 /* Send Location */
#define TN_TERMTY 24 /* Terminal Type */
#define TN_ENDREC 25 /* Terminal Type */
#define TN_TUID 26 /* TACACS User Identification */
#define TN_OUTMRK 27 /* Output Marking */
#define TN_TTYLOC 28 /* Terminal Location Number */
#define TN_3270 29 /* 3270 Regime */
#define TN_X3PAD 30 /* X.3 PAD */
#define TN_NAWS 31 /* Negotiate About Window Size */
#define TN_TERMSP 32 /* Terminal Speed */
#define TN_TOGFLO 33 /* Remote Flow Control */
#define TN_LINE 34 /* line mode */
#define TN_XDISPL 35 /* X Display Location */
#define TN_ENVIRO 36 /* Environment */
#define TN_AUTH 37 /* Authentication */
#define TN_ENCRYP 38 /* Data Encryption */
#define TN_NEWENV 39 /* New Environment */
#define TN_TN3270 40 /* TN3270 Enhancements */
#define TN_CHARST 42 /* CHARSET */
#define TN_COMPRT 44 /* Com Port Control */
#define TN_KERMIT 47 /* KERMIT */
#define TN_CR 015 /* carriage return */
#define TN_LF 012 /* line feed */
#define TN_NUL 000 /* null */
/* Telnet line states */
#define TNS_NORM 000 /* normal */
#define TNS_IAC 001 /* IAC seen */
#define TNS_WILL 002 /* WILL seen */
#define TNS_WONT 003 /* WONT seen */
#define TNS_SKIP 004 /* skip next cmd */
#define TNS_CRPAD 005 /* CR padding */
#define TNS_DO 006 /* DO request pending rejection */
/* Telnet Option Sent Flags */
#define TNOS_DONT 001 /* Don't has been sent */
#define TNOS_WONT 002 /* Won't has been sent */
static BITFIELD tmxr_modem_bits[] = {
BIT(DTR), /* Data Terminal Ready */
BIT(RTS), /* Request To Send */
BIT(DCD), /* Data Carrier Detect */
BIT(RNG), /* Ring Indicator */
BIT(CTS), /* Clear To Send */
BIT(DSR), /* Data Set Ready */
ENDBITS
};
static u_char mantra[] = { /* Telnet Option Negotiation Mantra */
TN_IAC, TN_WILL, TN_LINE,
TN_IAC, TN_WILL, TN_SGA,
TN_IAC, TN_WILL, TN_ECHO,
TN_IAC, TN_WILL, TN_BIN,
TN_IAC, TN_DO, TN_BIN
};
#define TMXR_GUARD ((int32)(lp->serport ? 1 : sizeof(mantra)))/* buffer guard */
#define TMXR_LINE_DISABLED (-1)
/* Local routines */
static void tmxr_add_to_open_list (TMXR* mux);
/* Initialize the line state.
Reset the line state to represent an idle line. Note that we do not clear
all of the line structure members, so a connected line remains connected
after this call.
Because a line break is represented by a flag in the "receive break status"
array, we must zero that array in order to clear any pending break
indications.
*/
static void tmxr_init_line (TMLN *lp)
{
lp->tsta = 0; /* init telnet state */
lp->xmte = 1; /* enable transmit */
lp->dstb = 0; /* default bin mode */
lp->rxbpr = lp->rxbpi = lp->rxcnt = lp->rxpcnt = 0; /* init receive indexes */
if (!lp->txbfd || lp->notelnet) /* if not buffered telnet */
lp->txbpr = lp->txbpi = lp->txcnt = lp->txpcnt = 0; /* init transmit indexes */
lp->txdrp = lp->txstall = 0;
tmxr_set_get_modem_bits (lp, 0, 0, NULL);
if (lp->mp && (!lp->mp->buffered) && (!lp->txbfd)) {
lp->txbfd = 0;
lp->txbsz = TMXR_MAXBUF;
lp->txb = (char *)realloc (lp->txb, lp->txbsz);
lp->rxbsz = TMXR_MAXBUF;
lp->rxb = (char *)realloc(lp->rxb, lp->rxbsz);
lp->rbr = (char *)realloc(lp->rbr, lp->rxbsz);
}
if (lp->loopback) {
lp->lpbsz = lp->rxbsz;
lp->lpb = (char *)realloc(lp->lpb, lp->lpbsz);
lp->lpbcnt = lp->lpbpi = lp->lpbpr = 0;
}
if (lp->rxpb) {
lp->rxpboffset = lp->rxpbsize = 0;
free (lp->rxpb);
lp->rxpb = NULL;
}
if (lp->txpb) {
lp->txpbsize = lp->txppsize = lp->txppoffset = 0;
free (lp->txpb);
lp->txpb = NULL;
}
memset (lp->rbr, 0, lp->rxbsz); /* clear break status array */
}
/* Report a connection to a line.
If the indicated line (lp) is speaking the telnet wire protocol, a
notification of the form:
Connected to the <sim> simulator <dev> device, line <n>
is sent to the newly connected line. If the device has only one line, the
"line <n>" part is omitted. If the device has not been defined, the "<dev>
device" part is omitted.
*/
static void tmxr_report_connection (TMXR *mp, TMLN *lp)
{
int32 unwritten, psave;
char cmsg[80];
char dmsg[80] = "";
char lmsg[80] = "";
char msgbuf[256] = "";
if ((!lp->notelnet) || (sim_switches & SWMASK ('V'))) {
sprintf (cmsg, "\n\r\nConnected to the %s simulator ", sim_name);
if (mp->dptr) { /* device defined? */
sprintf (dmsg, "%s device", /* report device name */
sim_dname (mp->dptr));
if (mp->lines > 1) /* more than one line? */
sprintf (lmsg, ", line %d", (int)(lp-mp->ldsc));/* report the line number */
}
sprintf (msgbuf, "%s%s%s\r\n\n", cmsg, dmsg, lmsg);
}
if (!mp->buffered) {
lp->txbpi = 0; /* init buf pointers */
lp->txbpr = (int32)(lp->txbsz - strlen (msgbuf));
lp->rxcnt = lp->txcnt = lp->txdrp = lp->txstall = 0;/* init counters */
lp->rxpcnt = lp->txpcnt = 0;
}
else
if (lp->txcnt > lp->txbsz)
lp->txbpr = (lp->txbpi + 1) % lp->txbsz;
else
lp->txbpr = (int32)(lp->txbsz - strlen (msgbuf));
psave = lp->txbpi; /* save insertion pointer */
lp->txbpi = lp->txbpr; /* insert connection message */
if ((lp->serport) && (!sim_is_running)) {
sim_os_ms_sleep (TMXR_DTR_DROP_TIME); /* Wait for DTR to be noticed */
lp->ser_connect_pending = FALSE; /* Mark line as ready for action */
lp->conn = TRUE;
}
tmxr_linemsg (lp, msgbuf); /* beginning of buffer */
lp->txbpi = psave; /* restore insertion pointer */
unwritten = tmxr_send_buffered_data (lp); /* send the message */
if ((lp->serport) && (!sim_is_running)) {
lp->ser_connect_pending = TRUE; /* Mark line as not yet ready for action */
lp->conn = FALSE;
}
if (unwritten == 0) /* buffer now empty? */
lp->xmte = 1; /* reenable transmission if paused */
lp->txcnt -= (int32)strlen (msgbuf); /* adjust statistics */
}
/* Report a disconnection to a line.
A notification of the form:
Disconnected from the <sim> simulator
is sent to the line about to be disconnected. We do not flush the buffer
here, because the disconnect routines will do that just after calling us.
*/
static void tmxr_report_disconnection (TMLN *lp)
{
if (lp->notelnet)
return;
tmxr_linemsgf (lp, "\r\nDisconnected from the %s simulator\r\n\n", sim_name);/* report disconnection */
}
static int32 loop_write_ex (TMLN *lp, char *buf, int32 length, t_bool prefix_datagram)
{
int32 written = 0;
int32 loopfree = lp->lpbsz - lp->lpbcnt;
if (lp->datagram && prefix_datagram) {
if ((size_t)loopfree < (size_t)(length + sizeof(length)))
return written;
loop_write_ex (lp, (char *)&length, sizeof(length), FALSE);
}
while (length) {
int32 chunksize;
loopfree = lp->lpbsz - lp->lpbcnt;
if (loopfree == 0)
break;
if (loopfree < length)
length = loopfree;
if (lp->lpbpi >= lp->lpbpr)
chunksize = lp->lpbsz - lp->lpbpi;
else
chunksize = lp->lpbpr - lp->lpbpi;
if (chunksize > length)
chunksize = length;
memcpy (&lp->lpb[lp->lpbpi], buf, chunksize);
buf += chunksize;
length -= chunksize;
written += chunksize;
lp->lpbpi = (lp->lpbpi + chunksize) % lp->lpbsz;
}
lp->lpbcnt += written;
return written;
}
static int32 loop_write (TMLN *lp, char *buf, int32 length)
{
return loop_write_ex (lp, buf, length, TRUE);
}
static int32 loop_read_ex (TMLN *lp, char *buf, int32 bufsize)
{
int32 bytesread = 0;
while (bufsize > 0) {
int32 chunksize;
int32 loopused = lp->lpbcnt;
if (loopused < bufsize)
bufsize = loopused;
if (loopused == 0)
break;
if (lp->lpbpi > lp->lpbpr)
chunksize = lp->lpbpi - lp->lpbpr;
else
chunksize = lp->lpbsz - lp->lpbpr;
if (chunksize > bufsize)
chunksize = bufsize;
memcpy (buf, &lp->lpb[lp->lpbpr], chunksize);
buf += chunksize;
bufsize -= chunksize;
bytesread += chunksize;
lp->lpbpr = (lp->lpbpr + chunksize) % lp->lpbsz;
}
lp->lpbcnt -= bytesread;
return bytesread;
}
static int32 loop_read (TMLN *lp, char *buf, int32 bufsize)
{
if (lp->datagram) {
int32 pktsize;
if (lp->lpbcnt < (int32)sizeof(pktsize))
return 0;
if ((sizeof(pktsize) != loop_read_ex (lp, (char *)&pktsize, sizeof(pktsize))) ||
(pktsize > bufsize))
return -1;
bufsize = pktsize;
}
return loop_read_ex (lp, buf, bufsize);
}
/* Read from a line.
Up to "length" characters are read into the character buffer associated with
line "lp". The actual number of characters read is returned. If no
characters are available, 0 is returned. If an error occurred while reading,
-1 is returned.
If a line break was detected on serial input, the associated receive break
status flag will be set. Line break indication for Telnet connections is
embedded in the Telnet protocol and must be determined externally.
*/
static int32 tmxr_read (TMLN *lp, int32 length)
{
int32 i = lp->rxbpi;
if (lp->loopback)
return loop_read (lp, &(lp->rxb[i]), length);
if (lp->serport) /* serial port connection? */
return sim_read_serial (lp->serport, &(lp->rxb[i]), length, &(lp->rbr[i]));
else /* Telnet connection */
return sim_read_sock (lp->sock, &(lp->rxb[i]), length);
}
/* Write to a line.
Up to "length" characters are written from the character buffer associated
with "lp". The actual number of characters written is returned. If an error
occurred while writing, -1 is returned.
*/
static int32 tmxr_write (TMLN *lp, int32 length)
{
int32 written = 0;
int32 i = lp->txbpr;
if ((lp->txbps) && (sim_gtime () < lp->txnexttime) && (sim_is_running))
return 0;
if (lp->loopback)
return loop_write (lp, &(lp->txb[i]), length);
if (lp->serport) { /* serial port connection? */
written = sim_write_serial (lp->serport, &(lp->txb[i]), length);
}
else {
if (lp->sock) { /* Telnet connection */
written = sim_write_sock (lp->sock, &(lp->txb[i]), length);
if (written == SOCKET_ERROR) { /* did an error occur? */
if (lp->datagram)
return written; /* ignore errors on datagram sockets */
else
return -1; /* return error indication */
}
}
else {
if ((lp->conn == TMXR_LINE_DISABLED) ||
((lp->conn == 0) && lp->txbfd)){
written = length; /* Count here output timing is correct */
if (lp->conn == TMXR_LINE_DISABLED)
lp->txdrp += length; /* Record as having been dropped on the floor */
}
}
}
if ((written > 0) && (lp->txbps) && (sim_is_running))
lp->txnexttime = floor (sim_gtime () + ((written * lp->txdeltausecs * sim_timer_inst_per_sec ()) / USECS_PER_SECOND));
return written;
}
/* Remove a character from the read buffer.
The character at position "p" in the read buffer associated with line "lp" is
removed by moving all of the following received characters down one position.
The receive break status array is adjusted accordingly.
*/
static void tmxr_rmvrc (TMLN *lp, int32 p)
{
for ( ; p < lp->rxbpi; p++) { /* work from "p" through end of buffer */
lp->rxb[p] = lp->rxb[p + 1]; /* slide following character down */
lp->rbr[p] = lp->rbr[p + 1]; /* adjust break status too */
}
lp->rbr[p] = 0; /* clear potential break from vacated slot */
lp->rxbpi = lp->rxbpi - 1; /* drop buffer insert index */
}
/* Find a line descriptor indicated by unit or number.
If "uptr" is NULL, then the line descriptor is determined by the line number
passed in "val". If "uptr" is not NULL, then it must point to a unit
associated with a line, and the line descriptor is determined by the unit
number, which is derived by the position of the unit in the device's unit
array.
Note: This routine may be called with a UNIT that does not belong to the
device indicated in the TMXR structure. That is, the multiplexer lines may
belong to a device other than the one attached to the socket (the HP 2100 MUX
device is one example). Therefore, we must look up the device from the unit
at each call, rather than depending on the DEVICE pointer stored in the TMXR.
*/
static TMLN *tmxr_find_ldsc (UNIT *uptr, int32 val, const TMXR *mp)
{
if (mp == NULL) /* invalid multiplexer descriptor? */
return NULL; /* programming error! */
if (uptr) { /* called from SET? */
DEVICE *dptr = find_dev_from_unit (uptr); /* find device */
if (dptr == NULL) /* what?? */
return NULL;
val = (int32) (uptr - dptr->units); /* implicit line # */
}
if ((val < 0) || (val >= mp->lines)) /* invalid line? */
return NULL;
return mp->ldsc + val; /* line descriptor */
}
/* Get a line descriptor indicated by a string or unit.
A pointer to the line descriptor associated with multiplexer "mp" and unit
"uptr" or specified by string "cptr" is returned. If "uptr" is non-null,
then the unit number within its associated device implies the line number.
If "uptr" is null, then the string "cptr" is parsed for a decimal line
number. If the line number is missing, malformed, or outside of the range of
line numbers associated with "mp", then NULL is returned with status set to
SCPE_ARG.
Implementation note:
1. A return status of SCPE_IERR implies a programming error (passing an
invalid pointer or an invalid unit).
*/
static TMLN *tmxr_get_ldsc (UNIT *uptr, const char *cptr, TMXR *mp, t_stat *status)
{
t_value ln;
TMLN *lp = NULL;
t_stat code = SCPE_OK;
if (mp == NULL) /* missing mux descriptor? */
code = SCPE_IERR; /* programming error! */
else if (uptr) { /* implied line form? */
lp = tmxr_find_ldsc (uptr, mp->lines, mp); /* determine line from unit */
if (lp == NULL) /* invalid line number? */
code = SCPE_IERR; /* programming error! */
}
else if (cptr == NULL) /* named line form, parameter supplied? */
code = SCPE_MISVAL; /* no, so report missing */
else {
ln = get_uint (cptr, 10, mp->lines - 1, &code); /* get line number */
if (code == SCPE_OK) /* line number OK? */
lp = mp->ldsc + (int32) ln; /* use as index to determine line */
}
if (status) /* return value pointer supplied? */
*status = code; /* store return status value */
return lp; /* return pointer to line descriptor */
}
/* Generate the Attach string which will fully configure the multiplexer
Inputs:
old = pointer to the original configuration string which will be replaced
*mp = pointer to multiplexer
Output:
a complete attach string for the current state of the multiplexer
*/
static char *growstring(char **string, size_t growth)
{
*string = (char *)realloc (*string, 1 + (*string ? strlen (*string) : 0) + growth);
return *string + strlen(*string);
}
static char *tmxr_mux_attach_string(char *old, TMXR *mp)
{
char* tptr = NULL;
int32 i;
TMLN *lp;
free (old);
tptr = (char *) calloc (1, 1);
if (tptr == NULL) /* no more mem? */
return tptr;
if (mp->port) /* copy port */
sprintf (growstring(&tptr, 13 + strlen (mp->port)), "%s%s", mp->port, mp->notelnet ? ";notelnet" : "");
if (mp->logfiletmpl[0]) /* logfile info */
sprintf (growstring(&tptr, 7 + strlen (mp->logfiletmpl)), ",Log=%s", mp->logfiletmpl);
if (mp->buffered)
sprintf (growstring(&tptr, 10 + 10), ",Buffered=%d", mp->buffered);
while ((*tptr == ',') || (*tptr == ' '))
memmove (tptr, tptr+1, strlen(tptr+1)+1);
for (i=0; i<mp->lines; ++i) {
char *lptr;
lp = mp->ldsc + i;
lptr = tmxr_line_attach_string(lp);
if (lptr) {
sprintf (growstring(&tptr, 10+strlen(lptr)), "%s%s", *tptr ? "," : "", lptr);
free (lptr);
}
}
if (mp->lines == 1)
while ((*tptr == ',') || (*tptr == ' '))
memmove (tptr, tptr+1, strlen(tptr+1)+1);
if (*tptr == '\0') {
free (tptr);
tptr = NULL;
}
return tptr;
}
/* Global routines */
/* Return the Line specific attach setup currently configured for a given line
Inputs:
*lp = pointer to terminal line descriptor
Outputs:
a string which can be used to reconfigure the line,
NULL if the line isn't configured
Note: The returned string is dynamically allocated memory and must be freed
when it is no longer needed by calling free
*/
char *tmxr_line_attach_string(TMLN *lp)
{
char* tptr = NULL;
tptr = (char *) calloc (1, 1);
if (tptr == NULL) /* no more mem? */
return tptr;
if (lp->destination || lp->port || lp->txlogname || (lp->conn == TMXR_LINE_DISABLED)) {
if ((lp->mp->lines > 1) || (lp->port))
sprintf (growstring(&tptr, 32), "Line=%d", (int)(lp-lp->mp->ldsc));
if (lp->conn == TMXR_LINE_DISABLED)
sprintf (growstring(&tptr, 32), ",Disabled");
if (lp->modem_control != lp->mp->modem_control)
sprintf (growstring(&tptr, 32), ",%s", lp->modem_control ? "Modem" : "NoModem");
if (lp->txbfd && (lp->txbsz != lp->mp->buffered))
sprintf (growstring(&tptr, 32), ",Buffered=%d", lp->txbsz);
if (!lp->txbfd && (lp->mp->buffered > 0))
sprintf (growstring(&tptr, 32), ",UnBuffered");
if (lp->mp->datagram != lp->datagram)
sprintf (growstring(&tptr, 8), ",%s", lp->datagram ? "UDP" : "TCP");
if (lp->mp->packet != lp->packet)
sprintf (growstring(&tptr, 8), ",Packet");
if (lp->port)
sprintf (growstring(&tptr, 12 + strlen (lp->port)), ",%s%s", lp->port, ((lp->mp->notelnet != lp->notelnet) && (!lp->datagram)) ? (lp->notelnet ? ";notelnet" : ";telnet") : "");
if (lp->destination) {
if (lp->serport) {
char portname[CBUFSIZE];
get_glyph_nc (lp->destination, portname, ';');
sprintf (growstring(&tptr, 25 + strlen (lp->destination)), ",Connect=%s%s%s", portname, strcmp("9600-8N1", lp->serconfig ? lp->serconfig : "") ? ";" : "", strcmp("9600-8N1", lp->serconfig ? lp->serconfig : "") ? lp->serconfig : "");
}
else
sprintf (growstring(&tptr, 25 + strlen (lp->destination)), ",Connect=%s%s", lp->destination, ((lp->mp->notelnet != lp->notelnet) && (!lp->datagram)) ? (lp->notelnet ? ";notelnet" : ";telnet") : "");
}
if (lp->txlogname)
sprintf (growstring(&tptr, 12 + strlen (lp->txlogname)), ",Log=%s", lp->txlogname);
if (lp->loopback)
sprintf (growstring(&tptr, 12 ), ",Loopback");
}
if (*tptr == '\0') {
free (tptr);
tptr = NULL;
}
return tptr;
}
/*
Set the connection polling interval
*/
t_stat tmxr_connection_poll_interval (TMXR *mp, uint32 seconds)
{
if (0 == seconds)
return SCPE_ARG;
mp->poll_interval = seconds;
return SCPE_OK;
}
/* Poll for new connection
Called from unit service routine to test for new connection
Inputs:
*mp = pointer to terminal multiplexer descriptor
Outputs:
line number activated, -1 if none
If a connection order is defined for the descriptor, and the first value is
not -1 (indicating default order), then the order array is used to find an
open line. Otherwise, a search is made of all lines in numerical sequence.
*/
int32 tmxr_poll_conn (TMXR *mp)
{
SOCKET newsock;
TMLN *lp;
int32 *op;
int32 i, j;
char *address;
char msg[512];
uint32 poll_time = sim_os_msec ();
if (mp->last_poll_time == 0) { /* first poll initializations */
UNIT *uptr = mp->uptr;
if (!uptr) /* Attached ? */
return -1; /* No connections are possinle! */
uptr->tmxr = (void *)mp; /* Connect UNIT to TMXR */
uptr->dynflags |= UNIT_TM_POLL; /* Tag as polling unit */
if (mp->poll_interval == 0) /* Assure reasonable polling interval */
mp->poll_interval = TMXR_DEFAULT_CONNECT_POLL_INTERVAL;
if (!(uptr->dynflags & TMUF_NOASYNCH)) /* if asynch not disabled */
sim_cancel (uptr);
for (i=0; i < mp->lines; i++) {
if (mp->ldsc[i].uptr) {
mp->ldsc[i].uptr->tmxr = (void *)mp; /* Connect UNIT to TMXR */
mp->ldsc[i].uptr->dynflags |= UNIT_TM_POLL; /* Tag as polling unit */
}
else
mp->ldsc[i].uptr = uptr; /* default line input polling to primary poll unit */
if (mp->ldsc[i].o_uptr) {
mp->ldsc[i].o_uptr->tmxr = (void *)mp; /* Connect UNIT to TMXR */
mp->ldsc[i].o_uptr->dynflags |= UNIT_TM_POLL;/* Tag as polling unit */
}
else
mp->ldsc[i].o_uptr = uptr; /* default line output polling to primary poll unit */
if (!(mp->uptr->dynflags & TMUF_NOASYNCH)) { /* if asynch not disabled */
if (mp->ldsc[i].uptr)
sim_cancel (mp->ldsc[i].uptr);
if (mp->ldsc[i].o_uptr)
sim_cancel (mp->ldsc[i].o_uptr);
}
}
}
if ((poll_time - mp->last_poll_time) < mp->poll_interval*1000)
return -1; /* too soon to try */
srand((unsigned int)poll_time);
tmxr_debug_trace (mp, "tmxr_poll_conn()");
mp->last_poll_time = poll_time;
/* Check for a pending Telnet/tcp connection */
if (mp->master) {
if (mp->ring_sock != INVALID_SOCKET) { /* Use currently 'ringing' socket if one is active */
newsock = mp->ring_sock;
mp->ring_sock = INVALID_SOCKET;
address = mp->ring_ipad;
mp->ring_ipad = NULL;
}
else
newsock = sim_accept_conn_ex (mp->master, &address, (mp->packet ? SIM_SOCK_OPT_NODELAY : 0));/* poll connect */
if (newsock != INVALID_SOCKET) { /* got a live one? */
sprintf (msg, "tmxr_poll_conn() - Connection from %s", address);
tmxr_debug_connect (mp, msg);
op = mp->lnorder; /* get line connection order list pointer */
i = mp->lines; /* play it safe in case lines == 0 */
++mp->sessions; /* count the new session */
for (j = 0; j < mp->lines; j++, i++) { /* find next avail line */
if (op && (*op >= 0) && (*op < mp->lines)) /* order list present and valid? */
i = *op++; /* get next line in list to try */
else /* no list or not used or range error */
i = j; /* get next sequential line */
lp = mp->ldsc + i; /* get pointer to line descriptor */
if ((lp->conn == FALSE) && /* is the line available? */
(lp->destination == NULL) &&
(lp->master == 0) &&
(lp->ser_connect_pending == FALSE) &&
(lp->modem_control ? ((lp->modembits & TMXR_MDM_DTR) != 0) : TRUE))
break; /* yes, so stop search */
}
if (i >= mp->lines) { /* all busy? */
int32 ringable_count = 0;
for (j = 0; j < mp->lines; j++, i++) { /* find next avail line */
lp = mp->ldsc + j; /* get pointer to line descriptor */
if ((lp->conn == FALSE) && /* is the line available? */
(lp->destination == NULL) &&
(lp->master == 0) &&
(lp->ser_connect_pending == FALSE) &&
((lp->modembits & TMXR_MDM_DTR) == 0)) {
++ringable_count;
tmxr_set_get_modem_bits (lp, TMXR_MDM_RNG, 0, NULL);
tmxr_debug_connect_line (lp, "tmxr_poll_conn() - Ringing line");
}
}
if (ringable_count > 0) {
if (mp->ring_start_time == 0) {
mp->ring_start_time = poll_time;
mp->ring_sock = newsock;
mp->ring_ipad = address;
}
else {
if ((poll_time - mp->ring_start_time) < TMXR_MODEM_RING_TIME*1000) {
mp->ring_sock = newsock;
mp->ring_ipad = address;
}
else { /* Timeout waiting for DTR */
int ln;
/* turn off pending ring signals */
for (ln = 0; ln < lp->mp->lines; ln++) {
TMLN *tlp = lp->mp->ldsc + ln;
if (((tlp->destination == NULL) && (tlp->master == 0)) &&
(tlp->modembits & TMXR_MDM_RNG) && (tlp->conn == FALSE))
tlp->modembits &= ~TMXR_MDM_RNG;
}
mp->ring_start_time = 0;
tmxr_msg (newsock, "No answer on any connection\r\n");
tmxr_debug_connect (mp, "tmxr_poll_conn() - No Answer - All connections busy");
sim_close_sock (newsock);
free (address);
}
}
}
else {
tmxr_msg (newsock, "All connections busy\r\n");
tmxr_debug_connect (mp, "tmxr_poll_conn() - All connections busy");
sim_close_sock (newsock);
free (address);
}
}
else {
lp = mp->ldsc + i; /* get line desc */
lp->conn = TRUE; /* record connection */
lp->sock = newsock; /* save socket */
lp->ipad = address; /* ip address */
tmxr_init_line (lp); /* init line */
lp->notelnet = mp->notelnet; /* apply mux default telnet setting */
if (!lp->notelnet) {
sim_write_sock (newsock, (char *)mantra, sizeof(mantra));
tmxr_debug (TMXR_DBG_XMT, lp, "Sending", (char *)mantra, sizeof(mantra));
lp->telnet_sent_opts = (uint8 *)realloc (lp->telnet_sent_opts, 256);
memset (lp->telnet_sent_opts, 0, 256);
}
tmxr_report_connection (mp, lp);
lp->cnms = sim_os_msec (); /* time of connection */
return i;
}
} /* end if newsock */
}
/* Look for per line listeners or outbound connecting sockets */
for (i = 0; i < mp->lines; i++) { /* check each line in sequence */
int j, r = rand();
lp = mp->ldsc + i; /* get pointer to line descriptor */
/* Check for pending serial port connection notification */
if (lp->ser_connect_pending) {
lp->ser_connect_pending = FALSE;
lp->conn = TRUE;
return i;
}
/* Don't service network connections for loopbacked lines */
if (lp->loopback)
continue;
/* If two simulators are configured with symmetric virtual null modem
cables pointing at each other, there may be a problem establishing
a connection if both systems happen to be checking for the success
of their connections in the exact same order. They can each observe
success in their respective outgoing connections, which haven't
actually been 'accept'ed on the peer end of the connection.
We address this issue by checking for the success of an outgoing
connection and the arrival of an incoming one in a random order.
*/
for (j=0; j<2; j++)
switch ((j+r)&1) {
case 0:
if (lp->connecting) { /* connecting? */
char *sockname, *peername;
switch (sim_check_conn(lp->connecting, FALSE))
{
case 1: /* successful connection */
lp->conn = TRUE; /* record connection */
lp->sock = lp->connecting; /* it now looks normal */
lp->connecting = 0;
lp->ipad = (char *)realloc (lp->ipad, 1+strlen (lp->destination));
strcpy (lp->ipad, lp->destination);
lp->cnms = sim_os_msec ();
sim_getnames_sock (lp->sock, &sockname, &peername);
sprintf (msg, "tmxr_poll_conn() - Outgoing Line Connection to %s (%s->%s) established", lp->destination, sockname, peername);
tmxr_debug_connect_line (lp, msg);
free (sockname);
free (peername);
return i;
case -1: /* failed connection */
sprintf (msg, "tmxr_poll_conn() - Outgoing Line Connection to %s failed", lp->destination);
tmxr_debug_connect_line (lp, msg);
tmxr_reset_ln (lp); /* retry */
break;
}
}
break;
case 1:
if (lp->master) { /* Check for a pending Telnet/tcp connection */
while (INVALID_SOCKET != (newsock = sim_accept_conn_ex (lp->master, &address, (lp->packet ? SIM_SOCK_OPT_NODELAY : 0)))) {/* got a live one? */
char *sockname, *peername;
sim_getnames_sock (newsock, &sockname, &peername);
sprintf (msg, "tmxr_poll_conn() - Incoming Line Connection from %s (%s->%s)", address, peername, sockname);
tmxr_debug_connect_line (lp, msg);
free (sockname);
free (peername);
++mp->sessions; /* count the new session */
if (lp->destination) { /* Virtual Null Modem Cable? */
char host[CBUFSIZE];
if (sim_parse_addr (lp->destination, host, sizeof(host), NULL, NULL, 0, NULL, address)) {
tmxr_msg (newsock, "Rejecting connection from unexpected source\r\n");
sprintf (msg, "tmxr_poll_conn() - Rejecting line connection from: %s, Expected: %s", address, host);
tmxr_debug_connect_line (lp, msg);
sim_close_sock (newsock);
free (address);
continue; /* Try for another connection */
}
if (lp->connecting) {
sprintf (msg, "tmxr_poll_conn() - aborting outgoing line connection attempt to: %s", lp->destination);
tmxr_debug_connect_line (lp, msg);
sim_close_sock (lp->connecting); /* abort our as yet unconnnected socket */
lp->connecting = 0;
}
}
if (lp->conn == FALSE) { /* is the line available? */
if ((!lp->modem_control) || (lp->modembits & TMXR_MDM_DTR)) {
lp->conn = TRUE; /* record connection */
lp->sock = newsock; /* save socket */
lp->ipad = address; /* ip address */
tmxr_init_line (lp); /* init line */
if (!lp->notelnet) {
sim_write_sock (newsock, (char *)mantra, sizeof(mantra));
tmxr_debug (TMXR_DBG_XMT, lp, "Sending", (char *)mantra, sizeof(mantra));
lp->telnet_sent_opts = (uint8 *)realloc (lp->telnet_sent_opts, 256);
memset (lp->telnet_sent_opts, 0, 256);
}
tmxr_report_connection (mp, lp);
lp->cnms = sim_os_msec (); /* time of connection */
return i;
}
else {
tmxr_msg (newsock, "Line connection not available\r\n");
tmxr_debug_connect_line (lp, "tmxr_poll_conn() - Line connection not available");
sim_close_sock (newsock);
free (address);
}
}
else {
tmxr_msg (newsock, "Line connection busy\r\n");
tmxr_debug_connect_line (lp, "tmxr_poll_conn() - Line connection busy");
sim_close_sock (newsock);
free (address);
}
}
}
break;
}
/* Check for needed outgoing connection initiation */
if (lp->destination && (!lp->sock) && (!lp->connecting) && (!lp->serport) &&
(!lp->modem_control || (lp->modembits & TMXR_MDM_DTR))) {
sprintf (msg, "tmxr_poll_conn() - establishing outgoing connection to: %s", lp->destination);
tmxr_debug_connect_line (lp, msg);
lp->connecting = sim_connect_sock_ex (lp->datagram ? lp->port : NULL, lp->destination, "localhost", NULL, (lp->datagram ? SIM_SOCK_OPT_DATAGRAM : 0) | (lp->mp->packet ? SIM_SOCK_OPT_NODELAY : 0));
}
}
return -1; /* no new connections made */
}
/* Reset a line.
The telnet/tcp or serial session associated with multiplexer descriptor "mp" and
line descriptor "lp" is disconnected. An associated tcp socket is
closed; a serial port is closed if the closeserial parameter is true, otherwise
for non modem control serial lines DTR is dropped and raised again after 500ms
to signal the attached serial device.
*/
static t_stat tmxr_reset_ln_ex (TMLN *lp, t_bool closeserial)
{
char msg[512];
tmxr_debug_trace_line (lp, "tmxr_reset_ln_ex()");
if (lp->txlog)
fflush (lp->txlog); /* flush log */
tmxr_send_buffered_data (lp); /* send any buffered data */
sprintf (msg, "tmxr_reset_ln_ex(%s)", closeserial ? "TRUE" : "FALSE");
tmxr_debug_connect_line (lp, msg);
if (lp->serport) {
if (closeserial) {
sim_close_serial (lp->serport);
lp->serport = 0;
lp->ser_connect_pending = FALSE;
free (lp->destination);
lp->destination = NULL;
free (lp->serconfig);
lp->serconfig = NULL;
lp->cnms = 0;
lp->xmte = 1;
}
else
if (!lp->modem_control) { /* serial connection? */
sim_control_serial (lp->serport, 0, TMXR_MDM_DTR|TMXR_MDM_RTS, NULL);/* drop DTR and RTS */
sim_os_ms_sleep (TMXR_DTR_DROP_TIME);
sim_control_serial (lp->serport, TMXR_MDM_DTR|TMXR_MDM_RTS, 0, NULL);/* raise DTR and RTS */
}
}
else /* Telnet connection */
if (lp->sock) {
sim_close_sock (lp->sock); /* close socket */
free (lp->telnet_sent_opts);
lp->telnet_sent_opts = NULL;
lp->sock = 0;
lp->conn = FALSE;
lp->cnms = 0;
lp->xmte = 1;
}
free(lp->ipad);
lp->ipad = NULL;
if ((lp->destination) && (!lp->serport)) {
if (lp->connecting) {
sim_close_sock (lp->connecting);
lp->connecting = 0;
}
if ((!lp->modem_control) || (lp->modembits & TMXR_MDM_DTR)) {
sprintf (msg, "tmxr_reset_ln_ex() - connecting to %s", lp->destination);
tmxr_debug_connect_line (lp, msg);
lp->connecting = sim_connect_sock_ex (lp->datagram ? lp->port : NULL, lp->destination, "localhost", NULL, (lp->datagram ? SIM_SOCK_OPT_DATAGRAM : 0) | (lp->mp->packet ? SIM_SOCK_OPT_NODELAY : 0));
}
}
tmxr_init_line (lp); /* initialize line state */
return SCPE_OK;
}
t_stat tmxr_close_ln (TMLN *lp)
{
tmxr_debug_trace_line (lp, "tmxr_close_ln()");
tmxr_debug_connect_line (lp, "tmxr_close_ln()");
return tmxr_reset_ln_ex (lp, TRUE);
}
t_stat tmxr_reset_ln (TMLN *lp)
{
tmxr_debug_trace_line (lp, "tmxr_reset_ln()");
return tmxr_reset_ln_ex (lp, FALSE);
}
/* Enable modem control pass thru
Inputs:
none
Output:
none
Implementation note:
1 Calling this API disables any actions on the part of this
library to directly manipulate DTR (&RTS) on serial ports.
2 Calling this API enables the tmxr_set_get_modem_bits and
tmxr_set_config_line APIs.
*/
static t_stat tmxr_clear_modem_control_passthru_state (TMXR *mp, t_bool state)
{
int i;
if (mp->modem_control == state)
return SCPE_OK;
if (mp->master)
return SCPE_ALATT;
for (i=0; i<mp->lines; ++i) {
TMLN *lp;
lp = mp->ldsc + i;
if ((lp->master) ||
(lp->sock) ||
(lp->connecting) ||
(lp->serport))
return SCPE_ALATT;
}
mp->modem_control = state;
for (i=0; i<mp->lines; ++i)
mp->ldsc[i].modem_control = state;
return SCPE_OK;
}
t_stat tmxr_set_modem_control_passthru (TMXR *mp)
{
return tmxr_clear_modem_control_passthru_state (mp, TRUE);
}
/* Disable modem control pass thru
Inputs:
none
Output:
none
Implementation note:
1 Calling this API enables this library's direct manipulation
of DTR (&RTS) on serial ports.
2 Calling this API disables the tmxr_set_get_modem_bits and
tmxr_set_config_line APIs.
3 This API will only change the state of the modem control processing
of this library if there are no listening ports, serial ports or
outgoing connecctions associated with the specified multiplexer
*/
t_stat tmxr_clear_modem_control_passthru (TMXR *mp)
{
return tmxr_clear_modem_control_passthru_state (mp, FALSE);
}
/* Declare that tmxr_set_config_line is used.
This would best be called in a device reset routine and left set.
If the device implementor wants to make this behavior a user option
we've got to reject the attempt to set or clear this mode if any
ports on the MUX are attached.
*/
t_stat tmxr_set_port_speed_control (TMXR *mp)
{
int i;
if (!mp->port_speed_control && mp->uptr && !(mp->uptr->flags & UNIT_ATT))
return sim_messagef (SCPE_ALATT, "Can't change speed mode while attached.\n:");
mp->port_speed_control = TRUE;
for (i=0; i<mp->lines; ++i)
mp->ldsc[i].port_speed_control = mp->port_speed_control;
return SCPE_OK;
}
/* Declare that tmxr_set_config_line is not used.
This should be only be called after a previous call to
tmxr_set_port_speed_control since the default is cleared. It can not
be called if any ports on the device are attached.
*/
t_stat tmxr_clear_port_speed_control (TMXR *mp)
{
int i;
if (mp->port_speed_control && mp->uptr && !(mp->uptr->flags & UNIT_ATT))
return sim_messagef (SCPE_ALATT, "Can't change speed mode while attached.\n:");
mp->port_speed_control = FALSE;
for (i=0; i<mp->lines; ++i)
mp->ldsc[i].port_speed_control = mp->port_speed_control;
return SCPE_OK;
}
/* Declare that tmxr_set_config_line is used for line.
This would best be called in a device reset routine and left set.
If the device implementor wants to make this behavior a user option
we've got to reject the attempt to set or clear this mode if any
ports on the MUX are attached.
*/
t_stat tmxr_set_line_port_speed_control (TMXR *mp, int line)
{
if (mp->uptr && !(mp->uptr->flags & UNIT_ATT))
return sim_messagef (SCPE_ALATT, "Can't change speed mode while attached.\n:");
if (line >= mp->lines)
return sim_messagef (SCPE_ARG, "Invalid line for multiplexer: %d\n", line);
mp->ldsc[line].port_speed_control = TRUE;
return SCPE_OK;
}
/* Declare that tmxr_set_config_line is not used for line.
This should be only be called after a previous call to
tmxr_set_port_speed_control since the default is cleared. It can not
be called if any ports on the device are attached.
*/
t_stat tmxr_clear_line_port_speed_control (TMXR *mp, int line)
{
if (mp->uptr && !(mp->uptr->flags & UNIT_ATT))
return sim_messagef (SCPE_ALATT, "Can't change speed mode while attached.\n:");
if (line >= mp->lines)
return sim_messagef (SCPE_ARG, "Invalid line for multiplexer: %d\n", line);
mp->ldsc[line].port_speed_control = FALSE;
return SCPE_OK;
}
/* Manipulate the modem control bits of a specific line
Inputs:
*lp = pointer to terminal line descriptor
bits_to_set TMXR_MDM_DTR and/or TMXR_MDM_RTS as desired
bits_to_clear TMXR_MDM_DTR and/or TMXR_MDM_RTS as desired
Output:
incoming_bits if non NULL, returns the current stat of DCD,
RNG, CTS and DSR along with the current state
of DTR and RTS
Implementation note:
If a line is connected to a serial port, then these values affect
and reflect the state of the serial port. If the line is connected
to a network socket (or could be) then the network session state is
set, cleared and/or returned.
*/
t_stat tmxr_set_get_modem_bits (TMLN *lp, int32 bits_to_set, int32 bits_to_clear, int32 *incoming_bits)
{
int32 before_modem_bits, incoming_state;
DEVICE *dptr;
tmxr_debug_trace_line (lp, "tmxr_set_get_modem_bits()");
if ((bits_to_set & ~(TMXR_MDM_OUTGOING)) || /* Assure only settable bits */
(bits_to_clear & ~(TMXR_MDM_OUTGOING)) ||
(bits_to_set & bits_to_clear)) /* and can't set and clear the same bits */
return SCPE_ARG;
before_modem_bits = lp->modembits;
lp->modembits |= bits_to_set;
lp->modembits &= ~(bits_to_clear | TMXR_MDM_INCOMING);
if ((lp->sock) || (lp->serport) || (lp->loopback)) {
if (lp->modembits & TMXR_MDM_DTR) {
incoming_state = TMXR_MDM_DSR;
if (lp->modembits & TMXR_MDM_RTS)
incoming_state |= TMXR_MDM_CTS;
if (lp->halfduplex) {
if (incoming_state & TMXR_MDM_CTS)
incoming_state |= TMXR_MDM_DCD;
}
else
incoming_state |= TMXR_MDM_DCD;
}
else
incoming_state = TMXR_MDM_DCD | TMXR_MDM_DSR | ((lp->modembits & TMXR_MDM_DTR) ? 0 : TMXR_MDM_RNG);
}
else {
if (((before_modem_bits & TMXR_MDM_DTR) == 0) && /* Upward transition of DTR? */
((lp->modembits & TMXR_MDM_DTR) != 0) &&
(lp->conn == FALSE) && /* Not connected */
(lp->modembits & TMXR_MDM_RNG)) { /* and Ring Signal Present */
if ((lp->destination == NULL) &&
(lp->master == 0) &&
(lp->mp && (lp->mp->ring_sock))) {
int ln;
lp->conn = TRUE; /* record connection */
lp->sock = lp->mp->ring_sock; /* save socket */
lp->mp->ring_sock = INVALID_SOCKET;
lp->ipad = lp->mp->ring_ipad; /* ip address */
lp->mp->ring_ipad = NULL;
lp->mp->ring_start_time = 0;
tmxr_init_line (lp); /* init line */
lp->notelnet = lp->mp->notelnet; /* apply mux default telnet setting */
if (!lp->notelnet) {
sim_write_sock (lp->sock, (char *)mantra, sizeof(mantra));
tmxr_debug (TMXR_DBG_XMT, lp, "Sending", (char *)mantra, sizeof(mantra));
lp->telnet_sent_opts = (uint8 *)realloc (lp->telnet_sent_opts, 256);
memset (lp->telnet_sent_opts, 0, 256);
}
tmxr_report_connection (lp->mp, lp);
lp->cnms = sim_os_msec (); /* time of connection */
lp->modembits &= ~TMXR_MDM_RNG; /* turn off ring on this line*/
/* turn off other pending ring signals */
for (ln = 0; ln < lp->mp->lines; ln++) {
TMLN *tlp = lp->mp->ldsc + ln;
if (((tlp->destination == NULL) && (tlp->master == 0)) &&
(tlp->modembits & TMXR_MDM_RNG) && (tlp->conn == FALSE))
tlp->modembits &= ~TMXR_MDM_RNG;
}
}
}
if ((lp->master) || (lp->mp && lp->mp->master) ||
(lp->port && lp->destination))
incoming_state = TMXR_MDM_DSR;
else
incoming_state = 0;
}
lp->modembits |= incoming_state;
dptr = (lp->dptr ? lp->dptr : (lp->mp ? lp->mp->dptr : NULL));
if ((lp->modembits != before_modem_bits) && (sim_deb && lp->mp && dptr)) {
sim_debug_bits (TMXR_DBG_MDM, dptr, tmxr_modem_bits, before_modem_bits, lp->modembits, FALSE);
sim_debug (TMXR_DBG_MDM, dptr, " - Line %d - %p\n", (int)(lp-lp->mp->ldsc), lp->txb);
}
if (incoming_bits)
*incoming_bits = lp->modembits;
if (lp->mp && lp->modem_control) { /* This API ONLY works on modem_control enabled multiplexer lines */
if (bits_to_set | bits_to_clear) { /* Anything to do? */
if (lp->loopback) {
if ((lp->modembits ^ before_modem_bits) & TMXR_MDM_DTR) { /* DTR changed? */
lp->ser_connect_pending = (lp->modembits & TMXR_MDM_DTR);
lp->conn = !(lp->modembits & TMXR_MDM_DTR);
}
return SCPE_OK;
}
if (lp->serport)
return sim_control_serial (lp->serport, bits_to_set, bits_to_clear, incoming_bits);
if ((lp->sock) || (lp->connecting)) {
if ((before_modem_bits & bits_to_clear & TMXR_MDM_DTR) != 0) { /* drop DTR? */
if (lp->sock)
tmxr_report_disconnection (lp); /* report closure */
tmxr_reset_ln (lp);
}
}
else {
if ((lp->destination) && /* Virtual Null Modem Cable */
(bits_to_set & ~before_modem_bits & /* and DTR being Raised */
TMXR_MDM_DTR)) {
char msg[512];
sprintf (msg, "tmxr_set_get_modem_bits() - establishing outgoing connection to: %s", lp->destination);
tmxr_debug_connect_line (lp, msg);
lp->connecting = sim_connect_sock_ex (lp->datagram ? lp->port : NULL, lp->destination, "localhost", NULL, (lp->datagram ? SIM_SOCK_OPT_DATAGRAM : 0) | (lp->mp->packet ? SIM_SOCK_OPT_NODELAY : 0));
}
}
}
return SCPE_OK;
}
if ((lp->sock) || (lp->connecting)) {
if ((before_modem_bits & bits_to_clear & TMXR_MDM_DTR) != 0) { /* drop DTR? */
if (lp->sock)
tmxr_report_disconnection (lp); /* report closure */
tmxr_reset_ln (lp);
}
}
if ((lp->serport) && (!lp->loopback))
sim_control_serial (lp->serport, 0, 0, incoming_bits);
return SCPE_INCOMP;
}
/* Enable or Disable loopback mode on a line
Inputs:
lp - the line to change
enable_loopback - enable or disable flag
Output:
none
Implementation note:
1) When enabling loopback mode, this API will disconnect any currently
connected TCP or Serial session.
2) When disabling loopback mode, prior network connections and/or
serial port connections will be restored.
*/
t_stat tmxr_set_line_loopback (TMLN *lp, t_bool enable_loopback)
{
if (lp->loopback == (enable_loopback != FALSE))
return SCPE_OK; /* Nothing to do */
lp->loopback = (enable_loopback != FALSE);
if (lp->loopback) {
lp->lpbsz = lp->rxbsz;
lp->lpb = (char *)realloc(lp->lpb, lp->lpbsz);
lp->lpbcnt = lp->lpbpi = lp->lpbpr = 0;
if (!lp->conn)
lp->ser_connect_pending = TRUE;
}
else {
free (lp->lpb);
lp->lpb = NULL;
lp->lpbsz = 0;
}
return SCPE_OK;
}
t_bool tmxr_get_line_loopback (TMLN *lp)
{
return (lp->loopback != FALSE);
}
/* Enable or Disable halfduplex mode on a line
Inputs:
lp - the line to change
enable_halfduplex - enable or disable flag
Output:
none
When a network connected line is in halfduplex mode, DCD modem signal
track with CTS. When not in halfduplex mode the DCD modem signal for
network connected lines tracks with DSR.
*/
t_stat tmxr_set_line_halfduplex (TMLN *lp, t_bool enable_halfduplex)
{
if (lp->halfduplex == (enable_halfduplex != FALSE))
return SCPE_OK; /* Nothing to do */
lp->halfduplex = (enable_halfduplex != FALSE);
return SCPE_OK;
}
t_bool tmxr_get_line_halfduplex (TMLN *lp)
{
return (lp->halfduplex != FALSE);
}
t_stat tmxr_set_config_line (TMLN *lp, CONST char *config)
{
t_stat r;
tmxr_debug_trace_line (lp, "tmxr_set_config_line()");
if (lp->serport) {
r = sim_config_serial (lp->serport, config);
if (r == SCPE_OK)
r = tmxr_set_line_speed (lp, config);
}
else {
lp->serconfig = (char *)realloc (lp->serconfig, 1 + strlen (config));
strcpy (lp->serconfig, config);
r = tmxr_set_line_speed (lp, lp->serconfig);;
if (r != SCPE_OK) {
free (lp->serconfig);
lp->serconfig = NULL;
}
}
if ((r == SCPE_OK) && (lp->mp) && (lp->mp->uptr)) /* Record port state for proper restore */
lp->mp->uptr->filename = tmxr_mux_attach_string (lp->mp->uptr->filename, lp->mp);
return r;
}
/* Get character from specific line
Inputs:
*lp = pointer to terminal line descriptor
Output:
(TMXR_VALID | char) or 0 if no data is currently available
on the specified line.
Implementation note:
1. If a line break was detected coincident with the current character, the
receive break status associated with the character is cleared, and
SCPE_BREAK is ORed into the return value.
*/
int32 tmxr_getc_ln (TMLN *lp)
{
int32 j;
t_stat val = 0;
uint32 tmp;
double sim_gtime_now = sim_gtime ();
tmxr_debug_trace_line (lp, "tmxr_getc_ln()");
if (((lp->conn || lp->txbfd) && lp->rcve) && /* (conn or buffered) & enb & */
((!lp->rxbps) || /* (!rate limited || enough time passed)? */
(sim_gtime_now >= lp->rxnexttime))) {
if (!sim_send_poll_data (&lp->send, &val)) { /* injected input characters available? */
j = lp->rxbpi - lp->rxbpr; /* # input chrs */
if (j) { /* any? */
tmp = lp->rxb[lp->rxbpr]; /* get char */
val = TMXR_VALID | (tmp & 0377); /* valid + chr */
if (lp->rbr[lp->rxbpr]) { /* break? */
lp->rbr[lp->rxbpr] = 0; /* clear status */
val = val | SCPE_BREAK; /* indicate to caller */
}
lp->rxbpr = lp->rxbpr + 1; /* adv pointer */
}
}
} /* end if conn */
if (lp->rxbpi == lp->rxbpr) /* empty? zero ptrs */
lp->rxbpi = lp->rxbpr = 0;
if (val) { /* Got something? */
if (lp->rxbps)
lp->rxnexttime = floor (sim_gtime_now + ((lp->rxdeltausecs * sim_timer_inst_per_sec ()) / USECS_PER_SECOND));
else
lp->rxnexttime = floor (sim_gtime_now + ((lp->mp->uptr->wait * sim_timer_inst_per_sec ()) / USECS_PER_SECOND));
}
tmxr_debug_return(lp, val);
return val;
}
/* Get packet from specific line
Inputs:
*lp = pointer to terminal line descriptor
**pbuf = pointer to pointer of packet contents
*psize = pointer to packet size
frame_byte - byte which separates packets in the tcp stream
(0 means no separation character)
Output:
SCPE_LOST link state lost
SCPE_OK Packet returned OR no packet available
Implementation notes:
1. If a packet is not yet available, then the pbuf address returned is
NULL, but success (SCPE_OK) is returned
*/
t_stat tmxr_get_packet_ln (TMLN *lp, const uint8 **pbuf, size_t *psize)
{
return tmxr_get_packet_ln_ex (lp, pbuf, psize, 0);
}
t_stat tmxr_get_packet_ln_ex (TMLN *lp, const uint8 **pbuf, size_t *psize, uint8 frame_byte)
{
int32 c;
size_t pktsize;
size_t fc_size = (frame_byte ? 1 : 0);
while (TMXR_VALID & (c = tmxr_getc_ln (lp))) {
if (lp->rxpboffset + 3 > lp->rxpbsize) {
lp->rxpbsize += 512;
lp->rxpb = (uint8 *)realloc (lp->rxpb, lp->rxpbsize);
}
if ((lp->rxpboffset == 0) && (fc_size) && (c != frame_byte)) {
tmxr_debug (TMXR_DBG_PRCV, lp, "Received Unexpected Framing Byte", (char *)&lp->rxpb[lp->rxpboffset], 1);
continue;
}
if ((lp->datagram) && (lp->rxpboffset == fc_size)) {
/* Datagram packet length is provided as a part of the natural datagram
delivery, for TCP lines, we read the packet length from the data stream.
So, here we stuff packet size into head of packet buffer so it looks like
it was delivered by TCP and the below return logic doesn't have to worry */
lp->rxpb[lp->rxpboffset++] = (uint8)(((1 + lp->rxbpi - lp->rxbpr) >> 8) & 0xFF);
lp->rxpb[lp->rxpboffset++] = (uint8)((1 + lp->rxbpi - lp->rxbpr) & 0xFF);
}
lp->rxpb[lp->rxpboffset++] = c & 0xFF;
if (lp->rxpboffset >= (2 + fc_size)) {
pktsize = (lp->rxpb[0+fc_size] << 8) | lp->rxpb[1+fc_size];
if (pktsize == (lp->rxpboffset - 2)) {
++lp->rxpcnt;
*pbuf = &lp->rxpb[2+fc_size];
*psize = pktsize;
lp->rxpboffset = 0;
tmxr_debug (TMXR_DBG_PRCV, lp, "Received Packet", (char *)&lp->rxpb[2+fc_size], pktsize);
return SCPE_OK;
}
}
}
*pbuf = NULL;
*psize = 0;
if (lp->conn)
return SCPE_OK;
return SCPE_LOST;
}
/* Poll for input
Inputs:
*mp = pointer to terminal multiplexer descriptor
Outputs: none
*/
void tmxr_poll_rx (TMXR *mp)
{
int32 i, nbytes, j;
TMLN *lp;
tmxr_debug_trace (mp, "tmxr_poll_rx()");
for (i = 0; i < mp->lines; i++) { /* loop thru lines */
lp = mp->ldsc + i; /* get line desc */
if (!(lp->sock || lp->serport || lp->loopback) ||
!(lp->rcve)) /* skip if not connected */
continue;
nbytes = 0;
if (lp->rxbpi == 0) /* need input? */
nbytes = tmxr_read (lp, /* yes, read */
lp->rxbsz - TMXR_GUARD); /* leave spc for Telnet cruft */
else if (lp->tsta) /* in Telnet seq? */
nbytes = tmxr_read (lp, /* yes, read to end */
lp->rxbsz - lp->rxbpi);
if (nbytes < 0) { /* line error? */
if (!lp->datagram) { /* ignore errors reading UDP sockets */
if (!lp->txbfd || lp->notelnet)
lp->txbpi = lp->txbpr = 0; /* Drop the data we already know we can't send */
tmxr_close_ln (lp); /* disconnect line */
}
}
else if (nbytes > 0) { /* if data rcvd */
tmxr_debug (TMXR_DBG_RCV, lp, "Received", &(lp->rxb[lp->rxbpi]), nbytes);
j = lp->rxbpi; /* start of data */
lp->rxbpi = lp->rxbpi + nbytes; /* adv pointers */
lp->rxcnt = lp->rxcnt + nbytes;
/* Examine new data, remove TELNET cruft before making input available */
if (!lp->notelnet) { /* Are we looking for telnet interpretation? */
for (; j < lp->rxbpi; ) { /* loop thru char */
u_char tmp = (u_char)lp->rxb[j]; /* get char */
switch (lp->tsta) { /* case tlnt state */
case TNS_NORM: /* normal */
if (tmp == TN_IAC) { /* IAC? */
lp->tsta = TNS_IAC; /* change state */
tmxr_rmvrc (lp, j); /* remove char */
break;
}
if ((tmp == TN_CR) && lp->dstb) /* CR, no bin */
lp->tsta = TNS_CRPAD; /* skip pad char */
j = j + 1; /* advance j */
break;
case TNS_IAC: /* IAC prev */
if (tmp == TN_IAC) { /* IAC + IAC */
lp->tsta = TNS_NORM; /* treat as normal */
j = j + 1; /* advance j */
break; /* keep IAC */
}
if (tmp == TN_BRK) { /* IAC + BRK? */
lp->tsta = TNS_NORM; /* treat as normal */
lp->rxb[j] = 0; /* char is null */
lp->rbr[j] = 1; /* flag break */
j = j + 1; /* advance j */
break;
}
switch (tmp) {
case TN_WILL: /* IAC + WILL? */
lp->tsta = TNS_WILL;
break;
case TN_WONT: /* IAC + WONT? */
lp->tsta = TNS_WONT;
break;
case TN_DO: /* IAC + DO? */
lp->tsta = TNS_DO;
break;
case TN_DONT: /* IAC + DONT? */
lp->tsta = TNS_SKIP; /* IAC + other */
break;
case TN_GA: case TN_EL: /* IAC + other 2 byte types */
case TN_EC: case TN_AYT:
case TN_AO: case TN_IP:
case TN_NOP:
lp->tsta = TNS_NORM; /* ignore */
break;
case TN_SB: /* IAC + SB sub-opt negotiation */
case TN_DATAMK: /* IAC + data mark */
case TN_SE: /* IAC + SE sub-opt end */
lp->tsta = TNS_NORM; /* ignore */
break;
}
tmxr_rmvrc (lp, j); /* remove char */
break;
case TNS_WILL: /* IAC+WILL prev */
if ((tmp == TN_STATUS) ||
(tmp == TN_TIMING) ||
(tmp == TN_NAOCRD) ||
(tmp == TN_NAOHTS) ||
(tmp == TN_NAOHTD) ||
(tmp == TN_NAOFFD) ||
(tmp == TN_NAOVTS) ||
(tmp == TN_NAOVTD) ||
(tmp == TN_NAOLFD) ||
(tmp == TN_EXTEND) ||
(tmp == TN_LOGOUT) ||
(tmp == TN_BM) ||
(tmp == TN_DET) ||
(tmp == TN_SENDLO) ||
(tmp == TN_TERMTY) ||
(tmp == TN_ENDREC) ||
(tmp == TN_TUID) ||
(tmp == TN_OUTMRK) ||
(tmp == TN_TTYLOC) ||
(tmp == TN_3270) ||
(tmp == TN_X3PAD) ||
(tmp == TN_NAWS) ||
(tmp == TN_TERMSP) ||
(tmp == TN_TOGFLO) ||
(tmp == TN_XDISPL) ||
(tmp == TN_ENVIRO) ||
(tmp == TN_AUTH) ||
(tmp == TN_ENCRYP) ||
(tmp == TN_NEWENV) ||
(tmp == TN_TN3270) ||
(tmp == TN_CHARST) ||
(tmp == TN_COMPRT) ||
(tmp == TN_KERMIT)) {
/* Reject (DONT) these 'uninteresting' options only one time to avoid loops */
if (0 == (lp->telnet_sent_opts[tmp] & TNOS_DONT)) {
lp->notelnet = TRUE; /* Temporarily disable so */
tmxr_putc_ln (lp, TN_IAC); /* IAC gets injected bare */
lp->notelnet = FALSE;
tmxr_putc_ln (lp, TN_DONT);
tmxr_putc_ln (lp, tmp);
lp->telnet_sent_opts[tmp] |= TNOS_DONT;/* Record DONT sent */
}
}
case TNS_WONT: /* IAC+WILL/WONT prev */
if (tmp == TN_BIN) { /* BIN? */
if (lp->tsta == TNS_WILL) {
lp->dstb = 0;
}
else {
lp->dstb = 1;
}
}
tmxr_rmvrc (lp, j); /* remove it */
lp->tsta = TNS_NORM; /* next normal */
break;
/* Negotiation with the HP terminal emulator "QCTerm" is not working.
QCTerm says "WONT BIN" but sends bare CRs. RFC 854 says:
Note that "CR LF" or "CR NUL" is required in both directions
(in the default ASCII mode), to preserve the symmetry of the
NVT model. ...The protocol requires that a NUL be inserted
following a CR not followed by a LF in the data stream.
Until full negotiation is implemented, we work around the problem
by checking the character following the CR in non-BIN mode and
strip it only if it is LF or NUL. This should not affect
conforming clients.
*/
case TNS_CRPAD: /* only LF or NUL should follow CR */
lp->tsta = TNS_NORM; /* next normal */
if ((tmp == TN_LF) || /* CR + LF ? */
(tmp == TN_NUL)) /* CR + NUL? */
tmxr_rmvrc (lp, j); /* remove it */
break;
case TNS_DO: /* pending DO request */
if ((tmp == TN_STATUS) ||
(tmp == TN_TIMING) ||
(tmp == TN_NAOCRD) ||
(tmp == TN_NAOHTS) ||
(tmp == TN_NAOHTD) ||
(tmp == TN_NAOFFD) ||
(tmp == TN_NAOVTS) ||
(tmp == TN_NAOVTD) ||
(tmp == TN_NAOLFD) ||
(tmp == TN_EXTEND) ||
(tmp == TN_LOGOUT) ||
(tmp == TN_BM) ||
(tmp == TN_DET) ||
(tmp == TN_SENDLO) ||
(tmp == TN_TERMTY) ||
(tmp == TN_ENDREC) ||
(tmp == TN_TUID) ||
(tmp == TN_OUTMRK) ||
(tmp == TN_TTYLOC) ||
(tmp == TN_3270) ||
(tmp == TN_X3PAD) ||
(tmp == TN_NAWS) ||
(tmp == TN_TERMSP) ||
(tmp == TN_TOGFLO) ||
(tmp == TN_XDISPL) ||
(tmp == TN_ENVIRO) ||
(tmp == TN_AUTH) ||
(tmp == TN_ENCRYP) ||
(tmp == TN_NEWENV) ||
(tmp == TN_TN3270) ||
(tmp == TN_CHARST) ||
(tmp == TN_COMPRT) ||
(tmp == TN_KERMIT)) {
/* Reject (WONT) these 'uninteresting' options only one time to avoid loops */
if (0 == (lp->telnet_sent_opts[tmp] & TNOS_WONT)) {
lp->notelnet = TRUE; /* Temporarily disable so */
tmxr_putc_ln (lp, TN_IAC); /* IAC gets injected bare */
lp->notelnet = FALSE;
tmxr_putc_ln (lp, TN_WONT);
tmxr_putc_ln (lp, tmp);
if (lp->conn) /* Still connected ? */
lp->telnet_sent_opts[tmp] |= TNOS_WONT;/* Record WONT sent */
}
}
case TNS_SKIP: default: /* skip char */
tmxr_rmvrc (lp, j); /* remove char */
lp->tsta = TNS_NORM; /* next normal */
break;
} /* end case state */
} /* end for char */
if (nbytes != (lp->rxbpi-lp->rxbpr)) {
tmxr_debug (TMXR_DBG_RCV, lp, "Remaining", &(lp->rxb[lp->rxbpr]), lp->rxbpi-lp->rxbpr);
}
}
} /* end else nbytes */
} /* end for lines */
for (i = 0; i < mp->lines; i++) { /* loop thru lines */
lp = mp->ldsc + i; /* get line desc */
if (lp->rxbpi == lp->rxbpr) /* if buf empty, */
lp->rxbpi = lp->rxbpr = 0; /* reset pointers */
} /* end for */
}
int32 tmxr_rqln_bare (const TMLN *lp, t_bool speed)
{
if (speed) {
if (lp->send.extoff < lp->send.insoff) {/* buffered SEND data? */
if (sim_gtime () < lp->send.next_time)
return 0;
else
return lp->send.delay ? 1 : (lp->send.insoff - lp->send.extoff);
}
if (lp->rxbps) { /* consider speed and rate limiting? */
if (sim_gtime () < lp->rxnexttime) /* too soon? */
return 0;
else
return 1;
}
}
return (lp->rxbpi - lp->rxbpr + ((lp->rxbpi < lp->rxbpr)? lp->rxbsz: 0));
}
/* Return count of available characters ready to be read for line */
int32 tmxr_rqln (const TMLN *lp)
{
return tmxr_rqln_bare (lp, TRUE);
}
int32 tmxr_input_pending_ln (TMLN *lp)
{
return (lp->rxbpi - lp->rxbpr);
}
/* Store character in line buffer
Inputs:
*lp = pointer to line descriptor
chr = character
Outputs:
status = ok, connection lost, or stall
Implementation note:
1. If the line is not connected, SCPE_LOST is returned.
*/
t_stat tmxr_putc_ln (TMLN *lp, int32 chr)
{
if ((lp->conn == FALSE) && /* no conn & not buffered telnet? */
(!lp->txbfd || lp->notelnet)) {
++lp->txdrp; /* lost */
return SCPE_LOST;
}
tmxr_debug_trace_line (lp, "tmxr_putc_ln()");
#define TXBUF_AVAIL(lp) ((lp->serport ? 2: lp->txbsz) - tmxr_tqln (lp))
#define TXBUF_CHAR(lp, c) { \
lp->txb[lp->txbpi++] = (char)(c); \
lp->txbpi %= lp->txbsz; \
if (lp->txbpi == lp->txbpr) \
lp->txbpr = (1+lp->txbpr)%lp->txbsz, ++lp->txdrp; \
}
if ((lp->xmte == 0) && (TXBUF_AVAIL(lp) > 1) &&
((lp->txbps == 0) || (lp->txnexttime <= sim_gtime ())))
lp->xmte = 1; /* enable line transmit */
if ((lp->txbfd && !lp->notelnet) || (TXBUF_AVAIL(lp) > 1)) {/* room for char (+ IAC)? */
if ((TN_IAC == (u_char) chr) && (!lp->notelnet)) /* char == IAC in telnet session? */
TXBUF_CHAR (lp, TN_IAC); /* stuff extra IAC char */
TXBUF_CHAR (lp, chr); /* buffer char & adv pointer */
if (((!lp->txbfd) &&
(TXBUF_AVAIL (lp) <= TMXR_GUARD)) || /* near full? */
(lp->txbps)) /* or we're rate limiting output */
lp->xmte = 0; /* disable line transmit until space available or character time has passed */
if (lp->txlog) { /* log if available */
extern TMLN *sim_oline; /* Make sure to avoid recursion */
TMLN *save_oline = sim_oline; /* when logging to a socket */
sim_oline = NULL; /* save output socket */
fputc (chr, lp->txlog); /* log to actual file */
sim_oline = save_oline; /* resture output socket */
}
sim_exp_check (&lp->expect, chr); /* process expect rules as needed */
if (!sim_is_running) { /* attach message or other non simulation time message? */
tmxr_send_buffered_data (lp); /* put data on wire */
sim_os_ms_sleep(((lp->txbps) && (lp->txdeltausecs > 1000)) ? /* rate limiting output slower than 1000 cps */
(lp->txdeltausecs - 1000) / 1000 :
10); /* wait an approximate character delay */
}
return SCPE_OK; /* char sent */
}
++lp->txstall; lp->xmte = 0; /* no room, dsbl line */
return SCPE_STALL; /* char not sent */
}
/* Store packet in line buffer
Inputs:
*lp = pointer to line descriptor
*buf = pointer to packet data
size = size of packet
frame_char = inter-packet franing character (0 means no frame character)
Outputs:
status = ok, connection lost, or stall
Implementation notea:
1. If the line is not connected, SCPE_LOST is returned.
2. If prior packet transmission still in progress, SCPE_STALL is
returned and no packet data is stored. The caller must retry later.
*/
t_stat tmxr_put_packet_ln (TMLN *lp, const uint8 *buf, size_t size)
{
return tmxr_put_packet_ln_ex (lp, buf, size, 0);
}
t_stat tmxr_put_packet_ln_ex (TMLN *lp, const uint8 *buf, size_t size, uint8 frame_byte)
{
t_stat r;
size_t fc_size = (frame_byte ? 1 : 0);
size_t pktlen_size = (lp->datagram ? 0 : 2);
if ((!lp->conn) && (!lp->loopback))
return SCPE_LOST;
if (lp->txppoffset < lp->txppsize) {
tmxr_debug (TMXR_DBG_PXMT, lp, "Skipped Sending Packet - Transmit Busy", (char *)&lp->txpb[3], size);
return SCPE_STALL;
}
if (lp->txpbsize < size + pktlen_size + fc_size) {
lp->txpbsize = size + pktlen_size + fc_size;
lp->txpb = (uint8 *)realloc (lp->txpb, lp->txpbsize);
}
lp->txpb[0] = frame_byte;
if (!lp->datagram) {
lp->txpb[0+fc_size] = (size >> 8) & 0xFF;
lp->txpb[1+fc_size] = size & 0xFF;
}
memcpy (lp->txpb + pktlen_size + fc_size, buf, size);
lp->txppsize = size + pktlen_size + fc_size;
lp->txppoffset = 0;
tmxr_debug (TMXR_DBG_PXMT, lp, "Sending Packet", (char *)&lp->txpb[pktlen_size+fc_size], size);
++lp->txpcnt;
while ((lp->txppoffset < lp->txppsize) &&
(SCPE_OK == (r = tmxr_putc_ln (lp, lp->txpb[lp->txppoffset]))))
++lp->txppoffset;
tmxr_send_buffered_data (lp);
return (lp->conn || lp->loopback) ? SCPE_OK : SCPE_LOST;
}
/* Poll for output
Inputs:
*mp = pointer to terminal multiplexer descriptor
Outputs:
none
*/
void tmxr_poll_tx (TMXR *mp)
{
int32 i, nbytes;
TMLN *lp;
double sim_gtime_now = sim_gtime ();
tmxr_debug_trace (mp, "tmxr_poll_tx()");
for (i = 0; i < mp->lines; i++) { /* loop thru lines */
lp = mp->ldsc + i; /* get line desc */
if ((!lp->conn) && (!lp->txbfd)) /* skip if !conn and !buffered */
continue;
nbytes = tmxr_send_buffered_data (lp); /* buffered bytes */
if (nbytes == 0) { /* buf empty? enab line */
#if defined(SIM_ASYNCH_MUX)
UNIT *ruptr = lp->uptr ? lp->uptr : lp->mp->uptr;
if ((ruptr->dynflags & UNIT_TM_POLL) &&
sim_asynch_enabled &&
tmxr_rqln (lp))
_sim_activate (ruptr, 0);
#endif
if ((lp->xmte == 0) &&
((lp->txbps == 0) ||
(lp->txnexttime <= sim_gtime_now)))
lp->xmte = 1; /* enable line transmit */
}
} /* end for */
}
/* Send buffered data across network
Inputs:
*lp = pointer to line descriptor
Outputs:
returns number of bytes still buffered
*/
int32 tmxr_send_buffered_data (TMLN *lp)
{
int32 nbytes, sbytes;
t_stat r;
tmxr_debug_trace_line (lp, "tmxr_send_buffered_data()");
nbytes = tmxr_tqln(lp); /* avail bytes */
if (nbytes) { /* >0? write */
if (lp->txbpr < lp->txbpi) /* no wrap? */
sbytes = tmxr_write (lp, nbytes); /* write all data */
else
sbytes = tmxr_write (lp, lp->txbsz - lp->txbpr);/* write to end buf */
if (sbytes >= 0) { /* ok? */
tmxr_debug (TMXR_DBG_XMT, lp, "Sent", &(lp->txb[lp->txbpr]), sbytes);
lp->txbpr = (lp->txbpr + sbytes); /* update remove ptr */
if (lp->txbpr >= lp->txbsz) /* wrap? */
lp->txbpr = 0;
lp->txcnt = lp->txcnt + sbytes; /* update counts */
nbytes = nbytes - sbytes;
if ((nbytes == 0) && (lp->datagram)) /* if Empty buffer on datagram line */
lp->txbpi = lp->txbpr = 0; /* Start next packet at beginning of buffer */
}
if (sbytes < 0) { /* I/O Error? */
lp->txbpi = lp->txbpr = 0; /* Drop the data we already know we can't send */
lp->rxpboffset = lp->txppoffset = lp->txppsize = 0;/* Drop the data we already know we can't send */
tmxr_close_ln (lp); /* close line/port on error */
return nbytes; /* done now. */
}
if (nbytes && (lp->txbpr == 0)) { /* more data and wrap? */
sbytes = tmxr_write (lp, nbytes);
if (sbytes > 0) { /* ok */
tmxr_debug (TMXR_DBG_XMT, lp, "Sent", lp->txb, sbytes);
lp->txbpr = (lp->txbpr + sbytes); /* update remove ptr */
if (lp->txbpr >= lp->txbsz) /* wrap? */
lp->txbpr = 0;
lp->txcnt = lp->txcnt + sbytes; /* update counts */
nbytes = nbytes - sbytes;
}
}
} /* end if nbytes */
while ((lp->txppoffset < lp->txppsize) && /* buffered packet data? */
(lp->txbsz > nbytes) && /* and room in xmt buffer */
(SCPE_OK == (r = tmxr_putc_ln (lp, lp->txpb[lp->txppoffset]))))
++lp->txppoffset;
if ((nbytes == 0) && (tmxr_tqln(lp) > 0))
return tmxr_send_buffered_data (lp);
return tmxr_tqln(lp) + tmxr_tpqln(lp);
}
/* Return count of buffered characters for line */
int32 tmxr_tqln (const TMLN *lp)
{
return (lp->txbpi - lp->txbpr + ((lp->txbpi < lp->txbpr)? lp->txbsz: 0));
}
/* Return count of buffered packet characters for line */
int32 tmxr_tpqln (const TMLN *lp)
{
return (lp->txppsize - lp->txppoffset);
}
/* Return transmit packet busy status for line */
t_bool tmxr_tpbusyln (const TMLN *lp)
{
return (0 != (lp->txppsize - lp->txppoffset));
}
static void _mux_detach_line (TMLN *lp, t_bool close_listener, t_bool close_connecting)
{
if (close_listener && lp->master) {
sim_close_sock (lp->master);
lp->master = 0;
free (lp->port);
lp->port = NULL;
}
if (lp->sock) { /* if existing tcp, drop it */
tmxr_report_disconnection (lp); /* report disconnection */
tmxr_reset_ln (lp);
}
if (close_connecting) {
free (lp->destination);
lp->destination = NULL;
if (lp->connecting) { /* if existing outgoing tcp, drop it */
lp->sock = lp->connecting;
lp->connecting = 0;
tmxr_reset_ln (lp);
}
}
if (lp->serport) { /* close current serial connection */
tmxr_reset_ln (lp);
sim_control_serial (lp->serport, 0, TMXR_MDM_DTR|TMXR_MDM_RTS, NULL);/* drop DTR and RTS */
sim_close_serial (lp->serport);
lp->serport = 0;
free (lp->serconfig);
lp->serconfig = NULL;
free (lp->destination);
lp->destination = NULL;
}
tmxr_set_line_loopback (lp, FALSE);
}
t_stat tmxr_detach_ln (TMLN *lp)
{
UNIT *uptr = NULL;
tmxr_debug_trace_line (lp, "tmxr_detach_ln()");
_mux_detach_line (lp, TRUE, TRUE);
if (lp->mp) {
if (lp->uptr)
uptr = lp->uptr;
else
uptr = lp->mp->uptr;
}
if (uptr && uptr->filename) {
/* Revise the unit's connect string to reflect the current attachments */
uptr->filename = tmxr_mux_attach_string (uptr->filename, lp->mp);
/* No connections or listeners exist, then we're equivalent to being fully detached. We should reflect that */
if (uptr->filename == NULL)
tmxr_detach (lp->mp, uptr);
}
return SCPE_OK;
}
static int32 _tmln_speed_delta (CONST char *cptr)
{
static struct {
const char *bps;
int32 delta;
} *spd, speeds[] = {
{"50", TMLN_SPD_50_BPS},
{"75", TMLN_SPD_75_BPS},
{"110", TMLN_SPD_110_BPS},
{"134", TMLN_SPD_134_BPS},
{"150", TMLN_SPD_150_BPS},
{"300", TMLN_SPD_300_BPS},
{"600", TMLN_SPD_600_BPS},
{"1200", TMLN_SPD_1200_BPS},
{"1800", TMLN_SPD_1800_BPS},
{"2000", TMLN_SPD_2000_BPS},
{"2400", TMLN_SPD_2400_BPS},
{"3600", TMLN_SPD_3600_BPS},
{"4800", TMLN_SPD_4800_BPS},
{"7200", TMLN_SPD_7200_BPS},
{"9600", TMLN_SPD_9600_BPS},
{"19200", TMLN_SPD_19200_BPS},
{"38400", TMLN_SPD_38400_BPS},
{"57600", TMLN_SPD_57600_BPS},
{"76800", TMLN_SPD_76800_BPS},
{"115200", TMLN_SPD_115200_BPS},
{"0", 0}}; /* End of List, last valid value */
int nspeed;
char speed[24];
int nfactor = 1;
nspeed = (uint32)strtotv (cptr, &cptr, 10);
if ((*cptr != '\0') && (*cptr != '-') && (*cptr != '*'))
return -1;
if (*cptr == '*') {
nfactor = (uint32)strtotv (cptr+1, NULL, 10);
if ((nfactor < 1) || (nfactor > 32))
return -1;
}
sprintf (speed, "%d", nspeed);
spd = speeds;
while (1) {
if (0 == strcmp(spd->bps, speed))
return spd->delta;
if (spd->delta == 0)
break;
++spd;
}
return -1;
}
t_stat tmxr_set_line_speed (TMLN *lp, CONST char *speed)
{
UNIT *uptr;
CONST char *cptr;
t_stat r;
uint32 rxbps;
if (!speed || !*speed)
return SCPE_2FARG;
if (_tmln_speed_delta (speed) < 0)
return SCPE_ARG;
rxbps = (uint32)strtotv (speed, &cptr, 10);
if (*cptr == '*') {
uint32 bpsfactor = (uint32) get_uint (cptr+1, 10, 32, &r);
if (r != SCPE_OK)
return r;
lp->bpsfactor = bpsfactor;
if (speed == cptr) { /* just changing bps factor? */
char speedbps[16];
sprintf (speedbps, "%d", lp->rxbps);
lp->rxdeltausecs = (uint32)(_tmln_speed_delta (speedbps) / lp->bpsfactor);
lp->txdeltausecs = lp->rxdeltausecs;
return SCPE_OK; /* Done now */
}
}
lp->rxbps = rxbps; /* use supplied speed */
if ((lp->serport) && (lp->bpsfactor != 0.0))
lp->bpsfactor = 1.0; /* Ignore bps factor for serial ports */
lp->rxdeltausecs = (uint32)(_tmln_speed_delta (speed) / lp->bpsfactor);
lp->rxnexttime = 0.0;
uptr = lp->uptr;
if ((!uptr) && (lp->mp))
uptr = lp->mp->uptr;
if (uptr)
uptr->wait = lp->rxdeltausecs;
lp->txbps = lp->rxbps;
lp->txdeltausecs = lp->rxdeltausecs;
if (lp->o_uptr)
lp->o_uptr->wait = lp->txdeltausecs;
return SCPE_OK;
}
/* Open a master listening socket (and all of the other variances of connections).
A listening socket for the port number described by "cptr" is opened for the
multiplexer associated with descriptor "mp". If the open is successful, all
lines not currently otherwise connected (via serial, outgoing or direct
listener) are initialized for Telnet connections.
Initialization for all connection styles (MUX wide listener, per line serial,
listener, outgoing, logging, buffering) are handled by this routine.
*/
t_stat tmxr_open_master (TMXR *mp, CONST char *cptr)
{
int32 i, line, nextline = -1;
char tbuf[CBUFSIZE], listen[CBUFSIZE], destination[CBUFSIZE],
logfiletmpl[CBUFSIZE], buffered[CBUFSIZE], hostport[CBUFSIZE],
port[CBUFSIZE], option[CBUFSIZE], speed[CBUFSIZE], dev_name[CBUFSIZE];
SOCKET sock;
SERHANDLE serport;
CONST char *tptr = cptr;
t_bool nolog, notelnet, listennotelnet, modem_control, loopback, datagram, packet, disabled;
TMLN *lp;
t_stat r = SCPE_OK;
snprintf (dev_name, sizeof(dev_name), "%s%s", mp->uptr ? sim_dname (find_dev_from_unit (mp->uptr)) : "", mp->uptr ? " " : "");
if (*tptr == '\0')
return SCPE_ARG;
for (i = 0; i < mp->lines; i++) { /* initialize lines */
lp = mp->ldsc + i;
lp->mp = mp; /* set the back pointer */
lp->modem_control = mp->modem_control;
if (lp->bpsfactor == 0.0)
lp->bpsfactor = 1.0;
}
mp->ring_sock = INVALID_SOCKET;
free (mp->ring_ipad);
mp->ring_ipad = NULL;
mp->ring_start_time = 0;
tmxr_debug_trace (mp, "tmxr_open_master()");
while (*tptr) {
line = nextline;
memset(logfiletmpl, '\0', sizeof(logfiletmpl));
memset(listen, '\0', sizeof(listen));
memset(destination, '\0', sizeof(destination));
memset(buffered, '\0', sizeof(buffered));
memset(port, '\0', sizeof(port));
memset(option, '\0', sizeof(option));
memset(speed, '\0', sizeof(speed));
nolog = notelnet = listennotelnet = loopback = disabled = FALSE;
datagram = mp->datagram;
packet = mp->packet;
if (mp->buffered)
sprintf(buffered, "%d", mp->buffered);
if (line != -1)
notelnet = listennotelnet = mp->notelnet;
modem_control = mp->modem_control;
while (*tptr) {
tptr = get_glyph_nc (tptr, tbuf, ',');
if (!tbuf[0])
break;
cptr = tbuf;
if (!isdigit(*cptr)) {
char gbuf[CBUFSIZE];
CONST char *init_cptr = cptr;
cptr = get_glyph (cptr, gbuf, '=');
if (0 == MATCH_CMD (gbuf, "LINE")) {
if ((NULL == cptr) || ('\0' == *cptr))
return sim_messagef (SCPE_2FARG, "Missing Line Specifier\n");
nextline = (int32) get_uint (cptr, 10, mp->lines-1, &r);
if (r)
return sim_messagef (SCPE_ARG, "Invalid Line Specifier: %s\n", cptr);
break;
}
if (0 == MATCH_CMD (gbuf, "LOG")) {
if ((NULL == cptr) || ('\0' == *cptr))
return sim_messagef (SCPE_2FARG, "Missing Log Specifier\n");
strlcpy(logfiletmpl, cptr, sizeof(logfiletmpl));
continue;
}
if (0 == MATCH_CMD (gbuf, "LOOPBACK")) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected Loopback Specifier: %s\n", cptr);
loopback = TRUE;
continue;
}
if ((0 == MATCH_CMD (gbuf, "NOBUFFERED")) ||
(0 == MATCH_CMD (gbuf, "UNBUFFERED"))) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected Unbuffered Specifier: %s\n", cptr);
buffered[0] = '\0';
continue;
}
if (0 == MATCH_CMD (gbuf, "BUFFERED")) {
if ((NULL == cptr) || ('\0' == *cptr))
strcpy (buffered, "32768");
else {
i = (int32) get_uint (cptr, 10, 1024*1024, &r);
if (r || (i == 0))
return sim_messagef (SCPE_ARG, "Invalid Buffered Specifier: %s\n", cptr);
sprintf(buffered, "%d", i);
}
continue;
}
if (0 == MATCH_CMD (gbuf, "NOLOG")) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected NoLog Specifier: %s\n", cptr);
nolog = TRUE;
continue;
}
if (0 == MATCH_CMD (gbuf, "NOMODEM")) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected NoModem Specifier: %s\n", cptr);
modem_control = FALSE;
continue;
}
if (0 == MATCH_CMD (gbuf, "MODEM")) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected Modem Specifier: %s\n", cptr);
modem_control = TRUE;
continue;
}
if ((0 == MATCH_CMD (gbuf, "DATAGRAM")) || (0 == MATCH_CMD (gbuf, "UDP"))) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected Datagram Specifier: %s\n", cptr);
notelnet = datagram = TRUE;
continue;
}
if (0 == MATCH_CMD (gbuf, "PACKET")) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected Packet Specifier: %s\n", cptr);
packet = TRUE;
continue;
}
if ((0 == MATCH_CMD (gbuf, "STREAM")) || (0 == MATCH_CMD (gbuf, "TCP"))) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2MARG, "Unexpected Stream Specifier: %s\n", cptr);
datagram = FALSE;
continue;
}
if (0 == MATCH_CMD (gbuf, "CONNECT")) {
if ((NULL == cptr) || ('\0' == *cptr))
return sim_messagef (SCPE_2FARG, "Missing Connect Specifier\n");
strlcpy (destination, cptr, sizeof(destination));
continue;
}
if (0 == MATCH_CMD (gbuf, "DISABLED")) {
if ((NULL != cptr) && ('\0' != *cptr))
return sim_messagef (SCPE_2FARG, "Unexpected Disabled Specifier: %s\n", cptr);
disabled = TRUE;
continue;
}
if (0 == MATCH_CMD (gbuf, "SPEED")) {
if ((NULL == cptr) || ('\0' == *cptr) ||
(_tmln_speed_delta (cptr) < 0))
return sim_messagef (SCPE_ARG, "Invalid Speed Specifier: %s\n", (cptr ? cptr : ""));
if (mp->port_speed_control &&
((_tmln_speed_delta (cptr) > 0) || (*cptr != '*')) &&
(!(sim_switches & SIM_SW_REST)))
return sim_messagef (SCPE_ARG, "%s simulator programmatically sets %sport speed\n", sim_name, dev_name);
strlcpy (speed, cptr, sizeof(speed));
continue;
}
cptr = get_glyph (gbuf, port, ';');
if (sim_parse_addr (port, NULL, 0, NULL, NULL, 0, NULL, NULL))
return sim_messagef (SCPE_ARG, "Invalid Port Specifier: %s\n", port);
if (cptr) {
char *tptr = gbuf + (cptr - gbuf);
get_glyph (cptr, tptr, 0); /* upcase this string */
if (0 == MATCH_CMD (cptr, "NOTELNET"))
listennotelnet = TRUE;
else
if (0 == MATCH_CMD (cptr, "TELNET"))
listennotelnet = FALSE;
else
return sim_messagef (SCPE_ARG, "Invalid Specifier: %s\n", tptr);
}
cptr = init_cptr;
}
cptr = get_glyph_nc (cptr, port, ';');
sock = sim_master_sock (port, &r); /* make master socket to validate port */
if (r)
return sim_messagef (SCPE_ARG, "Invalid Port Specifier: %s\n", port);
if (sock == INVALID_SOCKET) /* open error */
return sim_messagef (SCPE_OPENERR, "Can't open network port: %s\n", port);
sim_close_sock (sock);
sim_os_ms_sleep (2); /* let the close finish (required on some platforms) */
strcpy (listen, port);
cptr = get_glyph (cptr, option, ';');
if (option[0]) {
if (0 == MATCH_CMD (option, "NOTELNET"))
listennotelnet = TRUE;
else
if (0 == MATCH_CMD (option, "TELNET"))
listennotelnet = FALSE;
else
return sim_messagef (SCPE_ARG, "Invalid Specifier: %s\n", option);
}
}
if (disabled) {
if (destination[0] || listen[0] || loopback)
return sim_messagef (SCPE_ARG, "Can't disable line with%s%s%s%s%s\n", destination[0] ? " CONNECT=" : "", destination, listen[0] ? " " : "", listen, loopback ? " LOOPBACK" : "");
}
if (destination[0]) {
/* Validate destination */
serport = sim_open_serial (destination, NULL, &r);
if (serport != INVALID_HANDLE) {
sim_close_serial (serport);
if (strchr (destination, ';') && mp->modem_control && !(sim_switches & SIM_SW_REST))
return sim_messagef (SCPE_ARG, "Serial line parameters must be set within simulated OS: %s\n", 1 + strchr (destination, ';'));
}
else {
char *eptr;
memset (hostport, '\0', sizeof(hostport));
strlcpy (hostport, destination, sizeof(hostport));
if ((eptr = strchr (hostport, ';')))
*(eptr++) = '\0';
if (eptr) {
get_glyph (eptr, eptr, 0); /* upcase this string */
if (0 == MATCH_CMD (eptr, "NOTELNET"))
notelnet = TRUE;
else
if (0 == MATCH_CMD (eptr, "TELNET"))
if (datagram)
return sim_messagef (SCPE_ARG, "Telnet invalid on Datagram socket\n");
else
notelnet = FALSE;
else
return sim_messagef (SCPE_ARG, "Unexpected specifier: %s\n", eptr);
}
sock = sim_connect_sock_ex (NULL, hostport, "localhost", NULL, (datagram ? SIM_SOCK_OPT_DATAGRAM : 0) | (packet ? SIM_SOCK_OPT_NODELAY : 0));
if (sock != INVALID_SOCKET)
sim_close_sock (sock);
else
return sim_messagef (SCPE_ARG, "Invalid destination: %s\n", hostport);
}
}
if (line == -1) {
if (disabled)
return sim_messagef (SCPE_ARG, "Must specify line to disable\n");
if (modem_control != mp->modem_control)
return SCPE_ARG;
if (logfiletmpl[0]) {
strlcpy(mp->logfiletmpl, logfiletmpl, sizeof(mp->logfiletmpl));
for (i = 0; i < mp->lines; i++) {
lp = mp->ldsc + i;
sim_close_logfile (&lp->txlogref);
lp->txlog = NULL;
lp->txlogname = (char *)realloc(lp->txlogname, CBUFSIZE);
lp->txlogname[CBUFSIZE-1] = '\0';
if (mp->lines > 1)
snprintf(lp->txlogname, CBUFSIZE-1, "%s_%d", mp->logfiletmpl, i);
else
strlcpy (lp->txlogname, mp->logfiletmpl, CBUFSIZE);
r = sim_open_logfile (lp->txlogname, TRUE, &lp->txlog, &lp->txlogref);
if (r != SCPE_OK) {
free (lp->txlogname);
lp->txlogname = NULL;
break;
}
}
}
mp->buffered = atoi(buffered);
for (i = 0; i < mp->lines; i++) { /* initialize line buffers */
lp = mp->ldsc + i;
if (mp->buffered) {
lp->txbsz = mp->buffered;
lp->txbfd = 1;
lp->rxbsz = mp->buffered;
}
else {
lp->txbsz = TMXR_MAXBUF;
lp->txbfd = 0;
lp->rxbsz = TMXR_MAXBUF;
}
lp->txbpi = lp->txbpr = 0;
lp->txb = (char *)realloc(lp->txb, lp->txbsz);
lp->rxb = (char *)realloc(lp->rxb, lp->rxbsz);
lp->rbr = (char *)realloc(lp->rbr, lp->rxbsz);
}
if (nolog) {
mp->logfiletmpl[0] = '\0';
for (i = 0; i < mp->lines; i++) { /* close line logs */
lp = mp->ldsc + i;
free(lp->txlogname);
lp->txlogname = NULL;
if (lp->txlog) {
sim_close_logfile (&lp->txlogref);
lp->txlog = NULL;
}
}
}
if ((listen[0]) && (!datagram)) {
sock = sim_master_sock (listen, &r); /* make master socket */
if (r)
return sim_messagef (SCPE_ARG, "Invalid network listen port: %s\n", listen);
if (sock == INVALID_SOCKET) /* open error */
return sim_messagef (SCPE_OPENERR, "Can't open network socket for listen port: %s\n", listen);
if (mp->port) { /* close prior listener */
sim_close_sock (mp->master);
mp->master = 0;
free (mp->port);
mp->port = NULL;
}
sim_messagef (SCPE_OK, "Listening on port %s\n", listen);
mp->port = (char *)realloc (mp->port, 1 + strlen (listen));
strcpy (mp->port, listen); /* save port */
mp->master = sock; /* save master socket */
mp->ring_sock = INVALID_SOCKET;
free (mp->ring_ipad);
mp->ring_ipad = NULL;
mp->ring_start_time = 0;
mp->notelnet = listennotelnet; /* save desired telnet behavior flag */
for (i = 0; i < mp->lines; i++) { /* initialize lines */
lp = mp->ldsc + i;
lp->mp = mp; /* set the back pointer */
lp->packet = mp->packet;
if (lp->serport) { /* serial port attached? */
tmxr_reset_ln (lp); /* close current serial connection */
sim_control_serial (lp->serport, 0, TMXR_MDM_DTR|TMXR_MDM_RTS, NULL);/* drop DTR and RTS */
sim_close_serial (lp->serport);
lp->serport = 0;
free (lp->serconfig);
lp->serconfig = NULL;
}
else {
if (speed[0])
tmxr_set_line_speed (lp, speed);
}
tmxr_init_line (lp); /* initialize line state */
lp->sock = 0; /* clear the socket */
}
}
if (loopback) {
if (mp->lines > 1)
return sim_messagef (SCPE_ARG, "Ambiguous Loopback specification\n");
sim_messagef (SCPE_OK, "Operating in loopback mode\n");
for (i = 0; i < mp->lines; i++) {
lp = mp->ldsc + i;
tmxr_set_line_loopback (lp, loopback);
if (speed[0])
tmxr_set_line_speed (lp, speed);
}
}
if (destination[0]) {
if (mp->lines > 1)
return sim_messagef (SCPE_ARG, "Ambiguous Destination specification\n");
lp = &mp->ldsc[0];
serport = sim_open_serial (destination, lp, &r);
if (serport != INVALID_HANDLE) {
_mux_detach_line (lp, TRUE, TRUE);
if (lp->mp && lp->mp->master) { /* if existing listener, close it */
sim_close_sock (lp->mp->master);
lp->mp->master = 0;
free (lp->mp->port);
lp->mp->port = NULL;
}
lp->destination = (char *)malloc(1+strlen(destination));
strcpy (lp->destination, destination);
lp->mp = mp;
lp->serport = serport;
lp->ser_connect_pending = TRUE;
lp->notelnet = TRUE;
tmxr_init_line (lp); /* init the line state */
if (!lp->mp->modem_control) /* raise DTR and RTS for non modem control lines */
sim_control_serial (lp->serport, TMXR_MDM_DTR|TMXR_MDM_RTS, 0, NULL);
lp->cnms = sim_os_msec (); /* record time of connection */
if (sim_switches & SWMASK ('V')) /* -V flag reports connection on port */
tmxr_report_connection (mp, lp); /* report the connection to the line */
}
else {
lp->datagram = datagram;
if (datagram) {
if (listen[0]) {
lp->port = (char *)realloc (lp->port, 1 + strlen (listen));
strcpy (lp->port, listen); /* save port */
}
else
return sim_messagef (SCPE_ARG, "Missing listen port for Datagram socket\n");
}
lp->packet = packet;
sock = sim_connect_sock_ex (datagram ? listen : NULL, hostport, "localhost", NULL, (datagram ? SIM_SOCK_OPT_DATAGRAM : 0) | (packet ? SIM_SOCK_OPT_NODELAY : 0));
if (sock != INVALID_SOCKET) {
_mux_detach_line (lp, FALSE, TRUE);
lp->destination = (char *)malloc(1+strlen(hostport));
strcpy (lp->destination, hostport);
lp->mp = mp;
if (!lp->modem_control || (lp->modembits & TMXR_MDM_DTR)) {
lp->connecting = sock;
lp->ipad = (char *)malloc (1 + strlen (lp->destination));
strcpy (lp->ipad, lp->destination);
}
else
sim_close_sock (sock);
lp->notelnet = notelnet;
tmxr_init_line (lp); /* init the line state */
if (speed[0] && (!datagram))
tmxr_set_line_speed (lp, speed);
return SCPE_OK;
}
else
return sim_messagef (SCPE_ARG, "Can't open %s socket on %s%s%s\n", datagram ? "Datagram" : "Stream", datagram ? listen : "", datagram ? "<->" : "", hostport);
}
}
if (speed[0] &&
(destination[0] == '\0') &&
(listen[0] == '\0') &&
(!loopback)) {
for (i = 0; i < mp->lines; i++) {
lp = mp->ldsc + i;
tmxr_set_line_speed (lp, speed);
}
}
}
else { /* line specific attach */
lp = &mp->ldsc[line];
lp->mp = mp;
if (logfiletmpl[0]) {
sim_close_logfile (&lp->txlogref);
lp->txlog = NULL;
lp->txlogname = (char *)realloc (lp->txlogname, 1 + strlen (logfiletmpl));
strcpy (lp->txlogname, logfiletmpl);
r = sim_open_logfile (lp->txlogname, TRUE, &lp->txlog, &lp->txlogref);
if (r == SCPE_OK)
setvbuf(lp->txlog, NULL, _IOFBF, 65536);
else {
free (lp->txlogname);
lp->txlogname = NULL;
return sim_messagef (r, "Can't open log file: %s\n", logfiletmpl);
}
}
if (buffered[0] == '\0') {
lp->rxbsz = lp->txbsz = TMXR_MAXBUF;
lp->txbfd = 0;
}
else {
lp->rxbsz = lp->txbsz = atoi(buffered);
lp->txbfd = 1;
}
lp->txbpi = lp->txbpr = 0;
lp->txb = (char *)realloc (lp->txb, lp->txbsz);
lp->rxb = (char *)realloc(lp->rxb, lp->rxbsz);
lp->rbr = (char *)realloc(lp->rbr, lp->rxbsz);
lp->packet = packet;
if (nolog) {
free(lp->txlogname);
lp->txlogname = NULL;
if (lp->txlog) {
sim_close_logfile (&lp->txlogref);
lp->txlog = NULL;
}
}
if ((listen[0]) && (!datagram)) {
if ((mp->lines == 1) && (mp->master))
return sim_messagef (SCPE_ARG, "Single Line MUX can have either line specific OR MUS listener but NOT both\n");
sock = sim_master_sock (listen, &r); /* make master socket */
if (r)
return sim_messagef (SCPE_ARG, "Invalid Listen Specification: %s\n", listen);
if (sock == INVALID_SOCKET) /* open error */
return sim_messagef (SCPE_OPENERR, "Can't listen on port: %s\n", listen);
_mux_detach_line (lp, TRUE, FALSE);
sim_messagef (SCPE_OK, "Line %d Listening on port %s\n", line, listen);
lp->port = (char *)realloc (lp->port, 1 + strlen (listen));
strcpy (lp->port, listen); /* save port */
lp->master = sock; /* save master socket */
if (listennotelnet != mp->notelnet)
lp->notelnet = listennotelnet;
else
lp->notelnet = mp->notelnet;
}
if (destination[0]) {
serport = sim_open_serial (destination, lp, &r);
if (serport != INVALID_HANDLE) {
_mux_detach_line (lp, TRUE, TRUE);
lp->destination = (char *)malloc(1+strlen(destination));
strcpy (lp->destination, destination);
lp->serport = serport;
lp->ser_connect_pending = TRUE;
lp->notelnet = TRUE;
tmxr_init_line (lp); /* init the line state */
if (!lp->mp->modem_control) /* raise DTR and RTS for non modem control lines */
sim_control_serial (lp->serport, TMXR_MDM_DTR|TMXR_MDM_RTS, 0, NULL);
lp->cnms = sim_os_msec (); /* record time of connection */
if (sim_switches & SWMASK ('V')) /* -V flag reports connection on port */
tmxr_report_connection (mp, lp); /* report the connection to the line */
}
else {
lp->datagram = datagram;
if (datagram) {
if (listen[0]) {
lp->port = (char *)realloc (lp->port, 1 + strlen (listen));
strcpy (lp->port, listen); /* save port */
}
else
return sim_messagef (SCPE_ARG, "Missing listen port for Datagram socket\n");
}
sock = sim_connect_sock_ex (datagram ? listen : NULL, hostport, "localhost", NULL, (datagram ? SIM_SOCK_OPT_DATAGRAM : 0) | (packet ? SIM_SOCK_OPT_NODELAY : 0));
if (sock != INVALID_SOCKET) {
_mux_detach_line (lp, FALSE, TRUE);
lp->destination = (char *)malloc(1+strlen(hostport));
strcpy (lp->destination, hostport);
if (!lp->modem_control || (lp->modembits & TMXR_MDM_DTR)) {
lp->connecting = sock;
lp->ipad = (char *)malloc (1 + strlen (lp->destination));
strcpy (lp->ipad, lp->destination);
}
else
sim_close_sock (sock);
lp->notelnet = notelnet;
tmxr_init_line (lp); /* init the line state */
}
else
return sim_messagef (SCPE_ARG, "Can't open %s socket on %s%s%s\n", datagram ? "Datagram" : "Stream", datagram ? listen : "", datagram ? "<->" : "", hostport);
}
}
if (loopback) {
tmxr_set_line_loopback (lp, loopback);
sim_messagef (SCPE_OK, "Line %d operating in loopback mode\n", line);
}
if (disabled)
lp->conn = TMXR_LINE_DISABLED; /* Mark as not available */
lp->modem_control = modem_control;
if (speed[0] && (!datagram) && (!lp->serport))
tmxr_set_line_speed (lp, speed);
r = SCPE_OK;
}
}
if (r == SCPE_OK)
tmxr_add_to_open_list (mp);
return r;
}
/* Declare which unit polls for input
Inputs:
*mp = the mux
line = the line number
*uptr_poll = the unit which polls
Outputs:
none
Implementation note:
- This routine must be called before the MUX is attached.
- Only devices which poll on a unit different from the unit provided
at MUX attach time need call this function. Calling this API is
necessary for asynchronous multiplexer support and if speed limited
behaviors are desired.
*/
t_stat tmxr_set_line_unit (TMXR *mp, int line, UNIT *uptr_poll)
{
if ((line < 0) || (line >= mp->lines))
return SCPE_ARG;
if (mp->ldsc[line].uptr)
mp->ldsc[line].uptr->dynflags &= ~UNIT_TM_POLL;
mp->ldsc[line].uptr = uptr_poll;
return SCPE_OK;
}
/* Declare which unit performs output transmission in its unit service
routine for a particular line.
Inputs:
*mp = the mux
line = the line number
*uptr_poll = the unit which polls for output
Outputs:
none
Implementation notes:
- This routine must be called before the MUX is attached.
- Only devices which poll on a unit different from the unit provided
at MUX attach time need call this function ABD different from the
unit which polls for input. Calling this API is necessary for
asynchronous multiplexer support and if speed limited behaviors are
desired.
*/
t_stat tmxr_set_line_output_unit (TMXR *mp, int line, UNIT *uptr_poll)
{
if ((line < 0) || (line >= mp->lines))
return SCPE_ARG;
if (mp->ldsc[line].o_uptr)
mp->ldsc[line].o_uptr->dynflags &= ~UNIT_TM_POLL;
mp->ldsc[line].o_uptr = uptr_poll;
return SCPE_OK;
}
/* Declare which units are the console input and out devices
Inputs:
*rxuptr = the console input unit
*txuptr = the console output unit
Outputs:
none
Implementation note:
This routine is exported by the tmxr library so that it gets
defined to code which uses it by including sim_tmxr.h. Including
sim_tmxr.h is necessary so that sim_activate is properly defined
in the caller's code to actually call tmxr_activate.
*/
t_stat tmxr_set_console_units (UNIT *rxuptr, UNIT *txuptr)
{
extern TMXR sim_con_tmxr;
tmxr_set_line_unit (&sim_con_tmxr, 0, rxuptr);
tmxr_set_line_output_unit (&sim_con_tmxr, 0, txuptr);
return SCPE_OK;
}
static TMXR **tmxr_open_devices = NULL;
static int tmxr_open_device_count = 0;
#if defined(SIM_ASYNCH_MUX)
pthread_t sim_tmxr_poll_thread; /* Polling Thread Id */
#if defined(_WIN32) || defined(VMS)
pthread_t sim_tmxr_serial_poll_thread; /* Serial Polling Thread Id */
pthread_cond_t sim_tmxr_serial_startup_cond;
#endif
pthread_mutex_t sim_tmxr_poll_lock;
pthread_cond_t sim_tmxr_poll_cond;
pthread_cond_t sim_tmxr_startup_cond;
int32 sim_tmxr_poll_count = 0;
t_bool sim_tmxr_poll_running = FALSE;
static void *
_tmxr_poll(void *arg)
{
struct timeval timeout;
int timeout_usec;
DEVICE *dptr = tmxr_open_devices[0]->dptr;
UNIT **units = NULL;
UNIT **activated = NULL;
SOCKET *sockets = NULL;
int wait_count = 0;
/* Boost Priority for this I/O thread vs the CPU instruction execution
thread which, in general, won't be readily yielding the processor when
this thread needs to run */
sim_os_set_thread_priority (PRIORITY_ABOVE_NORMAL);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_poll() - starting\n");
units = (UNIT **)calloc(FD_SETSIZE, sizeof(*units));
activated = (UNIT **)calloc(FD_SETSIZE, sizeof(*activated));
sockets = (SOCKET *)calloc(FD_SETSIZE, sizeof(*sockets));
timeout_usec = 1000000;
pthread_mutex_lock (&sim_tmxr_poll_lock);
pthread_cond_signal (&sim_tmxr_startup_cond); /* Signal we're ready to go */
while (sim_asynch_enabled) {
int i, j, status, select_errno;
fd_set readfds, errorfds;
int socket_count;
SOCKET max_socket_fd;
TMXR *mp;
DEVICE *d;
if ((tmxr_open_device_count == 0) || (!sim_is_running)) {
for (j=0; j<wait_count; ++j) {
d = find_dev_from_unit(activated[j]);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_poll() - Removing interest in %s. Other interest: %d\n", sim_uname(activated[j]), activated[j]->a_poll_waiter_count);
--activated[j]->a_poll_waiter_count;
--sim_tmxr_poll_count;
}
break;
}
/* If we started something we should wait for, let it finish before polling again */
if (wait_count) {
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_poll() - waiting for %d units\n", wait_count);
pthread_cond_wait (&sim_tmxr_poll_cond, &sim_tmxr_poll_lock);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_poll() - continuing with timeout of %dms\n", timeout_usec/1000);
}
FD_ZERO (&readfds);
FD_ZERO (&errorfds);
for (i=max_socket_fd=socket_count=0; i<tmxr_open_device_count; ++i) {
mp = tmxr_open_devices[i];
if ((mp->master) && (mp->uptr->dynflags&UNIT_TM_POLL)) {
units[socket_count] = mp->uptr;
sockets[socket_count] = mp->master;
FD_SET (mp->master, &readfds);
FD_SET (mp->master, &errorfds);
if (mp->master > max_socket_fd)
max_socket_fd = mp->master;
++socket_count;
}
for (j=0; j<mp->lines; ++j) {
if (mp->ldsc[j].sock) {
units[socket_count] = mp->ldsc[j].uptr;
if (units[socket_count] == NULL)
units[socket_count] = mp->uptr;
sockets[socket_count] = mp->ldsc[j].sock;
FD_SET (mp->ldsc[j].sock, &readfds);
FD_SET (mp->ldsc[j].sock, &errorfds);
if (mp->ldsc[j].sock > max_socket_fd)
max_socket_fd = mp->ldsc[j].sock;
++socket_count;
}
#if !defined(_WIN32) && !defined(VMS)
if (mp->ldsc[j].serport) {
units[socket_count] = mp->ldsc[j].uptr;
if (units[socket_count] == NULL)
units[socket_count] = mp->uptr;
sockets[socket_count] = mp->ldsc[j].serport;
FD_SET (mp->ldsc[j].serport, &readfds);
FD_SET (mp->ldsc[j].serport, &errorfds);
if (mp->ldsc[j].serport > max_socket_fd)
max_socket_fd = mp->ldsc[j].serport;
++socket_count;
}
#endif
if (mp->ldsc[j].connecting) {
units[socket_count] = mp->uptr;
sockets[socket_count] = mp->ldsc[j].connecting;
FD_SET (mp->ldsc[j].connecting, &readfds);
FD_SET (mp->ldsc[j].connecting, &errorfds);
if (mp->ldsc[j].connecting > max_socket_fd)
max_socket_fd = mp->ldsc[j].connecting;
++socket_count;
}
if (mp->ldsc[j].master) {
units[socket_count] = mp->uptr;
sockets[socket_count] = mp->ldsc[j].master;
FD_SET (mp->ldsc[j].master, &readfds);
FD_SET (mp->ldsc[j].master, &errorfds);
if (mp->ldsc[j].master > max_socket_fd)
max_socket_fd = mp->ldsc[j].master;
++socket_count;
}
}
}
pthread_mutex_unlock (&sim_tmxr_poll_lock);
if (timeout_usec > 1000000)
timeout_usec = 1000000;
timeout.tv_sec = timeout_usec/1000000;
timeout.tv_usec = timeout_usec%1000000;
select_errno = 0;
if (socket_count == 0) {
sim_os_ms_sleep (timeout_usec/1000);
status = 0;
}
else
status = select (1+(int)max_socket_fd, &readfds, NULL, &errorfds, &timeout);
select_errno = errno;
wait_count=0;
pthread_mutex_lock (&sim_tmxr_poll_lock);
switch (status) {
case 0: /* timeout */
for (i=max_socket_fd=socket_count=0; i<tmxr_open_device_count; ++i) {
mp = tmxr_open_devices[i];
if (mp->master) {
if (!mp->uptr->a_polling_now) {
mp->uptr->a_polling_now = TRUE;
mp->uptr->a_poll_waiter_count = 0;
d = find_dev_from_unit(mp->uptr);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_poll() - Activating %s to poll connect\n", sim_uname(mp->uptr));
pthread_mutex_unlock (&sim_tmxr_poll_lock);
_sim_activate (mp->uptr, 0);
pthread_mutex_lock (&sim_tmxr_poll_lock);
}
if (mp->txcount) {
timeout_usec = 10000; /* Wait 10ms next time (this gets doubled below) */
mp->txcount = 0;
}
}
for (j=0; j<mp->lines; ++j) {
if ((mp->ldsc[j].conn) && (mp->ldsc[j].uptr)) {
if (tmxr_tqln(&mp->ldsc[j]) || tmxr_rqln (&mp->ldsc[j])) {
timeout_usec = 10000; /* Wait 10ms next time (this gets doubled below) */
/* More than one socket can be associated with the
same unit. Make sure to only activate it one time */
if (!mp->ldsc[j].uptr->a_polling_now) {
mp->ldsc[j].uptr->a_polling_now = TRUE;
mp->ldsc[j].uptr->a_poll_waiter_count = 0;
d = find_dev_from_unit(mp->ldsc[j].uptr);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_poll() - Line %d Activating %s to poll data: %d/%d\n",
j, sim_uname(mp->ldsc[j].uptr), tmxr_tqln(&mp->ldsc[j]), tmxr_rqln (&mp->ldsc[j]));
pthread_mutex_unlock (&sim_tmxr_poll_lock);
_sim_activate (mp->ldsc[j].uptr, 0);
pthread_mutex_lock (&sim_tmxr_poll_lock);
}
}
}
}
}
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_poll() - Poll Timeout - %dms\n", timeout_usec/1000);
timeout_usec *= 2; /* Double timeout time */
break;
case SOCKET_ERROR:
wait_count = 0;
if (select_errno == EINTR)
break;
sim_printf ("select() returned -1, errno=%d - %s\r\n", select_errno, strerror(select_errno));
abort();
break;
default:
wait_count = 0;
for (i=0; i<socket_count; ++i) {
if (FD_ISSET(sockets[i], &readfds) ||
FD_ISSET(sockets[i], &errorfds)) {
/* More than one socket can be associated with the
same unit. Only activate one time */
for (j=0; j<wait_count; ++j)
if (activated[j] == units[i])
break;
if (j == wait_count) {
activated[j] = units[i];
++wait_count;
if (!activated[j]->a_polling_now) {
activated[j]->a_polling_now = TRUE;
activated[j]->a_poll_waiter_count = 1;
d = find_dev_from_unit(activated[j]);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_poll() - Activating for data %s\n", sim_uname(activated[j]));
pthread_mutex_unlock (&sim_tmxr_poll_lock);
_sim_activate (activated[j], 0);
pthread_mutex_lock (&sim_tmxr_poll_lock);
}
else {
d = find_dev_from_unit(activated[j]);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_poll() - Already Activated %s%d %d times\n", sim_uname(activated[j]), activated[j]->a_poll_waiter_count);
++activated[j]->a_poll_waiter_count;
}
}
}
}
if (wait_count)
timeout_usec = 10000; /* Wait 10ms next time */
break;
}
sim_tmxr_poll_count += wait_count;
}
pthread_mutex_unlock (&sim_tmxr_poll_lock);
free(units);
free(activated);
free(sockets);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_poll() - exiting\n");
return NULL;
}
#if defined(_WIN32)
static void *
_tmxr_serial_poll(void *arg)
{
int timeout_usec;
DEVICE *dptr = tmxr_open_devices[0]->dptr;
UNIT **units = NULL;
UNIT **activated = NULL;
SERHANDLE *serports = NULL;
int wait_count = 0;
/* Boost Priority for this I/O thread vs the CPU instruction execution
thread which, in general, won't be readily yielding the processor when
this thread needs to run */
sim_os_set_thread_priority (PRIORITY_ABOVE_NORMAL);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_poll() - starting\n");
units = (UNIT **)calloc(MAXIMUM_WAIT_OBJECTS, sizeof(*units));
activated = (UNIT **)calloc(MAXIMUM_WAIT_OBJECTS, sizeof(*activated));
serports = (SERHANDLE *)calloc(MAXIMUM_WAIT_OBJECTS, sizeof(*serports));
timeout_usec = 1000000;
pthread_mutex_lock (&sim_tmxr_poll_lock);
pthread_cond_signal (&sim_tmxr_serial_startup_cond); /* Signal we're ready to go */
while (sim_asynch_enabled) {
int i, j;
DWORD status;
int serport_count;
TMXR *mp;
DEVICE *d;
if ((tmxr_open_device_count == 0) || (!sim_is_running)) {
for (j=0; j<wait_count; ++j) {
d = find_dev_from_unit(activated[j]);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_serial_poll() - Removing interest in %s. Other interest: %d\n", sim_uname(activated[j]), activated[j]->a_poll_waiter_count);
--activated[j]->a_poll_waiter_count;
--sim_tmxr_poll_count;
}
break;
}
/* If we started something we should wait for, let it finish before polling again */
if (wait_count) {
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_poll() - waiting for %d units\n", wait_count);
pthread_cond_wait (&sim_tmxr_poll_cond, &sim_tmxr_poll_lock);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_poll() - continuing with timeout of %dms\n", timeout_usec/1000);
}
for (i=serport_count=0; i<tmxr_open_device_count; ++i) {
mp = tmxr_open_devices[i];
for (j=0; j<mp->lines; ++j) {
if (mp->ldsc[j].serport) {
units[serport_count] = mp->ldsc[j].uptr;
if (units[serport_count] == NULL)
units[serport_count] = mp->uptr;
serports[serport_count] = mp->ldsc[j].serport;
++serport_count;
}
}
}
if (serport_count == 0) /* No open serial ports? */
break; /* We're done */
pthread_mutex_unlock (&sim_tmxr_poll_lock);
if (timeout_usec > 1000000)
timeout_usec = 1000000;
status = WaitForMultipleObjects (serport_count, serports, FALSE, timeout_usec/1000);
wait_count=0;
pthread_mutex_lock (&sim_tmxr_poll_lock);
switch (status) {
case WAIT_FAILED:
sim_printf ("WaitForMultipleObjects() Failed, LastError=%d\r\n", GetLastError());
abort();
break;
case WAIT_TIMEOUT:
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_poll() - Poll Timeout - %dms\n", timeout_usec/1000);
timeout_usec *= 2; /* Double timeout time */
break;
default:
i = status - WAIT_OBJECT_0;
wait_count = 0;
j = wait_count;
activated[j] = units[i];
++wait_count;
if (!activated[j]->a_polling_now) {
activated[j]->a_polling_now = TRUE;
activated[j]->a_poll_waiter_count = 1;
d = find_dev_from_unit(activated[j]);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_serial_poll() - Activating for data %s\n", sim_uname(activated[j]));
pthread_mutex_unlock (&sim_tmxr_poll_lock);
_sim_activate (activated[j], 0);
pthread_mutex_lock (&sim_tmxr_poll_lock);
}
else {
d = find_dev_from_unit(activated[j]);
sim_debug (TMXR_DBG_ASY, d, "_tmxr_serial_poll() - Already Activated %s%d %d times\n", sim_uname(activated[j]), activated[j]->a_poll_waiter_count);
++activated[j]->a_poll_waiter_count;
}
if (wait_count)
timeout_usec = 10000; /* Wait 10ms next time */
break;
}
sim_tmxr_poll_count += wait_count;
}
pthread_mutex_unlock (&sim_tmxr_poll_lock);
free(units);
free(activated);
free(serports);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_poll() - exiting\n");
return NULL;
}
#endif /* _WIN32 */
#if defined(VMS)
#include <descrip.h>
#include <ttdef.h>
#include <tt2def.h>
#include <iodef.h>
#include <ssdef.h>
#include <starlet.h>
#include <unistd.h>
typedef struct {
unsigned short status;
unsigned short count;
unsigned int dev_status; } IOSB;
#define MAXIMUM_WAIT_OBJECTS 64 /* Number of possible concurrently opened serial ports */
pthread_cond_t sim_serial_line_startup_cond;
static void *
_tmxr_serial_line_poll(void *arg)
{
TMLN *lp = (TMLN *)arg;
DEVICE *dptr = tmxr_open_devices[0]->dptr;
UNIT *uptr = (lp->uptr ? lp->uptr : lp->mp->uptr);
DEVICE *d = find_dev_from_unit(uptr);
int wait_count = 0;
/* Boost Priority for this I/O thread vs the CPU instruction execution
thread which, in general, won't be readily yielding the processor when
this thread needs to run */
sim_os_set_thread_priority (PRIORITY_ABOVE_NORMAL);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_line_poll() - starting\n");
pthread_mutex_lock (&sim_tmxr_poll_lock);
pthread_cond_signal (&sim_serial_line_startup_cond); /* Signal we're ready to go */
while (sim_asynch_enabled) {
int i, j;
int serport_count;
TMXR *mp = lp->mp;
unsigned int status, term[2];
unsigned char buf[4];
IOSB iosb;
if ((tmxr_open_device_count == 0) || (!sim_is_running)) {
if (wait_count) {
sim_debug (TMXR_DBG_ASY, d, "_tmxr_serial_line_poll() - Removing interest in %s. Other interest: %d\n", sim_uname(uptr), uptr->a_poll_waiter_count);
--uptr->a_poll_waiter_count;
--sim_tmxr_poll_count;
}
break;
}
/* If we started something we should wait for, let it finish before polling again */
if (wait_count) {
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_line_poll() - waiting for %d units\n", wait_count);
pthread_cond_wait (&sim_tmxr_poll_cond, &sim_tmxr_poll_lock);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_line_poll() - continuing with timeout of 1 sec\n");
}
lp->a_active = TRUE;
pthread_mutex_unlock (&sim_tmxr_poll_lock);
term[0] = term[1] = 0;
status = sys$qiow (0, lp->serport,
IO$_READLBLK | IO$M_NOECHO | IO$M_NOFILTR | IO$M_TIMED | IO$M_TRMNOECHO,
&iosb, 0, 0, buf, 1, 1, term, 0, 0);
if (status != SS$_NORMAL) {
sim_printf ("_tmxr_serial_line_poll() - QIO Failed, Status=%d\r\n", status);
abort();
}
wait_count = 0;
sys$synch (0, &iosb);
pthread_mutex_lock (&sim_tmxr_poll_lock);
lp->a_active = FALSE;
if (iosb.count == 1) {
lp->a_buffered_character = buf[0] | SCPE_KFLAG;
wait_count = 1;
if (!uptr->a_polling_now) {
uptr->a_polling_now = TRUE;
uptr->a_poll_waiter_count = 1;
sim_debug (TMXR_DBG_ASY, d, "_tmxr_serial_line_poll() - Activating for data %s\n", sim_uname(uptr));
pthread_mutex_unlock (&sim_tmxr_poll_lock);
_sim_activate (uptr, 0);
pthread_mutex_lock (&sim_tmxr_poll_lock);
}
else {
sim_debug (TMXR_DBG_ASY, d, "_tmxr_serial_line_poll() - Already Activated %s%d %d times\n", sim_uname(uptr), uptr->a_poll_waiter_count);
++uptr->a_poll_waiter_count;
}
}
sim_tmxr_poll_count += wait_count;
}
pthread_mutex_unlock (&sim_tmxr_poll_lock);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_line_poll() - exiting\n");
return NULL;
}
static void *
_tmxr_serial_poll(void *arg)
{
int timeout_usec;
DEVICE *dptr = tmxr_open_devices[0]->dptr;
TMLN **lines = NULL;
pthread_t *threads = NULL;
/* Boost Priority for this I/O thread vs the CPU instruction execution
thread which, in general, won't be readily yielding the processor when
this thread needs to run */
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_poll() - starting\n");
lines = (TMLN **)calloc(MAXIMUM_WAIT_OBJECTS, sizeof(*lines));
threads = (pthread_t *)calloc(MAXIMUM_WAIT_OBJECTS, sizeof(*threads));
pthread_mutex_lock (&sim_tmxr_poll_lock);
pthread_cond_signal (&sim_tmxr_serial_startup_cond); /* Signal we're ready to go */
pthread_cond_init (&sim_serial_line_startup_cond, NULL);
while (sim_asynch_enabled) {
pthread_attr_t attr;
int i, j;
int serport_count;
TMXR *mp;
DEVICE *d;
if ((tmxr_open_device_count == 0) || (!sim_is_running))
break;
pthread_attr_init (&attr);
pthread_attr_setscope (&attr, PTHREAD_SCOPE_SYSTEM);
for (i=serport_count=0; i<tmxr_open_device_count; ++i) {
mp = tmxr_open_devices[i];
for (j=0; j<mp->lines; ++j) {
if (mp->ldsc[j].serport) {
lines[serport_count] = &mp->ldsc[j];
pthread_create (&threads[serport_count], &attr, _tmxr_serial_line_poll, (void *)&mp->ldsc[j]);
pthread_cond_wait (&sim_serial_line_startup_cond, &sim_tmxr_poll_lock); /* Wait for thread to stabilize */
++serport_count;
}
}
}
pthread_attr_destroy( &attr);
if (serport_count == 0) /* No open serial ports? */
break; /* We're done */
pthread_mutex_unlock (&sim_tmxr_poll_lock);
for (i=0; i<serport_count; i++)
pthread_join (threads[i], NULL);
pthread_mutex_lock (&sim_tmxr_poll_lock);
}
pthread_mutex_unlock (&sim_tmxr_poll_lock);
pthread_cond_destroy (&sim_serial_line_startup_cond);
free(lines);
free(threads);
sim_debug (TMXR_DBG_ASY, dptr, "_tmxr_serial_poll() - exiting\n");
return NULL;
}
#endif /* VMS */
#endif /* defined(SIM_ASYNCH_MUX) */
t_stat tmxr_start_poll (void)
{
#if defined(SIM_ASYNCH_MUX)
pthread_mutex_lock (&sim_tmxr_poll_lock);
if ((tmxr_open_device_count > 0) &&
sim_asynch_enabled &&
sim_is_running &&
!sim_tmxr_poll_running) {
pthread_attr_t attr;
pthread_cond_init (&sim_tmxr_startup_cond, NULL);
pthread_attr_init (&attr);
pthread_attr_setscope (&attr, PTHREAD_SCOPE_SYSTEM);
pthread_create (&sim_tmxr_poll_thread, &attr, _tmxr_poll, NULL);
pthread_attr_destroy( &attr);
pthread_cond_wait (&sim_tmxr_startup_cond, &sim_tmxr_poll_lock); /* Wait for thread to stabilize */
pthread_cond_destroy (&sim_tmxr_startup_cond);
sim_tmxr_poll_running = TRUE;
}
pthread_mutex_unlock (&sim_tmxr_poll_lock);
#endif
return SCPE_OK;
}
t_stat tmxr_stop_poll (void)
{
#if defined(SIM_ASYNCH_MUX)
pthread_mutex_lock (&sim_tmxr_poll_lock);
if (sim_tmxr_poll_running) {
pthread_cond_signal (&sim_tmxr_poll_cond);
pthread_mutex_unlock (&sim_tmxr_poll_lock);
pthread_join (sim_tmxr_poll_thread, NULL);
sim_tmxr_poll_running = FALSE;
/* Transitioning from asynch mode so kick all polling units onto the event queue */
if (tmxr_open_device_count) {
int i, j;
for (i=0; i<tmxr_open_device_count; ++i) {
TMXR *mp = tmxr_open_devices[i];
if (mp->uptr)
_sim_activate (mp->uptr, 0);
for (j = 0; j < mp->lines; ++j)
if (mp->ldsc[j].uptr)
_sim_activate (mp->ldsc[j].uptr, 0);
}
}
}
else
pthread_mutex_unlock (&sim_tmxr_poll_lock);
#endif
return SCPE_OK;
}
static void tmxr_add_to_open_list (TMXR* mux)
{
int i;
t_bool found = FALSE;
#if defined(SIM_ASYNCH_MUX)
pthread_mutex_lock (&sim_tmxr_poll_lock);
#endif
for (i=0; i<tmxr_open_device_count; ++i)
if (tmxr_open_devices[i] == mux) {
found = TRUE;
break;
}
if (!found) {
tmxr_open_devices = (TMXR **)realloc(tmxr_open_devices, (tmxr_open_device_count+1)*sizeof(*tmxr_open_devices));
tmxr_open_devices[tmxr_open_device_count++] = mux;
for (i=0; i<mux->lines; i++)
mux->ldsc[i].send.after = mux->ldsc[i].send.delay = 0;
}
#if defined(SIM_ASYNCH_MUX)
pthread_mutex_unlock (&sim_tmxr_poll_lock);
if ((tmxr_open_device_count == 1) && (sim_asynch_enabled))
tmxr_start_poll ();
#endif
}
static void _tmxr_remove_from_open_list (TMXR* mux)
{
int i, j;
#if defined(SIM_ASYNCH_MUX)
tmxr_stop_poll ();
pthread_mutex_lock (&sim_tmxr_poll_lock);
#endif
for (i=0; i<tmxr_open_device_count; ++i)
if (tmxr_open_devices[i] == mux) {
for (j=i+1; j<tmxr_open_device_count; ++j)
tmxr_open_devices[j-1] = tmxr_open_devices[j];
--tmxr_open_device_count;
break;
}
#if defined(SIM_ASYNCH_MUX)
pthread_mutex_unlock (&sim_tmxr_poll_lock);
#endif
}
static t_stat _tmxr_locate_line_send_expect (const char *cptr, SEND **snd, EXPECT **exp)
{
char gbuf[CBUFSIZE];
DEVICE *dptr;
int i;
t_stat r;
if (snd)
*snd = NULL;
if (exp)
*exp = NULL;
cptr = get_glyph(cptr, gbuf, ':');
dptr = find_dev (gbuf); /* device match? */
if (!dptr)
return SCPE_ARG;
for (i=0; i<tmxr_open_device_count; ++i)
if (tmxr_open_devices[i]->dptr == dptr) {
int line = (int)get_uint (cptr, 10, tmxr_open_devices[i]->lines, &r);
if (r != SCPE_OK)
return r;
if (snd)
*snd = &tmxr_open_devices[i]->ldsc[line].send;
if (exp)
*exp = &tmxr_open_devices[i]->ldsc[line].expect;
return SCPE_OK;
}
return SCPE_ARG;
}
t_stat tmxr_locate_line_send (const char *cptr, SEND **snd)
{
return _tmxr_locate_line_send_expect (cptr, snd, NULL);
}
t_stat tmxr_locate_line_expect (const char *cptr, EXPECT **exp)
{
return _tmxr_locate_line_send_expect (cptr, NULL, exp);
}
static const char *_tmxr_send_expect_line_name (const SEND *snd, const EXPECT *exp)
{
static char line_name[CBUFSIZE];
int i, j;
strcpy (line_name, "");
for (i=0; i<tmxr_open_device_count; ++i)
for (j=0; j<tmxr_open_devices[i]->lines; ++j)
if ((snd == &tmxr_open_devices[i]->ldsc[j].send) ||
(exp == &tmxr_open_devices[i]->ldsc[j].expect)) {
if (tmxr_open_devices[i]->lines > 1)
snprintf (line_name, sizeof (line_name), "%s:%d", tmxr_open_devices[i]->ldsc[j].send.dptr->name, j);
else
strlcpy (line_name, tmxr_open_devices[i]->ldsc[j].send.dptr->name, sizeof (line_name));
break;
}
return line_name;
}
const char *tmxr_send_line_name (const SEND *snd)
{
if (snd == sim_cons_get_send ())
return "CONSOLE";
else
return _tmxr_send_expect_line_name (snd, NULL);
}
const char *tmxr_expect_line_name (const EXPECT *exp)
{
if (exp == sim_cons_get_expect ())
return "CONSOLE";
else
return _tmxr_send_expect_line_name (NULL, exp);
}
t_stat tmxr_change_async (void)
{
#if defined(SIM_ASYNCH_IO)
if (sim_asynch_enabled)
tmxr_start_poll ();
else
tmxr_stop_poll ();
#endif
return SCPE_OK;
}
static DEBTAB tmxr_debug[] = {
{"XMT", TMXR_DBG_XMT, "Transmit Data"},
{"RCV", TMXR_DBG_RCV, "Received Data"},
{"RET", TMXR_DBG_RET, "Returned Received Data"},
{"MODEM", TMXR_DBG_MDM, "Modem Signals"},
{"CONNECT", TMXR_DBG_CON, "Connection Activities"},
{"ASYNC", TMXR_DBG_ASY, "Asynchronous Activities"},
{"TRACE", TMXR_DBG_TRC, "trace routine calls"},
{"XMTPKT", TMXR_DBG_PXMT, "Transmit Packet Data"},
{"RCVPKT", TMXR_DBG_PRCV, "Received Packet Data"},
{"EXPECT", TMXR_DBG_EXP, "Expect Activities"},
{"SEND", TMXR_DBG_SEND, "Send Activities"},
{0}
};
t_stat tmxr_add_debug (DEVICE *dptr)
{
if (!(dptr->flags & DEV_MUX))
return SCPE_OK;
return sim_add_debug_flags (dptr, tmxr_debug);
}
/* Attach unit to master socket */
t_stat tmxr_attach_ex (TMXR *mp, UNIT *uptr, CONST char *cptr, t_bool async)
{
t_stat r;
int32 i;
if (mp->dptr == NULL) /* has device been set? */
mp->dptr = find_dev_from_unit (uptr); /* no, so set device now */
if (mp->uptr == NULL) /* has polling unit been set? */
mp->uptr = uptr; /* save unit for polling */
r = tmxr_open_master (mp, cptr); /* open master socket */
if (r != SCPE_OK) /* error? */
return r;
uptr->filename = tmxr_mux_attach_string (uptr->filename, mp);/* save */
if (uptr->filename == NULL) /* avoid dangling NULL pointer */
uptr->filename = (char *)calloc (1, 1); /* provide an emptry string */
uptr->flags = uptr->flags | UNIT_ATT; /* no more errors */
uptr->tmxr = (void *)mp;
if ((mp->lines > 1) ||
((mp->master == 0) &&
(mp->ldsc[0].connecting == 0) &&
(mp->ldsc[0].serport == 0)))
uptr->dynflags = uptr->dynflags | UNIT_ATTMULT; /* allow multiple attach commands */
#if defined(SIM_ASYNCH_MUX)
if (!async || (uptr->flags & TMUF_NOASYNCH)) /* if asynch disabled */
uptr->dynflags |= TMUF_NOASYNCH; /* tag as no asynch */
#else
uptr->dynflags |= TMUF_NOASYNCH; /* tag as no asynch */
#endif
uptr->dynflags |= UNIT_TM_POLL; /* tag as polling unit */
if (mp->dptr) {
for (i=0; i<mp->lines; i++) {
mp->ldsc[i].expect.dptr = mp->dptr;
mp->ldsc[i].expect.dbit = TMXR_DBG_EXP;
mp->ldsc[i].send.dptr = mp->dptr;
mp->ldsc[i].send.dbit = TMXR_DBG_SEND;
if (mp->ldsc[i].uptr == NULL)
mp->ldsc[i].uptr = mp->uptr;
mp->ldsc[i].uptr->tmxr = (void *)mp;
mp->ldsc[i].uptr->dynflags |= UNIT_TM_POLL; /* tag as polling unit */
if (mp->ldsc[i].o_uptr == NULL)
mp->ldsc[i].o_uptr = mp->ldsc[i].uptr;
mp->ldsc[i].o_uptr->tmxr = (void *)mp;
mp->ldsc[i].o_uptr->dynflags |= UNIT_TM_POLL; /* tag as polling unit */
}
}
tmxr_add_to_open_list (mp);
return SCPE_OK;
}
t_stat tmxr_startup (void)
{
return SCPE_OK;
}
t_stat tmxr_shutdown (void)
{
if (tmxr_open_device_count)
return SCPE_IERR;
return SCPE_OK;
}
t_stat tmxr_show_open_device (FILE* st, TMXR *mp)
{
int j;
TMLN *lp;
UNIT *o_uptr = mp->ldsc[0].o_uptr;
UNIT *uptr = mp->ldsc[0].uptr;
char *attach;
fprintf(st, "Multiplexer device: %s", (mp->dptr ? sim_dname (mp->dptr) : ""));
if (mp->lines > 1) {
fprintf(st, ", ");
tmxr_show_lines(st, NULL, 0, mp);
}
if (mp->packet)
fprintf(st, ", Packet");
if (mp->datagram)
fprintf(st, ", UDP");
if (mp->notelnet)
fprintf(st, ", Telnet=disabled");
if (mp->modem_control)
fprintf(st, ", ModemControl=enabled");
if (mp->buffered)
fprintf(st, ", Buffered=%d", mp->buffered);
for (j = 1; j < mp->lines; j++)
if (o_uptr != mp->ldsc[j].o_uptr)
break;
if (j == mp->lines)
fprintf(st, ", Output Unit: %s", sim_uname (o_uptr));
for (j = 1; j < mp->lines; j++)
if (uptr != mp->ldsc[j].uptr)
break;
if (j == mp->lines) {
fprintf(st, ",\n Input Polling Unit: %s", sim_uname (uptr));
if (uptr != mp->uptr)
fprintf(st, ", Connection Polling Unit: %s", sim_uname (mp->uptr));
}
attach = tmxr_mux_attach_string (NULL, mp);
if (attach)
fprintf(st, ",\n attached to %s, ", attach);
free (attach);
tmxr_show_summ(st, NULL, 0, mp);
fprintf(st, ", sessions=%d", mp->sessions);
if (mp->lines == 1) {
if (mp->ldsc->rxbps) {
fprintf(st, ", Speed=%d", mp->ldsc->rxbps);
if (mp->ldsc->bpsfactor != 1.0)
fprintf(st, "*%.0f", mp->ldsc->bpsfactor);
fprintf(st, " bps");
}
}
fprintf(st, "\n");
if (mp->ring_start_time) {
fprintf (st, " incoming Connection from: %s ringing for %d milliseconds\n", mp->ring_ipad, sim_os_msec () - mp->ring_start_time);
}
for (j = 0; j < mp->lines; j++) {
lp = mp->ldsc + j;
if (mp->lines > 1) {
if (lp->dptr && (mp->dptr != lp->dptr))
fprintf (st, "Device: %s ", sim_dname(lp->dptr));
fprintf (st, "Line: %d", j);
if (lp->conn == TMXR_LINE_DISABLED)
fprintf (st, " - Disabled");
if (mp->notelnet != lp->notelnet)
fprintf (st, " - %stelnet", lp->notelnet ? "no" : "");
if (lp->uptr && (lp->uptr != lp->mp->uptr))
fprintf (st, " - Unit: %s", sim_uname (lp->uptr));
if ((lp->o_uptr != o_uptr) && lp->o_uptr && (lp->o_uptr != lp->mp->uptr) && (lp->o_uptr != lp->uptr))
fprintf (st, " - Output Unit: %s", sim_uname (lp->o_uptr));
if (mp->modem_control != lp->modem_control)
fprintf(st, ", ModemControl=%s", lp->modem_control ? "enabled" : "disabled");
if (lp->loopback)
fprintf(st, ", Loopback");
if (lp->rxbps) {
fprintf(st, ", Speed=%d", lp->rxbps);
if (lp->bpsfactor != 1.0)
fprintf(st, "*%.0f", lp->bpsfactor);
fprintf(st, " bps");
}
else {
if (lp->bpsfactor != 1.0)
fprintf(st, ", Speed=*%.0f bps", lp->bpsfactor);
}
fprintf (st, "\n");
}
if ((!lp->sock) && (!lp->connecting) && (!lp->serport) && (!lp->master)) {
if ((lp->modem_control) || (lp->txbfd))
tmxr_fconns (st, lp, -1);
continue;
}
tmxr_fconns (st, lp, -1);
tmxr_fstats (st, lp, -1);
}
return SCPE_OK;
}
t_stat tmxr_show_open_devices (FILE* st, DEVICE *dptr, UNIT* uptr, int32 val, CONST char* cptr)
{
int i;
char gbuf[CBUFSIZE];
cptr = get_glyph (cptr, gbuf, 0);
if (*cptr)
return SCPE_2MARG;
if ((0 == tmxr_open_device_count) &&
(gbuf[0] == '\0'))
fprintf(st, "No Attached Multiplexer Devices\n");
else {
for (i=0; i<tmxr_open_device_count; ++i) {
TMXR *mp = tmxr_open_devices[i];
if ((gbuf[0] == '\0') ||
(0 == strcmp (gbuf, mp->dptr->name))) {
tmxr_show_open_device (st, mp);
if (gbuf[0] != '\0')
break;
}
}
if ((gbuf[0] != '\0') &&
(i == tmxr_open_device_count))
return sim_messagef (SCPE_ARG, "Multiplexer device %s not found or attached\n", gbuf);
}
return SCPE_OK;
}
/* Close a master listening socket.
The listening socket associated with multiplexer descriptor "mp" is closed
and deallocated. In addition, all current Telnet sessions are disconnected.
Serial and outgoing sessions are also disconnected.
*/
t_stat tmxr_close_master (TMXR *mp)
{
int32 i;
TMLN *lp;
for (i = 0; i < mp->lines; i++) { /* loop thru conn */
lp = mp->ldsc + i;
if (!lp->destination && lp->sock) { /* not serial and is connected? */
tmxr_report_disconnection (lp); /* report disconnection */
tmxr_reset_ln (lp); /* disconnect line */
}
else {
if (lp->sock) {
tmxr_report_disconnection (lp); /* report disconnection */
tmxr_reset_ln (lp);
}
if (lp->serport) {
sim_control_serial (lp->serport, 0, TMXR_MDM_DTR|TMXR_MDM_RTS, NULL);/* drop DTR and RTS */
tmxr_close_ln (lp);
}
free (lp->destination);
lp->destination = NULL;
if (lp->connecting) {
lp->sock = lp->connecting;
lp->connecting = 0;
tmxr_reset_ln (lp);
}
lp->conn = FALSE;
}
if (lp->master) {
sim_close_sock (lp->master); /* close master socket */
lp->master = 0;
free (lp->port);
lp->port = NULL;
}
lp->txbfd = 0;
free (lp->txb);
lp->txb = NULL;
free (lp->rxb);
lp->rxb = NULL;
free (lp->rbr);
lp->rbr = NULL;
lp->modembits = 0;
}
if (mp->master)
sim_close_sock (mp->master); /* close master socket */
mp->master = 0;
free (mp->port);
mp->port = NULL;
if (mp->ring_sock != INVALID_SOCKET) {
sim_close_sock (mp->ring_sock);
mp->ring_sock = INVALID_SOCKET;
free (mp->ring_ipad);
mp->ring_ipad = NULL;
mp->ring_start_time = 0;
}
_tmxr_remove_from_open_list (mp);
return SCPE_OK;
}
/* Detach unit from master socket and close all active network connections
and/or serial ports.
Note that we return SCPE_OK, regardless of whether a listening socket was
attached.
*/
t_stat tmxr_detach (TMXR *mp, UNIT *uptr)
{
int32 i;
char portname[CBUFSIZE];
if (!(uptr->flags & UNIT_ATT)) /* attached? */
return SCPE_OK;
for (i=0; i < mp->lines; i++) {
mp->ldsc[i].uptr->dynflags &= ~UNIT_TM_POLL; /* no polling */
mp->ldsc[i].uptr->tmxr = NULL;
mp->ldsc[i].o_uptr->dynflags &= ~UNIT_TM_POLL; /* no polling */
mp->ldsc[i].o_uptr->tmxr = NULL;
sprintf (portname, "%s:%d", mp->dptr->name, i);
expect_cmd (0, portname); /* clear dangling expects */
send_cmd (0, portname); /* clear dangling send data */
}
tmxr_close_master (mp); /* close master socket */
free (uptr->filename); /* free setup string */
uptr->filename = NULL;
uptr->tmxr = NULL;
mp->last_poll_time = 0;
uptr->flags &= ~(UNIT_ATT); /* not attached */
uptr->dynflags &= ~(UNIT_TM_POLL|TMUF_NOASYNCH); /* no polling, not asynch disabled */
return SCPE_OK;
}
static int32 _tmxr_activate_delay (UNIT *uptr, int32 interval)
{
TMXR *mp = (TMXR *)uptr->tmxr;
int32 i, sooner = interval, due;
double sim_gtime_now = sim_gtime ();
for (i=0; i<mp->lines; i++) {
TMLN *lp = &mp->ldsc[i];
if (uptr == lp->uptr) { /* read polling unit? */
if ((lp->send.extoff < lp->send.insoff) &&
(sim_gtime_now < lp->send.next_time))
due = (int32)(lp->send.next_time - sim_gtime_now);
else {
if ((lp->rxbps) && /* while rate limiting? */
(tmxr_rqln_bare (lp, FALSE))) { /* with pending input data */
if (lp->rxnexttime > sim_gtime_now)
due = (int32)(lp->rxnexttime - sim_gtime_now);
else
due = sim_processing_event ? 1 : 0; /* avoid potential infinite loop if called from service routine */
}
else
due = interval;
}
sooner = MIN(sooner, due);
}
if ((lp->conn || lp->txbfd) && /* Connected (or buffered)? */
(uptr == lp->o_uptr) && /* output completion unit? */
(lp->txbps)) { /* while rate limiting */
if ((tmxr_tqln(lp)) && /* pending output data */
(lp->txnexttime < sim_gtime_now))/* that can be transmitted now? */
tmxr_send_buffered_data (lp);/* flush it */
if (tmxr_tqln(lp) == 0) /* no pending output data */
due = interval; /* No rush */
else {
if (lp->txnexttime > sim_gtime_now)
due = (int32)(lp->txnexttime - sim_gtime_now);
else
due = sim_processing_event ? 1 : 0; /* avoid potential infinite loop if called from service routine */
}
sooner = MIN(sooner, due);
}
}
return sooner;
}
t_stat tmxr_activate (UNIT *uptr, int32 interval)
{
int32 sooner;
if (uptr->dynflags & UNIT_TMR_UNIT)
return sim_timer_activate (uptr, interval); /* Handle the timer case */
if (!(uptr->dynflags & UNIT_TM_POLL))
return _sim_activate (uptr, interval); /* Handle the non mux case */
sooner = _tmxr_activate_delay (uptr, interval);
if (sooner != interval) {
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate() - scheduling %s after %d instructions rather than %d instructions\n", sim_uname (uptr), sooner, interval);
return _sim_activate (uptr, sooner); /* Handle the busy case */
}
#if defined(SIM_ASYNCH_MUX)
if (!sim_asynch_enabled) {
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate() - scheduling %s after %d instructions\n", sim_uname (uptr), interval);
return _sim_activate (uptr, interval);
}
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate() - scheduling %s asynchronously instead of %d instructions\n", sim_uname (uptr), interval);
return SCPE_OK;
#else
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate() - scheduling %s after %d instructions\n", sim_uname (uptr), interval);
return _sim_activate (uptr, interval);
#endif
}
t_stat tmxr_activate_abs (UNIT *uptr, int32 interval)
{
AIO_VALIDATE; /* Can't call asynchronously */
sim_cancel (uptr);
return tmxr_activate (uptr, interval);
}
t_stat tmxr_activate_after (UNIT *uptr, uint32 usecs_walltime)
{
int32 sooner;
if (uptr->dynflags & UNIT_TMR_UNIT)
return _sim_activate_after (uptr, (double)usecs_walltime); /* Handle the timer case */
if (!(uptr->dynflags & UNIT_TM_POLL))
return _sim_activate_after (uptr, (double)usecs_walltime); /* Handle the non mux case */
sooner = _tmxr_activate_delay (uptr, 0x7FFFFFFF);
if (sooner != 0x7FFFFFFF) {
if (sooner < 0) {
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate_after() - scheduling %s for %u usecs produced overflow interval %d instructions, sceduling for %d instructions\n", sim_uname (uptr), usecs_walltime, sooner, 0x7FFFFFFF);
sooner = _tmxr_activate_delay (uptr, 0x7FFFFFFF); /* Breakpoint here on unexpected value */
}
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate_after() - scheduling %s after %d instructions rather than %u usecs\n", sim_uname (uptr), sooner, usecs_walltime);
return _sim_activate (uptr, sooner); /* Handle the busy case directly */
}
#if defined(SIM_ASYNCH_MUX)
if (!sim_asynch_enabled) {
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate_after() - scheduling %s after %u usecs\n", sim_uname (uptr), usecs_walltime);
return _sim_activate_after (uptr, (double)usecs_walltime);
}
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate_after() - scheduling %s asynchronously instead of %u usecs\n", sim_uname (uptr), usecs_walltime);
return SCPE_OK;
#else
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_activate_after() - scheduling %s after %.0f usecs\n", sim_uname (uptr), (double)usecs_walltime);
return _sim_activate_after (uptr, (double)usecs_walltime);
#endif
}
t_stat tmxr_activate_after_abs (UNIT *uptr, uint32 usecs_walltime)
{
sim_cancel (uptr);
return tmxr_activate_after (uptr, usecs_walltime);
}
t_stat tmxr_clock_coschedule (UNIT *uptr, int32 interval)
{
int32 tmr = sim_rtcn_calibrated_tmr ();
int32 ticks = (interval + (sim_rtcn_tick_size (tmr)/2))/sim_rtcn_tick_size (tmr);/* Convert to ticks */
return tmxr_clock_coschedule_tmr (uptr, tmr, ticks);
}
t_stat tmxr_clock_coschedule_abs (UNIT *uptr, int32 interval)
{
sim_cancel (uptr);
return tmxr_clock_coschedule (uptr, interval);
}
t_stat tmxr_clock_coschedule_tmr (UNIT *uptr, int32 tmr, int32 ticks)
{
int32 interval = ticks * sim_rtcn_tick_size (tmr);
int32 sooner;
if (uptr->dynflags & UNIT_TMR_UNIT)
return sim_clock_coschedule_tmr (uptr, tmr, ticks); /* Handle the timer case */
if (!(uptr->dynflags & UNIT_TM_POLL))
return sim_clock_coschedule_tmr (uptr, tmr, ticks); /* Handle the non mux case */
sooner = _tmxr_activate_delay (uptr, interval);
if (sooner != interval) {
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_clock_coschedule_tmr(tmr=%d) - scheduling %s after %d instructions rather than %d ticks (%d instructions)\n", tmr, sim_uname (uptr), sooner, ticks, interval);
return _sim_activate (uptr, sooner); /* Handle the busy case directly */
}
#if defined(SIM_ASYNCH_MUX)
if (!sim_asynch_enabled) {
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_clock_coschedule_tmr(tmr=%d) - coscheduling %s after interval %d ticks\n", tmr, sim_uname (uptr), ticks);
return sim_clock_coschedule (uptr, tmr, ticks);
}
return SCPE_OK;
#else
sim_debug (TIMER_DBG_MUX, &sim_timer_dev, "tmxr_clock_coschedule_tmr(tmr=%d) - coscheduling %s after interval %d ticks\n", tmr, sim_uname (uptr), ticks);
return sim_clock_coschedule_tmr (uptr, tmr, ticks);
#endif
}
t_stat tmxr_clock_coschedule_tmr_abs (UNIT *uptr, int32 tmr, int32 ticks)
{
sim_cancel (uptr);
return tmxr_clock_coschedule_tmr (uptr, tmr, ticks);
}
/* Generic Multiplexer attach help */
t_stat tmxr_attach_help(FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
TMXR *mux = (TMXR *)dptr->help_ctx;
t_bool single_line = FALSE; /* default to Multi-Line help */
t_bool port_speed_control = FALSE;
t_bool modem_control = FALSE;
if (mux) {
single_line = (mux->lines == 1);
port_speed_control = mux->port_speed_control;
modem_control = mux->modem_control;
}
if (!flag)
fprintf (st, "%s Multiplexer Attach Help\n\n", dptr->name);
if (single_line) { /* Single Line Multiplexer */
fprintf (st, "The %s multiplexer may be connected to terminal emulators supporting the\n", dptr->name);
fprintf (st, "Telnet protocol via sockets, or to hardware terminals via host serial\n");
fprintf (st, "ports.\n\n");
if (modem_control) {
fprintf (st, "The %s device is a full modem control device and therefore is capable of\n", dptr->name);
fprintf (st, "passing port configuration information and modem signals.\n");
}
fprintf (st, "A Telnet listening port can be configured with:\n\n");
fprintf (st, " sim> ATTACH %s {interface:}port\n\n", dptr->name);
fprintf (st, "Line buffering can be enabled for the %s device with:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s Buffer{=bufsize}\n\n", dptr->name);
fprintf (st, "Line buffering can be disabled for the %s device with:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s NoBuffer\n\n", dptr->name);
fprintf (st, "The default buffer size is 32k bytes, the max buffer size is 1024k bytes\n\n");
fprintf (st, "The outbound traffic the %s device can be logged to a file with:\n", dptr->name);
fprintf (st, " sim> ATTACH %s Log=LogFileName\n\n", dptr->name);
fprintf (st, "File logging can be disabled for the %s device with:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s NoLog\n\n", dptr->name);
fprintf (st, "The %s device may be connected to a serial port on the host system.\n", dptr->name);
}
else {
fprintf (st, "%s multiplexer lines may be connected to terminal emulators supporting the\n", dptr->name);
fprintf (st, "Telnet protocol via sockets, or to hardware terminals via host serial\n");
fprintf (st, "ports. Concurrent Telnet and serial connections may be mixed on a given\n");
fprintf (st, "multiplexer.\n\n");
if (modem_control) {
fprintf (st, "The %s device is a full modem control device and therefore is capable of\n", dptr->name);
fprintf (st, "passing port configuration information and modem signals on all lines.\n");
}
fprintf (st, "Modem Control signalling behaviors can be enabled/disabled on a specific\n");
fprintf (st, "multiplexer line with:\n\n");
fprintf (st, " sim> ATTACH %s Line=n,Modem\n", dptr->name);
fprintf (st, " sim> ATTACH %s Line=n,NoModem\n\n", dptr->name);
fprintf (st, "A Telnet listening port can be configured with:\n\n");
fprintf (st, " sim> ATTACH %s {interface:}port\n\n", dptr->name);
if (mux)
fprintf (st, "Line buffering for all %d lines on the %s device can be configured with:\n\n", mux->lines, dptr->name);
else
fprintf (st, "Line buffering for all lines on the %s device can be configured with:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s Buffer{=bufsize}\n\n", dptr->name);
if (mux)
fprintf (st, "Line buffering for all %d lines on the %s device can be disabled with:\n\n", mux->lines, dptr->name);
else
fprintf (st, "Line buffering for all lines on the %s device can be disabled with:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s NoBuffer\n\n", dptr->name);
fprintf (st, "The default buffer size is 32k bytes, the max buffer size is 1024k bytes\n\n");
fprintf (st, "The outbound traffic for the lines of the %s device can be logged to files\n", dptr->name);
fprintf (st, "with:\n\n");
fprintf (st, " sim> ATTACH %s Log=LogFileName\n\n", dptr->name);
fprintf (st, "The log file name for each line uses the above LogFileName as a template\n");
fprintf (st, "for the actual file name which will be LogFileName_n where n is the line\n");
fprintf (st, "number.\n\n");
fprintf (st, "Multiplexer lines may be connected to serial ports on the host system.\n");
}
fprintf (st, "Serial ports may be specified as an operating system specific device names\n");
fprintf (st, "or using simh generic serial names. simh generic names are of the form\n");
fprintf (st, "serN, where N is from 0 thru one less than the maximum number of serial\n");
fprintf (st, "ports on the local system. The mapping of simh generic port names to OS \n");
fprintf (st, "specific names can be displayed using the following command:\n\n");
fprintf (st, " sim> SHOW SERIAL\n");
fprintf (st, " Serial devices:\n");
fprintf (st, " ser0 COM1 (\\Device\\Serial0)\n");
fprintf (st, " ser1 COM3 (Winachcf0)\n\n");
if (single_line) { /* Single Line Multiplexer */
fprintf (st, " sim> ATTACH %s Connect=ser0\n\n", dptr->name);
fprintf (st, "or equivalently:\n\n");
fprintf (st, " sim> ATTACH %s Connect=COM1\n\n", dptr->name);
}
else {
fprintf (st, " sim> ATTACH %s Line=n,Connect=ser0\n\n", dptr->name);
fprintf (st, "or equivalently:\n\n");
fprintf (st, " sim> ATTACH %s Line=n,Connect=COM1\n\n", dptr->name);
if (mux)
fprintf (st, "Valid line numbers are from 0 thru %d\n\n", mux->lines-1);
}
if (single_line) { /* Single Line Multiplexer */
if (port_speed_control) {
fprintf (st, "The data rate for the %s device is set programmatically within\n", dptr->name);
fprintf (st, "the running simulator. When connected via a telnet session, a\n");
fprintf (st, "speed increase factor can be specified with a SPEED=*factor on\n");
fprintf (st, "the ATTACH command.\n");
}
else {
fprintf (st, "The data rate for the %s device can be controlled by\n", dptr->name);
fprintf (st, "specifying SPEED=nnn{*factor} on the the ATTACH command.\n");
}
}
else {
if (port_speed_control) {
fprintf (st, "The data rates for the lines of the %s device are set\n", dptr->name);
fprintf (st, "programmatically within the running simulator. When connected\n");
fprintf (st, "via telnet sessions, a speed increase factor can be specified with\n");
fprintf (st, "a SPEED=*factor on the ATTACH command.\n");
}
else {
fprintf (st, "The data rate for all lines or a particular line of a the %s\n", dptr->name);
fprintf (st, "device can be controlled by specifying SPEED=nnn{*fac} on the ATTACH\n");
fprintf (st, "command.\n");
}
}
if (!port_speed_control) {
fprintf (st, "SPEED values can be any one of:\n\n");
fprintf (st, " 0 50 75 110 134 150 300 600 1200 1800 2000 2400\n");
fprintf (st, " 3600 4800 7200 9600 19200 38400 57600 76800 115200\n\n");
fprintf (st, "A SPEED value of 0 causes input data to be delivered to the simulated\n");
fprintf (st, "port as fast as it arrives.\n\n");
}
else {
fprintf (st, "\n");
}
fprintf (st, "Some simulated systems run very much faster than the original system\n");
fprintf (st, "which is being simulated. To accommodate this, multiplexer lines \n");
fprintf (st, "connected via telnet sessions may include a factor which will increase\n");
fprintf (st, "the input and output data delivery rates by the specified factor.\n");
fprintf (st, "A factor is specified with a speed ");
if (!port_speed_control) {
fprintf (st, "value of the form \"speed*factor\"\n");
fprintf (st, "Factor values can range from 1 thru 32.\n");
fprintf (st, "Example:\n\n");
fprintf (st, " sim> ATTACH %s 1234,SPEED=2400\n", dptr->name);
fprintf (st, " sim> ATTACH %s 1234,SPEED=9600*8\n", dptr->name);
if (!single_line)
fprintf (st, " sim> ATTACH %s Line=2,SPEED=2400\n", dptr->name);
fprintf (st, "\n");
}
else {
fprintf (st, "value of the form \"*factor\"\n");
fprintf (st, "Factor values can range from 1 thru 32.\n");
fprintf (st, "Example:\n\n");
fprintf (st, " sim> ATTACH %s 1234,SPEED=*8\n", dptr->name);
if (!single_line)
fprintf (st, " sim> ATTACH %s Line=2,SPEED=*4\n", dptr->name);
fprintf (st, "\n");
fprintf (st, "If an attach command specifies a speed multiply factor, that value will\n");
fprintf (st, "persist independent of any programatic action by the simulated system to\n");
fprintf (st, "change the port speed.\n\n");
}
if (!port_speed_control) {
fprintf (st, "An optional serial port configuration string may be present after the port\n");
fprintf (st, "name. If present, it must be separated from the port name with a semicolon\n");
fprintf (st, "and has this form:\n\n");
fprintf (st, " <rate>-<charsize><parity><stopbits>\n\n");
fprintf (st, "where:\n");
fprintf (st, " rate = communication rate in bits per second\n");
fprintf (st, " charsize = character size in bits (5-8, including optional parity)\n");
fprintf (st, " parity = parity designator (N/E/O/M/S for no/even/odd/mark/space parity)\n");
fprintf (st, " stopbits = number of stop bits (1, 1.5, or 2)\n\n");
fprintf (st, "As an example:\n\n");
fprintf (st, " 9600-8n1\n\n");
fprintf (st, "The supported rates, sizes, and parity options are host-specific. If\n");
fprintf (st, "a configuration string is not supplied, then the default of 9600-8N1\n");
fprintf (st, "is used.\n");
fprintf (st, "Note: The serial port configuration option is only available on multiplexer\n");
fprintf (st, " lines which are not operating with full modem control behaviors enabled.\n");
fprintf (st, " Lines with full modem control behaviors enabled have all of their\n");
fprintf (st, " configuration managed by the Operating System running within the\n");
fprintf (st, " simulator.\n\n");
}
fprintf (st, "An attachment to a serial port with the '-V' switch will cause a\n");
fprintf (st, "connection message to be output to the connected serial port.\n");
fprintf (st, "This will help to confirm the correct port has been connected and\n");
fprintf (st, "that the port settings are reasonable for the connected device.\n");
fprintf (st, "This would be done as:\n\n");
if (single_line) /* Single Line Multiplexer */
fprintf (st, " sim> ATTACH -V %s Connect=SerN\n", dptr->name);
else {
fprintf (st, " sim> ATTACH -V %s Line=n,Connect=SerN\n\n", dptr->name);
fprintf (st, "Line specific tcp listening ports are supported. These are configured\n");
fprintf (st, "using commands of the form:\n\n");
fprintf (st, " sim> ATTACH %s Line=n,{interface:}port{;notelnet}\n\n", dptr->name);
}
fprintf (st, "Direct computer to computer connections (Virutal Null Modem cables) may\n");
fprintf (st, "be established using the telnet protocol or via raw tcp sockets.\n\n");
fprintf (st, " sim> ATTACH %s Line=n,Connect=host:port{;notelnet}\n\n", dptr->name);
fprintf (st, "Computer to computer virtual connections can be one way (as illustrated\n");
fprintf (st, "above) or symmetric. A symmetric connection is configured by combining\n");
if (single_line) { /* Single Line Multiplexer */
fprintf (st, "a one way connection with a tcp listening port on the same line:\n\n");
fprintf (st, " sim> ATTACH %s listenport,Connect=host:port\n\n", dptr->name);
}
else {
fprintf (st, "a one way connection with a tcp listening port on the same line:\n\n");
fprintf (st, " sim> ATTACH %s Line=n,listenport,Connect=host:port\n\n", dptr->name);
}
fprintf (st, "When symmetric virtual connections are configured, incoming connections\n");
fprintf (st, "on the specified listening port are checked to assure that they actually\n");
fprintf (st, "come from the specified connection destination host system.\n\n");
if (single_line) { /* Single Line Multiplexer */
fprintf (st, "The %s device can be attached in LOOPBACK mode:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s Loopback\n\n", dptr->name);
}
else {
fprintf (st, "A line on the %s device can be attached in LOOPBACK mode:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s Line=n,Loopback\n\n", dptr->name);
fprintf (st, "A line on the %s device can be specifically disabled:\n\n", dptr->name);
fprintf (st, " sim> ATTACH %s Line=n,Disable\n\n", dptr->name);
}
fprintf (st, "When operating in LOOPBACK mode, all outgoing data arrives as input and\n");
fprintf (st, "outgoing modem signals (if enabled) (DTR and RTS) are reflected in the\n");
fprintf (st, "incoming modem signals (DTR->(DCD and DSR), RTS->CTS)\n\n");
if (single_line) /* Single Line Multiplexer */
fprintf (st, "The connection configured for the %s device is unconfigured by:\n\n", dptr->name);
else
fprintf (st, "All connections configured for the %s device are unconfigured by:\n\n", dptr->name);
fprintf (st, " sim> DETACH %s\n\n", dptr->name);
if (dptr->modifiers) {
MTAB *mptr;
for (mptr = dptr->modifiers; mptr->mask != 0; mptr++)
if (mptr->valid == &tmxr_dscln) {
fprintf (st, "A specific line on the %s device can be disconnected with:\n\n", dptr->name);
fprintf (st, " sim> SET %s %s=n\n\n", dptr->name, mptr->mstring);
fprintf (st, "This will cause a telnet connection to be closed, but a serial port will\n");
fprintf (st, "normally have DTR dropped for 500ms and raised again (thus hanging up a\n");
fprintf (st, "modem on that serial port).\n\n");
fprintf (st, "A line which is connected to a serial port can be manually closed by\n");
fprintf (st, "adding the -C switch to a %s command.\n\n", mptr->mstring);
fprintf (st, " sim> SET -C %s %s=n\n\n", dptr->name, mptr->mstring);
}
}
return SCPE_OK;
}
/* Stub examine and deposit */
t_stat tmxr_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw)
{
return SCPE_NOFNC;
}
t_stat tmxr_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw)
{
return SCPE_NOFNC;
}
/* Write a message directly to a socket */
void tmxr_msg (SOCKET sock, const char *msg)
{
if ((sock) && (sock != INVALID_SOCKET))
sim_write_sock (sock, msg, (int32)strlen (msg));
}
/* Write a message to a line */
void tmxr_linemsg (TMLN *lp, const char *msg)
{
while (*msg) {
while (SCPE_STALL == tmxr_putc_ln (lp, (int32)(*msg)))
if (lp->txbsz == tmxr_send_buffered_data (lp))
sim_os_ms_sleep (10);
++msg;
}
}
/* Write a formatted message to a line */
void tmxr_linemsgf (TMLN *lp, const char *fmt, ...)
{
va_list arglist;
va_start (arglist, fmt);
tmxr_linemsgvf (lp, fmt, arglist);
va_end (arglist);
}
void tmxr_linemsgvf (TMLN *lp, const char *fmt, va_list arglist)
{
char stackbuf[STACKBUFSIZE];
int32 bufsize = sizeof(stackbuf);
char *buf = stackbuf;
int32 i, len;
buf[bufsize-1] = '\0';
while (1) { /* format passed string, args */
#if defined(NO_vsnprintf)
len = vsprintf (buf, fmt, arglist);
#else /* !defined(NO_vsnprintf) */
len = vsnprintf (buf, bufsize-1, fmt, arglist);
#endif /* NO_vsnprintf */
/* If the formatted result didn't fit into the buffer, then grow the buffer and try again */
if ((len < 0) || (len >= bufsize-1)) {
if (buf != stackbuf)
free (buf);
bufsize = bufsize * 2;
if (bufsize < len + 2)
bufsize = len + 2;
buf = (char *) malloc (bufsize);
if (buf == NULL) /* out of memory */
return;
buf[bufsize-1] = '\0';
continue;
}
break;
}
/* Output the formatted data expanding newlines where they exist */
for (i = 0; i < len; ++i) {
if (('\n' == buf[i]) && ((i == 0) || ('\r' != buf[i-1]))) {
while (SCPE_STALL == tmxr_putc_ln (lp, '\r'))
if (lp->txbsz == tmxr_send_buffered_data (lp))
sim_os_ms_sleep (10);
}
while (SCPE_STALL == tmxr_putc_ln (lp, buf[i]))
if (lp->txbsz == tmxr_send_buffered_data (lp))
sim_os_ms_sleep (10);
}
if (buf != stackbuf)
free (buf);
}
/* Print connections - used only in named SHOW command */
void tmxr_fconns (FILE *st, const TMLN *lp, int32 ln)
{
int32 hr, mn, sc;
uint32 ctime;
if (ln >= 0)
fprintf (st, "line %d: ", ln);
if ((lp->sock) || (lp->connecting)) { /* tcp connection? */
if (lp->destination) /* remote connection? */
if (lp->datagram)
fprintf (st, "Datagram Connection from %s to remote port %s\n", lp->port, lp->destination);/* print port name */
else
fprintf (st, "Connection to remote port %s\n", lp->destination);/* print port name */
else /* incoming connection */
fprintf (st, "Connection from IP address %s\n", lp->ipad);
}
else
if ((lp->destination) && (!lp->serport)) /* remote connection? */
fprintf (st, "Connecting to remote port %s\n", lp->destination);/* print port name */
if (lp->sock) {
char *sockname, *peername;
sim_getnames_sock (lp->sock, &sockname, &peername);
fprintf (st, "Connection %s->%s\n", sockname, peername);
free (sockname);
free (peername);
}
if ((lp->port) && (!lp->datagram))
fprintf (st, "Listening on port %s\n", lp->port); /* print port name */
if (lp->serport) /* serial connection? */
fprintf (st, "Connected to serial port %s\n", lp->destination); /* print port name */
if (lp->cnms) {
ctime = (sim_os_msec () - lp->cnms) / 1000;
hr = ctime / 3600;
mn = (ctime / 60) % 60;
sc = ctime % 60;
if (ctime)
fprintf (st, " %s %02d:%02d:%02d\n", lp->connecting ? "Connecting for" : "Connected", hr, mn, sc);
}
else
fprintf (st, " Line disconnected%s\n", lp->txbfd ? " (buffered)" : "");
if (lp->modem_control) {
fprintf (st, " Modem Bits: %s%s%s%s%s%s\n", (lp->modembits & TMXR_MDM_DTR) ? "DTR " : "",
(lp->modembits & TMXR_MDM_RTS) ? "RTS " : "",
(lp->modembits & TMXR_MDM_DCD) ? "DCD " : "",
(lp->modembits & TMXR_MDM_RNG) ? "RNG " : "",
(lp->modembits & TMXR_MDM_CTS) ? "CTS " : "",
(lp->modembits & TMXR_MDM_DSR) ? "DSR " : "");
}
if ((lp->serport == 0) && (lp->sock) && (!lp->datagram))
fprintf (st, " %s\n", (lp->notelnet) ? "Telnet disabled (RAW data)" : "Telnet protocol");
if (lp->send.buffer)
sim_show_send_input (st, &lp->send);
if (lp->expect.buf)
sim_exp_showall (st, &lp->expect);
if (lp->txlog)
fprintf (st, " Logging to %s\n", lp->txlogname);
}
/* Print statistics - used only in named SHOW command */
void tmxr_fstats (FILE *st, const TMLN *lp, int32 ln)
{
static const char *enab = "on";
static const char *dsab = "off";
if (ln >= 0)
fprintf (st, "Line %d:", ln);
if ((!lp->sock) && (!lp->connecting) && (!lp->serport))
fprintf (st, " not connected\n");
else {
if (ln >= 0)
fprintf (st, "\n");
fprintf (st, " input (%s)", (lp->rcve? enab: dsab));
if (lp->rxcnt)
fprintf (st, " queued/total = %d/%d", tmxr_rqln (lp), lp->rxcnt);
if (lp->rxpcnt)
fprintf (st, " packets = %d", lp->rxpcnt);
fprintf (st, "\n output (%s)", (lp->xmte? enab: dsab));
if (lp->txcnt || lp->txbpi)
fprintf (st, " queued/total = %d/%d", tmxr_tqln (lp), lp->txcnt);
if (lp->txpcnt || tmxr_tpqln (lp))
fprintf (st, " packet data queued/packets sent = %d/%d",
tmxr_tpqln (lp), lp->txpcnt);
fprintf (st, "\n");
if ((lp->rxbps) || (lp->txbps)) {
if ((lp->rxbps == lp->txbps))
fprintf (st, " speed = %u", lp->rxbps);
else
fprintf (st, " speed = %u/%u", lp->rxbps, lp->txbps);
if (lp->bpsfactor > 1.0)
fprintf (st, "*%.0f", lp->bpsfactor);
fprintf (st, " bps\n");
}
}
if (lp->txbfd)
fprintf (st, " output buffer size = %d\n", lp->txbsz);
if (lp->txcnt || lp->txbpi)
fprintf (st, " bytes in buffer = %d\n",
((lp->txcnt > 0) && (lp->txcnt > lp->txbsz)) ? lp->txbsz : lp->txbpi);
if (lp->txdrp)
fprintf (st, " dropped = %d\n", lp->txdrp);
if (lp->txstall)
fprintf (st, " stalled = %d\n", lp->txstall);
}
/* Disconnect a line.
Disconnect a line of the multiplexer associated with descriptor "desc" from a
tcp session or a serial port. Two calling sequences are supported:
1. If "val" is zero, then "uptr" is implicitly associated with the line
number corresponding to the position of the unit in the zero-based array
of units belonging to the associated device, and "cptr" is ignored. For
example, if "uptr" points to unit 3 in a given device, then line 3 will
be disconnected.
2. If "val" is non-zero, then "cptr" points to a string that is parsed for
an explicit line number, and "uptr" is ignored. For example, if "cptr"
points to the string "3", then line 3 will be disconnected.
If the line was connected to a tcp session, the socket associated with the
line will be closed. If the line was connected to a serial port, the port
will NOT be closed, but DTR will be dropped. After a 500ms delay DTR will
be raised again. If the sim_switches -C flag is set, then a serial port
connection will be closed.
Implementation notes:
1. This function is usually called as an MTAB processing routine.
*/
t_stat tmxr_dscln (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
{
TMXR *mp = (TMXR *) desc;
TMLN *lp;
t_stat status;
if (val) /* explicit line? */
uptr = NULL; /* indicate to get routine */
tmxr_debug_trace (mp, "tmxr_dscln()");
lp = tmxr_get_ldsc (uptr, cptr, mp, &status); /* get referenced line */
if (lp == NULL) /* bad line number? */
return status; /* report it */
if ((lp->sock) || (lp->serport)) { /* connection active? */
if (!lp->notelnet)
tmxr_linemsg (lp, "\r\nOperator disconnected line\r\n\n");/* report closure */
if (lp->serport && (sim_switches & SWMASK ('C')))
return tmxr_detach_ln (lp);
return tmxr_reset_ln_ex (lp, FALSE); /* drop the line */
}
return SCPE_OK;
}
/* Enable logging for line */
t_stat tmxr_set_log (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
{
TMXR *mp = (TMXR *) desc;
TMLN *lp;
if (cptr == NULL) /* no file name? */
return SCPE_2FARG;
lp = tmxr_find_ldsc (uptr, val, mp); /* find line desc */
if (lp == NULL)
return SCPE_IERR;
if (lp->txlog) /* close existing log */
tmxr_set_nolog (NULL, val, NULL, desc);
lp->txlogname = (char *) calloc (CBUFSIZE, sizeof (char)); /* alloc namebuf */
if (lp->txlogname == NULL) /* can't? */
return SCPE_MEM;
strlcpy (lp->txlogname, cptr, CBUFSIZE); /* save file name */
sim_open_logfile (cptr, TRUE, &lp->txlog, &lp->txlogref);/* open log */
if (lp->txlog == NULL) { /* error? */
free (lp->txlogname); /* free buffer */
return SCPE_OPENERR;
}
if (mp->uptr) /* attached?, then update attach string */
lp->mp->uptr->filename = tmxr_mux_attach_string (lp->mp->uptr->filename, lp->mp);
return SCPE_OK;
}
/* Disable logging for line */
t_stat tmxr_set_nolog (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
{
TMXR *mp = (TMXR *) desc;
TMLN *lp;
if (cptr) /* no arguments */
return SCPE_2MARG;
lp = tmxr_find_ldsc (uptr, val, mp); /* find line desc */
if (lp == NULL)
return SCPE_IERR;
if (lp->txlog) { /* logging? */
sim_close_logfile (&lp->txlogref); /* close log */
free (lp->txlogname); /* free namebuf */
lp->txlog = NULL;
lp->txlogname = NULL;
}
if (mp->uptr)
lp->mp->uptr->filename = tmxr_mux_attach_string (lp->mp->uptr->filename, lp->mp);
return SCPE_OK;
}
/* Show logging status for line */
t_stat tmxr_show_log (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
{
const TMXR *mp = (const TMXR *) desc;
TMLN *lp;
lp = tmxr_find_ldsc (uptr, val, mp); /* find line desc */
if (lp == NULL)
return SCPE_IERR;
if (lp->txlog)
fprintf (st, "logging to %s", lp->txlogname);
else fprintf (st, "no logging");
return SCPE_OK;
}
/* Set the line connection order.
Example command for eight-line multiplexer:
SET <dev> LINEORDER=1;5;2-4;7
Resulting connection order: 1,5,2,3,4,7,0,6.
Parameters:
- uptr = (not used)
- val = (not used)
- cptr = pointer to first character of range specification
- desc = pointer to multiplexer's TMXR structure
On entry, cptr points to the value portion of the command string, which may
be either a semicolon-separated list of line ranges or the keyword ALL.
If a line connection order array is not defined in the multiplexer
descriptor, the command is rejected. If the specified range encompasses all
of the lines, the first value of the connection order array is set to -1 to
indicate sequential connection order. Otherwise, the line values in the
array are set to the order specified by the command string. All values are
populated, first with those explicitly specified in the command string, and
then in ascending sequence with those not specified.
If an error occurs, the original line order is not disturbed.
*/
t_stat tmxr_set_lnorder (UNIT *uptr, int32 val, CONST char *carg, void *desc)
{
TMXR *mp = (TMXR *) desc;
char *tbuf;
char *tptr;
CONST char *cptr;
t_addr low, high, max = (t_addr) mp->lines - 1;
int32 *list;
t_bool *set;
uint32 line, idx = 0;
t_stat result = SCPE_OK;
if (mp->lnorder == NULL) /* line connection order undefined? */
return SCPE_NXPAR; /* "Non-existent parameter" error */
else if ((carg == NULL) || (*carg == '\0')) /* line range not supplied? */
return SCPE_MISVAL; /* "Missing value" error */
list = (int32 *) calloc (mp->lines, sizeof (int32)); /* allocate new line order array */
if (list == NULL) /* allocation failed? */
return SCPE_MEM; /* report it */
set = (t_bool *) calloc (mp->lines, sizeof (t_bool)); /* allocate line set tracking array */
if (set == NULL) { /* allocation failed? */
free (list); /* free successful list allocation */
return SCPE_MEM; /* report it */
}
tbuf = (char *) calloc (strlen(carg)+2, sizeof(*carg));
strcpy (tbuf, carg);
tptr = tbuf + strlen (tbuf); /* append a semicolon */
*tptr++ = ';'; /* to the command string */
*tptr = '\0'; /* to make parsing easier for get_range */
cptr = tbuf;
while (*cptr) { /* parse command string */
cptr = get_range (NULL, cptr, &low, &high, 10, max, ';');/* get a line range */
if (cptr == NULL) { /* parsing error? */
result = SCPE_ARG; /* "Invalid argument" error */
break;
}
else if ((low > max) || (high > max)) { /* line out of range? */
result = SCPE_SUB; /* "Subscript out of range" error */
break;
}
else if ((low == 0) && (high == max)) { /* entire line range specified? */
list [0] = -1; /* set sequential order flag */
idx = (uint32) max + 1; /* indicate no fill-in needed */
break;
}
else
for (line = (uint32) low; line <= (uint32) high; line++) /* see if previously specified */
if (set [line] == FALSE) { /* not already specified? */
set [line] = TRUE; /* now it is */
list [idx] = line; /* add line to connection order */
idx = idx + 1; /* bump "specified" count */
}
}
if (result == SCPE_OK) { /* assignment successful? */
if (idx <= max) /* any lines not specified? */
for (line = 0; line <= max; line++) /* fill them in sequentially */
if (set [line] == FALSE) { /* specified? */
list [idx] = line; /* no, so add it */
idx = idx + 1;
}
memcpy (mp->lnorder, list, mp->lines * sizeof (int32)); /* copy working array to connection array */
}
free (list); /* free list allocation */
free (set); /* free set allocation */
free (tbuf); /* free arg copy with ; */
return result;
}
/* Show line connection order.
Parameters:
- st = stream on which output is to be written
- uptr = (not used)
- val = (not used)
- desc = pointer to multiplexer's TMXR structure
If a connection order array is not defined in the multiplexer descriptor, the
command is rejected. If the first value of the connection order array is set
to -1, then the connection order is sequential. Otherwise, the line values
in the array are printed as a semicolon-separated list. Ranges are printed
where possible to shorten the output.
*/
t_stat tmxr_show_lnorder (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
{
int32 i, j, low, last;
const TMXR *mp = (const TMXR *) desc;
int32 *iptr = mp->lnorder;
t_bool first = TRUE;
if (iptr == NULL) /* connection order undefined? */
return SCPE_NXPAR; /* "Non-existent parameter" error */
if (*iptr < 0) /* sequential order indicated? */
fprintf (st, "Order=0-%d\n", mp->lines - 1); /* print full line range */
else {
low = last = *iptr++; /* set first line value */
for (j = 1; j <= mp->lines; j++) { /* print remaining lines in order list */
if (j < mp->lines) /* more lines to process? */
i = *iptr++; /* get next line in list */
else /* final iteration */
i = -1; /* get "tie-off" value */
if (i != last + 1) { /* end of a range? */
if (first) { /* first line to print? */
fputs ("Order=", st); /* print header */
first = FALSE;
}
else /* not first line printed */
fputc (';', st); /* print separator */
if (low == last) /* range null? */
fprintf (st, "%d", last); /* print single line value */
else /* range established */
fprintf (st, "%d-%d", low, last); /* print start and end line */
low = i; /* start new range */
}
last = i; /* note value for range check */
}
}
if (first == FALSE) /* sanity check for lines == 0 */
fputc ('\n', st);
return SCPE_OK;
}
/* Show summary processor */
t_stat tmxr_show_summ (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
{
const TMXR *mp = (const TMXR *) desc;
int32 i, t;
if (mp == NULL)
return SCPE_IERR;
for (i = t = 0; i < mp->lines; i++)
if ((mp->ldsc[i].sock != 0) || (mp->ldsc[i].serport != 0))
t = t + 1;
if (mp->lines > 1)
fprintf (st, "%d current connection%s", t, (t != 1) ? "s" : "");
else
fprintf (st, "%s", (t == 1) ? "connected" : "disconnected");
return SCPE_OK;
}
/* Show conn/stat processor */
t_stat tmxr_show_cstat (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
{
const TMXR *mp = (const TMXR *) desc;
int32 i, any;
if (mp == NULL)
return SCPE_IERR;
for (i = any = 0; i < mp->lines; i++) {
if ((mp->ldsc[i].sock != 0) ||
(mp->ldsc[i].serport != 0) || mp->ldsc[i].modem_control) {
if ((mp->ldsc[i].sock != 0) || (mp->ldsc[i].serport != 0))
any++;
if (val)
tmxr_fconns (st, &mp->ldsc[i], i);
else
if ((mp->ldsc[i].sock != 0) || (mp->ldsc[i].serport != 0))
tmxr_fstats (st, &mp->ldsc[i], i);
}
}
if (any == 0)
fprintf (st, (mp->lines == 1? "disconnected\n": "all disconnected\n"));
return SCPE_OK;
}
/* Show number of lines */
t_stat tmxr_show_lines (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
{
const TMXR *mp = (const TMXR *) desc;
if (mp == NULL)
return SCPE_IERR;
fprintf (st, "lines=%d", mp->lines);
return SCPE_OK;
}
static struct {
u_char value;
const char *name;
} tn_chars[] =
{
{TN_IAC, "TN_IAC"}, /* protocol delim */
{TN_DONT, "TN_DONT"}, /* dont */
{TN_DO, "TN_DO"}, /* do */
{TN_WONT, "TN_WONT"}, /* wont */
{TN_WILL, "TN_WILL"}, /* will */
{TN_SB, "TN_SB"}, /* sub-option negotiation */
{TN_GA, "TN_SG"}, /* go ahead */
{TN_EL, "TN_EL"}, /* erase line */
{TN_EC, "TN_EC"}, /* erase character */
{TN_AYT, "TN_AYT"}, /* are you there */
{TN_AO, "TN_AO"}, /* abort output */
{TN_IP, "TN_IP"}, /* interrupt process */
{TN_BRK, "TN_BRK"}, /* break */
{TN_DATAMK, "TN_DATAMK"}, /* data mark */
{TN_NOP, "TN_NOP"}, /* no operation */
{TN_SE, "TN_SE"}, /* end sub-option negot */
/* Options */
{TN_BIN, "TN_BIN"}, /* bin */
{TN_ECHO, "TN_ECHO"}, /* echo */
{TN_SGA, "TN_SGA"}, /* sga */
{TN_STATUS, "TN_STATUS"}, /* option status query */
{TN_TIMING, "TN_TIMING"}, /* Timing Mark */
{TN_NAOCRD, "TN_NAOCRD"}, /* Output Carriage-Return Disposition */
{TN_NAOHTS, "TN_NAOHTS"}, /* Output Horizontal Tab Stops */
{TN_NAOHTD, "TN_NAOHTD"}, /* Output Horizontal Tab Stop Disposition */
{TN_NAOFFD, "TN_NAOFFD"}, /* Output Forfeed Disposition */
{TN_NAOVTS, "TN_NAOVTS"}, /* Output Vertical Tab Stop */
{TN_NAOVTD, "TN_NAOVTD"}, /* Output Vertical Tab Stop Disposition */
{TN_NAOLFD, "TN_NAOLFD"}, /* Output Linefeed Disposition */
{TN_EXTEND, "TN_EXTEND"}, /* Extended Ascii */
{TN_LOGOUT, "TN_LOGOUT"}, /* Logout */
{TN_BM, "TN_BM"}, /* Byte Macro */
{TN_DET, "TN_DET"}, /* Data Entry Terminal */
{TN_SENDLO, "TN_SENDLO"}, /* Send Location */
{TN_TERMTY, "TN_TERMTY"}, /* Terminal Type */
{TN_ENDREC, "TN_ENDREC"}, /* Terminal Type */
{TN_TUID, "TN_TUID"}, /* TACACS User Identification */
{TN_OUTMRK, "TN_OUTMRK"}, /* Output Marking */
{TN_TTYLOC, "TN_TTYLOC"}, /* Terminal Location Number */
{TN_3270, "TN_3270"}, /* 3270 Regime */
{TN_X3PAD, "TN_X3PAD"}, /* X.3 PAD */
{TN_NAWS, "TN_NAWS"}, /* Negotiate About Window Size */
{TN_TERMSP, "TN_TERMSP"}, /* Terminal Speed */
{TN_TOGFLO, "TN_TOGFLO"}, /* Remote Flow Control */
{TN_LINE, "TN_LINE"}, /* line mode */
{TN_XDISPL, "TN_XDISPL"}, /* X Display Location */
{TN_ENVIRO, "TN_ENVIRO"}, /* Environment */
{TN_AUTH, "TN_AUTH"}, /* Authentication */
{TN_ENCRYP, "TN_ENCRYP"}, /* Data Encryption */
{TN_NEWENV, "TN_NEWENV"}, /* New Environment */
{TN_TN3270, "TN_TN3270"}, /* TN3270 Enhancements */
{TN_CHARST, "TN_CHARST"}, /* CHARSET */
{TN_COMPRT, "TN_COMPRT"}, /* Com Port Control */
{TN_KERMIT, "TN_KERMIT"}, /* KERMIT */
{0, NULL}};
static char *tmxr_debug_buf = NULL;
static size_t tmxr_debug_buf_used = 0;
static size_t tmxr_debug_buf_size = 0;
static void tmxr_buf_debug_char (char value)
{
if (tmxr_debug_buf_used+2 > tmxr_debug_buf_size) {
tmxr_debug_buf_size += 1024;
tmxr_debug_buf = (char *)realloc (tmxr_debug_buf, tmxr_debug_buf_size);
}
tmxr_debug_buf[tmxr_debug_buf_used++] = value;
tmxr_debug_buf[tmxr_debug_buf_used] = '\0';
}
static void tmxr_buf_debug_string (const char *string)
{
while (*string)
tmxr_buf_debug_char (*string++);
}
static void tmxr_buf_debug_telnet_option (u_char chr)
{
int j;
for (j=0; 1; ++j) {
if (NULL == tn_chars[j].name) {
if (isprint(chr))
tmxr_buf_debug_char (chr);
else {
tmxr_buf_debug_char ('_');
if ((chr >= 1) && (chr <= 26)) {
tmxr_buf_debug_char ('^');
tmxr_buf_debug_char ('A' + chr - 1);
}
else {
char octal[8];
sprintf(octal, "\\%03o", (u_char)chr);
tmxr_buf_debug_string (octal);
}
tmxr_buf_debug_char ('_');
}
break;
}
if ((u_char)chr == tn_chars[j].value) {
tmxr_buf_debug_char ('_');
tmxr_buf_debug_string (tn_chars[j].name);
tmxr_buf_debug_char ('_');
break;
}
}
}
static int tmxr_buf_debug_telnet_options (u_char *buf, int bufsize)
{
int optsize = 2;
tmxr_buf_debug_telnet_option ((u_char)buf[0]);
tmxr_buf_debug_telnet_option ((u_char)buf[1]);
switch ((u_char)buf[1]) {
case TN_IAC:
default:
return optsize;
break;
case TN_WILL:
case TN_WONT:
case TN_DO:
case TN_DONT:
++optsize;
tmxr_buf_debug_telnet_option ((u_char)buf[2]);
break;
}
return optsize;
}
void _tmxr_debug (uint32 dbits, TMLN *lp, const char *msg, char *buf, int bufsize)
{
DEVICE *dptr = (lp->dptr ? lp->dptr : (lp->mp ? lp->mp->dptr : NULL));
if ((dptr) && (dbits & dptr->dctrl)) {
int i;
tmxr_debug_buf_used = 0;
if (tmxr_debug_buf)
tmxr_debug_buf[tmxr_debug_buf_used] = '\0';
if (lp->notelnet) {
int same, group, sidx, oidx;
char outbuf[80], strbuf[18];
static char hex[] = "0123456789ABCDEF";
for (i=same=0; i<bufsize; i += 16) {
if ((i > 0) && (0 == memcmp(&buf[i], &buf[i-16], 16))) {
++same;
continue;
}
if (same > 0) {
if (lp->mp->lines > 1)
sim_debug (dbits, dptr, "Line:%d %04X thru %04X same as above\n", (int)(lp-lp->mp->ldsc), i-(16*same), i-1);
else
sim_debug (dbits, dptr, "%04X thru %04X same as above\n", i-(16*same), i-1);
same = 0;
}
group = (((bufsize - i) > 16) ? 16 : (bufsize - i));
for (sidx=oidx=0; sidx<group; ++sidx) {
outbuf[oidx++] = ' ';
outbuf[oidx++] = hex[(buf[i+sidx]>>4)&0xf];
outbuf[oidx++] = hex[buf[i+sidx]&0xf];
if (isprint((u_char)buf[i+sidx]))
strbuf[sidx] = buf[i+sidx];
else
strbuf[sidx] = '.';
}
outbuf[oidx] = '\0';
strbuf[sidx] = '\0';
if (lp->mp->lines > 1)
sim_debug (dbits, dptr, "Line:%d %04X%-48s %s\n", (int)(lp-lp->mp->ldsc), i, outbuf, strbuf);
else
sim_debug (dbits, dptr, "%04X%-48s %s\n", i, outbuf, strbuf);
}
if (same > 0) {
if (lp->mp->lines > 1)
sim_debug (dbits, dptr, "Line:%d %04X thru %04X same as above\n", (int)(lp-lp->mp->ldsc), i-(16*same), bufsize-1);
else
sim_debug (dbits, dptr, "%04X thru %04X same as above\n", i-(16*same), bufsize-1);
}
}
else {
tmxr_debug_buf_used = 0;
if (tmxr_debug_buf)
tmxr_debug_buf[tmxr_debug_buf_used] = '\0';
for (i=0; i<bufsize; ++i) {
switch ((u_char)buf[i]) {
case TN_CR:
tmxr_buf_debug_string ("_TN_CR_");
break;
case TN_LF:
tmxr_buf_debug_string ("_TN_LF_");
break;
case TN_IAC:
if (!lp->notelnet) {
i += (tmxr_buf_debug_telnet_options ((u_char *)(&buf[i]), bufsize-i) - 1);
break;
}
default:
if (isprint((u_char)buf[i]))
tmxr_buf_debug_char (buf[i]);
else {
tmxr_buf_debug_char ('_');
if ((buf[i] >= 1) && (buf[i] <= 26)) {
tmxr_buf_debug_char ('^');
tmxr_buf_debug_char ('A' + buf[i] - 1);
}
else {
char octal[8];
sprintf(octal, "\\%03o", (u_char)buf[i]);
tmxr_buf_debug_string (octal);
}
tmxr_buf_debug_char ('_');
}
break;
}
}
if (lp->mp->lines > 1)
sim_debug (dbits, dptr, "Line:%d %s %d bytes '%s'\n", (int)(lp-lp->mp->ldsc), msg, bufsize, tmxr_debug_buf);
else
sim_debug (dbits, dptr, "%s %d bytes '%s'\n", msg, bufsize, tmxr_debug_buf);
}
if ((lp->rxnexttime != 0.0) || (lp->txnexttime != 0.0)) {
if (lp->rxnexttime != 0.0)
sim_debug (dbits, dptr, " rxnexttime=%.0f", lp->rxnexttime);
if (lp->txnexttime != 0.0)
sim_debug (dbits, dptr, " txnexttime=%.0f", lp->txnexttime);
sim_debug (dbits, dptr, "\n");
}
}
}