/* pdp11_dup.c: PDP-11 DUP11/DPV11 bit synchronous interface | |
Copyright (c) 2013, Mark Pizzolato | |
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. | |
dup DUP11 Unibus/DPV11 Qbus bit synchronous interface | |
This module implements a bit synchronous interface to support DDCMP. Other | |
synchronous protocols which may have been supported on the DUP11/DPV11 bit | |
synchronous interface are explicitly not supported. | |
Connections are modeled with a tcp session with connection management and | |
I/O provided by the tmxr library. | |
The wire protocol implemented is native DDCMP WITHOUT the DDCMP SYNC | |
characters both initially and between DDCMP packets. | |
15-May-13 MP Initial implementation | |
*/ | |
#if defined (VM_PDP10) /* PDP10 version */ | |
#include "pdp10_defs.h" | |
#elif defined (VM_VAX) /* VAX version */ | |
#include "vax_defs.h" | |
#else /* PDP-11 version */ | |
#include "pdp11_defs.h" | |
#endif | |
#include "sim_tmxr.h" | |
#include "pdp11_ddcmp.h" | |
#include "pdp11_dup.h" | |
#if !defined(DUP_LINES) | |
#define DUP_LINES 8 | |
#endif | |
#define INITIAL_DUP_LINES 1 | |
#define DUP_WAIT 50 /* Minimum character time */ | |
#define DUP_CONNECT_POLL 2 /* Seconds */ | |
extern int32 IREQ (HLVL); | |
extern int32 tmxr_poll; /* calibrated delay */ | |
extern int32 clk_tps; /* clock ticks per second */ | |
extern int32 tmr_poll; /* instructions per tick */ | |
static uint16 dup_rxcsr[DUP_LINES]; | |
static uint16 dup_rxdbuf[DUP_LINES]; | |
static uint16 dup_parcsr[DUP_LINES]; | |
static uint16 dup_txcsr[DUP_LINES]; | |
static uint16 dup_txdbuf[DUP_LINES]; | |
static t_bool dup_W3[DUP_LINES]; | |
static t_bool dup_W5[DUP_LINES]; | |
static t_bool dup_W6[DUP_LINES]; | |
static uint32 dup_rxi = 0; /* rcv interrupts */ | |
static uint32 dup_txi = 0; /* xmt interrupts */ | |
static uint32 dup_wait[DUP_LINES]; /* rcv/xmt byte delay */ | |
static uint32 dup_speed[DUP_LINES]; /* line speed (bits/sec) */ | |
static uint8 *dup_rcvpacket[DUP_LINES]; /* rcv buffer */ | |
static uint16 dup_rcvpksize[DUP_LINES]; /* rcv buffer size */ | |
static uint16 dup_rcvpkbytes[DUP_LINES]; /* rcv buffer size of packet */ | |
static uint16 dup_rcvpkinoff[DUP_LINES]; /* rcv packet in offset */ | |
static uint8 *dup_xmtpacket[DUP_LINES]; /* xmt buffer */ | |
static uint16 dup_xmtpksize[DUP_LINES]; /* xmt buffer size */ | |
static uint16 dup_xmtpkoffset[DUP_LINES]; /* xmt buffer offset */ | |
static uint32 dup_xmtpkstart[DUP_LINES]; /* xmt packet start time */ | |
static uint16 dup_xmtpkbytes[DUP_LINES]; /* xmt packet size of packet */ | |
static uint16 dup_xmtpkdelaying[DUP_LINES]; /* xmt packet speed delaying completion */ | |
static int32 dup_corruption[DUP_LINES]; /* data corrupting troll hunger value */ | |
static PACKET_DATA_AVAILABLE_CALLBACK dup_rcv_packet_data_callback[DUP_LINES]; | |
static PACKET_TRANSMIT_COMPLETE_CALLBACK dup_xmt_complete_callback[DUP_LINES]; | |
static MODEM_CHANGE_CALLBACK dup_modem_change_callback[DUP_LINES]; | |
static t_stat dup_rd (int32 *data, int32 PA, int32 access); | |
static t_stat dup_wr (int32 data, int32 PA, int32 access); | |
static t_stat dup_set_modem (int32 dup, int32 rxcsr_bits); | |
static t_stat dup_get_modem (int32 dup); | |
static t_stat dup_svc (UNIT *uptr); | |
static t_stat dup_poll_svc (UNIT *uptr); | |
static t_stat dup_rcv_byte (int32 dup); | |
static t_stat dup_reset (DEVICE *dptr); | |
static t_stat dup_attach (UNIT *uptr, char *ptr); | |
static t_stat dup_detach (UNIT *uptr); | |
static t_stat dup_clear (int32 dup, t_bool flag); | |
static int32 dup_rxinta (void); | |
static int32 dup_txinta (void); | |
static void dup_update_rcvi (void); | |
static void dup_update_xmti (void); | |
static void dup_clr_rxint (int32 dup); | |
static void dup_set_rxint (int32 dup); | |
static void dup_clr_txint (int32 dup); | |
static void dup_set_txint (int32 dup); | |
static t_stat dup_setnl (UNIT *uptr, int32 val, char *cptr, void *desc); | |
static t_stat dup_setspeed (UNIT* uptr, int32 val, char* cptr, void* desc); | |
static t_stat dup_showspeed (FILE* st, UNIT* uptr, int32 val, void* desc); | |
static t_stat dup_setcorrupt (UNIT *uptr, int32 val, char *cptr, void *desc); | |
static t_stat dup_showcorrupt (FILE *st, UNIT *uptr, int32 val, void *desc); | |
static t_stat dup_set_W3 (UNIT* uptr, int32 val, char* cptr, void* desc); | |
static t_stat dup_show_W3 (FILE* st, UNIT* uptr, int32 val, void* desc); | |
static t_stat dup_set_W5 (UNIT* uptr, int32 val, char* cptr, void* desc); | |
static t_stat dup_show_W5 (FILE* st, UNIT* uptr, int32 val, void* desc); | |
static t_stat dup_set_W6 (UNIT* uptr, int32 val, char* cptr, void* desc); | |
static t_stat dup_show_W6 (FILE* st, UNIT* uptr, int32 val, void* desc); | |
static t_stat dup_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr); | |
static t_stat dup_help_attach (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr); | |
static const char *dup_description (DEVICE *dptr); | |
/* RXCSR - 16XXX0 - receiver control/status register */ | |
static BITFIELD dup_rxcsr_bits[] = { | |
BIT(BDATSET), /* Data Set Change B */ | |
#define RXCSR_V_BDATSET 0 | |
#define RXCSR_M_BDATSET (1<<RXCSR_V_BDATSET) | |
BIT(DTR), /* Data Terminal Ready */ | |
#define RXCSR_V_DTR 1 | |
#define RXCSR_M_DTR (1<<RXCSR_V_DTR) | |
BIT(RTS), /* Request To Send */ | |
#define RXCSR_V_RTS 2 | |
#define RXCSR_M_RTS (1<<RXCSR_V_RTS) | |
BIT(SECXMT), /* Secondary Transmit Data */ | |
#define RXCSR_V_SECXMT 3 | |
#define RXCSR_M_SECXMT (1<<RXCSR_V_SECXMT) | |
BIT(RCVEN), /* Receiver Enable */ | |
#define RXCSR_V_RCVEN 4 | |
#define RXCSR_M_RCVEN (1<<RXCSR_V_RCVEN) | |
BIT(DSCIE), /* Data Set Change Interrupt Enable */ | |
#define RXCSR_V_DSCIE 5 | |
#define RXCSR_M_DSCIE (1<<RXCSR_V_DSCIE) | |
BIT(RXIE), /* Receive Interrupt Enable */ | |
#define RXCSR_V_RXIE 6 | |
#define RXCSR_M_RXIE (1<<RXCSR_V_RXIE) | |
BIT(RXDONE), /* Receive Done */ | |
#define RXCSR_V_RXDONE 7 | |
#define RXCSR_M_RXDONE (1<<RXCSR_V_RXDONE) | |
BIT(STRSYN), /* Strip Sync */ | |
#define RXCSR_V_STRSYN 8 | |
#define RXCSR_M_STRSYN (1<<RXCSR_V_STRSYN) | |
BIT(DSR), /* Data Set Ready */ | |
#define RXCSR_V_DSR 9 | |
#define RXCSR_M_DSR (1<<RXCSR_V_DSR) | |
BIT(SECRCV), /* Secondary Receive Data */ | |
#define RXCSR_V_SECRCV 10 | |
#define RXCSR_M_SECRCV (1<<RXCSR_V_SECRCV) | |
BIT(RXACT), /* Receive Active */ | |
#define RXCSR_V_RXACT 11 | |
#define RXCSR_M_RXACT (1<<RXCSR_V_RXACT) | |
BIT(DCD), /* Carrier */ | |
#define RXCSR_V_DCD 12 | |
#define RXCSR_M_DCD (1<<RXCSR_V_DCD) | |
BIT(CTS), /* Clear to Send */ | |
#define RXCSR_V_CTS 13 | |
#define RXCSR_M_CTS (1<<RXCSR_V_CTS) | |
BIT(RING), /* Ring */ | |
#define RXCSR_V_RING 14 | |
#define RXCSR_M_RING (1<<RXCSR_V_RING) | |
BIT(DSCHNG), /* Data Set Change */ | |
#define RXCSR_V_DSCHNG 15 | |
#define RXCSR_M_DSCHNG (1<<RXCSR_V_DSCHNG) | |
ENDBITS | |
}; | |
#define RXCSR_A_MODEM_BITS (RXCSR_M_RING | RXCSR_M_CTS) | |
#define RXCSR_B_MODEM_BITS (RXCSR_M_DSR | RXCSR_M_DCD) | |
#define RXCSR_WRITEABLE (RXCSR_M_STRSYN|RXCSR_M_RXIE|RXCSR_M_DSCIE|RXCSR_M_RCVEN|RXCSR_M_SECXMT|RXCSR_M_RTS|RXCSR_M_DTR) | |
/* RXDBUF - 16XXX2 - receiver Data Buffer register */ | |
static BITFIELD dup_rxdbuf_bits[] = { | |
BITF(RXDBUF,8), /* Receive Data Buffer */ | |
#define RXDBUF_V_RXDBUF 0 | |
#define RXDBUF_S_RXDBUF 8 | |
#define RXDBUF_M_RXDBUF (((1<<RXDBUF_S_RXDBUF)-1)<<RXDBUF_V_RXDBUF) | |
BIT(RSTRMSG), /* Receiver Start of Message */ | |
#define RXDBUF_V_RSTRMSG 8 | |
#define RXDBUF_M_RSTRMSG (1<<RXDBUF_V_RSTRMSG) | |
BIT(RENDMSG), /* Receiver End Of Message */ | |
#define RXDBUF_V_RENDMSG 9 | |
#define RXDBUF_M_RENDMSG (1<<RXDBUF_V_RENDMSG) | |
BIT(RABRT), /* Receiver Abort */ | |
#define RXDBUF_V_RABRT 10 | |
#define RXDBUF_M_RABRT (1<<RXDBUF_V_RABRT) | |
BITNCF(1), /* reserved */ | |
BIT(RCRCER), /* Receiver CRC Error */ | |
#define RXDBUF_V_RCRCER 12 | |
#define RXDBUF_M_RCRCER (1<<RXDBUF_V_RCRCER) | |
BITNCF(1), /* reserved */ | |
BIT(RXOVR), /* Receiver Overrun */ | |
#define RXDBUF_V_RXOVR 14 | |
#define RXDBUF_M_RXOVR (1<<RXDBUF_V_RXOVR) | |
BIT(RXERR), /* Receiver Error */ | |
#define RXDBUF_V_RXERR 15 | |
#define RXDBUF_M_RXERR (1<<RXDBUF_V_RXERR) | |
ENDBITS | |
}; | |
#define RXDBUF_MBZ ((1<<13)|(1<<11)) | |
/* PARCSR - 16XXX2 - Parameter Control/Status register */ | |
static BITFIELD dup_parcsr_bits[] = { | |
BITF(ADSYNC,8), /* Secondart Station Address/Receiver Sync Char */ | |
#define PARCSR_V_ADSYNC 0 | |
#define PARCSR_S_ADSYNC 8 | |
#define PARCSR_M_ADSYNC (((1<<PARCSR_S_ADSYNC)-1)<<PARCSR_V_ADSYNC) | |
BITNCF(1), /* reserved */ | |
BIT(NOCRC), /* No CRC */ | |
#define PARCSR_V_NOCRC 9 | |
#define PARCSR_M_NOCRC (1<<PARCSR_V_NOCRC) | |
BITNCF(2), /* reserved */ | |
BIT(SECMODE), /* Secondary Mode Select */ | |
#define PARCSR_V_SECMODE 12 | |
#define PARCSR_M_SECMODE (1<<PARCSR_V_SECMODE) | |
BITNCF(2), /* reserved */ | |
BIT(DECMODE), /* DEC Mode */ | |
#define PARCSR_V_DECMODE 15 | |
#define PARCSR_M_DECMODE (1<<PARCSR_V_DECMODE) | |
ENDBITS | |
}; | |
#define PARCSR_MBZ ((1<<14)|(1<<13)|(1<<11)|(1<<10)|(1<<8)) | |
#define PARCSR_WRITEABLE (PARCSR_M_DECMODE|PARCSR_M_SECMODE|PARCSR_M_NOCRC|PARCSR_M_ADSYNC) | |
/* TXCSR - 16XXX4 - Transmitter Control/Status register */ | |
static BITFIELD dup_txcsr_bits[] = { | |
BITNCF(3), /* reserved */ | |
BIT(HALFDUP), /* Half Duplex */ | |
#define TXCSR_V_HALFDUP 3 | |
#define TXCSR_M_HALFDUP (1<<TXCSR_V_HALFDUP) | |
BIT(SEND), /* Enable Transmit */ | |
#define TXCSR_V_SEND 4 | |
#define TXCSR_M_SEND (1<<TXCSR_V_SEND) | |
BITNCF(1), /* reserved */ | |
BIT(TXIE), /* Transmit Interrupt Enable */ | |
#define TXCSR_V_TXIE 6 | |
#define TXCSR_M_TXIE (1<<TXCSR_V_TXIE) | |
BIT(TXDONE), /* Transmit Done */ | |
#define TXCSR_V_TXDONE 7 | |
#define TXCSR_M_TXDONE (1<<TXCSR_V_TXDONE) | |
BIT(DRESET), /* Device Reset */ | |
#define TXCSR_V_DRESET 8 | |
#define TXCSR_M_DRESET (1<<TXCSR_V_DRESET) | |
BIT(TXACT), /* Transmit Active */ | |
#define TXCSR_V_TXACT 9 | |
#define TXCSR_M_TXACT (1<<TXCSR_V_TXACT) | |
BIT(MAIDATA), /* Maintenance Mode Data Bit */ | |
#define TXCSR_V_MAIDATA 10 | |
#define TXCSR_M_MAIDATA (1<<TXCSR_V_MAIDATA) | |
BITF(MAISEL,2), /* Maintenance Select B and A */ | |
#define TXCSR_V_MAISEL 11 | |
#define TXCSR_S_MAISEL 2 | |
#define TXCSR_M_MAISEL (((1<<TXCSR_S_MAISEL)-1)<<TXCSR_V_MAISEL) | |
#define TXCSR_GETMAISEL(x) (((x) & TXCSR_M_MAISEL) >> TXCSR_V_MAISEL) | |
BIT(MAISSCLK), /* Maintenance Single Step Clock */ | |
#define TXCSR_V_MAISSCLK 13 | |
#define TXCSR_M_MAISSCLK (1<<TXCSR_V_MAISSCLK) | |
BIT(TXMNTOUT), /* Transmit Maint Data Out */ | |
#define TXCSR_V_TXMNTOUT 14 | |
#define TXCSR_M_TXMNTOUT (1<<TXCSR_V_TXMNTOUT) | |
BIT(TXDLAT), /* Transmit Data Late */ | |
#define TXCSR_V_TXDLAT 15 | |
#define TXCSR_M_TXDLAT (1<<TXCSR_V_TXDLAT) | |
ENDBITS | |
}; | |
#define TXCSR_MBZ ((1<<5)|(1<<2)|(1<<1)|(1<<0)) | |
#define TXCSR_WRITEABLE (TXCSR_M_MAISSCLK|TXCSR_M_MAISEL|TXCSR_M_MAIDATA|TXCSR_M_DRESET|TXCSR_M_TXIE|TXCSR_M_SEND|TXCSR_M_HALFDUP) | |
/* TXDBUF - 16XXX6 - transmitter Data Buffer register */ | |
static BITFIELD dup_txdbuf_bits[] = { | |
BITF(TXDBUF,8), /* Transmit Data Buffer */ | |
#define TXDBUF_V_TXDBUF 0 | |
#define TXDBUF_S_TXDBUF 8 | |
#define TXDBUF_M_TXDBUF (((1<<TXDBUF_S_TXDBUF)-1)<<TXDBUF_V_TXDBUF) | |
BIT(TSOM), /* Transmit Start of Message */ | |
#define TXDBUF_V_TSOM 8 | |
#define TXDBUF_M_TSOM (1<<TXDBUF_V_TSOM) | |
BIT(TEOM), /* End of Transmitted Message */ | |
#define TXDBUF_V_TEOM 9 | |
#define TXDBUF_M_TEOM (1<<TXDBUF_V_TEOM) | |
BIT(TABRT), /* Transmit Abort */ | |
#define TXDBUF_V_TABRT 10 | |
#define TXDBUF_M_TABRT (1<<TXDBUF_V_TABRT) | |
BIT(MAINTT), /* Maintenance Timer */ | |
#define TXDBUF_V_MAINTT 11 | |
#define TXDBUF_M_MAINTT (1<<TXDBUF_V_MAINTT) | |
BIT(TCRCTIN), /* Transmit CSR Input */ | |
#define TXDBUF_V_TCRCTIN 12 | |
#define TXDBUF_M_TCRCTIN (1<<TXDBUF_V_TCRCTIN) | |
BITNCF(1), /* reserved */ | |
BIT(RCRCTIN), /* Receive CSR Input */ | |
#define TXDBUF_V_RCRCTIN 14 | |
#define TXDBUF_M_RCRCTIN (1<<TXDBUF_V_RCRCTIN) | |
BITNCF(1), /* reserved */ | |
ENDBITS | |
}; | |
#define TXDBUF_MBZ ((1<<15)|(1<<13)) | |
#define TXDBUF_WRITEABLE (TXDBUF_M_TABRT|TXDBUF_M_TEOM|TXDBUF_M_TSOM|TXDBUF_M_TXDBUF) | |
/* DUP data structures | |
dup_dev DUP device descriptor | |
dup_unit DUP unit descriptor | |
dup_reg DUP register list | |
*/ | |
#define IOLN_DUP 010 | |
DIB dup_dib = { | |
IOBA_AUTO, | |
IOLN_DUP * INITIAL_DUP_LINES, | |
&dup_rd, /* read */ | |
&dup_wr, /* write */ | |
2, /* # of vectors */ | |
IVCL (DUPRX), | |
VEC_AUTO, | |
{ &dup_rxinta, &dup_txinta },/* int. ack. routines */ | |
IOLN_DUP, /* IO space per line */ | |
}; | |
static UNIT dup_unit_template = { | |
UDATA (&dup_svc, UNIT_ATTABLE|UNIT_IDLE, 0), | |
}; | |
static UNIT dup_poll_unit_template = { | |
UDATA (&dup_poll_svc, UNIT_DIS|UNIT_IDLE, 0), | |
}; | |
static UNIT dup_units[DUP_LINES+1]; /* One unit per line and a polling unit */ | |
static REG dup_reg[] = { | |
{ BRDATADF (RXCSR, dup_rxcsr, DEV_RDX, 16, DUP_LINES, "receive control/status register", dup_rxcsr_bits) }, | |
{ BRDATADF (RXDBUF, dup_rxdbuf, DEV_RDX, 16, DUP_LINES, "receive data buffer", dup_rxdbuf_bits) }, | |
{ BRDATADF (PARCSR, dup_parcsr, DEV_RDX, 16, DUP_LINES, "receive control/status register", dup_parcsr_bits) }, | |
{ BRDATADF (TXCSR, dup_txcsr, DEV_RDX, 16, DUP_LINES, "transmit control/status register", dup_txcsr_bits) }, | |
{ BRDATADF (TXDBUF, dup_txdbuf, DEV_RDX, 16, DUP_LINES, "transmit data buffer", dup_txdbuf_bits) }, | |
{ BRDATAD (W3, dup_W3, DEV_RDX, 1, DUP_LINES, "Clear Option Enable") }, | |
{ BRDATAD (W5, dup_W5, DEV_RDX, 1, DUP_LINES, "A Dataset Control Enable") }, | |
{ BRDATAD (W6, dup_W6, DEV_RDX, 1, DUP_LINES, "A and B Dataset Control Enable") }, | |
{ GRDATAD (RXINT, dup_rxi, DEV_RDX, DUP_LINES, 0, "receive interrupts") }, | |
{ GRDATAD (TXINT, dup_txi, DEV_RDX, DUP_LINES, 0, "transmit interrupts") }, | |
{ BRDATAD (WAIT, dup_wait, 10, 32, DUP_LINES, "delay time for transmit/receive bytes"), PV_RSPC }, | |
{ BRDATAD (SPEED, dup_speed, 10, 32, DUP_LINES, "line bit rate"), PV_RCOMMA }, | |
{ BRDATAD (TPOFFSET, dup_xmtpkoffset, DEV_RDX, 16, DUP_LINES, "transmit assembly packet offset") }, | |
{ BRDATAD (TPSIZE, dup_xmtpkbytes, DEV_RDX, 16, DUP_LINES, "transmit digest packet size") }, | |
{ BRDATAD (TPDELAY,dup_xmtpkdelaying, DEV_RDX, 16, DUP_LINES, "transmit packet completion delay") }, | |
{ BRDATAD (TPSTART, dup_xmtpkstart, DEV_RDX, 32, DUP_LINES, "transmit digest packet start time") }, | |
{ BRDATAD (RPINOFF, dup_rcvpkinoff, DEV_RDX, 16, DUP_LINES, "receive digest packet offset") }, | |
{ BRDATAD (CORRUPT, dup_corruption, DEV_RDX, 32, DUP_LINES, "data corruption factor (0.1%)") }, | |
{ NULL } | |
}; | |
static TMLN *dup_ldsc = NULL; /* line descriptors */ | |
static TMXR dup_desc = { INITIAL_DUP_LINES, 0, 0, NULL }; /* mux descriptor */ | |
static MTAB dup_mod[] = { | |
{ MTAB_XTD|MTAB_VUN, 0, "SPEED", "SPEED=bits/sec (0=unrestricted)" , | |
&dup_setspeed, &dup_showspeed, NULL, "Display rate limit" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "CORRUPTION", "CORRUPTION=factor (0=uncorrupted)" , | |
&dup_setcorrupt, &dup_showcorrupt, NULL, "Display corruption factor (0.1% of packets)" }, | |
{ MTAB_XTD|MTAB_VUN, 1, "W3", NULL , | |
NULL, &dup_show_W3, NULL, "Display Reset Option" }, | |
{ MTAB_XTD|MTAB_VUN, 1, NULL, "W3" , | |
&dup_set_W3, NULL, NULL, "Enable Reset Option" }, | |
{ MTAB_XTD|MTAB_VUN, 0, NULL, "NOW3" , | |
&dup_set_W3, NULL, NULL, "Disable Reset Option" }, | |
{ MTAB_XTD|MTAB_VUN, 1, "W5", NULL , | |
NULL, &dup_show_W5, NULL, "Display A Dataset Control Option" }, | |
{ MTAB_XTD|MTAB_VUN, 1, NULL, "W5" , | |
&dup_set_W5, NULL, NULL, "Enable A Dataset Control Option" }, | |
{ MTAB_XTD|MTAB_VUN, 0, NULL, "NOW5" , | |
&dup_set_W5, NULL, NULL, "Disable A Dataset Control Option" }, | |
{ MTAB_XTD|MTAB_VUN, 1, "W6", NULL , | |
NULL, &dup_show_W6, NULL, "Display A & B Dataset Control Option" }, | |
{ MTAB_XTD|MTAB_VUN, 1, NULL, "W6" , | |
&dup_set_W6, NULL, NULL, "Enable A & B Dataset Control Option" }, | |
{ MTAB_XTD|MTAB_VUN, 0, NULL, "NOW6" , | |
&dup_set_W6, NULL, NULL, "Disable A & B Dataset Control Option" }, | |
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 020, "ADDRESS", "ADDRESS", | |
&set_addr, &show_addr, NULL, "Bus address" }, | |
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 1, "VECTOR", "VECTOR", | |
&set_vec, &show_vec_mux, (void *) &dup_desc, "Interrupt vector" }, | |
{ MTAB_XTD|MTAB_VDV|MTAB_NMO, 1, "CONNECTIONS", NULL, | |
NULL, &tmxr_show_cstat, (void *) &dup_desc, "Display current connections" }, | |
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 0, "LINES", "LINES=n", | |
&dup_setnl, &tmxr_show_lines, (void *) &dup_desc, "Display number of lines" }, | |
{ 0 } | |
}; | |
/* debugging bitmaps */ | |
#define DBG_REG 0x0001 /* trace read/write registers */ | |
#define DBG_INT 0x0002 /* display transfer requests */ | |
#define DBG_PKT (TMXR_DBG_PXMT|TMXR_DBG_PRCV) /* display packets */ | |
#define DBG_XMT TMXR_DBG_XMT /* display Transmitted Data */ | |
#define DBG_RCV TMXR_DBG_RCV /* display Received Data */ | |
#define DBG_MDM TMXR_DBG_MDM /* display Modem SignalTransitions */ | |
#define DBG_CON TMXR_DBG_CON /* display connection activities */ | |
#define DBG_TRC TMXR_DBG_TRC /* display trace routine calls */ | |
#define DBG_ASY TMXR_DBG_ASY /* display Asynchronous Activities */ | |
static DEBTAB dup_debug[] = { | |
{"REG", DBG_REG}, | |
{"INT", DBG_INT}, | |
{"PKT", DBG_PKT}, | |
{"XMT", DBG_XMT}, | |
{"RCV", DBG_RCV}, | |
{"MDM", DBG_MDM}, | |
{"CON", DBG_CON}, | |
{"TRC", DBG_TRC}, | |
{"ASY", DBG_ASY}, | |
{0} | |
}; | |
/* | |
We have two devices defined here (dup_dev and dpv_dev) which have the | |
same units. This would normally never be allowed since two devices can't | |
actually share units. This problem is avoided in this case since both | |
devices start out as disabled and the logic in dup_reset allows only | |
one of these devices to be enabled at a time. The DUP device is allowed | |
on Unibus systems and the DPV device Qbus systems. | |
This monkey business is necessary due to the fact that although both | |
the DUP and DPV devices have almost the same functionality and almost | |
the same register programming interface, they are different enough that | |
they fall in different priorities in the autoconfigure address and vector | |
rules. | |
This 'shared' unit model therefore means we can't call the | |
find_dev_from_unit api to uniquely determine the device structure. | |
We define the DUPDPTR macro to return the active device pointer when | |
necessary. | |
*/ | |
DEVICE dup_dev = { | |
"DUP", dup_units, dup_reg, dup_mod, | |
2, 10, 31, 1, DEV_RDX, 8, | |
NULL, NULL, &dup_reset, | |
NULL, &dup_attach, &dup_detach, | |
&dup_dib, DEV_DIS | DEV_DISABLE | DEV_UBUS | DEV_DEBUG | DEV_DONTAUTO, 0, | |
dup_debug, NULL, NULL, &dup_help, dup_help_attach, &dup_desc, | |
&dup_description | |
}; | |
DEVICE dpv_dev = { | |
"DPV", dup_units, dup_reg, dup_mod, | |
2, 10, 31, 1, DEV_RDX, 8, | |
NULL, NULL, &dup_reset, | |
NULL, &dup_attach, &dup_detach, | |
&dup_dib, DEV_DIS | DEV_DISABLE | DEV_QBUS | DEV_DEBUG | DEV_DONTAUTO, 0, | |
dup_debug, NULL, NULL, &dup_help, dup_help_attach, &dup_desc, | |
&dup_description | |
}; | |
#define DUPDPTR ((UNIBUS) ? &dup_dev : &dpv_dev) | |
/* Register names for Debug tracing */ | |
static const char *dup_rd_regs[] = | |
{"RXCSR ", "RXDBUF", "TXCSR ", "TXDBUF" }; | |
static const char *dup_wr_regs[] = | |
{"RXCSR ", "PARCSR", "TXCSR ", "TXDBUF"}; | |
/* DUP11/DPV11 bit synchronous interface routines | |
dup_rd I/O page read | |
dup_wr I/O page write | |
dup_svc process event | |
dup_poll_svc process polling events | |
dup_reset process reset | |
dup_setnl set number of lines | |
dup_attach process attach | |
dup_detach process detach | |
*/ | |
static t_stat dup_rd (int32 *data, int32 PA, int32 access) | |
{ | |
static BITFIELD* bitdefs[] = {dup_rxcsr_bits, dup_rxdbuf_bits, dup_txcsr_bits, dup_txdbuf_bits}; | |
static uint16 *regs[] = {dup_rxcsr, dup_rxdbuf, dup_txcsr, dup_txdbuf}; | |
int32 dup = ((PA - dup_dib.ba) >> 3); /* get line num */ | |
int32 orig_val; | |
if (dup >= dup_desc.lines) /* validate line number */ | |
return SCPE_IERR; | |
orig_val = regs[(PA >> 1) & 03][dup]; | |
switch ((PA >> 1) & 03) { /* case on PA<2:1> */ | |
case 00: /* RXCSR */ | |
dup_get_modem (dup); | |
*data = dup_rxcsr[dup]; | |
dup_rxcsr[dup] &= ~(RXCSR_M_DSCHNG|RXCSR_M_BDATSET); | |
break; | |
case 01: /* RXDBUF */ | |
*data = dup_rxdbuf[dup]; | |
dup_rxcsr[dup] &= ~RXCSR_M_RXDONE; | |
if (dup_rxcsr[dup] & RXCSR_M_RXACT) | |
sim_activate (dup_units+dup, dup_wait[dup]); | |
break; | |
case 02: /* TXCSR */ | |
*data = dup_txcsr[dup]; | |
break; | |
case 03: /* TXDBUF */ | |
*data = dup_txdbuf[dup]; | |
break; | |
} | |
sim_debug(DBG_REG, DUPDPTR, "dup_rd(PA=0x%08X [%s], data=0x%X) ", PA, dup_rd_regs[(PA >> 1) & 03], *data); | |
sim_debug_bits(DBG_REG, DUPDPTR, bitdefs[(PA >> 1) & 03], (uint32)(orig_val), (uint32)(regs[(PA >> 1) & 03][dup]), TRUE); | |
return SCPE_OK; | |
} | |
static t_stat dup_wr (int32 data, int32 PA, int32 access) | |
{ | |
static BITFIELD* bitdefs[] = {dup_rxcsr_bits, dup_parcsr_bits, dup_txcsr_bits, dup_txdbuf_bits}; | |
static uint16 *regs[] = {dup_rxcsr, dup_parcsr, dup_txcsr, dup_txdbuf}; | |
int32 dup = ((PA - dup_dib.ba) >> 3); /* get line num */ | |
int32 orig_val; | |
if (dup >= dup_desc.lines) /* validate line number */ | |
return SCPE_IERR; | |
orig_val = regs[(PA >> 1) & 03][dup]; | |
if (PA & 1) /* unaligned byte access? */ | |
data = ((data << 8) | (orig_val & 0xFF)) & 0xFFFF; /* Merge with original word */ | |
else | |
if (access == WRITEB) /* byte access? */ | |
data = (orig_val & 0xFF00) | (data & 0xFF); /* Merge with original high word */ | |
switch ((PA >> 1) & 03) { /* case on PA<2:1> */ | |
case 00: /* RXCSR */ | |
dup_set_modem (dup, data); | |
dup_rxcsr[dup] &= ~RXCSR_WRITEABLE; | |
dup_rxcsr[dup] |= (data & RXCSR_WRITEABLE); | |
if ((dup_rxcsr[dup] & RXCSR_M_RTS) && /* Upward transition of RTS */ | |
(!(orig_val & RXCSR_M_RTS))) /* Enables Receive on the line */ | |
dup_desc.ldsc[dup].rcve = TRUE; | |
if ((dup_rxcsr[dup] & RXCSR_M_RTS) && /* Upward transition of RTS */ | |
(!(orig_val & RXCSR_M_RTS)) && /* while receiver is enabled and */ | |
(dup_rxcsr[dup] & RXCSR_M_RCVEN) && /* not stripping sync characters */ | |
(!(dup_rxcsr[dup] & RXCSR_M_STRSYN)) ) { /* Receive a SYNC character */ | |
dup_rxcsr[dup] |= RXCSR_M_RXDONE; | |
dup_rxdbuf[dup] &= ~RXDBUF_M_RXDBUF; | |
dup_rxdbuf[dup] |= (dup_parcsr[dup] & PARCSR_M_ADSYNC); | |
if (dup_rxcsr[dup] & RXCSR_M_RXIE) | |
dup_set_rxint (dup); | |
} | |
if ((dup_rxcsr[dup] & RXCSR_M_RCVEN) && | |
(!(orig_val & RXCSR_M_RCVEN))) { /* Upward transition of receiver enable */ | |
dup_rcv_byte (dup); /* start any pending receive */ | |
} | |
if ((!(dup_rxcsr[dup] & RXCSR_M_RCVEN)) && | |
(orig_val & RXCSR_M_RCVEN)) { /* Downward transition of receiver enable */ | |
dup_rxdbuf[dup] &= ~RXDBUF_M_RXDBUF; | |
dup_rxcsr[dup] &= ~RXCSR_M_RXACT; | |
if ((dup_rcvpkinoff[dup] != 0) || | |
(dup_rcvpkbytes[dup] != 0)) | |
dup_rcvpkinoff[dup] = dup_rcvpkbytes[dup] = 0; | |
} | |
if ((!(dup_rxcsr[dup] & RXCSR_M_RXIE)) && | |
(orig_val & RXCSR_M_RXIE)) /* Downward transition of receiver interrupt enable */ | |
dup_clr_rxint (dup); | |
if ((dup_rxcsr[dup] & RXCSR_M_RXIE) && (dup_rxcsr[dup] & RXCSR_M_RXDONE)) | |
dup_set_rxint (dup); | |
break; | |
case 01: /* PARCSR */ | |
dup_parcsr[dup] &= ~PARCSR_WRITEABLE; | |
dup_parcsr[dup] |= (data & PARCSR_WRITEABLE); | |
break; | |
case 02: /* TXCSR */ | |
dup_txcsr[dup] &= ~TXCSR_WRITEABLE; | |
dup_txcsr[dup] |= (data & TXCSR_WRITEABLE); | |
if (dup_txcsr[dup] & TXCSR_M_DRESET) { | |
dup_clear(dup, dup_W3[dup]); | |
break; | |
} | |
if (TXCSR_GETMAISEL(dup_txcsr[dup]) != TXCSR_GETMAISEL(orig_val)) { /* Maint Select Changed */ | |
switch (TXCSR_GETMAISEL(dup_txcsr[dup])) { | |
case 0: /* User/Normal Mode */ | |
tmxr_set_line_loopback (&dup_desc.ldsc[dup], FALSE); | |
break; | |
case 1: /* External Loopback Mode */ | |
case 2: /* Internal Loopback Mode */ | |
tmxr_set_line_loopback (&dup_desc.ldsc[dup], TRUE); | |
break; | |
case 3: /* System Test Mode */ | |
break; | |
} | |
} | |
if ((dup_txcsr[dup] & TXCSR_M_TXACT) && | |
(!(orig_val & TXCSR_M_TXACT)) && | |
(orig_val & TXCSR_M_TXDONE)) { | |
dup_txcsr[dup] &= ~TXCSR_M_TXDONE; | |
} | |
if ((!(dup_txcsr[dup] & TXCSR_M_SEND)) && | |
(orig_val & TXCSR_M_SEND)) { | |
dup_txcsr[dup] &= ~TXCSR_M_TXACT; | |
dup_put_msg_bytes (dup, NULL, 0, FALSE, TRUE); | |
} | |
if ((dup_txcsr[dup] & TXCSR_M_HALFDUP) ^ (orig_val & TXCSR_M_HALFDUP)) | |
tmxr_set_line_halfduplex (dup_desc.ldsc+dup, dup_txcsr[dup] & TXCSR_M_HALFDUP); | |
if ((dup_txcsr[dup] & TXCSR_M_TXIE) && | |
(!(orig_val & TXCSR_M_TXIE)) && | |
(dup_txcsr[dup] & TXCSR_M_TXDONE)) { | |
dup_set_txint (dup); | |
} | |
break; | |
case 03: /* TXDBUF */ | |
dup_txdbuf[dup] &= ~TXDBUF_WRITEABLE; | |
dup_txdbuf[dup] |= (data & TXDBUF_WRITEABLE); | |
dup_txcsr[dup] &= ~TXCSR_M_TXDONE; | |
if (dup_txcsr[dup] & TXCSR_M_SEND) { | |
dup_txcsr[dup] |= TXCSR_M_TXACT; | |
sim_activate (dup_units+dup, dup_wait[dup]); | |
} | |
break; | |
} | |
sim_debug(DBG_REG, DUPDPTR, "dup_wr(PA=0x%08X [%s], data=0x%X) ", PA, dup_wr_regs[(PA >> 1) & 03], data); | |
sim_debug_bits(DBG_REG, DUPDPTR, bitdefs[(PA >> 1) & 03], (uint32)orig_val, (uint32)regs[(PA >> 1) & 03][dup], TRUE); | |
dup_get_modem (dup); | |
return SCPE_OK; | |
} | |
static t_stat dup_set_modem (int32 dup, int32 rxcsr_bits) | |
{ | |
int32 bits_to_set, bits_to_clear; | |
if ((rxcsr_bits & (RXCSR_M_DTR | RXCSR_M_RTS)) == (dup_rxcsr[dup] & (RXCSR_M_DTR | RXCSR_M_RTS))) | |
return SCPE_OK; | |
bits_to_set = ((rxcsr_bits & RXCSR_M_DTR) ? TMXR_MDM_DTR : 0) | ((rxcsr_bits & RXCSR_M_RTS) ? TMXR_MDM_RTS : 0); | |
bits_to_clear = (~bits_to_set) & (TMXR_MDM_DTR | TMXR_MDM_RTS); | |
tmxr_set_get_modem_bits (dup_desc.ldsc+dup, bits_to_set, bits_to_clear, NULL); | |
return SCPE_OK; | |
} | |
static t_stat dup_get_modem (int32 dup) | |
{ | |
int32 modem_bits; | |
uint16 old_rxcsr = dup_rxcsr[dup]; | |
int32 old_rxcsr_a_modem_bits, new_rxcsr_a_modem_bits, old_rxcsr_b_modem_bits, new_rxcsr_b_modem_bits; | |
TMLN *lp = &dup_desc.ldsc[dup]; | |
t_bool new_modem_change = FALSE; | |
if (dup_W5[dup]) | |
old_rxcsr_a_modem_bits = dup_rxcsr[dup] & (RXCSR_M_RING | RXCSR_M_CTS | RXCSR_M_DSR | RXCSR_M_DCD); | |
else | |
old_rxcsr_a_modem_bits = dup_rxcsr[dup] & (RXCSR_M_RING | RXCSR_M_CTS); | |
if (dup_W6[dup]) | |
old_rxcsr_b_modem_bits = dup_rxcsr[dup] & RXCSR_B_MODEM_BITS; | |
else | |
old_rxcsr_b_modem_bits = 0; | |
old_rxcsr_a_modem_bits = dup_rxcsr[dup] & RXCSR_A_MODEM_BITS; | |
old_rxcsr_b_modem_bits = dup_rxcsr[dup] & RXCSR_B_MODEM_BITS; | |
tmxr_set_get_modem_bits (lp, 0, 0, &modem_bits); | |
if (dup_W5[dup]) | |
new_rxcsr_a_modem_bits = (((modem_bits & TMXR_MDM_RNG) ? RXCSR_M_RING : 0) | | |
((modem_bits & TMXR_MDM_CTS) ? RXCSR_M_CTS : 0) | | |
((modem_bits & TMXR_MDM_DSR) ? RXCSR_M_DSR : 0) | | |
((modem_bits & TMXR_MDM_DCD) ? RXCSR_M_DCD : 0)); | |
else | |
new_rxcsr_a_modem_bits = (((modem_bits & TMXR_MDM_RNG) ? RXCSR_M_RING : 0) | | |
((modem_bits & TMXR_MDM_CTS) ? RXCSR_M_CTS : 0)); | |
if (dup_W6[dup]) | |
new_rxcsr_b_modem_bits = (((modem_bits & TMXR_MDM_DSR) ? RXCSR_M_DSR : 0) | | |
((modem_bits & TMXR_MDM_DCD) ? RXCSR_M_DCD : 0)); | |
else | |
new_rxcsr_b_modem_bits = 0; | |
dup_rxcsr[dup] &= ~(RXCSR_A_MODEM_BITS | RXCSR_B_MODEM_BITS); | |
dup_rxcsr[dup] |= new_rxcsr_a_modem_bits | new_rxcsr_b_modem_bits; | |
if (old_rxcsr_a_modem_bits != new_rxcsr_a_modem_bits) { | |
dup_rxcsr[dup] |= RXCSR_M_DSCHNG; | |
new_modem_change = TRUE; | |
} | |
if (old_rxcsr_b_modem_bits != new_rxcsr_b_modem_bits) { | |
dup_rxcsr[dup] |= RXCSR_M_BDATSET; | |
new_modem_change = TRUE; | |
} | |
if (new_modem_change) { | |
sim_debug(DBG_MDM, DUPDPTR, "dup_get_modem() - Modem Signal Change "); | |
sim_debug_bits(DBG_MDM, DUPDPTR, dup_rxcsr_bits, (uint32)old_rxcsr, (uint32)dup_rxcsr[dup], TRUE); | |
} | |
if (dup_modem_change_callback[dup] && new_modem_change) | |
dup_modem_change_callback[dup](dup); | |
if ((dup_rxcsr[dup] & RXCSR_M_DSCHNG) && | |
((dup_rxcsr[dup] & RXCSR_M_DSCHNG) != (old_rxcsr & RXCSR_M_DSCHNG)) && | |
(dup_rxcsr[dup] & RXCSR_M_DSCIE)) | |
dup_set_rxint (dup); | |
return SCPE_OK; | |
} | |
/* | |
* Public routines for use by other devices (i.e. KDP11) | |
*/ | |
int32 dup_csr_to_linenum (int32 CSRPA) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
DIB *dib = (DIB *)dptr->ctxt; | |
CSRPA += IOPAGEBASE; | |
if ((dib->ba > (uint32)CSRPA) || ((uint32)CSRPA > (dib->ba + dib->lnt)) || (DUPDPTR->flags & DEV_DIS)) | |
return -1; | |
return ((uint32)CSRPA - dib->ba)/IOLN_DUP; | |
} | |
void dup_set_callback_mode (int32 dup, PACKET_DATA_AVAILABLE_CALLBACK receive, PACKET_TRANSMIT_COMPLETE_CALLBACK transmit, MODEM_CHANGE_CALLBACK modem) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return; | |
dup_rcv_packet_data_callback[dup] = receive; | |
dup_xmt_complete_callback[dup] = transmit; | |
dup_modem_change_callback[dup] = modem; | |
} | |
int32 dup_get_DCD (int32 dup) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return -1; | |
return (dup_rxcsr[dup] & RXCSR_M_DCD) ? 1 : 0; | |
} | |
int32 dup_get_DSR (int32 dup) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return -1; | |
return (dup_rxcsr[dup] & RXCSR_M_DSR) ? 1 : 0; | |
} | |
int32 dup_get_CTS (int32 dup) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return -1; | |
return (dup_rxcsr[dup] & RXCSR_M_CTS) ? 1 : 0; | |
} | |
int32 dup_get_RING (int32 dup) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return -1; | |
return (dup_rxcsr[dup] & RXCSR_M_RING) ? 1 : 0; | |
} | |
int32 dup_get_RCVEN (int32 dup) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return -1; | |
return (dup_rxcsr[dup] & RXCSR_M_RCVEN) ? 1 : 0; | |
} | |
t_stat dup_set_DTR (int32 dup, t_bool state) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
dup_set_modem (dup, (state ? RXCSR_M_DTR : 0) | (dup_rxcsr[dup] & RXCSR_M_RTS)); | |
if (state) | |
dup_rxcsr[dup] |= RXCSR_M_DTR; | |
else | |
dup_rxcsr[dup] &= ~RXCSR_M_DTR; | |
dup_ldsc[dup].rcve = state; | |
dup_get_modem (dup); | |
return SCPE_OK; | |
} | |
t_stat dup_set_RTS (int32 dup, t_bool state) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
dup_set_modem (dup, (state ? RXCSR_M_RTS : 0) | (dup_rxcsr[dup] & RXCSR_M_DTR)); | |
if (state) | |
dup_rxcsr[dup] |= RXCSR_M_RTS; | |
else | |
dup_rxcsr[dup] &= ~RXCSR_M_RTS; | |
dup_get_modem (dup); | |
return SCPE_OK; | |
} | |
t_stat dup_set_RCVEN (int32 dup, t_bool state) | |
{ | |
uint16 orig_val; | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
orig_val = dup_rxcsr[dup]; | |
dup_rxcsr[dup] &= ~RXCSR_M_RCVEN; | |
dup_rxcsr[dup] |= (state ? RXCSR_M_RCVEN : 0); | |
if ((dup_rxcsr[dup] & RXCSR_M_RCVEN) && | |
(!(orig_val & RXCSR_M_RCVEN))) { /* Upward transition of receiver enable */ | |
UNIT *uptr = dup_units + dup; | |
dup_poll_svc (uptr); /* start any pending receive */ | |
} | |
return SCPE_OK; | |
} | |
t_stat dup_setup_dup (int32 dup, t_bool enable, t_bool protocol_DDCMP, t_bool crc_inhibit, t_bool halfduplex, uint8 station) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
if (!enable) { | |
dup_clear(dup, TRUE); | |
return SCPE_OK; | |
} | |
if (!protocol_DDCMP) { | |
return SCPE_NOFNC; /* only DDCMP for now */ | |
} | |
if (crc_inhibit) { | |
return SCPE_ARG; /* Must enable CRC for DDCMP */ | |
} | |
/* These settings reflect how RSX operates a bare DUP when used for | |
DECnet communications */ | |
dup_clear(dup, FALSE); | |
dup_rxcsr[dup] |= RXCSR_M_STRSYN | RXCSR_M_RCVEN; | |
dup_parcsr[dup] = PARCSR_M_DECMODE | (DDCMP_SYN << PARCSR_V_ADSYNC); | |
dup_txcsr[dup] &= TXCSR_M_HALFDUP; | |
dup_txcsr[dup] |= (halfduplex ? TXCSR_M_HALFDUP : 0); | |
tmxr_set_line_halfduplex (dup_desc.ldsc+dup, dup_txcsr[dup] & TXCSR_M_HALFDUP); | |
return dup_set_DTR (dup, TRUE); | |
} | |
t_stat dup_reset_dup (int32 dup) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
dup_clear(dup, dup_W3[dup]); | |
return SCPE_OK; | |
} | |
t_stat dup_set_W3_option (int32 dup, t_bool state) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
dup_W3[dup] = state; | |
return SCPE_OK; | |
} | |
t_stat dup_set_W5_option (int32 dup, t_bool state) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
dup_W5[dup] = state; | |
return SCPE_OK; | |
} | |
t_stat dup_set_W6_option (int32 dup, t_bool state) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
dup_W6[dup] = state; | |
return SCPE_OK; | |
} | |
t_bool dup_put_msg_bytes (int32 dup, uint8 *bytes, size_t len, t_bool start, t_bool end) | |
{ | |
t_bool breturn = FALSE; | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return FALSE; | |
if (!tmxr_tpbusyln(&dup_ldsc[dup])) { /* Not Busy sending? */ | |
if (start) { | |
dup_xmtpkoffset[dup] = 0; | |
dup_xmtpkdelaying[dup] = 0; | |
dup_xmtpkstart[dup] = sim_grtime(); | |
} | |
if (dup_xmtpkoffset[dup] + 2 + len > dup_xmtpksize[dup]) { | |
dup_xmtpksize[dup] += 2 + (uint16)len; | |
dup_xmtpacket[dup] = (uint8 *)realloc (dup_xmtpacket[dup], dup_xmtpksize[dup]); | |
} | |
/* Strip sync bytes at the beginning of a message */ | |
while (len && (dup_xmtpkoffset[dup] == 0) && (bytes[0] == DDCMP_SYN)) { | |
--len; | |
++bytes; | |
} | |
/* Insert remaining bytes into transmit buffer */ | |
if (len) { | |
memcpy (&dup_xmtpacket[dup][dup_xmtpkoffset[dup]], bytes, len); | |
dup_xmtpkoffset[dup] += (uint16)len; | |
} | |
dup_txcsr[dup] |= TXCSR_M_TXDONE; | |
if (dup_txcsr[dup] & TXCSR_M_TXIE) | |
dup_set_txint (dup); | |
/* On End of Message, insert CRC and flag delivery start */ | |
if (end) { | |
uint16 crc16 = ddcmp_crc16 (0, dup_xmtpacket[dup], dup_xmtpkoffset[dup]); | |
dup_xmtpacket[dup][dup_xmtpkoffset[dup]++] = crc16 & 0xFF; | |
dup_xmtpacket[dup][dup_xmtpkoffset[dup]++] = crc16 >> 8; | |
if ((dup_xmtpkoffset[dup] > 8) || (dup_xmtpacket[dup][0] == DDCMP_ENQ)) { | |
dup_xmtpkbytes[dup] = dup_xmtpkoffset[dup]; | |
ddcmp_tmxr_put_packet_ln (&dup_ldsc[dup], dup_xmtpacket[dup], dup_xmtpkbytes[dup], dup_corruption[dup]); | |
} | |
} | |
breturn = TRUE; | |
} | |
sim_debug (DBG_TRC, DUPDPTR, "dup_put_msg_bytes(dup=%d, len=%d, start=%s, end=%s) %s\n", | |
dup, (int)len, start ? "TRUE" : "FALSE", end ? "TRUE" : "FALSE", breturn ? "Good" : "Busy"); | |
if (breturn && (tmxr_tpbusyln (&dup_ldsc[dup]) || dup_xmtpkbytes[dup])) { | |
if (dup_xmt_complete_callback[dup]) | |
dup_svc(dup_units+dup); | |
} | |
return breturn; | |
} | |
t_stat dup_get_packet (int32 dup, const uint8 **pbuf, uint16 *psize) | |
{ | |
if ((dup < 0) || (dup >= dup_desc.lines) || (DUPDPTR->flags & DEV_DIS)) | |
return SCPE_IERR; | |
if (*pbuf == &dup_rcvpacket[dup][0]) { | |
*pbuf = NULL; | |
*psize = 0; | |
dup_rcvpkinoff[dup] = dup_rcvpkbytes[dup] = 0; | |
dup_rxcsr[dup] &= ~RXCSR_M_RXACT; | |
} | |
if ((dup_rcvpkinoff[dup] == 0) && (dup_rcvpkbytes[dup] != 0)) { | |
*pbuf = &dup_rcvpacket[dup][0]; | |
*psize = dup_rcvpkbytes[dup]; | |
} | |
sim_debug (DBG_TRC, DUPDPTR, "dup_get_packet(dup=%d, psize=%d)\n", | |
dup, (int)*psize); | |
return SCPE_OK; | |
} | |
static t_stat dup_rcv_byte (int32 dup) | |
{ | |
sim_debug (DBG_TRC, DUPDPTR, "dup_rcv_byte(dup=%d) - %s, byte %d of %d\n", dup, | |
(dup_rxcsr[dup] & RXCSR_M_RCVEN) ? "enabled" : "disabled", | |
dup_rcvpkinoff[dup], dup_rcvpkbytes[dup]); | |
if (!(dup_rxcsr[dup] & RXCSR_M_RCVEN) || (dup_rcvpkbytes[dup] == 0) || (dup_rxcsr[dup] & RXCSR_M_RXDONE)) | |
return SCPE_OK; | |
if (dup_rcv_packet_data_callback[dup]) { | |
sim_debug (DBG_TRC, DUPDPTR, "dup_rcv_byte(dup=%d, psize=%d) - Invoking Receive Data callback\n", | |
dup, (int)dup_rcvpkbytes[dup]); | |
dup_rcv_packet_data_callback[dup](dup, dup_rcvpkbytes[dup]); | |
return SCPE_OK; | |
} | |
dup_rxcsr[dup] |= RXCSR_M_RXACT; | |
dup_rxdbuf[dup] &= ~RXDBUF_M_RCRCER; | |
dup_rxdbuf[dup] &= ~RXDBUF_M_RXDBUF; | |
dup_rxdbuf[dup] |= dup_rcvpacket[dup][dup_rcvpkinoff[dup]++]; | |
dup_rxcsr[dup] |= RXCSR_M_RXDONE; | |
if (((dup_rcvpkinoff[dup] == 8) || | |
(dup_rcvpkinoff[dup] >= dup_rcvpkbytes[dup])) && | |
(0 == ddcmp_crc16 (0, dup_rcvpacket[dup], dup_rcvpkinoff[dup]))) | |
dup_rxdbuf[dup] |= RXDBUF_M_RCRCER; | |
else | |
dup_rxdbuf[dup] &= ~RXDBUF_M_RCRCER; | |
if (dup_rcvpkinoff[dup] >= dup_rcvpkbytes[dup]) { | |
dup_rcvpkinoff[dup] = dup_rcvpkbytes[dup] = 0; | |
dup_rxcsr[dup] &= ~RXCSR_M_RXACT; | |
} | |
if (dup_rxcsr[dup] & RXCSR_M_RXIE) | |
dup_set_rxint (dup); | |
return SCPE_OK; | |
} | |
/* service routine to delay device activity */ | |
static t_stat dup_svc (UNIT *uptr) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
TMLN *lp = &dup_desc.ldsc[dup]; | |
sim_debug(DBG_TRC, DUPDPTR, "dup_svc(dup=%d)\n", dup); | |
if (!(dup_txcsr[dup] & TXCSR_M_TXDONE) && (!tmxr_tpbusyln (lp))) { | |
uint8 data = dup_txdbuf[dup] & TXDBUF_M_TXDBUF; | |
dup_put_msg_bytes (dup, &data, (dup_txdbuf[dup] & TXDBUF_M_TEOM) && (dptr == &dup_dev) ? 0 : 1, dup_txdbuf[dup] & TXDBUF_M_TSOM, (dup_txdbuf[dup] & TXDBUF_M_TEOM)); | |
if (tmxr_tpbusyln (lp)) { /* Packet ready to send? */ | |
sim_debug(DBG_TRC, DUPDPTR, "dup_svc(dup=%d) - Packet Done %d bytes\n", dup, dup_xmtpkoffset[dup]); | |
} | |
} | |
if ((tmxr_tpbusyln (lp) || dup_xmtpkbytes[dup]) && (lp->xmte || (!lp->conn))) { | |
int32 start = tmxr_tpbusyln (lp) ? tmxr_tpqln (lp) + tmxr_tqln (lp) : dup_xmtpkbytes[dup]; | |
int32 remain = tmxr_send_buffered_data (lp);/* send any buffered data */ | |
if (remain) { | |
sim_debug(DBG_PKT, DUPDPTR, "dup_svc(dup=%d) - Packet Transmission Stalled with %d bytes remaining\n", dup, remain); | |
} | |
else { | |
if (!lp->conn) { | |
if (dup_xmtpkoffset[dup]) { | |
sim_debug(DBG_PKT, DUPDPTR, "dup_svc(dup=%d) - %d byte packet transmission with link down (dropped)\n", dup, dup_xmtpkoffset[dup]); | |
} | |
dup_get_modem (dup); | |
} | |
else { | |
sim_debug(DBG_PKT, DUPDPTR, "dup_svc(dup=%d) - %d byte packet transmission complete\n", dup, dup_xmtpkbytes[dup]); | |
} | |
dup_xmtpkoffset[dup] = 0; | |
} | |
if (!tmxr_tpbusyln (lp)) { /* Done transmitting? */ | |
if (((start - remain) > 0) && dup_speed[dup] && dup_xmt_complete_callback[dup] && !dup_xmtpkdelaying[dup]) { /* just done, and speed limited using packet interface? */ | |
dup_xmtpkdelaying[dup] = 1; | |
sim_activate_notbefore (uptr, dup_xmtpkstart[dup] + (uint32)((tmr_poll*clk_tps)*((double)dup_xmtpkbytes[dup]*8)/dup_speed[dup])); | |
} | |
else { | |
dup_txcsr[dup] &= ~TXCSR_M_TXACT; /* Set idle */ | |
dup_xmtpkbytes[dup] = 0; | |
dup_xmtpkdelaying[dup] = 0; | |
if (dup_xmt_complete_callback[dup]) | |
dup_xmt_complete_callback[dup](dup, (dup_rxcsr[dup] & RXCSR_M_DCD) ? 0 : 1); | |
} | |
} | |
} | |
if (dup_rxcsr[dup] & RXCSR_M_RXACT) | |
dup_rcv_byte (dup); | |
return SCPE_OK; | |
} | |
static t_stat dup_poll_svc (UNIT *uptr) | |
{ | |
int32 dup, active, attached; | |
sim_debug(DBG_TRC, DUPDPTR, "dup_poll_svc()\n"); | |
tmxr_poll_conn(&dup_desc); | |
tmxr_poll_rx (&dup_desc); | |
tmxr_poll_tx (&dup_desc); | |
for (dup=active=attached=0; dup < dup_desc.lines; dup++) { | |
TMLN *lp = &dup_desc.ldsc[dup]; | |
if (dup_units[dup].flags & UNIT_ATT) | |
++attached; | |
if (dup_ldsc[dup].conn) | |
++active; | |
dup_get_modem (dup); | |
if (lp->xmte && tmxr_tpbusyln(lp)) { | |
sim_debug(DBG_PKT, DUPDPTR, "dup_poll_svc(dup=%d) - Packet Transmission of remaining %d bytes restarting...\n", dup, tmxr_tpqln (lp)); | |
dup_svc (&dup_units[dup]); /* Flush pending output */ | |
} | |
if (!(dup_rxcsr[dup] & RXCSR_M_RXACT)) { | |
const uint8 *buf; | |
uint16 size; | |
if (dup_parcsr[dup] & PARCSR_M_DECMODE) | |
ddcmp_tmxr_get_packet_ln (lp, &buf, &size, dup_corruption[dup]); | |
else { | |
size_t size_t_size; | |
tmxr_get_packet_ln (lp, &buf, &size_t_size); | |
size = (uint16)size_t_size; | |
} | |
if (buf) { | |
if (dup_rcvpksize[dup] < size) { | |
dup_rcvpksize[dup] = size; | |
dup_rcvpacket[dup] = (uint8 *)realloc (dup_rcvpacket[dup], dup_rcvpksize[dup]); | |
} | |
memcpy (dup_rcvpacket[dup], buf, size); | |
dup_rcvpkbytes[dup] = size; | |
dup_rcvpkinoff[dup] = 0; | |
dup_rxcsr[dup] |= RXCSR_M_RXACT; | |
dup_rcv_byte (dup); | |
} | |
} | |
} | |
if (active) | |
sim_clock_coschedule (uptr, tmxr_poll); /* reactivate */ | |
else { | |
for (dup=0; dup < dup_desc.lines; dup++) { | |
if (dup_speed[dup]/8) { | |
dup_wait[dup] = (tmr_poll*clk_tps)/(dup_speed[dup]/8); | |
if (dup_wait[dup] < DUP_WAIT) | |
dup_wait[dup] = DUP_WAIT; | |
} | |
else | |
dup_wait[dup] = DUP_WAIT; /* set minimum byte delay */ | |
} | |
if (attached) | |
sim_activate_after (uptr, DUP_CONNECT_POLL*1000000);/* periodic check for connections */ | |
} | |
return SCPE_OK; | |
} | |
/* Interrupt routines */ | |
static void dup_clr_rxint (int32 dup) | |
{ | |
dup_rxi = dup_rxi & ~(1 << dup); /* clr mux rcv int */ | |
if (dup_rxi == 0) /* all clr? */ | |
CLR_INT (DUPRX); | |
else SET_INT (DUPRX); /* no, set intr */ | |
return; | |
} | |
static void dup_set_rxint (int32 dup) | |
{ | |
dup_rxi = dup_rxi | (1 << dup); /* set mux rcv int */ | |
SET_INT (DUPRX); /* set master intr */ | |
sim_debug(DBG_INT, DUPDPTR, "dup_set_rxint(dup=%d)\n", dup); | |
return; | |
} | |
static int32 dup_rxinta (void) | |
{ | |
int32 dup; | |
for (dup = 0; dup < dup_desc.lines; dup++) { /* find 1st mux */ | |
if (dup_rxi & (1 << dup)) { | |
sim_debug(DBG_INT, DUPDPTR, "dup_rxinta(dup=%d)\n", dup); | |
dup_clr_rxint (dup); /* clear intr */ | |
return (dup_dib.vec + (dup * 010)); /* return vector */ | |
} | |
} | |
return 0; | |
} | |
static void dup_clr_txint (int32 dup) | |
{ | |
dup_txi = dup_txi & ~(1 << dup); /* clr mux xmt int */ | |
if (dup_txi == 0) /* all clr? */ | |
CLR_INT (DUPTX); | |
else SET_INT (DUPTX); /* no, set intr */ | |
return; | |
} | |
static void dup_set_txint (int32 dup) | |
{ | |
dup_txi = dup_txi | (1 << dup); /* set mux xmt int */ | |
SET_INT (DUPTX); /* set master intr */ | |
sim_debug(DBG_INT, DUPDPTR, "dup_set_txint(dup=%d)\n", dup); | |
return; | |
} | |
static int32 dup_txinta (void) | |
{ | |
int32 dup; | |
for (dup = 0; dup < dup_desc.lines; dup++) { /* find 1st mux */ | |
if (dup_txi & (1 << dup)) { | |
sim_debug(DBG_INT, DUPDPTR, "dup_txinta(dup=%d)\n", dup); | |
dup_clr_txint (dup); /* clear intr */ | |
return (dup_dib.vec + 4 + (dup * 010)); /* return vector */ | |
} | |
} | |
return 0; | |
} | |
/* Device reset */ | |
static t_stat dup_clear (int32 dup, t_bool flag) | |
{ | |
sim_debug(DBG_TRC, DUPDPTR, "dup_clear(dup=%d,flag=%d)\n", dup, flag); | |
dup_rxdbuf[dup] = 0; /* silo empty */ | |
dup_txdbuf[dup] = 0; | |
dup_parcsr[dup] = 0; /* no params */ | |
dup_txcsr[dup] = TXCSR_M_TXDONE; /* clear CSR */ | |
dup_wait[dup] = DUP_WAIT; /* initial/default byte delay */ | |
if (flag) { /* INIT? clr all */ | |
dup_rxcsr[dup] = 0; | |
dup_set_modem (dup, dup_rxcsr[dup]); /* push change out to line */ | |
} | |
else | |
dup_rxcsr[dup] &= ~(RXCSR_M_DTR|RXCSR_M_RTS); /* else save dtr & rts */ | |
dup_clr_rxint (dup); /* clear int */ | |
dup_clr_txint (dup); | |
if (!dup_ldsc[dup].conn) /* set xmt enb */ | |
dup_ldsc[dup].xmte = 1; | |
dup_ldsc[dup].rcve = 0; /* clr rcv enb */ | |
return SCPE_OK; | |
} | |
static t_stat dup_reset (DEVICE *dptr) | |
{ | |
t_stat r; | |
int32 i, ndev, attached = 0; | |
sim_debug(DBG_TRC, dptr, "dup_reset()\n"); | |
dup_desc.packet = TRUE; | |
dup_desc.buffered = 16384; | |
if ((UNIBUS) && (dptr == &dpv_dev)) { | |
if (!(dptr->flags & DEV_DIS)) { | |
sim_printf ("Can't enable Qbus device on Unibus system\n"); | |
dptr->flags |= DEV_DIS; | |
return SCPE_ARG; | |
} | |
return SCPE_OK; | |
} | |
if ((!UNIBUS) && (dptr == &dup_dev)) { | |
if (!(dptr->flags & DEV_DIS)) { | |
sim_printf ("Can't enable Unibus device on Qbus system\n"); | |
dptr->flags |= DEV_DIS; | |
return SCPE_ARG; | |
} | |
return SCPE_OK; | |
} | |
if (dup_ldsc == NULL) { /* First time startup */ | |
dup_desc.ldsc = dup_ldsc = (TMLN *)calloc (dup_desc.lines, sizeof(*dup_ldsc)); | |
for (i = 0; i < dup_desc.lines; i++) { /* init each line */ | |
dup_units[i] = dup_unit_template; | |
if (dup_units[i].flags & UNIT_ATT) | |
++attached; | |
} | |
dup_units[dup_desc.lines] = dup_poll_unit_template; | |
/* Initialize to standard factory Option Jumper Settings */ | |
for (i = 0; i < DUP_LINES; i++) { | |
dup_W3[i] = TRUE; | |
dup_W5[i] = FALSE; | |
dup_W6[i] = TRUE; | |
} | |
} | |
for (i = 0; i < dup_desc.lines; i++) { /* init each line */ | |
dup_clear (i, TRUE); | |
if (dup_units[i].flags & UNIT_ATT) | |
++attached; | |
} | |
dup_rxi = dup_txi = 0; /* clr master int */ | |
CLR_INT (DUPRX); | |
CLR_INT (DUPTX); | |
tmxr_set_modem_control_passthru (&dup_desc); /* We always want Modem Control */ | |
dup_desc.notelnet = TRUE; /* We always want raw tcp socket */ | |
dup_desc.dptr = DUPDPTR; /* Connect appropriate device */ | |
dup_desc.uptr = dup_units+dup_desc.lines; /* Identify polling unit */ | |
sim_cancel (dup_units+dup_desc.lines); /* stop poll */ | |
ndev = ((dptr->flags & DEV_DIS)? 0: dup_desc.lines ); | |
r = auto_config (dptr->name, ndev); /* auto config */ | |
if ((r == SCPE_OK) && (attached)) | |
sim_activate_after (dup_units+dup_desc.lines, DUP_CONNECT_POLL*1000000);/* start poll */ | |
return r; | |
} | |
static t_stat dup_attach (UNIT *uptr, char *cptr) | |
{ | |
t_stat r; | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
char attach_string[512]; | |
if (!cptr || !*cptr) | |
return SCPE_ARG; | |
if (!(uptr->flags & UNIT_ATTABLE)) | |
return SCPE_NOATT; | |
sprintf (attach_string, "Line=%d,%s", dup, cptr); | |
r = tmxr_open_master (&dup_desc, attach_string); /* open master socket */ | |
free (uptr->filename); | |
uptr->filename = tmxr_line_attach_string(&dup_desc.ldsc[dup]); | |
if (r != SCPE_OK) /* error? */ | |
return r; | |
uptr->flags |= UNIT_ATT; | |
sim_activate_after (dup_units+dup_desc.lines, DUP_CONNECT_POLL*1000000);/* start poll */ | |
return r; | |
} | |
static t_stat dup_detach (UNIT *uptr) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
TMLN *lp = &dup_ldsc[dup]; | |
int32 i, attached; | |
t_stat r; | |
if (!(uptr->flags & UNIT_ATT)) /* attached? */ | |
return SCPE_OK; | |
sim_cancel (uptr); | |
uptr->flags &= ~UNIT_ATT; | |
for (i=attached=0; i<dup_desc.lines; i++) | |
if (dup_dev.units[i].flags & UNIT_ATT) | |
++attached; | |
if (!attached) | |
sim_cancel (dup_units+dup_desc.lines); /* stop poll on last detach */ | |
r = tmxr_detach_ln (lp); | |
free (uptr->filename); | |
uptr->filename = NULL; | |
free (dup_rcvpacket[dup]); | |
dup_rcvpacket[dup] = NULL; | |
dup_rcvpksize[dup] = 0; | |
dup_rcvpkbytes[dup] = 0; | |
free (dup_xmtpacket[dup]); | |
dup_xmtpacket[dup] = NULL; | |
dup_xmtpksize[dup] = 0; | |
dup_xmtpkoffset[dup] = 0; | |
return r; | |
} | |
/* SET/SHOW SPEED processor */ | |
static t_stat dup_showspeed (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
if (dup_speed[dup]) | |
fprintf(st, "speed=%d bits/sec", dup_speed[dup]); | |
else | |
fprintf(st, "speed=0 (unrestricted)"); | |
return SCPE_OK; | |
} | |
static t_stat dup_setspeed (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
t_stat r; | |
int32 newspeed; | |
if (cptr == NULL) | |
return SCPE_ARG; | |
newspeed = (int32) get_uint (cptr, 10, 100000000, &r); | |
if (r != SCPE_OK) | |
return r; | |
dup_speed[dup] = newspeed; | |
return SCPE_OK; | |
} | |
/* SET/SHOW CORRUPTION processor */ | |
static t_stat dup_showcorrupt (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
if (dup_corruption[dup]) | |
fprintf(st, "Corruption=%d milligulps (%.1f%% of messages processed)", dup_corruption[dup], ((double)dup_corruption[dup])/10.0); | |
else | |
fprintf(st, "No Corruption"); | |
return SCPE_OK; | |
} | |
static t_stat dup_setcorrupt (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
t_stat r; | |
int32 appetite; | |
if (cptr == NULL) | |
return SCPE_ARG; | |
appetite = (int32) get_uint (cptr, 10, 999, &r); | |
if (r != SCPE_OK) | |
return r; | |
dup_corruption[dup] = appetite; | |
return SCPE_OK; | |
} | |
/* SET/SHOW W3 processor */ | |
static t_stat dup_show_W3 (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
if (dup_W3[dup]) | |
fprintf(st, "W3 Jumper Installed"); | |
else | |
fprintf(st, "W3 Jumper Removed"); | |
return SCPE_OK; | |
} | |
static t_stat dup_set_W3 (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
dup_W3[dup] = val; | |
return SCPE_OK; | |
} | |
/* SET/SHOW W5 processor */ | |
static t_stat dup_show_W5 (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
if (dup_W5[dup]) | |
fprintf(st, "W5 Jumper Installed"); | |
else | |
fprintf(st, "W5 Jumper Removed"); | |
return SCPE_OK; | |
} | |
static t_stat dup_set_W5 (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
dup_W5[dup] = val; | |
return SCPE_OK; | |
} | |
/* SET/SHOW W6 processor */ | |
static t_stat dup_show_W6 (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
if (dup_W6[dup]) | |
fprintf(st, "W6 Jumper Installed"); | |
else | |
fprintf(st, "W6 Jumper Removed"); | |
return SCPE_OK; | |
} | |
static t_stat dup_set_W6 (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
DEVICE *dptr = DUPDPTR; | |
int32 dup = (int32)(uptr-dptr->units); | |
dup_W6[dup] = val; | |
return SCPE_OK; | |
} | |
/* SET LINES processor */ | |
static t_stat dup_setnl (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
int32 newln, l; | |
uint32 i; | |
t_stat r; | |
DEVICE *dptr = DUPDPTR; | |
for (i=0; i<dptr->numunits; i++) | |
if (dptr->units[i].flags&UNIT_ATT) | |
return SCPE_ALATT; | |
if (cptr == NULL) | |
return SCPE_ARG; | |
newln = (int32) get_uint (cptr, 10, DUP_LINES, &r); | |
if ((r != SCPE_OK) || (newln == dup_desc.lines)) | |
return r; | |
if (newln == 0) | |
return SCPE_ARG; | |
sim_cancel (dup_units + dup_desc.lines); | |
dup_dib.lnt = newln * IOLN_DUP; /* set length */ | |
dup_desc.ldsc = dup_ldsc = (TMLN *)realloc(dup_ldsc, newln*sizeof(*dup_ldsc)); | |
for (l=dup_desc.lines; l < newln; l++) { | |
memset (&dup_ldsc[l], 0, sizeof(*dup_ldsc)); | |
dup_units[l] = dup_unit_template; | |
} | |
dup_units[newln] = dup_poll_unit_template; | |
dup_desc.lines = newln; | |
dup_desc.uptr = dptr->units + newln; /* Identify polling unit */ | |
dptr->numunits = newln + 1; | |
return dup_reset (dptr); /* setup lines and auto config */ | |
} | |
static t_stat dup_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr) | |
{ | |
const char helpString[] = | |
/* The '*'s in the next line represent the standard text width of a help line */ | |
/****************************************************************************/ | |
" The %D11 is a single-line, program controlled, double buffered\n" | |
" communications device designed to interface the %1s system to a\n" | |
" serial synchronous line. The original hardware is capable of handling\n" | |
" a wide variety of protocols, including byte oriented protocols, such\n" | |
" as DDCMP and BISYNC and bit-oriented protocols such as SDLC, HDLC\n" | |
" and ADCCP. The emulated device currently only supports connections\n" | |
" using the DDCMP protocol.\n\n" | |
" The %D11 is ideally suited for interfacing the %1s system\n" | |
" to medium-speed synchronous lines for remote batch, remote data\n" | |
" collection, remote concentration and network applications. Multiple\n" | |
" %D11's on a %1s allow its use in applications requiring several\n" | |
" synchronous lines.\n\n" | |
" The %D11 is capable of transmitting data at the maximum speed of\n" | |
" 9600 baud. The emulated device can move data at significantly faster\n" | |
" data rates. The maximum emulated rate is dependent on the host CPU's\n" | |
" available cycles.\n" | |
"1 Hardware Description\n" | |
" The %1s %D11 consists of a microprocessor module and a synchronous line unit\n" | |
" module.\n" | |
"2 $Registers\n" | |
"\n" | |
" These registers contain the emulated state of the device. These values\n" | |
" don't necessarily relate to any detail of the original device being\n" | |
" emulated but are merely internal details of the emulation.\n" | |
"1 Configuration\n" | |
" A %D device is configured with various simh SET and ATTACH commands\n" | |
"2 $Set commands\n" | |
"3 Lines\n" | |
" A maximum of %2s %D11 devices can be emulated concurrently in the %S\n" | |
" simulator. The number of simulated %D devices or lines can be\n" | |
" specified with command:\n" | |
"\n" | |
"+sim> SET %D LINES=n\n" | |
"3 Peer\n" | |
" To set the host and port to which data is to be transmitted use the\n" | |
" following command:\n" | |
"\n" | |
"+sim> SET %U PEER=host:port\n" | |
"3 Connectpoll\n" | |
" The minimum interval between attempts to connect to the other side is set\n" | |
" using the following command:\n" | |
"\n" | |
"+sim> SET %U CONNECTPOLL=n\n" | |
"\n" | |
" Where n is the number of seconds. The default is %3s seconds.\n" | |
"3 Speed\n" | |
" If you want to experience the actual data rates of the physical hardware\n" | |
" you can set the bit rate of the simulated line can be set using the\n" | |
" following command:\n" | |
"\n" | |
"+sim> SET %U SPEED=n\n" | |
"\n" | |
" Where n is the number of data bits per second that the simulated line\n" | |
" runs at. In practice this is implemented as a delay while transmitting\n" | |
" bytes to the socket. Use a value of zero to run at full speed with no\n" | |
" artificial throttling.\n" | |
"3 Corruption\n" | |
" Corruption Troll - the DDCMP emulation includes the ability to enable a\n" | |
" process that will intentionally drop or corrupt some messages. This\n" | |
" emulates the less-than-perfect communications lines encountered in the\n" | |
" real world, and enables network monitoring software to see non-zero error\n" | |
" counters.\n" | |
"\n" | |
" The troll selects messages with a probablility selected by the SET %U\n" | |
" CORRUPT command. The units are 0.1%%; that is, a value of 1 means that\n" | |
" every message has a 1/1000 chance of being selected to be corrupted\n" | |
" or discarded.\n" | |
/****************************************************************************/ | |
#define DUP_HLP_ATTACH "Configuration Attach" | |
"2 Attach\n" | |
" The communication line performs input and output through a TCP session\n" | |
" (or UDP session) connected to a user-specified port. The ATTACH command\n" | |
" specifies the port to be used as well as the peer address:\n" | |
"\n" | |
"+sim> ATTACH %U {interface:}port{,UDP},Connect=peerhost:port\n" | |
"\n" | |
" where port is a decimal number between 1 and 65535 that is not being\n" | |
" used for other TCP/IP activities.\n" | |
"\n" | |
" Specifying symmetric attach configuration (with both a listen port and\n" | |
" a peer address) will cause the side receiving an incoming\n" | |
" connection to validate that the connection actually comes from the\n" | |
" connecction destination system.\n" | |
" A symmetric attach configuration is required when using UDP packet\n" | |
" transport.\n" | |
"\n" | |
" The default connection uses TCP transport between the local system and\n" | |
" the peer. Alternatively, UDP can be used by specifying UDP on the\n" | |
" ATTACH command.\n" | |
"\n" | |
"2 Examples\n" | |
" To configure two simulators to talk to each other use the following\n" | |
" example:\n" | |
" \n" | |
" Machine 1\n" | |
"+sim> SET %D ENABLE\n" | |
"+sim> ATTACH %U 1111,connect=LOCALHOST:2222\n" | |
" \n" | |
" Machine 2\n" | |
"+sim> SET %D ENABLE\n" | |
"+sim> ATTACH %U 2222,connect=LOCALHOST:1111\n" | |
"\n" | |
"1 Monitoring\n" | |
" The %D device and %U line configuration and state can be displayed with\n" | |
" one of the available show commands.\n" | |
"2 $Show commands\n" | |
"1 Diagnostics\n" | |
" Corruption Troll - the DDCMP emulation includes a process that will\n" | |
" intentionally drop or corrupt some messages. This emulates the\n" | |
" less-than-perfect communications lines encountered in the real world,\n" | |
" and enables network monitoring software to see non-zero error counters.\n" | |
"\n" | |
" The troll selects messages with a probablility selected by the SET %U\n" | |
" CORRUPT command. The units are 0.1%%; that is, a value of 1 means that\n" | |
" every message has a 1/1000 chance of being selected to be corrupted\n" | |
" or discarded.\n" | |
"1 Restrictions\n" | |
" Real hardware synchronous connections could operate in Multi-Point mode.\n" | |
" Multi-Point mode was a way of sharing a single wire with multiple\n" | |
" destination systems or devices. Multi-Point mode is not currently\n" | |
" emulated by this or other simulated synchronous devices.\n" | |
"\n" | |
"1 Implementation\n" | |
" A real %D11 transports host generated protocol implemented data via a\n" | |
" synchronous connection, the emulated device makes a TCP (or UDP)\n" | |
" connection to another emulated device which either speaks DDCMP over the\n" | |
" TCP connection directly, or interfaces to a simulated computer where the\n" | |
" operating system speaks the DDCMP protocol on the wire.\n" | |
"\n" | |
" The %D11 can be used for point-to-point DDCMP connections carrying\n" | |
" DECnet and other types of networking, e.g. from ULTRIX or DSM.\n" | |
"1 Debugging\n" | |
" The simulator has a number of debug options, these are:\n" | |
"\n" | |
"++REG Shows whenever a CSR is programatically read or written\n" | |
"++++and the current value.\n" | |
"++INT Shows Interrupt activity.\n" | |
"++PKT Shows Packet activity.\n" | |
"++XMT Shows Transmitted data.\n" | |
"++RCV Shows Received data.\n" | |
"++MDM Shows Modem Signal Transitions.\n" | |
"++CON Shows connection activities.\n" | |
"++TRC Shows routine call traces.\n" | |
"++ASY Shows Asynchronous activities.\n" | |
"\n" | |
" To get a full trace use\n" | |
"\n" | |
"+sim> SET %D DEBUG\n" | |
"\n" | |
" However it is recommended to use the following when sending traces:\n" | |
"\n" | |
"+sim> SET %D DEBUG=REG;PKT;XMT;RCV;CON\n" | |
"\n" | |
"1 Related Devices\n" | |
" The %D11 can facilitate communication with other simh simulators which\n" | |
" have emulated synchronous network devices available. These include\n" | |
" the following:\n" | |
"\n" | |
"++DUP11* Unibus PDP11 simulators\n" | |
"++DPV11* Qbus PDP11 simulators\n" | |
"++KDP11* Unibus PDP11 simulators and PDP10 simulators\n" | |
"++DMR11 Unibus PDP11 simulators and Unibus VAX simulators\n" | |
"++DMC11 Unibus PDP11 simulators and Unibus VAX simulators\n" | |
"++DMP11 Unibus PDP11 simulators and Unibus VAX simulators\n" | |
"++DMV11 Qbus VAX simulators\n" | |
"\n" | |
"++* Indicates systems which have OS provided DDCMP implementations.\n" | |
; | |
char busname[16]; | |
char devcount[16]; | |
char connectpoll[16]; | |
sprintf (busname, UNIBUS ? "Unibus" : "Qbus"); | |
sprintf (devcount, "%d", DUP_LINES); | |
sprintf (connectpoll, "%d", DUP_CONNECT_POLL); | |
return scp_help (st, dptr, uptr, flag, helpString, cptr, busname, devcount, connectpoll); | |
} | |
static t_stat dup_help_attach (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr) | |
{ | |
return dup_help (st, dptr, uptr, flag, DUP_HLP_ATTACH); | |
} | |
static const char *dup_description (DEVICE *dptr) | |
{ | |
return (UNIBUS) ? "DUP11 bit synchronous interface" : | |
"DPV11 bit synchronous interface"; | |
} |