/* pdp11_dmc.c: DMC11/DMR11/DMP11/DMV11 Emulation | |
------------------------------------------------------------------------------ | |
Copyright (c) 2011, Robert M. A. Jarratt, 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 | |
THE AUTHOR 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 the author shall not be | |
used in advertising or otherwise to promote the sale, use or other dealings | |
in this Software without prior written authorization from the author. | |
------------------------------------------------------------------------------ | |
Written by Mark Pizzolato based on an original version by Robert Jarratt | |
Modification history: | |
25-Jan-13 RJ Error checking for already attached in dmc_settype() fixed. | |
25-Jan-13 RJ If attach when already attached then detach first. | |
23-Jan-13 RJ Don't do anything if not attached. See https://github.com/simh/simh/issues/28 | |
23-Jan-13 RJ Clock co-scheduling move to generic framework (from Mark Pizzolato) | |
21-Jan-13 RJ Added help. | |
15-Jan-13 RJ Contribution from Paul Koning: | |
Support for RSTS using the ROM INPUT (ROM I) command to get | |
the DMC11 to report DSR status. | |
Don't accept any data from the peer until a buffer has been | |
made available. | |
04-Aug-13 MP Massive Rewrite/Restructure to implement the DDCMP wire | |
protocol for interoperation with other sync devices (DUP11, | |
KDP, etc.) | |
------------------------------------------------------------------------------ | |
I/O is done through sockets so that the remote system can be on the same | |
host machine. The device starts polling for incoming connections when it | |
receives its first read buffer. The device opens the connection for writing | |
when it receives the first write buffer. | |
Transmit and receive buffers are added to their respective queues and the | |
polling method in dmc_poll_svc() checks for input and sends any output. | |
Tested with two diagnostics. To run the diagnostics set the default | |
directory to SYS$MAINTENANCE, run ESSAA and then configure it for the | |
DMC-11 with the following commands: | |
The above commands can be put into a COM file in SYS$MAINTENANCE (works | |
on VMS 3.0 but not 4.6, not sure why). | |
ATT DW780 SBI DW0 3 4 | |
ATT DMC11 DW0 XMA0 760070 300 5 | |
SELECT XMA0 | |
(if putting these into a COM file to be executed by ESSAA add a "DS> " prefix) | |
The first is EVDCA which takes no parameters. Invoke it with the command | |
R EVDCA. This diagnostic uses the DMC-11 loopback functionality and the | |
transmit port is not used when LU LOOP is enabled. Seems to work only under | |
later versions of VMS such as 4.6, does not work on 3.0. It does not work | |
under VMS 3.x since in that environment, no receive buffers are ever made | |
available to the device while testing. | |
The second is EVDMC, invoke this with the command R EVDMC. For this I used | |
the following commands inside the diagnostic: | |
RUN MODE=TRAN on one machine | |
RUN MODE=REC on the other | |
or using loopback mode: | |
SET TRANSMIT=CCITT/SIZE=25/COPY=5 | |
SET EXPECT=CCITT/SIZE=25/COPY=5 | |
RUN MODE=ACTIVE/LOOP=INT/STATUS/PASS=3 | |
You can add /PASS=n to the above commands to get the diagnostic to send and | |
receive more buffers. | |
The other test was to configure DECnet on VMS 4.6 and do SET HOST. | |
*/ | |
// TODO: Test MOP. | |
#if defined (VM_PDP10) /* PDP10 version */ | |
#include "pdp10_defs.h" | |
#if !defined(DMP_NUMDEVICE) | |
#define DMP_NUMDEVICE 1 /* Minimum number for array size DMP-11/DMV-11 devices */ | |
#endif | |
#elif defined (VM_VAX) /* VAX version */ | |
#include "vax_defs.h" | |
#else /* PDP-11 version */ | |
#include "pdp11_defs.h" | |
#endif | |
#include <assert.h> | |
#include "sim_tmxr.h" | |
#include "pdp11_ddcmp.h" | |
#define DMC_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 */ | |
#if !defined(DMC_NUMDEVICE) | |
#define DMC_NUMDEVICE 8 /* default MAX # DMC-11 devices */ | |
#endif | |
#if !defined(DMP_NUMDEVICE) | |
#define DMP_NUMDEVICE 8 /* default MAX # DMP-11/DMV-11 devices */ | |
#endif | |
#define DMC_RDX 8 | |
/* DMC/DMR register SEL0 */ | |
#define DMC_SEL0_V_ITYPE 0 | |
#define DMC_SEL0_S_ITYPE 4 | |
#define DMC_SEL0_M_ITYPE (((1<<DMC_SEL0_S_ITYPE)-1)<<DMC_SEL0_V_ITYPE) | |
#define DMC_C_TYPE_XBACC 0 /* Transmit Buffer Address/Character Count Command and Response */ | |
#define DMC_C_TYPE_CNTL 1 /* Control In Command and Control Out Response */ | |
#define DMC_C_TYPE_HALT 2 /* Halt In Command */ | |
#define DMC_C_TYPE_BASEIN 3 /* Base In Command */ | |
#define DMC_C_TYPE_RBACC 4 /* Receive Buffer Address/Character Count Command and Response */ | |
#define DMC_SEL0_V_RQI 5 | |
#define DMC_SEL0_M_RQI 0x0020 | |
#define DMC_SEL0_V_IEI 6 | |
#define DMC_SEL0_M_IEI 0x0040 | |
#define DMC_SEL0_V_RDI 7 | |
#define DMC_SEL0_M_RDI 0x0080 | |
#define DMC_SEL0_V_STEPUP 8 | |
#define DMC_SEL0_M_STEPUP 0x0100 | |
#define DMC_SEL0_V_ROMI 9 | |
#define DMC_SEL0_M_ROMI 0x0200 | |
#define DMC_SEL0_V_ROMO 10 | |
#define DMC_SEL0_M_ROMO 0x0400 | |
#define DMC_SEL0_V_LU_LOOP 11 | |
#define DMC_SEL0_M_LU_LOOP 0x0800 | |
#define DMC_SEL0_V_STEPLU 12 | |
#define DMC_SEL0_M_STEPLU 0x1000 | |
#define DMC_SEL0_V_UDIAG 13 | |
#define DMC_SEL0_M_UDIAG 0x2000 | |
#define DMC_SEL0_V_MCLEAR 14 | |
#define DMC_SEL0_M_MCLEAR 0x4000 | |
#define DMC_SEL0_V_RUN 15 | |
#define DMC_SEL0_M_RUN 0x8000 | |
/* DMP/DMV register SEL0 */ | |
#define DMP_SEL0_V_IEI 0 | |
#define DMP_SEL0_M_IEI 0x0001 | |
#define DMP_SEL0_V_IEO 4 | |
#define DMP_SEL0_M_IEO 0x0010 | |
#define DMP_SEL0_V_RQI 7 | |
#define DMP_SEL0_M_RQI 0x0080 | |
/* DMC/DMR register SEL2 */ | |
#define DMC_SEL2_V_CODE 0 | |
#define DMC_SEL2_S_CODE 3 | |
#define DMC_SEL2_M_CODE (((1<<DMC_SEL2_S_CODE)-1)<<DMC_SEL2_V_CODE) | |
#define DMC_SEL2_V_IEO 6 | |
#define DMC_SEL2_M_IEO 0x0040 | |
#define DMC_SEL2_V_RDO 7 | |
#define DMC_SEL2_M_RDO 0x0080 | |
/* DMP/DMV register SEL2 */ | |
#define DMP_SEL2_V_CODE 0 | |
#define DMP_SEL2_S_CODE 3 | |
#define DMP_SEL2_M_CODE (((1<<DMP_SEL2_S_CODE)-1)<<DMP_SEL2_V_CODE) | |
#define DMP_C_TYPE_RBACC 0 /* Receive Buffer Address/Character Count Command and Response */ | |
#define DMP_C_TYPE_CNTL 1 /* Control Command or Control Response */ | |
#define DMP_C_TYPE_MODE 2 /* Mode Definition Command or Information Response */ | |
#define DMP_C_TYPE_UNUSED 3 /* Receive Buffer disposition (unused) Response */ | |
#define DMP_C_TYPE_XBACC 4 /* Transmit Buffer Address/Character Count Command and Response */ | |
#define DMP_C_TYPE_RESERVED 5 /* Reserved/Unused code */ | |
#define DMP_C_TYPE_SENT 6 /* Buffer disposition (sent but not acknowledged) Response */ | |
#define DMP_C_TYPE_UNSENT 7 /* Buffer disposition (not sent) Response */ | |
#define DMP_SEL2_V_22BIT 3 | |
#define DMP_SEL2_M_22BIT 0x0008 | |
#define DMP_SEL2_V_RDI 4 | |
#define DMP_SEL2_M_RDI 0x0010 | |
#define DMP_SEL2_V_RDO 7 | |
#define DMP_SEL2_M_RDO 0x0080 | |
/* DMC/DMR register SEL4 */ | |
#define DMC_SEL4_V_CAR 0 | |
#define DMC_SEL4_M_CAR 0x0001 | |
#define DMC_SEL4_V_STN 1 | |
#define DMC_SEL4_M_STN 0x0002 | |
#define DMC_SEL4_V_CTS 2 | |
#define DMC_SEL4_M_CTS 0x0004 | |
#define DMC_SEL4_V_DSR 3 | |
#define DMC_SEL4_M_DSR 0x0008 | |
#define DMC_SEL4_V_HDX 4 | |
#define DMC_SEL4_M_HDX 0x0010 | |
#define DMC_SEL4_V_RTS 5 | |
#define DMC_SEL4_M_RTS 0x0020 | |
#define DMC_SEL4_V_DTR 6 | |
#define DMC_SEL4_M_DTR 0x0040 | |
#define DMC_SEL4_V_RI 7 | |
#define DMC_SEL4_M_RI 0x0080 | |
/* SEL2 */ | |
#define DMP_TYPE_INPUT_MASK 0x0007 | |
/* DMC/DMR register SEL6 */ | |
/* Bit Flags used in a Control Out command */ | |
#define DMC_SEL6_V_NAKTRSH 0 /* NAK Threshold */ | |
#define DMC_SEL6_M_NAKTRSH 0x0001 | |
#define DMC_SEL6_V_TIMEOUT 1 | |
#define DMC_SEL6_M_TIMEOUT 0x0002 | |
#define DMC_SEL6_V_NOBUF 2 | |
#define DMC_SEL6_M_NOBUF 0x0004 | |
#define DMC_SEL6_V_MAINTRCV 3 | |
#define DMC_SEL6_M_MAINTRCV 0x0008 | |
#define DMC_SEL6_V_LOSTDATA 4 | |
#define DMC_SEL6_M_LOSTDATA 0x0010 | |
#define DMC_SEL6_V_DISCONN 6 | |
#define DMC_SEL6_M_DISCONN 0x0040 | |
#define DMC_SEL6_V_STRTRCVD 7 | |
#define DMC_SEL6_M_STRTRCVD 0x0080 | |
#define DMC_SEL6_V_NXM 8 | |
#define DMC_SEL6_M_NXM 0x0100 | |
#define DMC_SEL6_V_HALTCOMP 9 | |
#define DMC_SEL6_M_HALTCOMP 0x0200 | |
/* Bit Flags used in a Control In command */ | |
#define DMC_SEL6_V_MAINT 8 /* NAK Threshold */ | |
#define DMC_SEL6_M_MAINT 0x0100 | |
#define DMC_SEL6_V_HDX 10 | |
#define DMC_SEL6_M_HDX 0x0400 | |
#define DMC_SEL6_V_LONGSTRT 11 | |
#define DMC_SEL6_M_LONGSTRT 0x0800 | |
#define DSPDSR 0x22b3 /* KMC opcode to move line unit status to SEL2 */ | |
#define DROPDTR 0xa40b /* KMC opcode to drop DTR */ | |
#define UINST_CNF 0x2296 /* KMC opcode to get config switches */ | |
#define UINST_RROM 0x814d /* KMC opcode to read DMC ROM */ | |
#define SEL2_TYPEO_BIT 0 | |
#define SEL2_RDO_BIT 7 | |
#define SEL2_IEO_BIT 6 | |
#define SEL2_OUT_IO_BIT 2 | |
#define SEL2_LINE_BIT 8 | |
#define SEL2_LINE_BIT_LENGTH 6 | |
#define SEL2_PRIO_BIT 14 | |
#define SEL2_PRIO_BIT_LENGTH 2 | |
#define DMC_QUEUE_SIZE 7 | |
#define DMR_QUEUE_SIZE 64 | |
#define DMP_QUEUE_SIZE 64 | |
struct csrs { | |
uint16 *sel0; | |
uint16 *sel2; | |
uint16 *sel4; | |
uint16 *sel6; | |
uint16 *sel10; | |
}; | |
typedef struct csrs CSRS; | |
typedef enum { | |
Uninitialised, /* before MASTER CLEAR */ | |
Initialised, /* after MASTER CLEAR */ | |
Running, /* after any transmit or receive buffer has been supplied */ | |
Halted /* after reciept of explicit halt input command */ | |
} ControllerState; | |
typedef enum { | |
Idle, | |
InputTransfer, | |
OutputTransfer, | |
OutputControl | |
} TransferState; | |
/* Queue elements | |
* A queue is a double-linked list of element headers. | |
* The head of the queue is an element without a body. | |
* A queue is empty when the only element in the queue is | |
* the head. | |
* Each queue has an asociated count of the elements in the | |
* queue; this simplifies knowing its state. | |
* Each queue also has a maximum length. | |
* | |
* Queues are manipulated with initqueue, insqueue, and remqueue. | |
*/ | |
struct queuehdr { | |
struct queuehdr *next; | |
struct queuehdr *prev; | |
struct buffer_queue *queue; | |
}; | |
typedef struct queuehdr QH; | |
typedef struct buffer_queue { | |
QH hdr; /* Forward/Back Buffer pointers */ | |
char * name; /* Queue name */ | |
size_t size; /* Maximum number of entries (0 means no limit) */ | |
size_t count; /* Current Used Count */ | |
struct dmc_controller *controller; /* back pointer to the containing controller */ | |
} BUFFER_QUEUE; | |
/* Queue management */ | |
/* Insert entry on queue after pred, if count < max. | |
* Increment count. | |
* To insert at head of queue, specify &head for predecessor. | |
* To insert at tail, specify head.prev | |
* | |
* returns FALSE if queue is full. | |
*/ | |
static t_bool insqueue (QH *entry, QH *pred) | |
{ | |
if ((pred->queue->size > 0) && (pred->queue->count >= pred->queue->size)) | |
return FALSE; | |
assert (entry->queue == NULL); | |
entry->next = pred->next; | |
entry->prev = pred; | |
entry->queue = pred->queue; | |
pred->next->prev = entry; | |
pred->next = entry; | |
++pred->queue->count; | |
return TRUE; | |
} | |
/* Remove entry from queue. | |
* Decrement count. | |
* To remove from head of queue, specify head.next. | |
* To remove form tail of queue, specify head.prev. | |
* | |
* returns NULL if queue is empty. | |
*/ | |
static void *remqueue (QH *entry) | |
{ | |
if (entry->queue->count == 0) | |
return NULL; | |
entry->prev->next = entry->next; | |
entry->next->prev = entry->prev; | |
--entry->queue->count; | |
entry->next = entry->prev = NULL; | |
entry->queue = NULL; | |
return (void *)entry; | |
} | |
/* Initialize a queue to empty. | |
* | |
* Optionally, adds a list of elements to the queue. | |
* max, list and size are only used if list is non-NULL. | |
* | |
* Convenience macros: | |
* MAX_LIST_SIZE(q) specifies max, list and size for an array of elements q | |
* INIT_HDR_ONLY provides placeholders for these arguments when only the | |
* header and count are to be initialized. | |
*/ | |
#define DIM(x) (sizeof(x)/sizeof((x)[0])) | |
/* Convenience for initqueue() calls */ | |
# define MAX_LIST_SIZE(q) DIM(q), (q), sizeof(q[0]) | |
# define INIT_HDR_ONLY 0, NULL, 0 | |
static void initqueue (QH *head, struct buffer_queue *queue, size_t max, void *list, size_t size) | |
{ | |
head->next = head->prev = head; | |
head->queue = queue; | |
head->queue->count = 0; | |
head->queue->size = max; | |
if (list == NULL) | |
return; | |
while (insqueue ((QH *)list, head->prev)) | |
list = (QH *)(((char *)list)+size); | |
return; | |
} | |
typedef enum { | |
Receive, /* Receive Buffer */ | |
TransmitData, /* Transmit Buffer */ | |
TransmitControl /* Transmit Control Packet */ | |
} BufferType; | |
typedef struct buffer { | |
QH hdr; /* queue linkage */ | |
BufferType type; /* 0 = Receive Buffer, 1 = Transmit Buffer */ | |
uint32 address; /* unibus address of the buffer (or 0 for DDCMP control messages) */ | |
uint16 count; /* size of the buffer passed to the device by the driver */ | |
uint8 *transfer_buffer; /* the buffer into which data is received or from which it is transmitted*/ | |
int actual_bytes_transferred;/* the number of bytes from the actual block that have been read or written */ | |
uint32 buffer_return_time;/* time to return buffer to host */ | |
} BUFFER; | |
typedef enum { | |
Halt, /* initially */ | |
IStart, /* Initiating Start */ | |
AStart, /* Acknowledging Start */ | |
Run, /* Start ACK received */ | |
Maintenance,/* off-line maintenance messages */ | |
All /* Not settable, but match for any state in state table */ | |
} DDCMP_LinkState; | |
typedef struct { | |
uint8 R; /* number of the highest sequential data message received . | |
Sent in the RESP field of data messages, ACK messages, | |
and NAK messages as acknowledgment to the other station. */ | |
uint8 N; /* Number of the highest sequential data message | |
transmitted. Sent in the NUM field of REP | |
messages. N is the number assigned to the last | |
user transmit request which has been transmitted | |
(sent in the NUM field of that data message).*/ | |
uint8 A; /* Number of the highest sequential data message acknowledged. | |
Received in the RESP field of data messages, ACK messages, | |
and NAK messages.*/ | |
uint8 T; /* Number of the next data message to be transmitted. | |
When sending new data messages T will have the | |
value N+l. When retransmitting T will be set back | |
to A+l and will advance to N+l.*/ | |
uint8 X; /* Number of the last data message that has been | |
transmitted. When a new data message has been | |
completely transmitted X will have the value N. | |
When retransmitting and receiving acknowledgments | |
asynchronously with respect to transmission, X will | |
have some value less than or equal to N. */ | |
uint8 NAKed; /* The value of R sent in the most recent NAK message. This | |
is used to avoid sending additional NAKs when one has already | |
been sent while the remaining packets in the transmit pipeline | |
are still arriving. */ | |
t_bool SACK; /* Send ACK flag. This flag is set when either R | |
is incremented, meaning a new sequential data | |
message has been received which requires an ACK | |
reply, or a REP message is received which requires | |
an ACK reply. The SACK flag is cleared when | |
sending either a DATA message with the latest RESP | |
field information, an ACK with the latest RESP | |
field information, or when the SNAK flag is set. */ | |
/* | |
The SACK and SNAK flags are mutually exclusive. At most one | |
will be set at a given time. The events that set the SACK | |
flag, R is increment~d or a REP is received requiring an ACK, | |
also clear the SNAK flag. Similarly, the events that set the | |
SNAK flag, reasons for send ing a NAK (see 5.3.7), also clear | |
the SACK flag. Setting or clearing a flag that is already set | |
or cleared respectively has no effect. For the SNAK flag, a | |
reason variable (or field) is also maintained which is | |
overwritten with the latest NAK error reason. | |
Whenever the SNAK flag is set the NAK reason variable is set | |
to the reason for the NAK. */ | |
t_bool SNAK; /* Send NAK flag. This flag is set when a receive | |
error occurs that requires a NAK reply. It is | |
cleared when a NAK message is sent with the | |
latest RESP information, or when the SACK flag | |
is set.*/ | |
t_bool SREP; /* Send REP flag. This flag is set when a reply | |
timer expires in the running state and a REP | |
should be sent. It is independent of the SACK | |
and SNAK flags.*/ | |
uint8 *rcv_pkt; /* Current Rcvd Packet buffer */ | |
uint16 rcv_pkt_size; /* Current Rcvd Packet size */ | |
BUFFER *xmt_buffer; /* Current Transmit Buffer */ | |
BUFFER *xmt_done_buffer;/* Just Completed Transmit Buffer */ | |
uint8 nak_reason; /* */ | |
uint8 nak_crc_reason; /* CRC status for current received packet */ | |
DDCMP_LinkState state; /* Current State */ | |
t_bool TimerRunning; /* Timer Running Flag */ | |
t_bool TimeRemaining; /* Seconds remaining before timeout (when timer running) */ | |
t_bool Scanning; /* Event Scanning in progress */ | |
uint32 ScanningEvents; /* Event Mask while scanning */ | |
t_bool RecurseScan; /* Scan was attempted while scanning */ | |
uint32 RecurseEventMask;/* Mask for recursive Scan */ | |
#define DDCMP_EVENT_XMIT_DONE 0x001 | |
#define DDCMP_EVENT_PKT_RCVD 0x002 | |
#define DDCMP_EVENT_TIMER 0x004 | |
#define DDCMP_EVENT_MAINTMODE 0x008 | |
} DDCMP; | |
typedef struct control { | |
struct control *next; /* Link */ | |
uint16 sel6; /* Control Out Status Flags */ | |
} CONTROL_OUT; | |
typedef enum { | |
DMC, | |
DMR, | |
DMP | |
} DEVTYPE; | |
typedef struct dmc_controller { | |
CSRS *csrs; | |
DEVICE *device; | |
UNIT *unit; | |
int index; /* Index in controller array */ | |
ControllerState state; | |
TransferState transfer_state; /* current transfer state (type of transfer) */ | |
DDCMP link; | |
int transfer_type; /* Input Command setting at start of input transfer as host changes it during transfer! */ | |
TMLN *line; | |
BUFFER_QUEUE *rcv_queue; /* Receive Buffer Queue */ | |
BUFFER_QUEUE *completion_queue; /* Transmit and Recieve Buffers waiting to pass to driver */ | |
BUFFER_QUEUE *xmt_queue; /* Control and/or Data packets pending transmission */ | |
BUFFER_QUEUE *ack_wait_queue; /* Data packets awaiting acknowledgement */ | |
BUFFER_QUEUE *free_queue; /* Unused Buffer Queue */ | |
BUFFER **buffers; /* Buffers */ | |
CONTROL_OUT *control_out; | |
DEVTYPE dev_type; | |
uint32 in_int; | |
uint32 out_int; | |
uint32 dmc_wr_delay; | |
uint32 *baseaddr; | |
uint16 *basesize; | |
uint8 *modem; | |
int32 *corruption_factor; | |
uint32 buffers_received_from_net; | |
uint32 buffers_transmitted_to_net; | |
uint32 receive_buffer_output_transfers_completed; | |
uint32 transmit_buffer_output_transfers_completed; | |
uint32 receive_buffer_input_transfers_completed; | |
uint32 transmit_buffer_input_transfers_completed; | |
uint32 control_out_operations_completed; | |
uint32 ddcmp_control_packets_received; | |
uint32 ddcmp_control_packets_sent; | |
uint32 byte_wait; /* rcv/xmt byte delay */ | |
} CTLR; | |
/* | |
DDCMP implementation follows the DDCMP protocol specification documented in the | |
"DECNET DIGITAL NETWORK ARCHITECTURE Digital Data Communications Message Protocol" | |
Version 4.0, March 1, 1978. | |
available on http://bitsavers.org/pdf/dec/decnet/AA-D599A-TC_DDCMP4.0_Mar78.pdf | |
*/ | |
typedef void (*DDCMP_LinkAction_Routine)(CTLR *controller); | |
typedef t_bool (*DDCMP_Condition_Routine)(CTLR *controller); | |
t_bool ddcmp_UserHalt (CTLR *controller); | |
t_bool ddcmp_UserStartup (CTLR *controller); | |
t_bool ddcmp_UserMaintenanceMode (CTLR *controller); | |
t_bool ddcmp_ReceiveStack (CTLR *controller); | |
t_bool ddcmp_ReceiveStrt (CTLR *controller); | |
t_bool ddcmp_TimerRunning (CTLR *controller); | |
t_bool ddcmp_TimerNotRunning (CTLR *controller); | |
t_bool ddcmp_TimerExpired (CTLR *controller); | |
t_bool ddcmp_ReceiveMaintMessage (CTLR *controller); | |
t_bool ddcmp_ReceiveAck (CTLR *controller); | |
t_bool ddcmp_ReceiveNak (CTLR *controller); | |
t_bool ddcmp_ReceiveRep (CTLR *controller); | |
t_bool ddcmp_NUMEqRplus1 (CTLR *controller); /* (NUM == R+1) */ | |
t_bool ddcmp_NUMGtRplus1 (CTLR *controller); /* (NUM > R+1) */ | |
t_bool ddcmp_ReceiveDataMsg (CTLR *controller); /* Receive Data Message */ | |
t_bool ddcmp_ReceiveMaintMsg (CTLR *controller); /* Receive Maintenance Message */ | |
t_bool ddcmp_ALtRESPleN (CTLR *controller); /* (A < RESP <= N) */ | |
t_bool ddcmp_ALeRESPleN (CTLR *controller); /* (A <= RESP <= N) */ | |
t_bool ddcmp_RESPleAOrRESPgtN (CTLR *controller); /* (RESP <= A) OR (RESP > N) */ | |
t_bool ddcmp_TltNplus1 (CTLR *controller); /* T < N + 1 */ | |
t_bool ddcmp_TeqNplus1 (CTLR *controller); /* T == N + 1 */ | |
t_bool ddcmp_ReceiveMessageError (CTLR *controller); | |
t_bool ddcmp_NumEqR (CTLR *controller); /* (NUM == R) */ | |
t_bool ddcmp_NumNeR (CTLR *controller); /* (NUM != R) */ | |
t_bool ddcmp_TransmitterIdle (CTLR *controller); | |
t_bool ddcmp_TramsmitterBusy (CTLR *controller); | |
t_bool ddcmp_SACKisSet (CTLR *controller); | |
t_bool ddcmp_SACKisClear (CTLR *controller); | |
t_bool ddcmp_SNAKisSet (CTLR *controller); | |
t_bool ddcmp_SNAKisClear (CTLR *controller); | |
t_bool ddcmp_SREPisSet (CTLR *controller); | |
t_bool ddcmp_SREPisClear (CTLR *controller); | |
t_bool ddcmp_UserSendMessage (CTLR *controller); | |
t_bool ddcmp_LineConnected (CTLR *controller); | |
t_bool ddcmp_LineDisconnected (CTLR *controller); | |
t_bool ddcmp_DataMessageSent (CTLR *controller); | |
t_bool ddcmp_REPMessageSent (CTLR *controller); | |
void ddcmp_StartTimer (CTLR *controller); | |
void ddcmp_StopTimer (CTLR *controller); | |
void ddcmp_ResetVariables (CTLR *controller); | |
void ddcmp_SendStrt (CTLR *controller); | |
void ddcmp_SendStack (CTLR *controller); | |
void ddcmp_SendAck (CTLR *controller); | |
void ddcmp_SendNak (CTLR *controller); | |
void ddcmp_SendRep (CTLR *controller); | |
void ddcmp_SetSACK (CTLR *controller); | |
void ddcmp_ClearSACK (CTLR *controller); | |
void ddcmp_SetSNAK (CTLR *controller); | |
void ddcmp_ClearSNAK (CTLR *controller); | |
void ddcmp_SetSREP (CTLR *controller); | |
void ddcmp_ClearSREP (CTLR *controller); | |
void ddcmp_IncrementR (CTLR *controller); | |
void ddcmp_SetAeqRESP (CTLR *controller); | |
void ddcmp_SetTequalAplus1 (CTLR *controller); | |
void ddcmp_IncrementT (CTLR *controller); | |
void ddcmp_SetNAKreason3 (CTLR *controller); | |
void ddcmp_SetNAKReasonCRCError (CTLR *controller); | |
void ddcmp_NAKMissingPacket (CTLR *controller); | |
void ddcmp_IfTleAthenSetTeqAplus1 (CTLR *controller); | |
void ddcmp_IfAltXthenStartTimer (CTLR *controller); | |
void ddcmp_IfAgeXthenStopTimer (CTLR *controller); | |
void ddcmp_Ignore (CTLR *controller); | |
void ddcmp_GiveBufferToUser (CTLR *controller); | |
void ddcmp_CompleteAckedTransmits (CTLR *controller); | |
void ddcmp_ReTransmitMessageT (CTLR *controller); | |
void ddcmp_NotifyDisconnect (CTLR *controller); | |
void ddcmp_NotifyStartRcvd (CTLR *controller); | |
void ddcmp_NotifyMaintRcvd (CTLR *controller); | |
void ddcmp_SendDataMessage (CTLR *controller); | |
void ddcmp_SendMaintMessage (CTLR *controller); | |
void ddcmp_SetXSetNUM (CTLR *controller); | |
typedef struct _ddcmp_state_table { | |
int RuleNumber; | |
DDCMP_LinkState State; | |
DDCMP_Condition_Routine Conditions[10]; | |
DDCMP_LinkState NewState; | |
DDCMP_LinkAction_Routine Actions[10]; | |
} DDCMP_STATETABLE; | |
DDCMP_STATETABLE DDCMP_TABLE[] = { | |
{ 0, All, {ddcmp_UserHalt}, Halt, {ddcmp_StopTimer}}, | |
{ 1, Halt, {ddcmp_UserStartup, | |
ddcmp_LineConnected}, IStart, {ddcmp_ResetVariables, | |
ddcmp_SendStrt, | |
ddcmp_StopTimer}}, | |
{ 2, Halt, {ddcmp_UserMaintenanceMode}, Maintenance, {ddcmp_ResetVariables}}, | |
{ 3, Halt, {ddcmp_ReceiveMaintMsg}, Maintenance, {ddcmp_ResetVariables, | |
ddcmp_NotifyMaintRcvd}}, | |
{ 4, IStart, {ddcmp_TimerNotRunning}, IStart, {ddcmp_StartTimer}}, | |
{ 5, IStart, {ddcmp_ReceiveStack}, Run, {ddcmp_SetSACK, | |
ddcmp_StopTimer}}, | |
{ 6, IStart, {ddcmp_ReceiveStrt}, AStart, {ddcmp_SendStack, | |
ddcmp_StartTimer}}, | |
{ 7, IStart, {ddcmp_TimerExpired}, IStart, {ddcmp_ResetVariables, | |
ddcmp_SendStrt, | |
ddcmp_StartTimer}}, | |
{ 8, IStart, {ddcmp_ReceiveMaintMsg}, Maintenance, {ddcmp_ResetVariables, | |
ddcmp_NotifyMaintRcvd}}, | |
{ 9, IStart, {ddcmp_ReceiveMessageError}, IStart, {ddcmp_Ignore}}, | |
{10, IStart, {ddcmp_UserSendMessage, | |
ddcmp_TimerNotRunning}, IStart, {ddcmp_StartTimer}}, | |
{11, IStart, {ddcmp_LineDisconnected}, Halt, {ddcmp_StopTimer}}, | |
{12, AStart, {ddcmp_LineDisconnected}, Halt, {ddcmp_StopTimer}}, | |
{13, AStart, {ddcmp_ReceiveAck}, Run, {ddcmp_StopTimer}}, | |
{14, AStart, {ddcmp_ReceiveDataMsg}, Run, {ddcmp_StopTimer}}, | |
{15, AStart, {ddcmp_ReceiveStack}, Run, {ddcmp_SetSACK, | |
ddcmp_StopTimer}}, | |
{16, AStart, {ddcmp_TimerExpired}, AStart, {ddcmp_SendStack, | |
ddcmp_StartTimer}}, | |
{17, AStart, {ddcmp_ReceiveMaintMsg}, Maintenance, {ddcmp_ResetVariables, | |
ddcmp_NotifyMaintRcvd}}, | |
{18, AStart, {ddcmp_ReceiveMessageError}, AStart, {ddcmp_Ignore}}, | |
{19, Run, {ddcmp_LineDisconnected}, Halt, {ddcmp_StopTimer, | |
ddcmp_NotifyDisconnect, | |
ddcmp_NotifyStartRcvd}}, | |
{20, Run, {ddcmp_ReceiveStrt}, Halt, {ddcmp_NotifyStartRcvd}}, | |
{21, Run, {ddcmp_ReceiveMaintMsg}, Maintenance, {ddcmp_ResetVariables, | |
ddcmp_NotifyMaintRcvd}}, | |
{22, Run, {ddcmp_ReceiveStack}, Run, {ddcmp_SetSACK}}, | |
{23, Run, {ddcmp_ReceiveDataMsg, | |
ddcmp_NUMGtRplus1}, Run, {ddcmp_NAKMissingPacket}}, | |
{24, Run, {ddcmp_ReceiveDataMsg, | |
ddcmp_NUMEqRplus1}, Run, {ddcmp_GiveBufferToUser}}, | |
{25, Run, {ddcmp_ReceiveMessageError}, Run, {ddcmp_SetSNAK, | |
ddcmp_SetNAKReasonCRCError}}, | |
{26, Run, {ddcmp_ReceiveRep, | |
ddcmp_NumEqR}, Run, {ddcmp_SetSACK}}, | |
{27, Run, {ddcmp_ReceiveRep, | |
ddcmp_NumNeR}, Run, {ddcmp_SetSNAK, | |
ddcmp_SetNAKreason3}}, | |
{28, Run, {ddcmp_ReceiveDataMsg, | |
ddcmp_ALtRESPleN}, Run, {ddcmp_CompleteAckedTransmits, | |
ddcmp_SetAeqRESP, | |
ddcmp_IfTleAthenSetTeqAplus1, | |
ddcmp_IfAgeXthenStopTimer}}, | |
{29, Run, {ddcmp_ReceiveAck, | |
ddcmp_ALtRESPleN}, Run, {ddcmp_CompleteAckedTransmits, | |
ddcmp_SetAeqRESP, | |
ddcmp_IfTleAthenSetTeqAplus1, | |
ddcmp_IfAgeXthenStopTimer}}, | |
{30, Run, {ddcmp_ReceiveAck, | |
ddcmp_RESPleAOrRESPgtN}, Run, {ddcmp_Ignore}}, | |
{31, Run, {ddcmp_ReceiveDataMsg, | |
ddcmp_RESPleAOrRESPgtN}, Run, {ddcmp_Ignore}}, | |
{32, Run, {ddcmp_ReceiveNak, | |
ddcmp_ALeRESPleN}, Run, {ddcmp_CompleteAckedTransmits, | |
ddcmp_SetAeqRESP, | |
ddcmp_SetTequalAplus1, | |
ddcmp_StopTimer}}, | |
{33, Run, {ddcmp_ReceiveNak, | |
ddcmp_RESPleAOrRESPgtN}, Run, {ddcmp_Ignore}}, | |
{34, Run, {ddcmp_TimerExpired}, Run, {ddcmp_SetSREP}}, | |
{35, Run, {ddcmp_TransmitterIdle, | |
ddcmp_SNAKisSet}, Run, {ddcmp_SendNak, | |
ddcmp_ClearSNAK}}, | |
{36, Run, {ddcmp_TransmitterIdle, | |
ddcmp_SNAKisClear, | |
ddcmp_SREPisSet}, Run, {ddcmp_SendRep, | |
ddcmp_ClearSREP}}, | |
{37, Run, {ddcmp_TransmitterIdle, | |
ddcmp_SNAKisClear, | |
ddcmp_SREPisClear, | |
ddcmp_TltNplus1}, Run, {ddcmp_ReTransmitMessageT, | |
ddcmp_IncrementT, | |
ddcmp_ClearSACK}}, | |
{38, Run, {ddcmp_UserSendMessage, | |
ddcmp_TeqNplus1, | |
ddcmp_TransmitterIdle, | |
ddcmp_SNAKisClear, | |
ddcmp_SREPisClear}, Run, {ddcmp_SendDataMessage, | |
ddcmp_ClearSACK}}, | |
{39, Run, {ddcmp_TransmitterIdle, | |
ddcmp_SNAKisClear, | |
ddcmp_SREPisClear, | |
ddcmp_SACKisSet, | |
ddcmp_TeqNplus1}, Run, {ddcmp_SendAck, | |
ddcmp_ClearSACK}}, | |
{40, Run, {ddcmp_DataMessageSent}, Run, {ddcmp_SetXSetNUM, | |
ddcmp_IfAltXthenStartTimer, | |
ddcmp_IfAgeXthenStopTimer}}, | |
{41, Run, {ddcmp_REPMessageSent}, Run, {ddcmp_StartTimer}}, | |
{42, Maintenance, {ddcmp_ReceiveMaintMsg}, Maintenance, {ddcmp_GiveBufferToUser}}, | |
{43, Maintenance, {ddcmp_UserSendMessage, | |
ddcmp_TransmitterIdle}, Maintenance, {ddcmp_SendMaintMessage}}, | |
{44, All} /* End of Table */ | |
}; | |
typedef struct _ddcmp_condition_name { | |
DDCMP_Condition_Routine Condition; | |
const char *Name; | |
} DDCMP_CONDITION_NAME; | |
#define NAME(name) {ddcmp_##name,#name} | |
DDCMP_CONDITION_NAME ddcmp_Condition_Names[] = { | |
NAME(UserHalt), | |
NAME(UserStartup), | |
NAME(UserMaintenanceMode), | |
NAME(ReceiveStack), | |
NAME(ReceiveStrt), | |
NAME(TimerRunning), | |
NAME(TimerNotRunning), | |
NAME(TimerExpired), | |
NAME(ReceiveMaintMessage), | |
NAME(ReceiveAck), | |
NAME(ReceiveNak), | |
NAME(ReceiveRep), | |
NAME(NUMEqRplus1), | |
NAME(NUMGtRplus1), | |
NAME(ReceiveDataMsg), | |
NAME(ReceiveMaintMsg), | |
NAME(ALtRESPleN), | |
NAME(ALeRESPleN), | |
NAME(RESPleAOrRESPgtN), | |
NAME(TltNplus1), | |
NAME(TeqNplus1), | |
NAME(ReceiveMessageError), | |
NAME(NumEqR), | |
NAME(NumNeR), | |
NAME(TransmitterIdle), | |
NAME(TramsmitterBusy), | |
NAME(SACKisSet), | |
NAME(SACKisClear), | |
NAME(SNAKisSet), | |
NAME(SNAKisClear), | |
NAME(SREPisSet), | |
NAME(SREPisClear), | |
NAME(UserSendMessage), | |
NAME(LineConnected), | |
NAME(LineDisconnected), | |
NAME(DataMessageSent), | |
NAME(REPMessageSent), | |
{NULL, NULL} | |
}; | |
char *ddcmp_conditions(DDCMP_Condition_Routine *Conditions) | |
{ | |
static char buf[512]; | |
DDCMP_CONDITION_NAME *Name; | |
buf[0] = '\0'; | |
while (*Conditions) | |
{ | |
for (Name = ddcmp_Condition_Names; Name->Condition != NULL; ++Name) { | |
if (Name->Condition == *Conditions) | |
break; | |
} | |
++Conditions; | |
if (Name->Name) | |
sprintf (&buf[strlen(buf)], "%s%s", Name->Name, *Conditions ? " && " : ""); | |
} | |
return buf; | |
} | |
typedef struct _ddcmp_action_name { | |
DDCMP_LinkAction_Routine Action; | |
const char *Name; | |
} DDCMP_ACTION_NAME; | |
DDCMP_ACTION_NAME ddcmp_Actions[] = { | |
NAME(StartTimer), | |
NAME(StopTimer), | |
NAME(ResetVariables), | |
NAME(SendStrt), | |
NAME(SendStack), | |
NAME(SendAck), | |
NAME(SendNak), | |
NAME(SendRep), | |
NAME(SetSACK), | |
NAME(ClearSACK), | |
NAME(SetSNAK), | |
NAME(ClearSNAK), | |
NAME(SetSREP), | |
NAME(ClearSREP), | |
NAME(IncrementR), | |
NAME(SetAeqRESP), | |
NAME(SetTequalAplus1), | |
NAME(IncrementT), | |
NAME(SetNAKreason3), | |
NAME(SetNAKReasonCRCError), | |
NAME(NAKMissingPacket), | |
NAME(IfTleAthenSetTeqAplus1), | |
NAME(IfAltXthenStartTimer), | |
NAME(IfAgeXthenStopTimer), | |
NAME(Ignore), | |
NAME(GiveBufferToUser), | |
NAME(CompleteAckedTransmits), | |
NAME(ReTransmitMessageT), | |
NAME(NotifyDisconnect), | |
NAME(NotifyStartRcvd), | |
NAME(NotifyMaintRcvd), | |
NAME(SendDataMessage), | |
NAME(SendMaintMessage), | |
NAME(SetXSetNUM), | |
{NULL, NULL} | |
}; | |
char *ddcmp_actions(DDCMP_LinkAction_Routine *Actions) | |
{ | |
static char buf[512]; | |
DDCMP_ACTION_NAME *Name; | |
buf[0] = '\0'; | |
while (*Actions) | |
{ | |
for (Name = ddcmp_Actions; Name->Action != NULL; ++Name) { | |
if (Name->Action == *Actions) | |
break; | |
} | |
++Actions; | |
if (Name->Name) | |
sprintf (&buf[strlen(buf)], "%s%s", Name->Name, *Actions ? " + " : ""); | |
} | |
return buf; | |
} | |
char *ddcmp_link_state(DDCMP *link) | |
{ | |
static char buf[512]; | |
sprintf (buf, "(R:%d,N:%d,A:%d,T:%d,X:%d,SACK:%d,SNAK:%d,SREP:%d,NAKed:%d)", link->R, link->N, link->A, link->T, link->X, link->SACK, link->SNAK, link->SREP, link->NAKed); | |
return buf; | |
} | |
char *controller_queue_state(CTLR *controller) | |
{ | |
static char buf[512]; | |
sprintf (buf, "(ACKW:%d,XMT:%d,RCV:%d,CMPL:%d,FREE:%d) TOT:%d", | |
(int)controller->ack_wait_queue->count, | |
(int)controller->xmt_queue->count, | |
(int)controller->rcv_queue->count, | |
(int)controller->completion_queue->count, | |
(int)controller->free_queue->count, | |
(int)controller->ack_wait_queue->count+ | |
(int)controller->xmt_queue->count+ | |
(int)controller->rcv_queue->count+ | |
(int)controller->completion_queue->count+ | |
(int)controller->free_queue->count); | |
return buf; | |
} | |
DDCMP_LinkState NewState; | |
DDCMP_LinkAction_Routine Actions[10]; | |
#define ctlr up7 /* Unit back pointer to controller */ | |
void ddcmp_dispatch (CTLR *controller, uint32 EventMask); | |
t_stat dmc_rd (int32* data, int32 PA, int32 access); | |
t_stat dmc_wr (int32 data, int32 PA, int32 access); | |
t_stat dmc_svc (UNIT * uptr); | |
t_stat dmc_poll_svc (UNIT * uptr); | |
t_stat dmc_timer_svc (UNIT * uptr); | |
t_stat dmc_reset (DEVICE * dptr); | |
t_stat dmc_attach (UNIT * uptr, char * cptr); | |
t_stat dmc_detach (UNIT * uptr); | |
int32 dmc_ininta (void); | |
int32 dmc_outinta (void); | |
t_stat dmc_setnumdevices (UNIT *uptr, int32 val, char *cptr, void *desc); | |
t_stat dmc_shownumdevices (FILE *st, UNIT *uptr, int32 val, void *desc); | |
t_stat dmc_setpeer (UNIT* uptr, int32 val, char* cptr, void* desc); | |
t_stat dmc_showpeer (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_setspeed (UNIT* uptr, int32 val, char* cptr, void* desc); | |
t_stat dmc_showspeed (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_setcorrupt (UNIT *uptr, int32 val, char *cptr, void *desc); | |
t_stat dmc_showcorrupt (FILE *st, UNIT *uptr, int32 val, void *desc); | |
t_stat dmc_set_microdiag (UNIT* uptr, int32 val, char* cptr, void* desc); | |
t_stat dmc_show_microdiag (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_settype (UNIT* uptr, int32 val, char* cptr, void* desc); | |
t_stat dmc_showtype (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_setstats (UNIT* uptr, int32 val, char* cptr, void* desc); | |
t_stat dmc_showstats (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_showqueues (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_setconnectpoll (UNIT* uptr, int32 val, char* cptr, void* desc); | |
t_stat dmc_showconnectpoll (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_showddcmp (FILE* st, UNIT* uptr, int32 val, void* desc); | |
t_stat dmc_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, char *cptr); | |
t_stat dmc_help_attach (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, char *cptr); | |
char *dmc_description (DEVICE *dptr); | |
char *dmp_description (DEVICE *dptr); | |
int dmc_is_attached (UNIT* uptr); | |
int dmc_is_dmc (CTLR *controller); | |
int dmc_is_rqi_set (CTLR *controller); | |
int dmc_is_rdyi_set (CTLR *controller); | |
int dmc_is_iei_set (CTLR *controller); | |
int dmc_is_ieo_set (CTLR *controller); | |
uint32 dmc_get_addr (CTLR *controller); | |
void dmc_set_addr (CTLR *controller, uint32 addr); | |
uint16 dmc_get_count (CTLR *controller); | |
void dmc_set_count (CTLR *controller, uint16 count); | |
uint8 dmc_get_modem (CTLR *controller); | |
void dmc_set_modem_dtr (CTLR *controller); | |
void dmc_clr_modem_dtr (CTLR *controller); | |
void dmc_process_command (CTLR *controller); | |
t_bool dmc_buffer_fill_receive_buffers (CTLR *controller); | |
void dmc_start_transfer_buffer (CTLR *controller); | |
void dmc_buffer_queue_init (CTLR *controller, BUFFER_QUEUE *q, char *name, size_t size, BUFFER *buffers); | |
void dmc_buffer_queue_init_all (CTLR *controller); | |
BUFFER *dmc_buffer_queue_head (BUFFER_QUEUE *q); | |
BUFFER *dmc_buffer_allocate (CTLR *controller); | |
t_bool dmc_transmit_queue_empty (CTLR *controller); | |
void dmc_ddcmp_start_transmitter (CTLR *controller); | |
void dmc_queue_control_out (CTLR *controller, uint16 sel6); | |
/* debugging bitmaps */ | |
#define DBG_TRC 0x0001 /* trace routine calls */ | |
#define DBG_REG 0x0002 /* trace programatic read/write registers */ | |
#define DBG_RGC 0x0004 /* internal read/write registers changes */ | |
#define DBG_WRN 0x0008 /* display warnings */ | |
#define DBG_INF 0x0010 /* display informational messages (high level trace) */ | |
#define DBG_DTS (DDCMP_DBG_PXMT|DDCMP_DBG_PRCV) /* display data summary */ | |
#define DBG_DAT (DBG_DTS|DDCMP_DBG_PDAT) /* display data buffer contents */ | |
#define DBG_MDM 0x0040 /* modem related transitions */ | |
#define DBG_CON TMXR_DBG_CON /* display socket open/close, connection establishment */ | |
#define DBG_INT 0x0080 /* display interrupt activites */ | |
DEBTAB dmc_debug[] = { | |
{"TRACE", DBG_TRC}, | |
{"WARN", DBG_WRN}, | |
{"REG", DBG_REG}, | |
{"INTREG", DBG_RGC}, | |
{"INFO", DBG_INF}, | |
{"DATA", DBG_DAT}, | |
{"DATASUM", DBG_DTS}, | |
{"MODEM", DBG_MDM}, | |
{"CONNECT", DBG_CON}, | |
{"INT", DBG_INT}, | |
{0} | |
}; | |
UNIT dmc_units[DMC_NUMDEVICE+2]; /* One per device plus an I/O polling unit and a timing unit */ | |
UNIT dmc_unit_template = { UDATA (&dmc_svc, UNIT_ATTABLE|UNIT_IDLE, 0) }; | |
UNIT dmc_poll_unit_template = { UDATA (&dmc_poll_svc, UNIT_DIS|UNIT_IDLE, 0) }; | |
UNIT dmc_timer_unit_template = { UDATA (&dmc_timer_svc, UNIT_DIS|UNIT_IDLE, 0) }; | |
UNIT dmp_units[DMP_NUMDEVICE+2]; /* One per device plus an I/O polling unit and a timing unit */ | |
CSRS dmc_csrs[DMC_NUMDEVICE]; | |
uint16 dmc_sel0[DMC_NUMDEVICE]; | |
uint16 dmc_sel2[DMC_NUMDEVICE]; | |
uint16 dmc_sel4[DMC_NUMDEVICE]; | |
uint16 dmc_sel6[DMC_NUMDEVICE]; | |
uint32 dmc_speed[DMC_NUMDEVICE]; | |
char dmc_peer[DMC_NUMDEVICE][CBUFSIZE]; | |
char dmc_port[DMC_NUMDEVICE][CBUFSIZE]; | |
uint32 dmc_baseaddr[DMC_NUMDEVICE]; | |
uint16 dmc_basesize[DMC_NUMDEVICE]; | |
uint8 dmc_modem[DMC_NUMDEVICE]; | |
t_bool dmc_microdiag[DMC_NUMDEVICE]; | |
int32 dmc_corruption[DMC_NUMDEVICE]; | |
CSRS dmp_csrs[DMP_NUMDEVICE]; | |
uint16 dmp_sel0[DMC_NUMDEVICE]; | |
uint16 dmp_sel2[DMC_NUMDEVICE]; | |
uint16 dmp_sel4[DMC_NUMDEVICE]; | |
uint16 dmp_sel6[DMC_NUMDEVICE]; | |
uint16 dmp_sel10[DMC_NUMDEVICE]; | |
uint32 dmp_speed[DMP_NUMDEVICE]; | |
char dmp_peer[DMP_NUMDEVICE][CBUFSIZE]; | |
char dmp_port[DMP_NUMDEVICE][CBUFSIZE]; | |
uint32 dmp_baseaddr[DMP_NUMDEVICE]; | |
uint16 dmp_basesize[DMP_NUMDEVICE]; | |
uint8 dmp_modem[DMP_NUMDEVICE]; | |
int32 dmp_corruption[DMC_NUMDEVICE]; | |
TMLN dmc_ldsc[DMC_NUMDEVICE]; /* line descriptors */ | |
TMXR dmc_desc = { 1, NULL, 0, dmc_ldsc }; /* mux descriptor */ | |
uint32 dmc_connect_poll = DMC_CONNECT_POLL; /* seconds between polls when no connection */ | |
uint32 dmc_ini_summary = 0; /* In Command Interrupt Summary for all controllers */ | |
uint32 dmc_outi_summary = 0; /* Out Command Interrupt Summary for all controllers */ | |
BUFFER_QUEUE dmc_rcv_queues[DMC_NUMDEVICE]; | |
BUFFER_QUEUE dmc_completion_queues[DMC_NUMDEVICE]; | |
BUFFER_QUEUE dmc_xmt_queues[DMC_NUMDEVICE]; | |
BUFFER_QUEUE dmc_ack_wait_queues[DMC_NUMDEVICE]; | |
BUFFER_QUEUE dmc_free_queues[DMC_NUMDEVICE]; | |
BUFFER *dmc_buffers[DMC_NUMDEVICE]; | |
TMLN dmp_ldsc[DMC_NUMDEVICE]; /* line descriptors */ | |
TMXR dmp_desc = { 1, NULL, 0, dmp_ldsc }; /* mux descriptor */ | |
uint32 dmp_connect_poll; /* seconds between polls when no connection */ | |
BUFFER_QUEUE dmp_rcv_queues[DMP_NUMDEVICE]; | |
BUFFER_QUEUE dmp_completion_queues[DMP_NUMDEVICE]; | |
BUFFER_QUEUE dmp_xmt_queues[DMP_NUMDEVICE]; | |
BUFFER_QUEUE dmp_ack_wait_queues[DMP_NUMDEVICE]; | |
BUFFER_QUEUE dmp_free_queues[DMP_NUMDEVICE]; | |
BUFFER *dmp_buffers[DMC_NUMDEVICE]; | |
REG dmc_reg[] = { | |
{ GRDATAD (RXINT, dmc_ini_summary, DEV_RDX, 32, 0, "input interrupt summary") }, | |
{ GRDATAD (TXINT, dmc_outi_summary, DEV_RDX, 32, 0, "output interrupt summary") }, | |
{ GRDATAD (POLL, dmc_connect_poll, DEV_RDX, 32, 0, "connect poll interval") }, | |
{ BRDATAD (SEL0, dmc_sel0, DEV_RDX, 16, DMC_NUMDEVICE, "Select 0 CSR") }, | |
{ BRDATAD (SEL2, dmc_sel2, DEV_RDX, 16, DMC_NUMDEVICE, "Select 2 CSR") }, | |
{ BRDATAD (SEL4, dmc_sel4, DEV_RDX, 16, DMC_NUMDEVICE, "Select 4 CSR") }, | |
{ BRDATAD (SEL6, dmc_sel6, DEV_RDX, 16, DMC_NUMDEVICE, "Select 6 CSR") }, | |
{ BRDATAD (SPEED, dmc_speed, DEV_RDX, 32, DMC_NUMDEVICE, "line speed") }, | |
{ BRDATAD (CORRUPT, dmc_corruption, DEV_RDX, 32, DMC_NUMDEVICE, "data corruption factor (0.1%)") }, | |
{ BRDATAD (DIAG, dmc_microdiag, DEV_RDX, 1, DMC_NUMDEVICE, "Microdiagnostic Enabled") }, | |
{ BRDATAD (PEER, dmc_peer, DEV_RDX, 8, DMC_NUMDEVICE*CBUFSIZE, "peer address:port") }, | |
{ BRDATAD (PORT, dmc_port, DEV_RDX, 8, DMC_NUMDEVICE*CBUFSIZE, "listen port") }, | |
{ BRDATAD (BASEADDR, dmc_baseaddr, DEV_RDX, 32, DMC_NUMDEVICE, "program set base address") }, | |
{ BRDATAD (BASESIZE, dmc_basesize, DEV_RDX, 16, DMC_NUMDEVICE, "program set base size") }, | |
{ BRDATAD (MODEM, dmc_modem, DEV_RDX, 8, DMC_NUMDEVICE, "modem control bits") }, | |
{ NULL } }; | |
REG dmp_reg[] = { | |
{ GRDATAD (RXINT, dmc_ini_summary, DEV_RDX, 32, 0, "input interrupt summary") }, | |
{ GRDATAD (TXINT, dmc_outi_summary, DEV_RDX, 32, 0, "output interrupt summary") }, | |
{ GRDATAD (POLL, dmp_connect_poll, DEV_RDX, 32, 0, "connect poll interval") }, | |
{ BRDATAD (SEL0, dmp_sel0, DEV_RDX, 16, DMC_NUMDEVICE, "Select 0 CSR") }, | |
{ BRDATAD (SEL2, dmp_sel2, DEV_RDX, 16, DMC_NUMDEVICE, "Select 2 CSR") }, | |
{ BRDATAD (SEL4, dmp_sel4, DEV_RDX, 16, DMC_NUMDEVICE, "Select 4 CSR") }, | |
{ BRDATAD (SEL6, dmp_sel6, DEV_RDX, 16, DMC_NUMDEVICE, "Select 6 CSR") }, | |
{ BRDATAD (SEL10, dmp_sel10, DEV_RDX, 16, DMP_NUMDEVICE, "Select 10 CSR") }, | |
{ BRDATAD (SPEED, dmp_speed, DEV_RDX, 32, DMC_NUMDEVICE, "line speed") }, | |
{ BRDATAD (CORRUPT, dmp_corruption, DEV_RDX, 32, DMC_NUMDEVICE, "data corruption factor (0.1%)") }, | |
{ BRDATAD (PEER, dmp_peer, DEV_RDX, 8, DMC_NUMDEVICE*CBUFSIZE, "peer address:port") }, | |
{ BRDATAD (PORT, dmp_port, DEV_RDX, 8, DMC_NUMDEVICE*CBUFSIZE, "listen port") }, | |
{ BRDATAD (BASEADDR, dmp_baseaddr, DEV_RDX, 32, DMC_NUMDEVICE, "program set base address") }, | |
{ BRDATAD (BASESIZE, dmp_basesize, DEV_RDX, 16, DMC_NUMDEVICE, "program set base size") }, | |
{ BRDATAD (MODEM, dmp_modem, DEV_RDX, 8, DMP_NUMDEVICE, "modem control bits") }, | |
{ NULL } }; | |
extern DEVICE dmc_dev; | |
MTAB dmc_mod[] = { | |
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 0, "LINES", "LINES=n", | |
&dmc_setnumdevices, &dmc_shownumdevices, (void *) &dmc_dev, "Display number of devices" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "PEER", "PEER=address:port", | |
&dmc_setpeer, &dmc_showpeer, NULL, "Display destination/source" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "SPEED", "SPEED=bits/sec (0=unrestricted)" , | |
&dmc_setspeed, &dmc_showspeed, NULL, "Display rate limit" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "MICRODIAG", "MICRODIAG={ENABLE,DISABLE}" , | |
&dmc_set_microdiag, &dmc_show_microdiag, NULL, "MicroDiagnostic Enable" }, | |
#if !defined (VM_PDP10) | |
{ MTAB_XTD|MTAB_VUN|MTAB_VALR,0, "TYPE", "TYPE={DMR,DMC}" ,&dmc_settype, &dmc_showtype, NULL, "Set/Display device type" }, | |
#endif | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "STATS", "STATS", | |
&dmc_setstats, &dmc_showstats, NULL, "Display/Clear statistics" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "QUEUES", "QUEUES", | |
NULL, &dmc_showqueues, NULL, "Display Queue state" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "DDCMP", "DDCMP", | |
NULL, &dmc_showddcmp, NULL, "Display DDCMP state information" }, | |
{ MTAB_XTD|MTAB_VDV, 0, "CONNECTPOLL", "CONNECTPOLL=seconds", | |
&dmc_setconnectpoll, &dmc_showconnectpoll, (void *) &dmc_connect_poll, "Display connection poll interval" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_VALR|MTAB_NMO, 0, "CORRUPT", "CORRUPTION=factor (0=uncorrupted)" , | |
&dmc_setcorrupt, &dmc_showcorrupt, NULL, "Display corruption factor (0.1% of packets)" }, | |
{ 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, NULL, "Interrupt vector" }, | |
{ 0 } }; | |
extern DEVICE dmp_dev; | |
MTAB dmp_mod[] = { | |
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 0, "LINES", "LINES=n", | |
&dmc_setnumdevices, &dmc_shownumdevices, (void *) &dmp_dev, "Display number of devices" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "PEER", "PEER=address:port", | |
&dmc_setpeer, &dmc_showpeer, NULL, "Display destination/source" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "SPEED", "SPEED=bits/sec (0=unrestricted)" , | |
&dmc_setspeed, &dmc_showspeed, NULL, "Display rate limit" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "STATS", "STATS", | |
&dmc_setstats, &dmc_showstats, NULL, "Display/Clear statistics" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "QUEUES", "QUEUES", | |
NULL, &dmc_showqueues, NULL, "Display Queue state" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "DDCMP", "DDCMP", | |
NULL, &dmc_showddcmp, NULL, "Display DDCMP state information" }, | |
{ MTAB_XTD|MTAB_VDV, 0, "CONNECTPOLL", "CONNECTPOLL=seconds", | |
&dmc_setconnectpoll, &dmc_showconnectpoll, (void *) &dmp_connect_poll, "Display connection poll interval" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_VALR|MTAB_NMO, 0, "CORRUPTION", "CORRUPTION=factor (0=uncorrupted)" , | |
&dmc_setcorrupt, &dmc_showcorrupt, NULL, "Display corruption factor (0.1% of packets)" }, | |
{ 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, NULL, "Interrupt vector" }, | |
{ 0 } }; | |
extern DEVICE dmv_dev; | |
MTAB dmv_mod[] = { | |
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 0, "LINES", "LINES=n", | |
&dmc_setnumdevices, &dmc_shownumdevices, (void *) &dmv_dev, "Display number of devices" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "PEER", "PEER=address:port", | |
&dmc_setpeer, &dmc_showpeer, NULL, "Display destination/source" }, | |
{ MTAB_XTD|MTAB_VUN, 0, "SPEED", "SPEED=bits/sec (0=unrestricted)" , | |
&dmc_setspeed, &dmc_showspeed, NULL, "Display rate limit" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "STATS", "STATS", | |
&dmc_setstats, &dmc_showstats, NULL, "Display/Clear statistics" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "QUEUES", "QUEUES", | |
NULL, &dmc_showqueues, NULL, "Display Queue state" }, | |
{ MTAB_XTD|MTAB_VUN|MTAB_NMO, 0, "DDCMP", "DDCMP", | |
NULL, &dmc_showddcmp, NULL, "Display DDCMP state information" }, | |
{ MTAB_XTD|MTAB_VDV, 0, "CONNECTPOLL", "CONNECTPOLL=seconds", | |
&dmc_setconnectpoll, &dmc_showconnectpoll, (void *) &dmp_connect_poll, "Display connection poll interval" }, | |
{ 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, NULL, "Interrupt vector" }, | |
{ 0 } }; | |
#define IOLN_DMC 010 | |
DIB dmc_dib = { IOBA_AUTO, IOLN_DMC, &dmc_rd, &dmc_wr, 2, IVCL (DMCRX), VEC_AUTO, {&dmc_ininta, &dmc_outinta}, IOLN_DMC }; | |
#define IOLN_DMP 010 | |
DIB dmp_dib = { IOBA_AUTO, IOLN_DMP, &dmc_rd, &dmc_wr, 2, IVCL (DMCRX), VEC_AUTO, {&dmc_ininta, &dmc_outinta }, IOLN_DMP}; | |
#define IOLN_DMV 020 | |
DIB dmv_dib = { IOBA_AUTO, IOLN_DMV, &dmc_rd, &dmc_wr, 2, IVCL (DMCRX), VEC_AUTO, {&dmc_ininta, &dmc_outinta }, IOLN_DMV}; | |
DEVICE dmc_dev = | |
{ | |
#if defined (VM_PDP10) | |
"DMR", | |
#else | |
"DMC", | |
#endif | |
dmc_units, dmc_reg, dmc_mod, 3, DMC_RDX, 8, 1, DMC_RDX, 8, | |
NULL, NULL, &dmc_reset, NULL, &dmc_attach, &dmc_detach, | |
&dmc_dib, DEV_DISABLE | DEV_DIS | DEV_UBUS | DEV_DEBUG | DEV_DONTAUTO, 0, dmc_debug, | |
NULL, NULL, &dmc_help, &dmc_help_attach, NULL, &dmc_description }; | |
/* | |
We have two devices defined here (dmp_dev and dmv_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 dmc_reset allows only | |
one of these devices to be enabled at a time. The DMP device is allowed | |
on Unibus systems and the DMV device Qbus systems. | |
This monkey business is necessary due to the fact that although both | |
the DMP and DMV 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. | |
*/ | |
DEVICE dmp_dev = | |
{ "DMP", dmp_units, dmp_reg, dmp_mod, 3, DMC_RDX, 8, 1, DMC_RDX, 8, | |
NULL, NULL, &dmc_reset, NULL, &dmc_attach, &dmc_detach, | |
&dmp_dib, DEV_DISABLE | DEV_DIS | DEV_UBUS | DEV_DEBUG | DEV_DONTAUTO, 0, dmc_debug, | |
NULL, NULL, &dmc_help, &dmc_help_attach, NULL, &dmp_description }; | |
DEVICE dmv_dev = | |
{ "DMV", dmp_units, dmp_reg, dmv_mod, 3, DMC_RDX, 8, 1, DMC_RDX, 8, | |
NULL, NULL, &dmc_reset, NULL, &dmc_attach, &dmc_detach, | |
&dmp_dib, DEV_DISABLE | DEV_DIS | DEV_QBUS | DEV_DEBUG | DEV_DONTAUTO, 0, dmc_debug, | |
NULL, NULL, &dmc_help, &dmc_help_attach, NULL, &dmp_description }; | |
CTLR dmc_ctrls[DMC_NUMDEVICE + DMP_NUMDEVICE]; | |
int dmc_is_attached(UNIT* uptr) | |
{ | |
return uptr->flags & UNIT_ATT; | |
} | |
int dmc_is_dmc(CTLR *controller) | |
{ | |
return controller->dev_type != DMP; | |
} | |
CTLR *dmc_get_controller_from_unit(UNIT *unit) | |
{ | |
return (CTLR *)unit->ctlr; | |
} | |
CTLR* dmc_get_controller_from_address(uint32 address) | |
{ | |
int i; | |
for (i=0; i<DMC_NUMDEVICE + DMP_NUMDEVICE; i++) { | |
DIB *dib = (DIB *)dmc_ctrls[i].device->ctxt; | |
if ((address >= dib->ba) && (address < (dib->ba + dib->lnt))) | |
return &dmc_ctrls[(address - dib->ba) >> ((UNIBUS) ? 3 : 4)]; | |
} | |
/* not found */ | |
return 0; | |
} | |
t_stat dmc_showpeer (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
char *peer = ((dptr == &dmc_dev)? &dmc_peer[dmc][0] : &dmp_peer[dmc][0]); | |
if (peer[0]) | |
fprintf(st, "peer=%s", peer); | |
else | |
fprintf(st, "peer=unspecified"); | |
return SCPE_OK; | |
} | |
t_stat dmc_setpeer (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
char *peer = ((dptr == &dmc_dev)? &dmc_peer[dmc][0] : &dmp_peer[dmc][0]); | |
t_stat status = SCPE_OK; | |
char host[CBUFSIZE], port[CBUFSIZE]; | |
if ((!cptr) || (!*cptr)) | |
return SCPE_ARG; | |
if (dmc_is_attached(uptr)) | |
return SCPE_ALATT; | |
status = sim_parse_addr (cptr, host, sizeof(host), NULL, port, sizeof(port), NULL, NULL); | |
if (status != SCPE_OK) | |
return status; | |
if (host[0] == '\0') | |
return SCPE_ARG; | |
strncpy(peer, cptr, CBUFSIZE-1); | |
return status; | |
} | |
t_stat dmc_showspeed (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
uint32 *speeds = ((dptr == &dmc_dev)? dmc_speed : dmp_speed); | |
if (speeds[dmc] > 0) | |
fprintf(st, "speed=%d bits/sec", speeds[dmc]); | |
else | |
fprintf(st, "speed=0 (unrestricted)"); | |
return SCPE_OK; | |
} | |
t_stat dmc_setspeed (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
uint32 *speeds = ((dptr == &dmc_dev)? dmc_speed : dmp_speed); | |
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; | |
speeds[dmc] = newspeed; | |
return SCPE_OK; | |
} | |
t_stat dmc_show_microdiag (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
int32 dmc = (int32)(uptr-dmc_dev.units); | |
fprintf(st, "MicroDiag=%s", dmc_microdiag[dmc] ? "enabled" : "disabled"); | |
return SCPE_OK; | |
} | |
/* Manage the corruption troll's appetite, in units of milli-gulps. | |
* | |
* See ddcmp_feedCorruptionTroll for usage. | |
*/ | |
t_stat dmc_setcorrupt (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
int32 *hunger = (dptr == &dmc_dev) ? &dmc_corruption[dmc] : &dmp_corruption[dmc]; | |
t_stat r; | |
int32 appetite; | |
if ((cptr == NULL) || (*cptr == '\0')) | |
return SCPE_ARG; | |
appetite = (int32) get_uint (cptr, 10, 999, &r); | |
if (r != SCPE_OK) | |
return r; | |
*hunger = appetite; | |
return SCPE_OK; | |
} | |
/* Display the corruption troll's appetite */ | |
t_stat dmc_showcorrupt (FILE *st, UNIT *uptr, int32 val, void *desc) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
int32 *hunger = (dptr == &dmc_dev) ? &dmc_corruption[dmc] : &dmp_corruption[dmc]; | |
if (*hunger) | |
fprintf(st, "Corruption=%d milligulps (%.1f%% of messages processed)", | |
*hunger, ((double)*hunger)/10.0); | |
else | |
fprintf(st, "No Corruption"); | |
return SCPE_OK; | |
} | |
t_stat dmc_set_microdiag(UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
int32 dmc = (int32)(uptr-dmc_dev.units); | |
char gbuf[CBUFSIZE]; | |
if ((cptr == NULL) || (*cptr == '\0')) | |
return SCPE_ARG; | |
get_glyph (cptr, gbuf, 0); | |
if (MATCH_CMD (gbuf, "ENABLE") == 0) | |
dmc_microdiag[dmc] = TRUE; | |
else | |
if (MATCH_CMD (gbuf, "DISABLE") == 0) | |
dmc_microdiag[dmc] = FALSE; | |
else | |
return SCPE_ARG; | |
return SCPE_OK; | |
} | |
t_stat dmc_showtype (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
CTLR *controller = dmc_get_controller_from_unit(uptr); | |
switch (controller->dev_type) { | |
case DMC: | |
fprintf(st, "type=DMC"); | |
break; | |
case DMR: | |
fprintf(st, "type=DMR"); | |
break; | |
case DMP: | |
fprintf(st, "type=%s", (UNIBUS) ? "DMP" : "DMV"); | |
break; | |
default: | |
fprintf(st, "type=???"); | |
break; | |
} | |
return SCPE_OK; | |
} | |
t_stat dmc_settype (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
char gbuf[80]; | |
t_stat status = SCPE_OK; | |
CTLR *controller = dmc_get_controller_from_unit(uptr); | |
if ((!cptr) || (!*cptr)) | |
return SCPE_2FARG; | |
if (dmc_is_attached(uptr)) | |
return SCPE_ALATT; | |
cptr = get_glyph (cptr, gbuf, 0); | |
if (strcmp (gbuf,"DMC") == 0) | |
controller->dev_type = DMC; | |
else | |
if (strcmp (gbuf,"DMR") == 0) | |
controller->dev_type = DMR; | |
else | |
status = SCPE_ARG; | |
return status; | |
} | |
t_stat dmc_showstats (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
CTLR *controller = dmc_get_controller_from_unit(uptr); | |
fprintf (st, "%s%d\n", controller->device->name, (int)(uptr-controller->device->units)); | |
tmxr_fstats (st, controller->line, -1); | |
fprintf(st, "Buffers received from the network=%d\n", controller->buffers_received_from_net); | |
fprintf(st, "Buffers sent to the network=%d\n", controller->buffers_transmitted_to_net); | |
fprintf(st, "Output transfers completed for receive buffers=%d\n", controller->receive_buffer_output_transfers_completed); | |
fprintf(st, "Output transfers completed for transmit buffers=%d\n", controller->transmit_buffer_output_transfers_completed); | |
fprintf(st, "Input transfers completed for receive buffers=%d\n", controller->receive_buffer_input_transfers_completed); | |
fprintf(st, "Input transfers completed for transmit buffers=%d\n", controller->transmit_buffer_input_transfers_completed); | |
fprintf(st, "Control Out operations processed=%d\n", controller->control_out_operations_completed); | |
fprintf(st, "DDCMP control packets received=%d\n", controller->ddcmp_control_packets_received); | |
fprintf(st, "DDCMP control packets sent=%d\n", controller->ddcmp_control_packets_sent); | |
return SCPE_OK; | |
} | |
void dmc_showqueue (FILE* st, BUFFER_QUEUE *queue, t_bool detail) | |
{ | |
size_t i; | |
fprintf (st, "%s Queue:\n", queue->name); | |
fprintf (st, " Size: %d\n", (int)queue->size); | |
fprintf (st, " Count: %d\n", (int)queue->count); | |
if (detail) { | |
BUFFER *buffer = (BUFFER *)queue->hdr.next; | |
size_t same; | |
for (i=same=0; i<queue->count; ++i) { | |
if ((i == 0) || | |
(0 != memcmp(((char *)buffer)+sizeof(QH), ((char *)(buffer->hdr.prev))+sizeof(QH), sizeof(*buffer)-sizeof(QH)))) { | |
if (same > 0) | |
fprintf (st, "%s.queue[%d] thru %s.queue[%d] same as above\n", queue->name, (int)(i-same), queue->name, (int)(i-1)); | |
fprintf (st, "%s.queue[%d] at %p\n", queue->name, (int)i, buffer); | |
fprintf (st, " address: 0x%08X\n", buffer->address); | |
fprintf (st, " count: 0x%04X\n", buffer->count); | |
fprintf (st, " actual_bytes_transferred: 0x%04X\n", buffer->actual_bytes_transferred); | |
if (buffer->buffer_return_time) | |
fprintf (st, " buffer_return_time: 0x%08X\n", buffer->buffer_return_time); | |
if (strcmp(queue->name, "transmit") == 0) { | |
uint8 *msg = buffer->transfer_buffer; | |
static const char *const flags [4] = { "..", ".Q", "S.", "SQ" }; | |
static const char *const nak[18] = { "", " (HCRC)", " (DCRC)", " (REPREPLY)", /* 0-3 */ | |
"", "", "", "", /* 4-7 */ | |
" (NOBUF)", " (RXOVR)", "", "", /* 8-11 */ | |
"", "", "", "", /* 12-15 */ | |
" (TOOLONG)", " (HDRFMT)" }; /* 16-17 */ | |
const char *flag = flags[msg[2]>>6]; | |
int msg2 = msg[2] & 0x3F; | |
switch (msg[0]) { | |
case DDCMP_SOH: /* Data Message */ | |
fprintf (st, "Data Message, Count: %d, Num: %d, Flags: %s, Resp: %d, HDRCRC: %s, DATACRC: %s\n", (msg2 << 8)|msg[1], msg[4], flag, msg[3], | |
(0 == ddcmp_crc16 (0, msg, 8)) ? "OK" : "BAD", (0 == ddcmp_crc16 (0, msg+8, 2+((msg2 << 8)|msg[1]))) ? "OK" : "BAD"); | |
break; | |
case DDCMP_ENQ: /* Control Message */ | |
fprintf (st, "Control: Type: %d ", msg[1]); | |
switch (msg[1]) { | |
case DDCMP_CTL_ACK: /* ACK */ | |
fprintf (st, "(ACK) ACKSUB: %d, Flags: %s, Resp: %d\n", msg2, flag, msg[3]); | |
break; | |
case DDCMP_CTL_NAK: /* NAK */ | |
fprintf (st, "(NAK) Reason: %d%s, Flags: %s, Resp: %d\n", msg2, ((msg2 > 17)? "": nak[msg2]), flag, msg[3]); | |
break; | |
case DDCMP_CTL_REP: /* REP */ | |
fprintf (st, "(REP) REPSUB: %d, Num: %d, Flags: %s\n", msg2, msg[4], flag); | |
break; | |
case DDCMP_CTL_STRT: /* STRT */ | |
fprintf (st, "(STRT) STRTSUB: %d, Flags: %s\n", msg2, flag); | |
break; | |
case DDCMP_CTL_STACK: /* STACK */ | |
fprintf (st, "(STACK) STCKSUB: %d, Flags: %s\n", msg2, flag); | |
break; | |
default: /* Unknown */ | |
fprintf (st, "(Unknown=0%o)\n", msg[1]); | |
break; | |
} | |
if (buffer->count != DDCMP_HEADER_SIZE) | |
fprintf (st, "Unexpected Control Message Length: %d expected %d\n", buffer->count, DDCMP_HEADER_SIZE); | |
} | |
} | |
same = 0; | |
} | |
else | |
++same; | |
buffer = (BUFFER *)buffer->hdr.next; | |
} | |
if (same > 0) | |
fprintf (st, "%s.queue[%d] thru %s.queue[%d] same as above\n", queue->name, (int)(i-same), queue->name, (int)(i-1)); | |
} | |
} | |
t_stat dmc_showqueues (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
CTLR *controller = dmc_get_controller_from_unit(uptr); | |
static const char *states[] = {"Uninitialised", "Initialised", "Running", "Halted"}; | |
static const char *tstates[] = {"Idle", "InputTransfer", "OutputTransfer", "OutputControl"}; | |
dmc_showstats (st, uptr, val, desc); | |
fprintf (st, "State: %s\n", states[controller->state]); | |
fprintf (st, "TransferState: %s\n", tstates[controller->transfer_state]); | |
dmc_showqueue (st, controller->completion_queue, TRUE); | |
dmc_showqueue (st, controller->xmt_queue, TRUE); | |
dmc_showqueue (st, controller->ack_wait_queue, TRUE); | |
dmc_showqueue (st, controller->rcv_queue, TRUE); | |
dmc_showqueue (st, controller->free_queue, TRUE); | |
if (controller->control_out) { | |
CONTROL_OUT *control; | |
fprintf (st, "Control Out Queue:\n"); | |
for (control=controller->control_out; control; control=control->next) | |
fprintf (st, " SEL6: 0x%04X\n", control->sel6); | |
} | |
return SCPE_OK; | |
} | |
t_stat dmc_setstats (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
CTLR *controller = dmc_get_controller_from_unit(uptr); | |
controller->receive_buffer_output_transfers_completed = 0; | |
controller->transmit_buffer_output_transfers_completed = 0; | |
controller->receive_buffer_input_transfers_completed = 0; | |
controller->transmit_buffer_input_transfers_completed = 0; | |
controller->control_out_operations_completed = 0; | |
controller->ddcmp_control_packets_received = 0; | |
controller->ddcmp_control_packets_sent = 0; | |
sim_printf("Statistics reset\n"); | |
return SCPE_OK; | |
} | |
t_stat dmc_showconnectpoll (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
uint32 poll_interval = *((uint32 *)desc); | |
fprintf(st, "connectpoll=%u", poll_interval); | |
return SCPE_OK; | |
} | |
t_stat dmc_setconnectpoll (UNIT* uptr, int32 val, char* cptr, void* desc) | |
{ | |
t_stat status = SCPE_OK; | |
uint32 *poll_interval = ((uint32 *)desc); | |
uint32 newpoll; | |
if (!cptr) | |
return SCPE_IERR; | |
newpoll = (int32) get_uint (cptr, 10, 1800, &status); | |
if ((status != SCPE_OK) || (newpoll == (*poll_interval))) | |
return status; | |
*poll_interval = newpoll; | |
return tmxr_connection_poll_interval ((poll_interval == &dmc_connect_poll) ? &dmc_desc : &dmp_desc, newpoll); | |
} | |
/* SET LINES processor */ | |
t_stat dmc_setnumdevices (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
int32 newln; | |
uint32 i, j; | |
t_stat r; | |
DEVICE *dptr = (DEVICE *)desc; | |
TMXR *mp = (dptr == &dmc_dev) ? &dmc_desc : &dmp_desc; | |
int maxunits = (&dmc_dev == dptr) ? DMC_NUMDEVICE : DMP_NUMDEVICE; | |
DIB *dibptr = (DIB *)dptr->ctxt; | |
int addrlnt = (UNIBUS) ? IOLN_DMC : IOLN_DMV; | |
for (j=0; j<2; j++) { | |
dptr = (j == 0) ? &dmc_dev : &dmp_dev; | |
for (i=0; i<dptr->numunits; i++) | |
if (dptr->units[i].flags&UNIT_ATT) | |
return SCPE_ALATT; | |
} | |
dptr = (DEVICE *)desc; | |
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, maxunits, &r); | |
if ((r != SCPE_OK) || (newln == (int32)(dptr->numunits - 2))) | |
return r; | |
if (newln == 0) | |
return SCPE_ARG; | |
sim_cancel (dptr->units + dptr->numunits - 2); | |
sim_cancel (dptr->units + dptr->numunits - 1); | |
for (i=dptr->numunits-2; i<(uint32)newln; ++i) { | |
dptr->units[i] = dmc_unit_template; | |
dptr->units[i].ctlr = &dmc_ctrls[(dptr == &dmc_dev) ? i : i+DMC_NUMDEVICE]; | |
} | |
dibptr->lnt = newln * addrlnt; /* set length */ | |
dptr->numunits = newln + 2; | |
dptr->units[newln] = dmc_poll_unit_template; | |
dptr->units[newln].ctlr = &dmc_ctrls[(dptr == &dmc_dev) ? 0 : DMC_NUMDEVICE]; | |
dptr->units[newln+1] = dmc_timer_unit_template; | |
dptr->units[newln+1].ctlr = &dmc_ctrls[(dptr == &dmc_dev) ? 0 : DMC_NUMDEVICE]; | |
mp->lines = newln; | |
mp->uptr = dptr->units + newln; /* Identify polling unit */ | |
return dmc_reset ((DEVICE *)desc); /* setup devices and auto config */ | |
} | |
t_stat dmc_shownumdevices (FILE *st, UNIT *uptr, int32 val, void *desc) | |
{ | |
DEVICE *dptr = (UNIBUS) ? find_dev_from_unit (uptr) : &dmv_dev; | |
fprintf (st, "lines=%d", dptr->numunits-2); | |
return SCPE_OK; | |
} | |
t_stat dmc_showddcmp (FILE* st, UNIT* uptr, int32 val, void* desc) | |
{ | |
CTLR *controller = dmc_get_controller_from_unit(uptr); | |
static const char *states[] = {"Halt", "IStart", "AStart", "Run", "Maintenance"}; | |
fprintf (st, "%s%d\n", controller->device->name, (int)(uptr-controller->device->units)); | |
fprintf(st, "DDCMP Link State: %s\n", states[controller->link.state]); | |
fprintf(st, " R: %d\n", controller->link.R); | |
fprintf(st, " N: %d\n", controller->link.N); | |
fprintf(st, " A: %d\n", controller->link.A); | |
fprintf(st, " T: %d\n", controller->link.T); | |
fprintf(st, " X: %d\n", controller->link.X); | |
fprintf(st, " SACK: %s\n", controller->link.SACK ? "true" : "false"); | |
fprintf(st, " SNAK: %s\n", controller->link.SNAK ? "true" : "false"); | |
fprintf(st, " SREP: %s\n", controller->link.SREP ? "true" : "false"); | |
fprintf(st, " rcv_pkt: %p\n", controller->link.rcv_pkt); | |
fprintf(st, " rcv_pkt_size: %d\n", controller->link.rcv_pkt_size); | |
fprintf(st, " xmt_buffer: %p\n", controller->link.xmt_buffer); | |
fprintf(st, " nak_reason: %d\n", controller->link.nak_reason); | |
fprintf(st, " TimerRunning: %s\n", controller->link.TimerRunning ? "true" : "false"); | |
fprintf(st, " TimeRemaining: %d\n", controller->link.TimeRemaining); | |
return SCPE_OK; | |
} | |
t_stat dmc_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, char *cptr) | |
{ | |
const char helpString[] = | |
/* The '*'s in the next line represent the standard text width of a help line */ | |
/****************************************************************************/ | |
" The %1s is a communication subsystem which consists of a microprocessor\n" | |
" based, intelligent synchronous communications controller which employs\n" | |
" the DIGITAL Data Communications Message Protocol (DDCMP).\n" | |
"1 Hardware Description\n" | |
" The %1s consists of a microprocessor module and a synchronous line unit\n" | |
" module.\n" | |
#if !defined (VM_PDP10) | |
"2 Models\n" | |
" There were a number of microprocessor DDCMP devices produced.\n" | |
"3 DMC11\n" | |
" The original kmc11 microprocessor board with DMC microcode and a sync\n" | |
" line unit.\n" | |
"3 DMR11\n" | |
" The more advanced kmc11 microprocessor board with DMR microcode and a sync\n" | |
" line unit.\n" | |
"3 DMP11\n" | |
" A newly designed Unibus board with a more complete programming interface\n" | |
" and a sync line unit.\n" | |
"3 DMV11\n" | |
" A Qbus version of the DMP11 with some more advanced refinements and a sync\n" | |
" line unit.\n" | |
#endif | |
"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 %1s devices can be emulated concurrently in the %S\n" | |
" simulator. The number of simulated %1s 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" | |
#if !defined (VM_PDP10) | |
"3 Type\n" | |
" The type of device being emulated can be changed with the following\n" | |
" command:\n" | |
"\n" | |
"+sim> SET %U TYPE={DMR|DMC}\n" | |
"\n" | |
" A SET TYPE command should be entered before the device is attached to a\n" | |
" listening port.\n" | |
#endif | |
"3 Corruption\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" | |
/****************************************************************************/ | |
#define DMC_HLP_ATTACH "Configuration Attach" | |
"2 Attach\n" | |
" The device must be attached to a receive port, use the ATTACH command\n" | |
" specifying the receive port number.\n" | |
"\n" | |
"+sim> ATTACH %U port\n" | |
"\n" | |
" The Peer host:port value must be specified before the attach command.\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" | |
"+sim> ATTACH %U port,UDP\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> SET %U PEER=LOCALHOST:2222\n" | |
"+sim> ATTACH %U 1111\n" | |
" \n" | |
" Machine 2\n" | |
"+sim> SET %D ENABLE\n" | |
"+sim> SET %U PEER=LOCALHOST:1111\n" | |
"+sim> ATTACH %U 2222\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\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" | |
" In real hardware, the DMC11 spoke a version of DDCMP which peer devices\n" | |
" needed to be aware of. The DMR11, DMP11, and DMV11 boards have\n" | |
" configuration switches or programatic methods to indicate that the peer\n" | |
" device was a DMC11. The emulated devices all speak the same level of\n" | |
" DDCMP so no special remote device awareness need be considered.\n" | |
"1 Implementation\n" | |
" A real %1s transports data using DDCMP via a synchronous connection, the\n" | |
" emulated device makes a TCP/IP connection to another emulated device which\n" | |
" either speaks DDCMP over the TCP connection directly, or interfaces to a\n" | |
" simulated computer where the operating system speaks the DDCMP protocol on\n" | |
" the wire.\n" | |
"\n" | |
" The %1s 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" | |
"++INTREG Shows internal register value changes.\n" | |
"++INFO Shows higher-level tracing only.\n" | |
"++WARN Shows any warnings.\n" | |
"++TRACE Shows more detailed trace information.\n" | |
"++DATASUM Brief summary of each received and transmitted buffer.\n" | |
"++++Ignored if DATA is set.\n" | |
"++DATA Shows the actual data sent and received.\n" | |
"++MODEM Shows modem signal transitions details.\n" | |
"++CONNECT Shows sockets connection activity.\n" | |
"++INT Shows Interrupt activity.\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;INFO;WARN\n" | |
"\n" | |
"1 Related Devices\n" | |
" The %D 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 devname[16]; | |
char devcount[16]; | |
char connectpoll[16]; | |
sprintf (devname, "%s11" , dptr->name); | |
sprintf (devcount, "%d", (dptr == &dmc_dev) ? DMC_NUMDEVICE : DMP_NUMDEVICE); | |
sprintf (connectpoll, "%d", DMC_CONNECT_POLL); | |
return scp_help (st, dptr, uptr, flag, helpString, cptr, devname, devcount, connectpoll); | |
} | |
t_stat dmc_help_attach (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, char *cptr) | |
{ | |
return dmc_help (st, dptr, uptr, flag, DMC_HLP_ATTACH); | |
} | |
void dmc_setinint(CTLR *controller) | |
{ | |
if (!dmc_is_iei_set(controller)) | |
return; | |
if (!controller->in_int) { | |
sim_debug(DBG_INT, controller->device, "SET_INT(RX:%s%d) summary=0x%x\n", controller->device->name, controller->index, dmc_ini_summary); | |
} | |
controller->in_int = 1; | |
dmc_ini_summary |= (1u << controller->index); | |
SET_INT(DMCRX); | |
} | |
void dmc_clrinint(CTLR *controller) | |
{ | |
controller->in_int = 0; | |
if (dmc_ini_summary & (1u << controller->index)) { | |
sim_debug(DBG_INT, controller->device, "CLR_INT(RX:%s%d) summary=0x%x\n", controller->device->name, controller->index, dmc_ini_summary); | |
} | |
dmc_ini_summary &= ~(1u << controller->index); | |
if (!dmc_ini_summary) | |
CLR_INT(DMCRX); | |
else | |
SET_INT(DMCRX); | |
} | |
void dmc_setoutint(CTLR *controller) | |
{ | |
if (!dmc_is_ieo_set(controller)) | |
return; | |
if (!controller->out_int) { | |
sim_debug(DBG_INT, controller->device, "SET_INT(TX:%s%d) summary=0x%x\n", controller->device->name, controller->index, dmc_outi_summary ); | |
} | |
controller->out_int = 1; | |
dmc_outi_summary |= (1u << controller->index); | |
SET_INT(DMCTX); | |
} | |
void dmc_clroutint(CTLR *controller) | |
{ | |
controller->out_int = 0; | |
if (dmc_outi_summary & (1u << controller->index)) { | |
sim_debug(DBG_INT, controller->device, "CLR_INT(TX:%s%d) summary=0x%x\n", controller->device->name, controller->index, dmc_outi_summary); | |
} | |
dmc_outi_summary &= ~(1u << controller->index); | |
if (!dmc_outi_summary) | |
CLR_INT(DMCTX); | |
else | |
SET_INT(DMCTX); | |
} | |
int dmc_getsel(int addr) | |
{ | |
return (addr >> 1) & ((UNIBUS) ? 03 : 07); | |
} | |
uint16 dmc_bitfld(int data, int start_bit, int length) | |
{ | |
uint16 ans = (uint16)(data >> start_bit); | |
uint32 mask = (1 << (length))-1; | |
ans &= mask; | |
return ans; | |
} | |
void dmc_dumpregsel0(CTLR *controller, int trace_level, char * prefix, uint16 data) | |
{ | |
char *type_str = ""; | |
uint16 type = dmc_bitfld(data, DMC_SEL0_V_ITYPE, DMC_SEL0_S_ITYPE); | |
static char *dmc_types[] = {"XMT BA/CC", "CNTL IN", "HALT", "BASE IN", "RCV BA/CC", "?????", "?????", "?????"}; | |
if (dmc_is_dmc(controller)) { | |
if (dmc_is_rqi_set(controller)) { | |
type_str = dmc_types[type]; | |
} | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL0 (0x%04x) %s%s%s%s%s%s%s%s%s\n", | |
controller->device->name, controller->index, | |
prefix, | |
data, | |
dmc_bitfld(data, DMC_SEL0_V_RUN, 1) ? "RUN " : "", | |
dmc_bitfld(data, DMC_SEL0_V_MCLEAR, 1) ? "MCLR " : "", | |
dmc_bitfld(data, DMC_SEL0_V_LU_LOOP, 1) ? "LU LOOP " : "", | |
dmc_bitfld(data, DMC_SEL0_V_ROMI, 1) ? "ROMI " : "", | |
dmc_bitfld(data, DMC_SEL0_V_STEPUP, 1) ? "STEPUP " : "", | |
dmc_bitfld(data, DMC_SEL0_V_RDI, 1) ? "RDI " : "", | |
dmc_bitfld(data, DMC_SEL0_V_IEI, 1) ? "IEI " : "", | |
dmc_bitfld(data, DMC_SEL0_V_RQI, 1) ? "RQI " : "", | |
type_str | |
); | |
} | |
else { | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL0 (0x%04x) %s%s%s%s%s%s\n", | |
controller->device->name, controller->index, | |
prefix, | |
data, | |
dmc_bitfld(data, DMC_SEL0_V_RUN, 1) ? "RUN " : "", | |
dmc_bitfld(data, DMC_SEL0_V_MCLEAR, 1) ? "MCLR " : "", | |
dmc_bitfld(data, DMC_SEL0_V_LU_LOOP, 1) ? "LU LOOP " : "", | |
dmc_bitfld(data, DMP_SEL0_V_RQI, 1) ? "RQI " : "", | |
dmc_bitfld(data, DMP_SEL0_V_IEO, 1) ? "IEO " : "", | |
dmc_bitfld(data, DMP_SEL0_V_IEI, 1) ? "IEI " : "" | |
); | |
} | |
} | |
void dmc_dumpregsel2(CTLR *controller, int trace_level, char *prefix, uint16 data) | |
{ | |
char *type_str = ""; | |
uint16 type = dmc_bitfld(data, DMC_SEL2_V_CODE, DMC_SEL2_S_CODE); | |
static char *dmc_types[] = {"XMT BA/CC OUT", "CNTL OUT", "?????", "?????", "RCV BA/CC OUT", "?????", "?????", "?????"}; | |
type_str = dmc_types[type]; | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL2 (0x%04x) PRIO=%d LINE=%d %s%s%s%s\n", | |
controller->device->name, controller->index, | |
prefix, | |
data, | |
dmc_bitfld(data, SEL2_PRIO_BIT, SEL2_PRIO_BIT_LENGTH), | |
dmc_bitfld(data, SEL2_LINE_BIT, SEL2_LINE_BIT_LENGTH), | |
dmc_bitfld(data, SEL2_RDO_BIT, 1) ? "RDO " : "", | |
dmc_bitfld(data, SEL2_IEO_BIT, 1) ? "IEO " : "", | |
dmc_bitfld(data, SEL2_OUT_IO_BIT, 1) ? "OUT I/O " : "", | |
type_str | |
); | |
} | |
void dmc_dumpregsel4(CTLR *controller, int trace_level, char *prefix, uint16 data) | |
{ | |
if (dmc_is_rdyi_set(controller)) { | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL4 (0x%04x) %s%s%s%s%s%s%s%s\n", | |
controller->device->name, controller->index, | |
prefix, | |
data, | |
dmc_bitfld(data, DMC_SEL4_V_RI, 1) ? "RI " : "", | |
dmc_bitfld(data, DMC_SEL4_V_DTR, 1) ? "DTR " : "", | |
dmc_bitfld(data, DMC_SEL4_V_RTS, 1) ? "RTS " : "", | |
dmc_bitfld(data, DMC_SEL4_V_HDX, 1) ? "HDX " : "", | |
dmc_bitfld(data, DMC_SEL4_V_DSR, 1) ? "DSR " : "", | |
dmc_bitfld(data, DMC_SEL4_V_CTS, 1) ? "CTS " : "", | |
dmc_bitfld(data, DMC_SEL4_V_STN, 1) ? "STN " : "", | |
dmc_bitfld(data, DMC_SEL4_V_CAR, 1) ? "CAR " : ""); | |
} | |
else { | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL4 (0x%04x)\n", | |
controller->device->name, controller->index, | |
prefix, | |
data); | |
} | |
} | |
void dmc_dumpregsel6(CTLR *controller, int trace_level, char *prefix, uint16 data) | |
{ | |
if (dmc_is_rdyi_set(controller)) { | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL6 (0x%04x) %s%s\n", | |
controller->device->name, controller->index, | |
prefix, | |
data, | |
dmc_bitfld(data, DMC_SEL6_M_LOSTDATA, 1) ? "LOST_DATA " : "", | |
dmc_bitfld(data, DMC_SEL6_M_DISCONN, 1) ? "DISCONNECT " : ""); | |
} | |
else { | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL6 (0x%04x)\n", | |
controller->device->name, controller->index, | |
prefix, | |
data); | |
} | |
} | |
void dmc_dumpregsel10(CTLR *controller, int trace_level, char *prefix, uint16 data) | |
{ | |
sim_debug( | |
trace_level, | |
controller->device, | |
"%s%d: %s SEL10 (0x%04x) %s\n", | |
controller->device->name, controller->index, | |
prefix, | |
data, | |
dmc_bitfld(data, DMC_SEL6_M_LOSTDATA, 1) ? "LOST_DATA " : ""); | |
} | |
uint16 dmc_getreg(CTLR *controller, int reg, int ctx) | |
{ | |
uint16 ans = 0; | |
switch (dmc_getsel(reg)) { | |
case 00: | |
ans = *controller->csrs->sel0; | |
dmc_dumpregsel0(controller, ctx, "Getting", ans); | |
break; | |
case 01: | |
ans = *controller->csrs->sel2; | |
dmc_dumpregsel2(controller, ctx, "Getting", ans); | |
break; | |
case 02: | |
ans = *controller->csrs->sel4; | |
dmc_dumpregsel4(controller, ctx, "Getting", ans); | |
break; | |
case 03: | |
ans = *controller->csrs->sel6; | |
dmc_dumpregsel6(controller, ctx, "Getting", ans); | |
break; | |
case 04: | |
ans = *controller->csrs->sel10; | |
dmc_dumpregsel10(controller, ctx, "Getting", ans); | |
break; | |
default: | |
sim_debug(DBG_WRN, controller->device, "%s%d: dmc_getreg(). Invalid register %d", controller->device->name, controller->index, reg); | |
break; | |
} | |
return ans; | |
} | |
void dmc_setreg(CTLR *controller, int reg, uint16 data, int ctx) | |
{ | |
char *trace = "Setting"; | |
switch (dmc_getsel(reg)) { | |
case 00: | |
dmc_dumpregsel0(controller, ctx, trace, data); | |
*controller->csrs->sel0 = data; | |
break; | |
case 01: | |
dmc_dumpregsel2(controller, ctx, trace, data); | |
*controller->csrs->sel2 = data; | |
break; | |
case 02: | |
dmc_dumpregsel4(controller, ctx, trace, data); | |
*controller->csrs->sel4 = data; | |
break; | |
case 03: | |
dmc_dumpregsel6(controller, ctx, trace, data); | |
*controller->csrs->sel6 = data; | |
break; | |
case 04: | |
dmc_dumpregsel10(controller, ctx, trace, data); | |
*controller->csrs->sel10 = data; | |
break; | |
default: | |
sim_debug(DBG_WRN, controller->device, "%s%d: dmc_setreg(). Invalid register %d", controller->device->name, controller->index, reg); | |
} | |
} | |
int dmc_is_master_clear_set(CTLR *controller) | |
{ | |
return *controller->csrs->sel0 & DMC_SEL0_M_MCLEAR; | |
} | |
int dmc_is_lu_loop_set(CTLR *controller) | |
{ | |
if (dmc_is_dmc(controller)) | |
return ((*controller->csrs->sel0 & DMC_SEL0_M_LU_LOOP) != 0); | |
else | |
return FALSE; | |
} | |
int dmc_is_run_set(CTLR *controller) | |
{ | |
return *controller->csrs->sel0 & DMC_SEL0_M_RUN; | |
} | |
int dmc_is_rqi_set(CTLR *controller) | |
{ | |
int ans = 0; | |
if (dmc_is_dmc(controller)) | |
ans = *controller->csrs->sel0 & DMC_SEL0_M_RQI; | |
else | |
ans = *controller->csrs->sel0 & DMP_SEL0_M_RQI; | |
return ans; | |
} | |
int dmc_is_rdyi_set(CTLR *controller) | |
{ | |
int ans = 0; | |
if (dmc_is_dmc(controller)) | |
ans = *controller->csrs->sel0 & DMC_SEL0_M_RDI; | |
else | |
ans = *controller->csrs->sel2 & DMP_SEL2_M_RDI; | |
return ans; | |
} | |
int dmc_is_iei_set(CTLR *controller) | |
{ | |
int ans = 0; | |
if (dmc_is_dmc(controller)) | |
ans = *controller->csrs->sel0 & DMC_SEL0_M_IEI; | |
else | |
ans = *controller->csrs->sel0 & DMP_SEL0_M_IEI; | |
return ans; | |
} | |
int dmc_is_ieo_set(CTLR *controller) | |
{ | |
int ans = 0; | |
if (dmc_is_dmc(controller)) | |
ans = *controller->csrs->sel2 & DMC_SEL2_M_IEO; | |
else | |
ans = *controller->csrs->sel0 & DMP_SEL0_M_IEO; | |
return ans; | |
} | |
int dmc_is_in_io(CTLR *controller) | |
{ | |
int ans = 0; | |
if (dmc_is_dmc(controller)) | |
ans = ((*controller->csrs->sel0 & DMC_SEL0_M_ITYPE) == DMC_C_TYPE_RBACC); | |
else | |
ans = ((*controller->csrs->sel2 & DMP_SEL2_M_CODE) == DMP_C_TYPE_RBACC); | |
return ans; | |
} | |
int dmc_is_rdyo_set(CTLR *controller) | |
{ | |
return *controller->csrs->sel2 & DMC_SEL2_M_RDO; | |
} | |
void dmc_set_rdyi(CTLR *controller) | |
{ | |
if (dmc_is_dmc(controller)) { | |
dmc_setreg(controller, 0, *controller->csrs->sel0 | DMC_SEL0_M_RDI, DBG_RGC); | |
dmc_setreg(controller, 4, *controller->modem | 0x0800, DBG_RGC); | |
dmc_setreg(controller, 6, *controller->modem & DMC_SEL4_M_DTR, DBG_RGC); | |
} | |
else | |
dmc_setreg(controller, 2, *controller->csrs->sel2 | DMP_SEL2_M_RDI, DBG_RGC); | |
dmc_setinint(controller); | |
} | |
void dmc_clear_rdyi(CTLR *controller) | |
{ | |
if (dmc_is_dmc(controller)) | |
dmc_setreg(controller, 0, *controller->csrs->sel0 & ~(DMC_SEL0_M_RDI|DMC_SEL0_M_ITYPE), DBG_RGC); | |
else | |
dmc_setreg(controller, 2, *controller->csrs->sel2 & ~DMP_SEL2_M_RDI, DBG_RGC); | |
} | |
void dmc_set_rdyo(CTLR *controller) | |
{ | |
dmc_setreg(controller, 2, *controller->csrs->sel2 | DMC_SEL2_M_RDO, DBG_RGC); | |
dmc_setoutint(controller); | |
} | |
uint32 dmc_get_addr(CTLR *controller) | |
{ | |
if (dmc_is_dmc(controller) || (!(*controller->csrs->sel2 & DMP_SEL2_M_22BIT))) | |
return ((uint32)dmc_getreg(controller, 4, DBG_RGC)) | ((((uint32)dmc_getreg(controller, 6, DBG_RGC) & 0xc000)) << 2); | |
else | |
return ((uint32)dmc_getreg(controller, 4, DBG_RGC)) | (((uint32)dmc_getreg(controller, 6, DBG_RGC) & 0x3FF) << 16); | |
} | |
void dmc_set_addr(CTLR *controller, uint32 addr) | |
{ | |
if (dmc_is_dmc(controller) || (!(*controller->csrs->sel2 & DMP_SEL2_M_22BIT))) { | |
dmc_setreg(controller, 4, addr & 0xFFFF, DBG_RGC); | |
dmc_setreg(controller, 6, (uint16)(((addr >> 16) << 14) | (*controller->csrs->sel6 & 0x3FFF)) , DBG_RGC); | |
} | |
else { | |
dmc_setreg(controller, 4, addr & 0xFFFF, DBG_RGC); | |
dmc_setreg(controller, 6, ((addr >> 16) & 0x3F), DBG_RGC); | |
} | |
} | |
uint16 dmc_get_count(CTLR *controller) | |
{ | |
if (dmc_is_dmc(controller) || (!(*controller->csrs->sel2 & DMP_SEL2_M_22BIT))) | |
return dmc_getreg(controller, 6, DBG_RGC) & 0x3FFF; | |
else | |
return dmc_getreg(controller, 010, DBG_RGC) & 0x3FFF; | |
} | |
void dmc_set_count(CTLR *controller, uint16 count) | |
{ | |
if (dmc_is_dmc(controller) || (!(*controller->csrs->sel2 & DMP_SEL2_M_22BIT))) | |
dmc_setreg(controller, 6, (*controller->csrs->sel6 & 0xc000) | (0x3FFF & count), DBG_RGC); | |
else | |
dmc_setreg(controller, 010, (*controller->csrs->sel10 & 0xc000) | (0x3FFF & count), DBG_RGC); | |
} | |
uint8 dmc_get_modem(CTLR *controller) | |
{ | |
int32 modem_bits; | |
tmxr_set_get_modem_bits (controller->line, 0, 0, &modem_bits); | |
*controller->modem &= ~(DMC_SEL4_M_CTS|DMC_SEL4_M_CAR|DMC_SEL4_M_RI|DMC_SEL4_M_DSR|DMC_SEL4_M_DTR|DMC_SEL4_M_RTS); | |
*controller->modem |= (modem_bits&TMXR_MDM_DCD) ? DMC_SEL4_M_CAR : 0; | |
*controller->modem |= (modem_bits&TMXR_MDM_CTS) ? DMC_SEL4_M_CTS : 0; | |
*controller->modem |= (modem_bits&TMXR_MDM_DSR) ? DMC_SEL4_M_DSR : 0; | |
*controller->modem |= (modem_bits&TMXR_MDM_RNG) ? DMC_SEL4_M_RI : 0; | |
*controller->modem |= (modem_bits&TMXR_MDM_DTR) ? DMC_SEL4_M_DTR : 0; | |
*controller->modem |= (modem_bits&TMXR_MDM_RTS) ? DMC_SEL4_M_RTS : 0; | |
return (*controller->modem); | |
} | |
void dmc_set_modem_dtr(CTLR *controller) | |
{ | |
if (dmc_is_attached(controller->unit) && (!(DMC_SEL4_M_DTR & *controller->modem))) { | |
sim_debug(DBG_MDM, controller->device, "%s%d: DTR State Change to UP(ON)\n", controller->device->name, controller->index); | |
tmxr_set_get_modem_bits (controller->line, TMXR_MDM_DTR|TMXR_MDM_RTS, 0, NULL); | |
dmc_get_modem(controller); | |
controller->line->rcve = 1; | |
} | |
} | |
void dmc_clr_modem_dtr(CTLR *controller) | |
{ | |
if (*controller->modem & DMC_SEL4_M_DTR) { | |
sim_debug(DBG_MDM, controller->device, "%s%d: DTR State Change to DOWN(OFF)\n", controller->device->name, controller->index); | |
} | |
tmxr_set_get_modem_bits (controller->line, 0, TMXR_MDM_DTR|TMXR_MDM_RTS, NULL); | |
dmc_get_modem(controller); | |
} | |
void dmc_set_lost_data(CTLR *controller) | |
{ | |
dmc_setreg(controller, 6, *controller->csrs->sel6 | DMC_SEL6_M_LOSTDATA, DBG_RGC); | |
} | |
void dmc_clear_master_clear(CTLR *controller) | |
{ | |
dmc_setreg(controller, 0, *controller->csrs->sel0 & ~DMC_SEL0_M_MCLEAR, DBG_RGC); | |
} | |
void dmc_set_run(CTLR *controller) | |
{ | |
dmc_setreg(controller, 0, *controller->csrs->sel0 | DMC_SEL0_M_RUN, DBG_RGC); | |
} | |
int dmc_get_input_transfer_type(CTLR *controller) | |
{ | |
int ans = 0; | |
if (dmc_is_dmc(controller)) | |
ans = *controller->csrs->sel0 & DMC_SEL0_M_ITYPE; | |
else | |
ans = *controller->csrs->sel2 & DMP_SEL2_M_CODE; | |
return ans; | |
} | |
void dmc_set_type_output(CTLR *controller, int type) | |
{ | |
dmc_setreg(controller, 2, (*controller->csrs->sel2 & ~DMC_SEL2_M_CODE) | (type & DMC_SEL2_M_CODE), DBG_RGC); | |
} | |
void dmc_process_master_clear(CTLR *controller) | |
{ | |
CONTROL_OUT *control; | |
sim_debug(DBG_INF, controller->device, "%s%d: Master clear\n", controller->device->name, controller->index); | |
dmc_clear_master_clear(controller); | |
dmc_clr_modem_dtr(controller); | |
controller->link.state = Halt; | |
controller->state = Initialised; | |
while ((control = controller->control_out)) { | |
controller->control_out = control->next; | |
free (control); | |
} | |
controller->control_out = NULL; | |
dmc_setreg(controller, 0, 0, DBG_RGC); | |
if (controller->dev_type == DMR) { | |
if (dmc_is_attached(controller->unit)) { | |
/* Indicates microdiagnostics complete */ | |
if (((*controller->csrs->sel0 & DMC_SEL0_M_UDIAG) != 0) ^ | |
(dmc_microdiag[controller->index])) | |
dmc_setreg(controller, 2, 0x8000, DBG_RGC);/* Microdiagnostics Complete */ | |
else | |
dmc_setreg(controller, 2, 0x4000, DBG_RGC); /* Microdiagnostics Inhibited */ | |
} | |
else { | |
/* Indicate M8203 (Line Unit) test failed */ | |
dmc_setreg(controller, 2, 0x0200, DBG_RGC); | |
} | |
} | |
else { | |
/* preserve contents of BSEL3 if DMC-11 */ | |
dmc_setreg(controller, 2, *controller->csrs->sel2 & 0xFF00, DBG_RGC); | |
} | |
if (controller->dev_type == DMP) | |
dmc_setreg(controller, 4, 077, DBG_RGC); | |
else | |
dmc_setreg(controller, 4, 0, DBG_RGC); | |
if (controller->dev_type == DMP) | |
dmc_setreg(controller, 6, 0305, DBG_RGC); | |
else | |
dmc_setreg(controller, 6, 0, DBG_RGC); | |
dmc_buffer_queue_init_all(controller); | |
controller->transfer_state = Idle; | |
if (dmc_is_attached(controller->unit)) | |
dmc_set_run(controller); | |
} | |
void dmc_start_input_transfer(CTLR *controller) | |
{ | |
sim_debug(DBG_INF, controller->device, "%s%d: Starting input transfer\n", controller->device->name, controller->index); | |
controller->transfer_state = InputTransfer; | |
dmc_set_rdyi(controller); | |
} | |
void dmc_start_control_output_transfer(CTLR *controller) | |
{ | |
if ((!controller->control_out) || | |
(controller->transfer_state != Idle) || | |
(dmc_is_rdyo_set(controller))) | |
return; | |
sim_debug(DBG_INF, controller->device, "%s%d: Starting control output transfer: SEL6 = 0x%04X\n", controller->device->name, controller->index, controller->control_out->sel6); | |
controller->transfer_state = OutputControl; | |
dmc_setreg (controller, 6, controller->control_out->sel6, DBG_RGC); | |
dmc_set_type_output(controller, DMC_C_TYPE_CNTL); | |
dmc_set_rdyo(controller); | |
} | |
void dmc_complete_transmit(CTLR *controller) | |
{ | |
BUFFER *buffer = controller->link.xmt_buffer; | |
if (!buffer) | |
return; | |
controller->link.xmt_done_buffer = buffer; | |
ddcmp_dispatch (controller, DDCMP_EVENT_XMIT_DONE); | |
controller->link.xmt_done_buffer = NULL; | |
buffer = (BUFFER *)remqueue (&buffer->hdr); | |
buffer->actual_bytes_transferred = buffer->count; | |
controller->buffers_transmitted_to_net++; | |
if (buffer->type == TransmitData) { | |
buffer->actual_bytes_transferred = buffer->count - (DDCMP_HEADER_SIZE + DDCMP_CRC_SIZE); | |
ASSURE (insqueue (&buffer->hdr, controller->ack_wait_queue->hdr.prev)); | |
} | |
else { | |
ASSURE (insqueue (&buffer->hdr, &controller->free_queue->hdr)); | |
} | |
controller->link.xmt_buffer = NULL; | |
} | |
t_stat dmc_svc(UNIT* uptr) | |
{ | |
CTLR *controller = dmc_get_controller_from_unit(uptr); | |
DEVICE *dptr = controller->device; | |
sim_debug(DBG_TRC, dptr, "dmc_svc(%s%d)\n", controller->device->name, controller->index); | |
/* Perform delayed register actions */ | |
if (controller->dmc_wr_delay) { | |
controller->dmc_wr_delay = 0; | |
dmc_process_command(controller); | |
if (controller->link.xmt_buffer) { | |
sim_activate_notbefore (uptr, controller->link.xmt_buffer->buffer_return_time); | |
return SCPE_OK; | |
} | |
} | |
if (dmc_is_attached(controller->unit)) { | |
/* Speed limited transmissions are completed here after the appropriate service delay */ | |
if (controller->link.xmt_buffer) { | |
dmc_complete_transmit(controller); | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
dmc_start_control_output_transfer(controller); | |
if (controller->xmt_queue->count) | |
ddcmp_dispatch (controller, 0); | |
if (controller->transfer_state == Idle) | |
dmc_start_transfer_buffer(controller); | |
dmc_buffer_fill_receive_buffers(controller); | |
if (controller->transfer_state == Idle) | |
dmc_start_transfer_buffer(controller); | |
/* Execution of this routine normally is triggered by programatic access by the | |
simulated system's device driver to the device registers or the arrival of | |
traffic from the network. Network traffic is handled by the dmc_poll_svc | |
which may call this routine as needed. Direct polling here is extra overhead | |
and is only scheduled when needed. | |
*/ | |
if ((controller->completion_queue->count) || /* if completion queue not empty? */ | |
(controller->control_out) || /* or pending control outs? */ | |
(controller->transfer_state != Idle)) /* or registers are busy */ | |
sim_clock_coschedule (uptr, tmxr_poll); /* wake up periodically until these don't exist */ | |
} | |
return SCPE_OK; | |
} | |
t_stat dmc_poll_svc (UNIT *uptr) | |
{ | |
DEVICE *dptr = ((CTLR *)uptr->ctlr)->device; | |
CTLR *controller; | |
TMXR *mp = (dptr == &dmc_dev) ? &dmc_desc : &dmp_desc; | |
int32 dmc, active, attached; | |
sim_debug(DBG_TRC, dptr, "dmc_poll_svc()\n"); | |
dmc = tmxr_poll_conn(mp); | |
if (dmc >= 0) { /* new connection? */ | |
controller = (CTLR *)dptr->units[dmc].ctlr; | |
dmc_get_modem (controller); | |
sim_debug(DBG_MDM, dptr, "dmc_poll_svc(dmc=%d) - Connection State Change to UP(ON)\n", dmc); | |
ddcmp_dispatch (controller, 0); | |
sim_clock_coschedule (controller->unit, tmxr_poll); /* be sure to wake up soon to continue processing */ | |
} | |
tmxr_poll_rx (mp); | |
tmxr_poll_tx (mp); | |
for (dmc=active=attached=0; dmc < mp->lines; dmc++) { | |
CTLR *controller = (CTLR *)dptr->units[dmc].ctlr; | |
TMLN *lp = controller->line; | |
uint8 old_modem, new_modem; | |
controller = (CTLR *)dptr->units[dmc].ctlr; | |
if (controller->unit->flags & UNIT_ATT) | |
++attached; | |
if (lp->conn) | |
++active; | |
old_modem = *controller->modem; | |
new_modem = dmc_get_modem (controller); | |
if ((old_modem & DMC_SEL4_M_CAR) && | |
(!(new_modem & DMC_SEL4_M_CAR))) { | |
sim_debug(DBG_MDM, controller->device, "dmc_poll_svc(dmc=%d) - Connection State Change to %s\n", dmc, (new_modem & DMC_SEL4_M_CAR) ? "UP(ON)" : "DOWN(OFF)"); | |
ddcmp_dispatch (controller, 0); | |
sim_clock_coschedule (controller->unit, tmxr_poll); /* wake up soon to finish processing */ | |
} | |
if ((lp->xmte && tmxr_tpbusyln(lp)) || | |
(lp->xmte && controller->link.xmt_buffer) || | |
ddcmp_UserSendMessage(controller)) { | |
if (tmxr_tpbusyln(lp)) { | |
sim_debug(DBG_DAT, controller->device, "dmc_poll_svc(dmc=%d) - Packet Transmission of remaining %d bytes restarting...\n", dmc, tmxr_tpqln (lp)); | |
} | |
dmc_svc (&controller->device->units[dmc]); /* Flush pending output */ | |
} | |
if (dmc_buffer_fill_receive_buffers(controller)) | |
dmc_svc (&controller->device->units[dmc]); /* return ACKed transmit packets */ | |
} | |
if (active) | |
sim_clock_coschedule (uptr, tmxr_poll); /* reactivate */ | |
else { | |
for (dmc=0; dmc < mp->lines; dmc++) { | |
uint32 *speeds = (dptr == &dmc_dev) ? dmc_speed : dmp_speed; | |
CTLR *controller = (CTLR *)dptr->units[dmc].ctlr; | |
if (speeds[dmc]/8) | |
controller->byte_wait = (tmr_poll*clk_tps)/(speeds[dmc]/8); | |
else | |
controller->byte_wait = 0; | |
} | |
if (attached) | |
sim_activate_after (uptr, DMC_CONNECT_POLL*1000000);/* periodic check for connections */ | |
} | |
return SCPE_OK; | |
} | |
t_stat dmc_timer_svc (UNIT *uptr) | |
{ | |
int32 dmc, active; | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
TMXR *mp = (dptr == &dmc_dev) ? &dmc_desc : &dmp_desc; | |
CTLR *controller; | |
sim_debug(DBG_TRC, dptr, "dmc_timer_svc()\n"); | |
for (dmc=active=0; dmc < mp->lines; dmc++) { | |
controller = (CTLR *)dptr->units[dmc].ctlr; | |
if (controller->link.TimerRunning) { | |
if (controller->link.TimeRemaining > 0) { | |
--controller->link.TimeRemaining; | |
if (controller->link.TimeRemaining > 0) | |
++active; | |
else | |
ddcmp_dispatch (controller, DDCMP_EVENT_TIMER); /* Timer Expiring Event */ | |
} | |
} | |
} | |
if (active) | |
sim_activate_after (uptr, 1000000); /* Per Second Event trigger */ | |
return SCPE_OK; | |
} | |
void dmc_buffer_queue_init(CTLR *controller, BUFFER_QUEUE *q, char *name, size_t size, BUFFER *buffers) | |
{ | |
q->name = name; | |
initqueue (&q->hdr, q, size, buffers, sizeof(*buffers)); | |
q->controller = controller; | |
} | |
t_bool dmc_transmit_queue_empty(CTLR *controller) | |
{ | |
return (controller->xmt_queue->count == 0); | |
} | |
void dmc_buffer_queue_init_all(CTLR *controller) | |
{ | |
size_t queue_size = (controller->dev_type == DMC) ? DMC_QUEUE_SIZE : | |
((controller->dev_type == DMR) ? DMR_QUEUE_SIZE : | |
DMP_QUEUE_SIZE); | |
queue_size *= 2; | |
*controller->buffers = (BUFFER *)realloc(*controller->buffers, queue_size*sizeof(**controller->buffers)); | |
memset (*controller->buffers, 0, queue_size*sizeof(**controller->buffers)); | |
dmc_buffer_queue_init(controller, controller->rcv_queue, "receive", 0, NULL); | |
dmc_buffer_queue_init(controller, controller->completion_queue, "completion", 0, NULL); | |
dmc_buffer_queue_init(controller, controller->xmt_queue, "transmit", 0, NULL); | |
dmc_buffer_queue_init(controller, controller->ack_wait_queue, "ack wait", 0, NULL); | |
dmc_buffer_queue_init(controller, controller->free_queue, "free", queue_size, *controller->buffers); | |
} | |
BUFFER *dmc_buffer_allocate(CTLR *controller) | |
{ | |
BUFFER *buffer = (BUFFER *)remqueue (controller->free_queue->hdr.next); | |
if (!buffer) { | |
sim_printf ("DDCMP Buffer allocation failure.\n"); | |
sim_printf ("This is a fatal error which should never happen.\n"); | |
sim_printf ("Please submit this output when you report this bug.\n"); | |
dmc_showqueues (stdout, controller->unit, 0, NULL); | |
dmc_showstats (stdout, controller->unit, 0, NULL); | |
dmc_showddcmp (stdout, controller->unit, 0, NULL); | |
if (sim_log) { | |
dmc_showqueues (sim_log, controller->unit, 0, NULL); | |
dmc_showstats (sim_log, controller->unit, 0, NULL); | |
dmc_showddcmp (sim_log, controller->unit, 0, NULL); | |
fflush (sim_log); | |
} | |
if (sim_deb) { | |
dmc_showqueues (sim_deb, controller->unit, 0, NULL); | |
dmc_showstats (sim_deb, controller->unit, 0, NULL); | |
dmc_showddcmp (sim_deb, controller->unit, 0, NULL); | |
fflush (sim_deb); | |
} | |
return buffer; | |
} | |
buffer->address = 0; | |
buffer->count = 0; | |
free (buffer->transfer_buffer); | |
buffer->transfer_buffer = NULL; | |
buffer->actual_bytes_transferred = 0; | |
buffer->type = TransmitControl; /* Default */ | |
buffer->buffer_return_time = 0; | |
return buffer; | |
} | |
BUFFER *dmc_buffer_queue_add(BUFFER_QUEUE *q, uint32 address, uint16 count, BufferType type) | |
{ | |
BUFFER *buffer = dmc_buffer_allocate(q->controller); | |
if (buffer) { | |
buffer->type = type; | |
buffer->address = address; | |
buffer->count = count; | |
ASSURE (insqueue (&buffer->hdr, q->hdr.prev)); /* Insert at tail */ | |
sim_debug(DBG_INF, q->controller->device, "%s%d: Queued %s buffer address=0x%08x count=%d %s\n", q->controller->device->name, q->controller->index, q->name, address, count, controller_queue_state(q->controller)); | |
} | |
else { | |
sim_debug(DBG_WRN, q->controller->device, "%s%d: Failed to queue %s buffer address=0x%08x, queue full %s\n", q->controller->device->name, q->controller->index, q->name, address, controller_queue_state(q->controller)); | |
// TODO: Report error here. | |
} | |
return buffer; | |
} | |
BUFFER *dmc_buffer_queue_head(BUFFER_QUEUE *q) | |
{ | |
return ((q->hdr.next == &q->hdr) ? NULL : (BUFFER *)q->hdr.next); | |
} | |
void dmc_queue_control_out(CTLR *controller, uint16 sel6) | |
{ | |
CONTROL_OUT *control = calloc(1, sizeof(*control)); | |
CONTROL_OUT *last = NULL; | |
control->sel6 = sel6; | |
if (controller->control_out) { | |
last = controller->control_out; | |
while (last->next) | |
last = last->next; | |
last->next = control; | |
} | |
else | |
controller->control_out = control; | |
} | |
/* returns true if some data was received */ | |
t_bool dmc_buffer_fill_receive_buffers(CTLR *controller) | |
{ | |
int ans = FALSE; | |
if (controller->state == Running) { | |
BUFFER *buffer = dmc_buffer_queue_head(controller->rcv_queue); | |
while (buffer) { | |
ddcmp_tmxr_get_packet_ln (controller->line, (const uint8 **)&controller->link.rcv_pkt, &controller->link.rcv_pkt_size, *controller->corruption_factor); | |
if (!controller->link.rcv_pkt) | |
break; | |
ans = TRUE; | |
controller->buffers_received_from_net++; | |
controller->ddcmp_control_packets_received += (controller->link.rcv_pkt[0] == DDCMP_ENQ) ? 1 : 0; | |
ddcmp_dispatch(controller, DDCMP_EVENT_PKT_RCVD); | |
buffer = dmc_buffer_queue_head(controller->rcv_queue); | |
} | |
} | |
return ans; | |
} | |
void dmc_start_transfer_buffer(CTLR *controller) | |
{ | |
BUFFER *head = dmc_buffer_queue_head(controller->completion_queue); | |
uint16 count; | |
if ((!head) || | |
(controller->transfer_state != Idle) || | |
(dmc_is_rdyo_set(controller))) | |
return; | |
count = (uint16)head->actual_bytes_transferred; | |
switch (head->type) { | |
case Receive: | |
sim_debug(DBG_INF, controller->device, "%s%d: Starting data output transfer for receive, address=0x%08x, count=%d %s\n", controller->device->name, controller->index, head->address, count, controller_queue_state(controller)); | |
dmc_set_type_output(controller, DMC_C_TYPE_RBACC); | |
break; | |
case TransmitData: | |
sim_debug(DBG_INF, controller->device, "%s%d: Starting data output transfer for transmit, address=0x%08x, count=%d %s\n", controller->device->name, controller->index, head->address, count, controller_queue_state(controller)); | |
dmc_set_type_output(controller, DMC_C_TYPE_XBACC); | |
break; | |
default: | |
break; | |
} | |
dmc_set_addr(controller, head->address); | |
dmc_set_count(controller, count); | |
controller->transfer_state = OutputTransfer; | |
dmc_set_rdyo(controller); | |
} | |
void dmc_check_for_output_transfer_completion(CTLR *controller) | |
{ | |
BUFFER *buffer; | |
if ((dmc_is_rdyo_set(controller)) || | |
(controller->transfer_state != OutputTransfer)) | |
return; | |
sim_debug(DBG_INF, controller->device, "%s%d: Output transfer completed %s\n", controller->device->name, controller->index, controller_queue_state(controller)); | |
buffer = (BUFFER *)remqueue (controller->completion_queue->hdr.next); | |
ASSURE (insqueue (&buffer->hdr, controller->free_queue->hdr.prev)); | |
controller->transmit_buffer_output_transfers_completed++; | |
controller->transfer_state = Idle; | |
dmc_process_command(controller); // check for any other transfers | |
} | |
void dmc_check_for_output_control_completion(CTLR *controller) | |
{ | |
CONTROL_OUT *control = controller->control_out; | |
if ((dmc_is_rdyo_set(controller)) || | |
(controller->transfer_state != OutputControl)) | |
return; | |
dmc_dumpregsel6(controller, DBG_INF, "Output command completed:", control->sel6); | |
controller->transfer_state = Idle; | |
controller->control_out = control->next; | |
free(control); | |
controller->control_out_operations_completed++; | |
dmc_process_command(controller); // check for any other transfers | |
} | |
void dmc_process_input_transfer_completion(CTLR *controller) | |
{ | |
if (dmc_is_dmc(controller)) { | |
if (dmc_is_run_set(controller) && | |
(!dmc_is_rqi_set(controller))) { | |
/* Time to decode input command arguments */ | |
uint16 sel6 = *controller->csrs->sel6; | |
uint32 addr = dmc_get_addr(controller); | |
uint16 count = dmc_get_count(controller); | |
controller->transfer_type = dmc_get_input_transfer_type(controller); | |
dmc_clear_rdyi(controller); | |
switch (controller->transfer_type) { | |
case DMC_C_TYPE_BASEIN: | |
*controller->baseaddr = dmc_get_addr(controller); | |
*controller->basesize = dmc_get_count(controller); | |
sim_debug(DBG_INF, controller->device, "%s%d: Completing Base In input transfer, base address=0x%08x count=%d\n", controller->device->name, controller->index, *controller->baseaddr, *controller->basesize); | |
break; | |
case DMC_C_TYPE_XBACC: | |
if (1) { | |
BUFFER *buffer = dmc_buffer_queue_add(controller->xmt_queue, addr, count, TransmitData); | |
int n; | |
/* construct buffer - leaving room for DDCMP header and CRCs */ | |
buffer->transfer_buffer = (uint8 *)realloc (buffer->transfer_buffer, buffer->count + DDCMP_HEADER_SIZE + DDCMP_CRC_SIZE); | |
memset (buffer->transfer_buffer, 0, DDCMP_HEADER_SIZE); | |
n = Map_ReadB (buffer->address, buffer->count, buffer->transfer_buffer + DDCMP_HEADER_SIZE); | |
if (n > 0) { | |
sim_debug(DBG_WRN, controller->device, "%s%d: DMA error\n", controller->device->name, controller->index); | |
} | |
buffer->count += DDCMP_HEADER_SIZE + DDCMP_CRC_SIZE; | |
controller->transmit_buffer_input_transfers_completed++; | |
} | |
if (controller->state != Running) { | |
controller->state = Running; | |
dmc_set_modem_dtr (controller); | |
} | |
ddcmp_dispatch (controller, 0); | |
break; | |
case DMC_C_TYPE_RBACC: | |
dmc_buffer_queue_add(controller->rcv_queue, addr, count, Receive); | |
dmc_buffer_fill_receive_buffers(controller); | |
controller->receive_buffer_input_transfers_completed++; | |
ddcmp_dispatch (controller, 0); | |
break; | |
case DMC_C_TYPE_CNTL: | |
sim_debug(DBG_INF, controller->device, "%s%d: Control In Command Received(%s MODE%s%s)\n", | |
controller->device->name, controller->index, | |
(sel6&DMC_SEL6_M_MAINT) ? "MAINTENANCE" : "DDCMP", | |
(sel6&DMC_SEL6_M_HDX) ? ", Half Duples" : "", | |
(sel6&DMC_SEL6_M_LONGSTRT) ? ", Long Start Timer" : ""); | |
dmc_set_modem_dtr (controller); | |
controller->transfer_state = Idle; | |
ddcmp_dispatch (controller, (sel6&DMC_SEL6_M_MAINT) ? DDCMP_EVENT_MAINTMODE : 0); | |
return; | |
case DMC_C_TYPE_HALT: | |
sim_debug(DBG_INF, controller->device, "%s%d: Halt Command Received\n", controller->device->name, controller->index); | |
controller->state = Halted; | |
ddcmp_dispatch(controller, 0); | |
dmc_clr_modem_dtr(controller); | |
dmc_queue_control_out(controller, DMC_SEL6_M_HALTCOMP); | |
return; | |
} | |
controller->transfer_state = Idle; | |
dmc_process_command (controller); | |
} | |
} | |
else { /* DMP */ | |
if (!dmc_is_rdyi_set(controller)) { | |
uint16 sel6 = *controller->csrs->sel6; | |
if (controller->transfer_type == DMP_C_TYPE_MODE) { | |
uint16 mode = sel6 & DMP_TYPE_INPUT_MASK; | |
char * duplex = (mode & 1) ? "Full-Duplex" : "Half-Duplex"; | |
char * config; | |
if (mode & 4) | |
config = "Point-to-point"; | |
else | |
config = (mode & 2) ? "Tributary station" : "Control Station"; | |
sim_debug(DBG_INF, controller->device, "%s%d: Completing Mode input transfer, %s %s\n", controller->device->name, controller->index, duplex, config); | |
} | |
else | |
if (controller->transfer_type == DMP_C_TYPE_CNTL) { | |
sim_debug(DBG_WRN, controller->device, "%s%d: Control command (not processed yet)\n", controller->device->name, controller->index); | |
} | |
else | |
if (controller->transfer_type == DMP_C_TYPE_RBACC) { | |
sim_debug(DBG_WRN, controller->device, "%s%d: Receive Buffer command (not processed yet)\n", controller->device->name, controller->index); | |
} | |
else | |
if (controller->transfer_type == DMP_C_TYPE_XBACC) { | |
sim_debug(DBG_WRN, controller->device, "%s%d: Transmit Buffer command (not processed yet)\n", controller->device->name, controller->index); | |
} | |
else { | |
sim_debug(DBG_WRN, controller->device, "%s%d: Unrecognised command code %hu\n", controller->device->name, controller->index, controller->transfer_type); | |
} | |
controller->transfer_state = Idle; | |
} | |
} | |
} | |
typedef enum { | |
EQ, | |
NE, | |
LT, | |
LE, | |
GT, | |
GE | |
} CompareOP; | |
/* DDCMP Modulo 256 compare - from Rob Jarratt */ | |
static int Mod256Cmp(uint8 a, uint8 b, size_t queue_size) | |
{ | |
int ans; | |
int abdiff = (int)b - (int)a; | |
int badiff = (int)a - (int)b; | |
if (abdiff == 0) | |
ans = 0; | |
else | |
if (abdiff < 0) | |
ans = -1; | |
else | |
ans = 1; | |
if (abs(badiff) <= (int)queue_size) | |
ans = -1 * ans; | |
return ans; | |
} | |
t_bool ddcmp_compare (uint8 a, CompareOP Op, uint8 b, CTLR *controller) | |
{ | |
int cmp = Mod256Cmp(a & 0xFF, b & 0xFF, controller->free_queue->size); | |
switch (Op) { | |
case EQ: | |
return (cmp == 0); | |
case NE: | |
return (cmp != 0); | |
case LE: | |
if (cmp == 0) | |
return TRUE; | |
case LT: | |
return (cmp < 0); | |
case GE: | |
if (cmp == 0) | |
return TRUE; | |
case GT: | |
return (cmp > 0); | |
default: /* Never happens */ | |
return FALSE; | |
} | |
} | |
void ddcmp_StartTimer (CTLR *controller) | |
{ | |
controller->link.TimerRunning = TRUE; | |
controller->link.TimeRemaining = DDCMP_PACKET_TIMEOUT; | |
sim_activate_after (controller->device->units+(controller->device->numunits-1), controller->link.TimeRemaining*1000000); | |
} | |
void ddcmp_StopTimer (CTLR *controller) | |
{ | |
controller->link.TimerRunning = FALSE; | |
} | |
void ddcmp_ResetVariables (CTLR *controller) | |
{ | |
size_t data_packets = 0; | |
BUFFER *buffer; | |
controller->link.R = 0; | |
controller->link.N = 0; | |
controller->link.A = 0; | |
controller->link.T = 1; | |
controller->link.X = 0; | |
controller->link.SACK = FALSE; | |
controller->link.SNAK = FALSE; | |
controller->link.SREP = FALSE; | |
controller->link.state = Halt; | |
controller->link.nak_reason = 0; | |
/* Move any ack wait packets back to the transmit queue so they get | |
resent when the link is restored */ | |
while (controller->ack_wait_queue->count) { | |
buffer = (BUFFER *)remqueue (controller->ack_wait_queue->hdr.prev); | |
memset (buffer->transfer_buffer, 0, DDCMP_HEADER_SIZE); | |
ASSURE (insqueue (&buffer->hdr, &controller->xmt_queue->hdr)); | |
} | |
/* Also make sure that the transmit queue has no control packets in it | |
and that any non transmit buffer(s) have zeroed headers so they will | |
be properly constructed when the link comes up */ | |
buffer = (BUFFER *)controller->xmt_queue->hdr.next; | |
while (controller->xmt_queue->count - data_packets) { | |
if (((BUFFER *)controller->xmt_queue->hdr.next)->transfer_buffer[0] == DDCMP_ENQ) { | |
BUFFER *buffer_next = (BUFFER *)buffer->hdr.next; | |
buffer = (BUFFER *)remqueue (&buffer->hdr); | |
ASSURE (insqueue (&buffer->hdr, &controller->free_queue->hdr)); | |
buffer = buffer_next; | |
continue; | |
} | |
++data_packets; | |
memset (buffer->transfer_buffer, 0, DDCMP_HEADER_SIZE); | |
buffer = (BUFFER *)buffer->hdr.next; | |
} | |
} | |
void ddcmp_SendStrt (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_allocate(controller); | |
buffer->transfer_buffer = (uint8 *)malloc (DDCMP_HEADER_SIZE); | |
buffer->count = DDCMP_HEADER_SIZE; | |
ddcmp_build_start_packet (buffer->transfer_buffer); | |
ASSURE (insqueue (&buffer->hdr, &controller->xmt_queue->hdr)); | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_SendStack (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_allocate(controller); | |
buffer->transfer_buffer = (uint8 *)malloc (DDCMP_HEADER_SIZE); | |
buffer->count = DDCMP_HEADER_SIZE; | |
ddcmp_build_start_ack_packet (buffer->transfer_buffer); | |
ASSURE (insqueue (&buffer->hdr, &controller->xmt_queue->hdr)); | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_SendAck (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_allocate(controller); | |
buffer->transfer_buffer = (uint8 *)malloc (DDCMP_HEADER_SIZE); | |
buffer->count = DDCMP_HEADER_SIZE; | |
ddcmp_build_ack_packet (buffer->transfer_buffer, controller->link.R, DDCMP_FLAG_SELECT); | |
ASSURE (insqueue (&buffer->hdr, &controller->xmt_queue->hdr)); | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_SendNak (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_allocate(controller); | |
buffer->transfer_buffer = (uint8 *)malloc (DDCMP_HEADER_SIZE); | |
buffer->count = DDCMP_HEADER_SIZE; | |
ddcmp_build_nak_packet (buffer->transfer_buffer, controller->link.nak_reason, controller->link.R, DDCMP_FLAG_SELECT); | |
ASSURE (insqueue (&buffer->hdr, &controller->xmt_queue->hdr)); | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_SendRep (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_allocate(controller); | |
buffer->transfer_buffer = (uint8 *)malloc (DDCMP_HEADER_SIZE); | |
buffer->count = DDCMP_HEADER_SIZE; | |
ddcmp_build_rep_packet (buffer->transfer_buffer, controller->link.N, DDCMP_FLAG_SELECT); | |
ASSURE (insqueue (&buffer->hdr, &controller->xmt_queue->hdr)); | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_SetSACK (CTLR *controller) | |
{ | |
controller->link.SACK = TRUE; | |
} | |
void ddcmp_ClearSACK (CTLR *controller) | |
{ | |
controller->link.SACK = FALSE; | |
} | |
void ddcmp_SetSNAK (CTLR *controller) | |
{ | |
controller->link.SNAK = TRUE; | |
} | |
void ddcmp_ClearSNAK (CTLR *controller) | |
{ | |
controller->link.SNAK = FALSE; | |
} | |
void ddcmp_SetSREP (CTLR *controller) | |
{ | |
controller->link.SREP = TRUE; | |
} | |
void ddcmp_ClearSREP (CTLR *controller) | |
{ | |
controller->link.SREP = FALSE; | |
} | |
void ddcmp_IncrementR (CTLR *controller) | |
{ | |
controller->link.R++; | |
} | |
void ddcmp_SetAeqRESP (CTLR *controller) | |
{ | |
controller->link.A = controller->link.rcv_pkt[DDCMP_RESP_OFFSET]; | |
} | |
void ddcmp_SetTequalAplus1 (CTLR *controller) | |
{ | |
controller->link.T = controller->link.A + 1; | |
} | |
void ddcmp_IncrementT (CTLR *controller) | |
{ | |
controller->link.T++; | |
} | |
void ddcmp_SetNAKreason3 (CTLR *controller) | |
{ | |
controller->link.nak_reason = 3; | |
} | |
void ddcmp_SetNAKReasonCRCError (CTLR *controller) | |
{ | |
controller->link.nak_reason = controller->link.nak_crc_reason; | |
} | |
void ddcmp_NAKMissingPacket (CTLR *controller) | |
{ | |
uint8 R = controller->link.R; | |
QH *qh = &controller->xmt_queue->hdr; | |
while (ddcmp_compare (controller->link.rcv_pkt[DDCMP_NUM_OFFSET], GE, R, controller)) { | |
BUFFER *buffer = dmc_buffer_allocate(controller); | |
if (NULL == buffer) { | |
sim_debug(DBG_INF, controller->device, "%s%d: No Buffers cause NAKMissingPackets to stop %s\n", controller->device->name, controller->index, controller_queue_state(controller)); | |
break; | |
} | |
if (ddcmp_compare (controller->link.rcv_pkt[DDCMP_NUM_OFFSET], GE, controller->link.NAKed, controller)) { | |
sim_debug(DBG_INF, controller->device, "%s%d: NAK for prior missing packet %d already sent, still waiting %s\n", controller->device->name, controller->index, controller->link.NAKed, controller_queue_state(controller)); | |
ASSURE (insqueue (&buffer->hdr, &controller->free_queue->hdr)); /* Release buffer */ | |
break; | |
} | |
buffer->transfer_buffer = (uint8 *)malloc (DDCMP_HEADER_SIZE); | |
buffer->count = DDCMP_HEADER_SIZE; | |
ddcmp_build_nak_packet (buffer->transfer_buffer, 2, R, DDCMP_FLAG_SELECT); | |
controller->link.NAKed = R; | |
R = R + 1; | |
ASSURE (insqueue (&buffer->hdr, qh)); | |
qh = &buffer->hdr; | |
break; /* Only generate a single NAK */ | |
} | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_IfTleAthenSetTeqAplus1 (CTLR *controller) | |
{ | |
if (ddcmp_compare (controller->link.T, LE, controller->link.A, controller)) | |
controller->link.T = controller->link.A + 1; | |
} | |
void ddcmp_IfAltXthenStartTimer (CTLR *controller) | |
{ | |
if (ddcmp_compare (controller->link.A, LT, controller->link.X, controller)) | |
ddcmp_StartTimer (controller); | |
} | |
void ddcmp_IfAgeXthenStopTimer (CTLR *controller) | |
{ | |
if (ddcmp_compare (controller->link.A, GE, controller->link.X, controller)) | |
ddcmp_StopTimer (controller); | |
} | |
void ddcmp_Ignore (CTLR *controller) | |
{ | |
} | |
void ddcmp_GiveBufferToUser (CTLR *controller) | |
{ | |
BUFFER *buffer = (BUFFER *)remqueue (controller->rcv_queue->hdr.next); | |
if (!buffer) { | |
ddcmp_SetSNAK (controller); | |
controller->link.nak_reason = 8; /* buffer temporarily unavailable */ | |
return; | |
} | |
buffer->actual_bytes_transferred = controller->link.rcv_pkt_size - (DDCMP_HEADER_SIZE + DDCMP_CRC_SIZE); | |
Map_WriteB(buffer->address, buffer->actual_bytes_transferred, controller->link.rcv_pkt + DDCMP_HEADER_SIZE); | |
ASSURE (insqueue (&buffer->hdr, controller->completion_queue->hdr.prev)); /* Insert at tail */ | |
ddcmp_IncrementR (controller); | |
ddcmp_SetSACK (controller); | |
} | |
void ddcmp_CompleteAckedTransmits (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_queue_head(controller->ack_wait_queue); | |
while (buffer != NULL) { | |
if ((!buffer->transfer_buffer) || | |
(!controller->link.rcv_pkt) || | |
ddcmp_compare (buffer->transfer_buffer[DDCMP_NUM_OFFSET], GT, controller->link.rcv_pkt[DDCMP_RESP_OFFSET], controller)) | |
break; | |
buffer = (BUFFER *)remqueue (&buffer->hdr); | |
ASSURE (insqueue (&buffer->hdr, controller->completion_queue->hdr.prev)); /* Insert at tail */ | |
buffer = dmc_buffer_queue_head(controller->ack_wait_queue); | |
} | |
} | |
void ddcmp_ReTransmitMessageT (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_queue_head(controller->ack_wait_queue); | |
size_t i; | |
uint8 T = controller->link.T; | |
for (i=0; i < controller->ack_wait_queue->count; ++i) { | |
if ((!buffer->transfer_buffer) || | |
ddcmp_compare (buffer->transfer_buffer[DDCMP_NUM_OFFSET], NE, T, controller)) { | |
buffer = (BUFFER *)buffer->hdr.next; | |
continue; | |
} | |
ddcmp_build_data_packet (buffer->transfer_buffer, buffer->count - (DDCMP_HEADER_SIZE + DDCMP_CRC_SIZE), DDCMP_FLAG_SELECT|DDCMP_FLAG_QSYNC, T, controller->link.R); | |
buffer = (BUFFER *)remqueue (&buffer->hdr); | |
ASSURE (insqueue (&buffer->hdr, controller->xmt_queue->hdr.prev)); /* Insert at tail */ | |
break; | |
} | |
} | |
void ddcmp_NotifyDisconnect (CTLR *controller) | |
{ | |
dmc_queue_control_out(controller, DMC_SEL6_M_DISCONN); | |
} | |
void ddcmp_NotifyStartRcvd (CTLR *controller) | |
{ | |
dmc_queue_control_out(controller, DMC_SEL6_M_STRTRCVD); | |
} | |
void ddcmp_NotifyMaintRcvd (CTLR *controller) | |
{ | |
dmc_queue_control_out(controller, DMC_SEL6_M_MAINTRCV); | |
} | |
void ddcmp_SendDataMessage (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_queue_head(controller->xmt_queue); | |
ddcmp_build_data_packet (buffer->transfer_buffer, buffer->count - (DDCMP_HEADER_SIZE + DDCMP_CRC_SIZE), DDCMP_FLAG_SELECT|DDCMP_FLAG_QSYNC, controller->link.N + 1, controller->link.R); | |
controller->link.N += 1; | |
controller->link.T = controller->link.N + 1; | |
controller->link.SACK = 0; | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_SendMaintMessage (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_queue_head(controller->xmt_queue); | |
ddcmp_build_maintenance_packet (buffer->transfer_buffer, buffer->count - (DDCMP_HEADER_SIZE + DDCMP_CRC_SIZE)); | |
dmc_ddcmp_start_transmitter (controller); | |
} | |
void ddcmp_SetXSetNUM (CTLR *controller) | |
{ | |
controller->link.X = controller->link.xmt_done_buffer->transfer_buffer[DDCMP_NUM_OFFSET]; | |
} | |
/* Conditions/Events */ | |
t_bool ddcmp_UserHalt (CTLR *controller) | |
{ | |
return (controller->state == Halted); | |
} | |
t_bool ddcmp_UserStartup (CTLR *controller) | |
{ | |
return (*controller->modem & DMC_SEL4_M_DTR); | |
} | |
t_bool ddcmp_UserMaintenanceMode (CTLR *controller) | |
{ | |
return (controller->link.ScanningEvents & DDCMP_EVENT_MAINTMODE); | |
} | |
t_bool ddcmp_ReceiveStack (CTLR *controller) | |
{ | |
return ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_ENQ) && | |
(controller->link.rcv_pkt[1] == DDCMP_CTL_STACK) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
} | |
t_bool ddcmp_ReceiveStrt (CTLR *controller) | |
{ | |
return ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_ENQ) && | |
(controller->link.rcv_pkt[1] == DDCMP_CTL_STRT) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
} | |
t_bool ddcmp_TimerRunning (CTLR *controller) | |
{ | |
return (controller->link.TimerRunning); | |
} | |
t_bool ddcmp_TimerNotRunning (CTLR *controller) | |
{ | |
return (!controller->link.TimerRunning); | |
} | |
t_bool ddcmp_TimerExpired (CTLR *controller) | |
{ | |
return (controller->link.ScanningEvents & DDCMP_EVENT_TIMER); | |
} | |
t_bool ddcmp_ReceiveMaintMessage (CTLR *controller) | |
{ | |
return ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_DLE) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
} | |
t_bool ddcmp_ReceiveAck (CTLR *controller) | |
{ | |
return ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_ENQ) && | |
(controller->link.rcv_pkt[1] == DDCMP_CTL_ACK) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
} | |
t_bool ddcmp_ReceiveNak (CTLR *controller) | |
{ | |
return ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_ENQ) && | |
(controller->link.rcv_pkt[1] == DDCMP_CTL_NAK) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
} | |
t_bool ddcmp_ReceiveRep (CTLR *controller) | |
{ | |
return ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_ENQ) && | |
(controller->link.rcv_pkt[1] == DDCMP_CTL_REP) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
} | |
t_bool ddcmp_NUMEqRplus1 (CTLR *controller) | |
{ | |
t_bool breturn = (controller->link.rcv_pkt && | |
ddcmp_compare (controller->link.rcv_pkt[DDCMP_NUM_OFFSET], EQ, controller->link.R + 1, controller)); | |
return breturn; | |
} | |
t_bool ddcmp_NUMGtRplus1 (CTLR *controller) | |
{ | |
t_bool breturn = (controller->link.rcv_pkt && | |
ddcmp_compare (controller->link.rcv_pkt[DDCMP_NUM_OFFSET], GT, controller->link.R + 1, controller)); | |
return breturn; | |
} | |
t_bool ddcmp_ReceiveDataMsg (CTLR *controller) | |
{ | |
t_bool breturn = ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_SOH) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
if (breturn) | |
return breturn; | |
return breturn; | |
} | |
t_bool ddcmp_ReceiveMaintMsg (CTLR *controller) | |
{ | |
t_bool breturn = ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && | |
controller->link.rcv_pkt && | |
(controller->link.rcv_pkt[0] == DDCMP_DLE) && | |
(!ddcmp_ReceiveMessageError(controller))); | |
if (breturn) | |
return breturn; | |
return breturn; | |
} | |
t_bool ddcmp_ALtRESPleN (CTLR *controller) | |
{ | |
return (controller->link.rcv_pkt && | |
ddcmp_compare (controller->link.A, LT, controller->link.rcv_pkt[DDCMP_RESP_OFFSET], controller) && | |
ddcmp_compare (controller->link.rcv_pkt[DDCMP_RESP_OFFSET], LE, controller->link.N, controller)); | |
} | |
t_bool ddcmp_ALeRESPleN (CTLR *controller) | |
{ | |
return (controller->link.rcv_pkt && | |
ddcmp_compare (controller->link.A, LE, controller->link.rcv_pkt[DDCMP_RESP_OFFSET], controller) && | |
ddcmp_compare (controller->link.rcv_pkt[DDCMP_RESP_OFFSET], LE, controller->link.N, controller)); | |
} | |
t_bool ddcmp_RESPleAOrRESPgtN (CTLR *controller) | |
{ | |
return (controller->link.rcv_pkt && | |
(ddcmp_compare (controller->link.rcv_pkt[DDCMP_RESP_OFFSET], LE, controller->link.A, controller) || | |
ddcmp_compare (controller->link.rcv_pkt[DDCMP_RESP_OFFSET], GT, controller->link.N, controller))); | |
} | |
t_bool ddcmp_TltNplus1 (CTLR *controller) | |
{ | |
return (ddcmp_compare (controller->link.T, LT, controller->link.N + 1, controller)); | |
} | |
t_bool ddcmp_TeqNplus1 (CTLR *controller) | |
{ | |
return (ddcmp_compare (controller->link.T, EQ, controller->link.N + 1, controller)); | |
} | |
t_bool ddcmp_ReceiveMessageError (CTLR *controller) | |
{ | |
if ((controller->link.ScanningEvents & DDCMP_EVENT_PKT_RCVD) && controller->link.rcv_pkt) { | |
if (0 != ddcmp_crc16 (0, controller->link.rcv_pkt, 8)) { | |
controller->link.nak_crc_reason = 1; /* Header CRC Error */ | |
return TRUE; | |
} | |
if ((controller->link.rcv_pkt[0] != DDCMP_ENQ) && | |
(0 != ddcmp_crc16 (0, controller->link.rcv_pkt+8, controller->link.rcv_pkt_size-8))) { | |
controller->link.nak_crc_reason = 2; /* Data CRC Error */ | |
return TRUE; | |
} | |
controller->link.nak_crc_reason = 0; /* No CRC Error */ | |
} | |
return FALSE; | |
} | |
t_bool ddcmp_NumEqR (CTLR *controller) | |
{ | |
return (controller->link.rcv_pkt && | |
ddcmp_compare (controller->link.rcv_pkt[DDCMP_NUM_OFFSET], EQ, controller->link.R, controller)); | |
} | |
t_bool ddcmp_NumNeR (CTLR *controller) | |
{ | |
return (controller->link.rcv_pkt && | |
ddcmp_compare (controller->link.rcv_pkt[DDCMP_NUM_OFFSET], NE, controller->link.R, controller)); | |
} | |
t_bool ddcmp_TransmitterIdle (CTLR *controller) | |
{ | |
return (NULL == controller->link.xmt_buffer); | |
} | |
t_bool ddcmp_TramsmitterBusy (CTLR *controller) | |
{ | |
return !ddcmp_TransmitterIdle(controller); | |
} | |
t_bool ddcmp_SACKisSet (CTLR *controller) | |
{ | |
return (controller->link.SACK); | |
} | |
t_bool ddcmp_SACKisClear (CTLR *controller) | |
{ | |
return (!(controller->link.SACK)); | |
} | |
t_bool ddcmp_SNAKisSet (CTLR *controller) | |
{ | |
return (controller->link.SNAK); | |
} | |
t_bool ddcmp_SNAKisClear (CTLR *controller) | |
{ | |
return (!(controller->link.SNAK)); | |
} | |
t_bool ddcmp_SREPisSet (CTLR *controller) | |
{ | |
return (controller->link.SREP); | |
} | |
t_bool ddcmp_SREPisClear (CTLR *controller) | |
{ | |
return (!(controller->link.SREP)); | |
} | |
t_bool ddcmp_UserSendMessage (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_queue_head(controller->xmt_queue); | |
return (buffer && (buffer->transfer_buffer[0] == 0)); | |
} | |
t_bool ddcmp_LineConnected (CTLR *controller) | |
{ | |
return (*controller->modem & DMC_SEL4_M_CAR); | |
} | |
t_bool ddcmp_LineDisconnected (CTLR *controller) | |
{ | |
return (!(*controller->modem & DMC_SEL4_M_CAR)); | |
} | |
t_bool ddcmp_DataMessageSent (CTLR *controller) | |
{ | |
t_bool breturn = ((controller->link.ScanningEvents & DDCMP_EVENT_XMIT_DONE) && | |
controller->link.xmt_done_buffer && | |
(controller->link.xmt_done_buffer->transfer_buffer[0] == DDCMP_SOH)); | |
if (breturn) | |
return breturn; | |
return breturn; | |
} | |
t_bool ddcmp_REPMessageSent (CTLR *controller) | |
{ | |
return ((controller->link.ScanningEvents & DDCMP_EVENT_XMIT_DONE) && | |
controller->link.xmt_done_buffer && | |
(controller->link.xmt_done_buffer->transfer_buffer[0] == DDCMP_ENQ) && | |
(controller->link.xmt_done_buffer->transfer_buffer[1] == DDCMP_CTL_REP)); | |
} | |
void ddcmp_dispatch(CTLR *controller, uint32 EventMask) | |
{ | |
DDCMP_STATETABLE *table; | |
int matched = 0; | |
static const char *states[] = {"Halt", "IStart", "AStart", "Run", "Maintenance"}; | |
if (controller->link.Scanning) { | |
if (!controller->link.RecurseScan) { | |
controller->link.RecurseScan = TRUE; | |
controller->link.RecurseEventMask |= EventMask; | |
} | |
return; | |
} | |
controller->link.Scanning = TRUE; | |
controller->link.ScanningEvents |= EventMask; | |
for (table=DDCMP_TABLE; table->Conditions[0] != NULL; ++table) { | |
if ((table->State == controller->link.state) || | |
(table->State == All)) { | |
t_bool match = TRUE; | |
DDCMP_Condition_Routine *cond = table->Conditions; | |
DDCMP_LinkAction_Routine *action = table->Actions; | |
while (match && *cond != NULL) { | |
match = (*cond)(controller); | |
++cond; | |
} | |
if (!match) | |
continue; | |
++matched; | |
sim_debug (DBG_INF, controller->device, "%s%d: ddcmp_dispatch(%X) - %s conditions matching for rule %2d(%s)%s,\n" | |
" initiating actions (%s)\n", controller->device->name, controller->index, EventMask, states[table->State], table->RuleNumber, ddcmp_conditions(table->Conditions), ddcmp_link_state(&controller->link), ddcmp_actions(table->Actions)); | |
while (*action != NULL) { | |
(*action)(controller); | |
++action; | |
} | |
if (table->NewState != controller->link.state) { | |
sim_debug (DBG_INF, controller->device, "%s%d: ddcmp_dispatch(%X) - state changing from %s to %s\n", controller->device->name, controller->index, EventMask, states[controller->link.state], states[table->NewState]); | |
controller->link.state = table->NewState; | |
} | |
} | |
} | |
if (matched) { | |
sim_debug (DBG_INF, controller->device, "%s%d: ddcmp_dispatch(%X) - queues: %s\n", controller->device->name, controller->index, EventMask, controller_queue_state(controller)); | |
} | |
controller->link.Scanning = FALSE; | |
controller->link.ScanningEvents &= ~EventMask; | |
if (controller->link.RecurseScan) { | |
controller->link.RecurseScan = FALSE; | |
EventMask = controller->link.RecurseEventMask; | |
controller->link.RecurseEventMask = 0; | |
ddcmp_dispatch (controller, EventMask); | |
dmc_svc (controller->unit); | |
} | |
} | |
void dmc_ddcmp_start_transmitter (CTLR *controller) | |
{ | |
BUFFER *buffer = dmc_buffer_queue_head(controller->xmt_queue); | |
t_stat r; | |
if ((controller->link.xmt_buffer) || /* if Already Transmitting */ | |
(!buffer) || /* or nothing pending */ | |
(!controller->line->conn)) /* or not connected */ | |
return; /* Do nothing */ | |
while (buffer) { | |
if (buffer->transfer_buffer[0] == 0) | |
return; | |
if ((controller->link.state != Maintenance) && (buffer->transfer_buffer[DDCMP_RESP_OFFSET] != controller->link.R)) { | |
sim_debug(DBG_INF, controller->device, "%s%d: Packet RESP fixup from %d to %d %s\n", controller->device->name, controller->index, buffer->transfer_buffer[DDCMP_RESP_OFFSET], controller->link.R, controller_queue_state(controller)); | |
buffer->transfer_buffer[DDCMP_RESP_OFFSET] = controller->link.R; /* Make sure that ACK or implied ACK is always up to date */ | |
} | |
/* Need to make sure we dynamically compute the packet CRCs since header details can change */ | |
r = ddcmp_tmxr_put_packet_crc_ln (controller->line, buffer->transfer_buffer, buffer->count, *controller->corruption_factor); | |
if (r == SCPE_OK) { | |
controller->link.xmt_buffer = buffer; | |
controller->ddcmp_control_packets_sent += (buffer->transfer_buffer[0] == DDCMP_ENQ) ? 1 : 0; | |
if (controller->byte_wait) { /* Speed limited? */ | |
buffer->buffer_return_time = buffer->count*controller->byte_wait + sim_grtime(); | |
sim_activate (controller->unit, buffer->count*controller->byte_wait); | |
break; | |
} | |
dmc_complete_transmit (controller); | |
buffer = dmc_buffer_queue_head(controller->xmt_queue); | |
continue; | |
} | |
break; | |
} | |
} | |
void dmc_process_command(CTLR *controller) | |
{ | |
if (dmc_is_master_clear_set(controller)) { | |
dmc_process_master_clear(controller); | |
return; | |
} | |
if (controller->transfer_state == InputTransfer) { | |
dmc_process_input_transfer_completion(controller); | |
return; | |
} | |
if (controller->transfer_state == OutputTransfer) { | |
dmc_check_for_output_transfer_completion(controller); | |
return; | |
} | |
if (controller->transfer_state == OutputControl) { | |
dmc_check_for_output_control_completion(controller); | |
return; | |
} | |
/* transfer_state Idle */ | |
if (dmc_is_rqi_set(controller)) { | |
dmc_start_input_transfer(controller); | |
return; | |
} | |
if (dmc_is_dmc (controller) && | |
(*controller->csrs->sel0 & DMC_SEL0_M_ROMI) && | |
(!dmc_is_run_set(controller)) && | |
(*controller->csrs->sel0 & DMC_SEL0_M_STEPUP)) { | |
/* DMC-11 or DMR-11, with RUN off and step and ROMI bits set. */ | |
switch (*controller->csrs->sel6) { | |
case DSPDSR: /* 0x22b3 (read line status instruction), set the DTR bit in SEL2. */ | |
dmc_setreg (controller, 2, 0x800, DBG_RGC); | |
break; | |
case DROPDTR: /* 0xa40b (drop DTR instruction) - VMS Driver uses this */ | |
dmc_clr_modem_dtr (controller); | |
break; | |
case UINST_CNF: /* 0x2296 (get configuration switches) - VMS Driver uses this */ | |
dmc_setreg (controller, 6, 0x0006, DBG_RGC); | |
break; | |
case UINST_RROM:/* 0x814d (read DMC ROM) - VMS Driver uses this */ | |
dmc_setreg (controller, 6, 0x0391, DBG_RGC); /* Not Low Speed uCode value (0x390) */ | |
break; | |
default: | |
sim_debug(DBG_WRN, controller->device, "%s%d: dmc_process_command(). Unknown Microcode instruction 0x%04x", controller->device->name, controller->index, *controller->csrs->sel6); | |
break; | |
} | |
*controller->csrs->sel0 &= ~DMC_SEL0_M_STEPUP; | |
controller->transfer_state = Idle; | |
} | |
else { | |
if (dmc_is_run_set(controller)) { | |
dmc_start_control_output_transfer(controller); | |
dmc_start_transfer_buffer(controller); | |
} | |
} | |
if (tmxr_get_line_loopback (controller->line) ^ dmc_is_lu_loop_set (controller)) { | |
sim_debug(DBG_INF, controller->device, "%s%d: %s loopback mode\n", controller->device->name, controller->index, dmc_is_lu_loop_set (controller) ? "Enabling" : "Disabling"); | |
tmxr_set_line_loopback (controller->line, dmc_is_lu_loop_set (controller)); | |
} | |
} | |
t_stat dmc_rd(int32 *data, int32 PA, int32 access) | |
{ | |
CTLR *controller = dmc_get_controller_from_address(PA); | |
int reg = PA & ((UNIBUS) ? 07 : 017); | |
*data = dmc_getreg(controller, PA, DBG_REG); | |
if (access == READ) { | |
sim_debug(DBG_REG, controller->device, "dmc_rd(%s%d), addr=0x%08x, SEL%d, data=0x%04x\n", controller->device->name, controller->index, PA, reg, *data); | |
} | |
else { | |
sim_debug(DBG_REG, controller->device, "dmc_rd(%s%d), addr=0x%08x, BSEL%d, data=%02x\n", controller->device->name, controller->index, PA, reg, *data & 0xFF); | |
} | |
return SCPE_OK; | |
} | |
t_stat dmc_wr(int32 data, int32 PA, int32 access) | |
{ | |
CTLR *controller = dmc_get_controller_from_address(PA); | |
int reg = PA & ((UNIBUS) ? 07 : 017); | |
uint16 oldValue = dmc_getreg(controller, PA, 0); | |
if (access == WRITE) { | |
sim_debug(DBG_REG, controller->device, "dmc_wr(%s%d), addr=0x%08x, SEL%d, newdata=0x%04x, olddata=0x%04x\n", controller->device->name, controller->index, PA, reg, data, oldValue); | |
} | |
else { | |
sim_debug(DBG_REG, controller->device, "dmc_wr(%s%d), addr=0x%08x, BSEL%d, newdata=%02x, olddata=0x%02x\n", controller->device->name, controller->index, PA, reg, data & 0xFF, ((PA&1) ? oldValue>>8 : oldValue) & 0xFF); | |
} | |
if (access == WRITE) { | |
if (PA & 1) { | |
sim_debug(DBG_WRN, controller->device, "dmc_wr(%s%d), Unexpected non-16-bit write access to SEL%d\n", controller->device->name, controller->index, reg); | |
} | |
dmc_setreg(controller, PA, (uint16)data, DBG_REG); | |
} | |
else { | |
uint16 mask; | |
if (PA & 1) { | |
mask = 0xFF00; | |
data = data << 8; | |
} | |
else { | |
mask = 0x00FF; | |
} | |
dmc_setreg(controller, PA, (oldValue & ~mask) | (data & mask), DBG_REG); | |
} | |
if ((dmc_getsel(reg) == 0) || (dmc_getsel(reg) == 1)) {/* writes to SEL0 and SEL2 are actionable */ | |
if (0 == controller->dmc_wr_delay) { /* Not waiting? */ | |
controller->dmc_wr_delay = 10; /* Wait a bit before acting on the changed register */ | |
sim_activate_abs (controller->unit, controller->dmc_wr_delay); | |
} | |
} | |
return SCPE_OK; | |
} | |
int32 dmc_ininta (void) | |
{ | |
int i; | |
int32 ans = 0; /* no interrupt request active */ | |
for (i=0; i<DMC_NUMDEVICE+DMP_NUMDEVICE; i++) { | |
CTLR *controller = &dmc_ctrls[i]; | |
if (controller->in_int != 0) { | |
DIB *dib = (DIB *)controller->device->ctxt; | |
ans = dib->vec + (8 * (int)(controller->unit - controller->device->units)); | |
dmc_clrinint(controller); | |
sim_debug(DBG_INT, controller->device, "RXINTA Device %d - Vector: 0x%x(0%3o)\n", (int)(controller->unit-controller->device->units), ans, ans); | |
break; | |
} | |
} | |
return ans; | |
} | |
int32 dmc_outinta (void) | |
{ | |
int i; | |
int32 ans = 0; /* no interrupt request active */ | |
for (i=0; i<DMC_NUMDEVICE+DMP_NUMDEVICE; i++) { | |
CTLR *controller = &dmc_ctrls[i]; | |
if (controller->out_int != 0) { | |
DIB *dib = (DIB *)controller->device->ctxt; | |
ans = dib->vec + 4 + (8 * (int)(controller->unit - controller->device->units)); | |
dmc_clroutint(controller); | |
sim_debug(DBG_INT, controller->device, "TXINTA Device %d - Vector: 0x%x(0%3o)\n", (int)(controller->unit-controller->device->units), ans, ans); | |
break; | |
} | |
} | |
return ans; | |
} | |
t_stat dmc_reset (DEVICE *dptr) | |
{ | |
t_stat ans = SCPE_OK; | |
CTLR *controller; | |
uint32 i, j; | |
sim_debug(DBG_TRC, dptr, "dmc_reset(%s)\n", dptr->name); | |
dmc_desc.packet = TRUE; | |
dmc_desc.buffered = 16384; | |
dmp_desc.packet = TRUE; | |
dmp_desc.buffered = 16384; | |
/* Connect structures together */ | |
for (i=0; i < DMC_NUMDEVICE; i++) { | |
dmc_csrs[i].sel0 = &dmc_sel0[i]; | |
dmc_csrs[i].sel2 = &dmc_sel2[i]; | |
dmc_csrs[i].sel4 = &dmc_sel4[i]; | |
dmc_csrs[i].sel6 = &dmc_sel6[i]; | |
controller = &dmc_ctrls[i]; | |
controller->csrs = &dmc_csrs[i]; | |
controller->line = &dmc_desc.ldsc[i]; | |
controller->rcv_queue = &dmc_rcv_queues[i]; | |
controller->completion_queue = &dmc_completion_queues[i]; | |
controller->xmt_queue = &dmc_xmt_queues[i]; | |
controller->ack_wait_queue = &dmc_ack_wait_queues[i]; | |
controller->free_queue = &dmc_free_queues[i]; | |
controller->buffers = &dmc_buffers[i]; | |
controller->device = &dmc_dev; | |
controller->baseaddr = &dmc_baseaddr[i]; | |
controller->basesize = &dmc_basesize[i]; | |
controller->modem = &dmc_modem[i]; | |
controller->corruption_factor = &dmc_corruption[i]; | |
controller->unit = &controller->device->units[i]; | |
controller->unit->ctlr = (void *)controller; | |
controller->index = i; | |
} | |
tmxr_connection_poll_interval (&dmc_desc, dmc_connect_poll); | |
for (i=0; i < DMP_NUMDEVICE; i++) { | |
dmp_csrs[i].sel0 = &dmp_sel0[i]; | |
dmp_csrs[i].sel2 = &dmp_sel2[i]; | |
dmp_csrs[i].sel4 = &dmp_sel4[i]; | |
dmp_csrs[i].sel6 = &dmp_sel6[i]; | |
dmp_csrs[i].sel10 = &dmp_sel10[i]; | |
controller = &dmc_ctrls[i+DMC_NUMDEVICE]; | |
controller->csrs = &dmp_csrs[i]; | |
controller->line = &dmp_desc.ldsc[i]; | |
controller->rcv_queue = &dmp_rcv_queues[i]; | |
controller->completion_queue = &dmp_completion_queues[i]; | |
controller->xmt_queue = &dmp_xmt_queues[i]; | |
controller->ack_wait_queue = &dmp_ack_wait_queues[i]; | |
controller->free_queue = &dmp_free_queues[i]; | |
controller->buffers = &dmp_buffers[i]; | |
controller->device = (UNIBUS) ? &dmp_dev : &dmv_dev; | |
controller->dev_type = DMP; | |
controller->baseaddr = &dmp_baseaddr[i]; | |
controller->basesize = &dmp_basesize[i]; | |
controller->modem = &dmp_modem[i]; | |
controller->corruption_factor = &dmp_corruption[i]; | |
controller->unit = &controller->device->units[i]; | |
controller->unit->ctlr = (void *)controller; | |
controller->index = i + DMC_NUMDEVICE; | |
} | |
tmxr_connection_poll_interval (&dmp_desc, dmp_connect_poll); | |
if (0 == dmc_units[0].flags) { /* First Time Initializations */ | |
for (i=0; i < DMC_NUMDEVICE; i++) { | |
controller = &dmc_ctrls[i]; | |
controller->state = Uninitialised; | |
controller->transfer_state = Idle; | |
controller->control_out = NULL; | |
*controller->modem = 0; | |
#if defined (VM_PDP10) | |
controller->dev_type = DMR; | |
#else | |
controller->dev_type = DMC; | |
#endif | |
dmc_dev.units[i] = dmc_unit_template; | |
controller->unit->ctlr = (void *)controller; | |
dmc_microdiag[i] = TRUE; | |
dmc_corruption[i] = 0; | |
} | |
tmxr_set_modem_control_passthru (&dmc_desc); /* We always want Modem Control */ | |
dmc_units[dmc_dev.numunits-2] = dmc_poll_unit_template; | |
dmc_units[dmc_dev.numunits-2].ctlr = dmc_units[0].ctlr; | |
dmc_units[dmc_dev.numunits-1] = dmc_timer_unit_template; | |
dmc_units[dmc_dev.numunits-1].ctlr = dmc_units[0].ctlr; | |
dmc_desc.notelnet = TRUE; /* We always want raw tcp socket */ | |
dmc_desc.dptr = &dmc_dev; /* Connect appropriate device */ | |
dmc_desc.uptr = dmc_units+dmc_desc.lines; /* Identify polling unit */ | |
for (i=0; i < DMP_NUMDEVICE; i++) { | |
controller = &dmc_ctrls[i+DMC_NUMDEVICE]; | |
controller->state = Uninitialised; | |
controller->transfer_state = Idle; | |
controller->control_out = NULL; | |
*controller->modem = 0; | |
dmp_dev.units[i] = dmc_unit_template; | |
controller->unit->ctlr = (void *)controller; | |
dmp_corruption[i] = 0; | |
} | |
tmxr_set_modem_control_passthru (&dmp_desc); /* We always want Modem Control */ | |
dmp_units[dmp_dev.numunits-2] = dmc_poll_unit_template; | |
dmp_units[dmp_dev.numunits-2].ctlr = dmp_units[0].ctlr; | |
dmp_units[dmp_dev.numunits-1] = dmc_timer_unit_template; | |
dmp_units[dmp_dev.numunits-1].ctlr = dmp_units[0].ctlr; | |
dmp_desc.notelnet = TRUE; /* We always want raw tcp socket */ | |
dmp_desc.dptr = &dmp_dev; /* Connect appropriate device */ | |
dmp_desc.uptr = dmp_units+dmp_desc.lines; /* Identify polling unit */ | |
} | |
ans = auto_config (dptr->name, (dptr->flags & DEV_DIS) ? 0 : dptr->numunits - 2); | |
if (!(dptr->flags & DEV_DIS)) { | |
int32 attached = 0; | |
for (i = 0; i < DMC_NUMDEVICE + DMP_NUMDEVICE; i++) { | |
if (dmc_ctrls[i].device == dptr) { | |
BUFFER *buffer; | |
controller = &dmc_ctrls[i]; | |
/* Avoid memory leaks by moving all buffers back to the free queue | |
and then freeing any allocated transfer buffers for each buffer | |
on the free queue */ | |
while (controller->ack_wait_queue->count) { | |
buffer = (BUFFER *)remqueue (controller->ack_wait_queue->hdr.next); | |
ASSURE (insqueue (&buffer->hdr, controller->free_queue->hdr.prev)); | |
} | |
while (controller->completion_queue->count) { | |
buffer = (BUFFER *)remqueue (controller->completion_queue->hdr.next); | |
ASSURE (insqueue (&buffer->hdr, controller->free_queue->hdr.prev)); | |
} | |
while (controller->rcv_queue->count) { | |
buffer = (BUFFER *)remqueue (controller->rcv_queue->hdr.next); | |
ASSURE (insqueue (&buffer->hdr, controller->free_queue->hdr.prev)); | |
} | |
while (controller->xmt_queue->count) { | |
buffer = (BUFFER *)remqueue (controller->xmt_queue->hdr.next); | |
ASSURE (insqueue (&buffer->hdr, controller->free_queue->hdr.prev)); | |
} | |
for (j = 0; j < controller->free_queue->size; j++) { | |
buffer = (BUFFER *)remqueue (controller->free_queue->hdr.next); | |
free (buffer->transfer_buffer); | |
buffer->transfer_buffer = NULL; | |
ASSURE (insqueue (&buffer->hdr, controller->free_queue->hdr.prev)); | |
} | |
dmc_buffer_queue_init_all(controller); | |
dmc_clrinint(controller); | |
dmc_clroutint(controller); | |
controller->dmc_wr_delay = 0; | |
for (j=0; j<dptr->numunits-1; j++) { | |
sim_cancel (&dptr->units[j]); /* stop poll */ | |
if (dptr->units[j].flags & UNIT_ATT) | |
++attached; | |
} | |
dmc_process_master_clear(controller); | |
} | |
} | |
if (attached) | |
sim_activate_after (dptr->units+(dptr->numunits-2), DMC_CONNECT_POLL*1000000);/* start poll */ | |
} | |
return ans; | |
} | |
t_stat dmc_attach (UNIT *uptr, char *cptr) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
TMXR *mp = (dptr == &dmc_dev) ? &dmc_desc : &dmp_desc; | |
t_stat ans = SCPE_OK; | |
char *peer = ((dptr == &dmc_dev)? &dmc_peer[dmc][0] : &dmp_peer[dmc][0]); | |
char *port = ((dptr == &dmc_dev)? &dmc_port[dmc][0] : &dmp_port[dmc][0]); | |
char attach_string[1024]; | |
if (!cptr || !*cptr) | |
return SCPE_ARG; | |
if (!(uptr->flags & UNIT_ATTABLE)) | |
return SCPE_NOATT; | |
if (!peer[0]) { | |
sim_printf ("Peer must be specified before attach\n"); | |
return SCPE_ARG; | |
} | |
sprintf (attach_string, "Line=%d,Connect=%s,%s", dmc, peer, cptr); | |
ans = tmxr_open_master (mp, attach_string); /* open master socket */ | |
if (ans != SCPE_OK) | |
return ans; | |
strncpy (port, cptr, CBUFSIZE-1); | |
uptr->filename = (char *)malloc (strlen(port)+1); | |
strcpy (uptr->filename, port); | |
uptr->flags |= UNIT_ATT; | |
sim_activate_after (dptr->units+(dptr->numunits-2), DMC_CONNECT_POLL*1000000);/* start poll */ | |
return ans; | |
} | |
t_stat dmc_detach (UNIT *uptr) | |
{ | |
DEVICE *dptr = (UNIBUS) ? ((&dmc_dev == find_dev_from_unit(uptr)) ? &dmc_dev : &dmp_dev) : &dmv_dev; | |
int32 dmc = (int32)(uptr-dptr->units); | |
TMXR *mp = (dptr == &dmc_dev) ? &dmc_desc : &dmp_desc; | |
TMLN *lp = &mp->ldsc[dmc]; | |
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<mp->lines; i++) | |
if (dptr->units[i].flags & UNIT_ATT) | |
++attached; | |
if (!attached) { | |
sim_cancel (dptr->units+mp->lines); /* stop poll on last detach */ | |
sim_cancel (dptr->units+(mp->lines+1)); /* stop timer on last detach */ | |
} | |
r = tmxr_detach_ln (lp); | |
free (uptr->filename); | |
uptr->filename = NULL; | |
return r; | |
} | |
char *dmc_description (DEVICE *dptr) | |
{ | |
#if defined (VM_PDP10) | |
return "DMR11 Synchronous network controller"; | |
#else | |
return "DMC11 Synchronous network controller"; | |
#endif | |
} | |
char *dmp_description (DEVICE *dptr) | |
{ | |
return (UNIBUS) ? "DMP11 Synchronous network controller" | |
: "DMV11 Synchronous network controller"; | |
} | |