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/* pdp11_kg.c - Communications Arithmetic Option KG11-A
Copyright (c) 2007-2010, John A. Dundas III
Permission is hereby granted, free of charge, to any person obtaining a
copy of this software and associated documentation files (the "Software"),
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
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kg KG11-A Communications Arithmetic Option (M7251)
03-Jan-10 JAD Eliminate gcc warnings
08-Jan-08 JAD First public release integrated with SIMH V3.7-3.
09-Dec-07 JAD SIMH-style debugging.
Finished validating against real hardware.
Support for up to 8 units, the maximum.
Keep all module data in the UNIT structure.
Clean up bit and mask definitions.
01-Dec-07 JAD Now work on the corner cases that the
diagnostic does not check.
CLR does not clear the QUO bit.
Correct SR write logic.
29-Nov-07 JAD Original implementation and testing based on
an idea from 07-Jul-03. Passes the ZKGAB0
diagnostic.
Information necessary to create this simulation was gathered from
a number of sources including:
KG11-A Exclusive-OR and CRC block check manual, DEC-11-HKGAA-B-D
<http://www.computer.museum.uq.edu.au/pdf/DEC-11-HKGAA-B-D%20KG11-A%20Exclusive-OR%20and%20CRC%20Block%20Check%20Manual.pdf>
Maintenance print set
<http://bitsavers.org/pdf/dec/unibus/KG11A_EngrDrws.pdf>
A Painless Guide to CRC Error Detection Algorithms, Ross N. Williams
<http://www.ross.net/crc/download/crc_v3.txt">
The original PDP-11 instruction set, as implemented in the /20,
/15, /10, and /5, did not include XOR. [One of the differences
tables incorrectly indicates the /04 does not implement this
instruction.] This device implements XOR, XORB, and a variety of
CRCs.
The maintenance prints indicate that the device was probably available
starting in late 1971. May need to check further. The first edition
of the manual was May 1972.
The device was still sold at least as late as mid-1982 according
to the PDP-11 Systems and Options Summary. RSTS/E included support
for up to 8 units in support of the 2780 emulation or for use with
DP11, DU11, or DUP11. The device appears to have been retired by
1983-03, and possibly earlier.
I/O Page Registers
SR 7707x0 (read-write) status
BCC 7707x2 (read-only) BCC (block check character)
DR 7707x4 (write-only) data
Vector: none
Priority: none
The KG11-A is a programmed-I/O, non-interrupting device. Therefore
no vector or bus request level are necessary. It is a Unibus device
but since it does not address memory itself (it only presents
registers in the I/O page) it is compatible with extended Unibus
machines (22-bit) as well as traditional Unibus.
Implements 5 error detection codes:
LRC-8
LRC-16
CRC-12
CRC-16
CRC-CCITT
*/
#if !defined (VM_PDP11)
#error "KG11 is not supported!"
#endif
#include "pdp11_defs.h"
extern REG cpu_reg[];
extern int32 R[];
#ifndef KG_UNITS
#define KG_UNITS (8)
#endif
/* Control and Status Register */
#define KGSR_V_QUO (8) /* RO */
#define KGSR_V_DONE (7) /* RO */
#define KGSR_V_SEN (6) /* R/W shift enable */
#define KGSR_V_STEP (5) /* W */
#define KGSR_V_CLR (4) /* W */
#define KGSR_V_DDB (3) /* R/W double data byte */
#define KGSR_V_CRCIC (2) /* R/W */
#define KGSR_V_LRC (1) /* R/W */
#define KGSR_V_16 (0) /* R/W */
#define KGSR_M_QUO (1u << KGSR_V_QUO)
#define KGSR_M_DONE (1u << KGSR_V_DONE)
#define KGSR_M_SEN (1u << KGSR_V_SEN)
#define KGSR_M_STEP (1u << KGSR_V_STEP)
#define KGSR_M_CLR (1u << KGSR_V_CLR)
#define KGSR_M_DDB (1u << KGSR_V_DDB)
#define KGSR_M_CRCIC (1u << KGSR_V_CRCIC)
#define KGSR_M_LRC (1u << KGSR_V_LRC)
#define KGSR_M_16 (1u << KGSR_V_16)
#define KG_SR_RDMASK (KGSR_M_QUO | KGSR_M_DONE | KGSR_M_SEN | KGSR_M_DDB | \
KGSR_M_CRCIC | KGSR_M_LRC | KGSR_M_16)
#define KG_SR_WRMASK (KGSR_M_SEN | KGSR_M_DDB | KGSR_M_CRCIC | \
KGSR_M_LRC | KGSR_M_16)
#define KG_SR_POLYMASK (KGSR_M_CRCIC|KGSR_M_LRC|KGSR_M_16)
#define POLY_LRC8 (0x0008)
#define POLY_LRC16 (0x0080)
#define POLY_CRC12 (0x0f01)
#define POLY_CRC16 (0xa001)
#define POLY_CCITT (0x8408)
static const struct {
uint16 poly;
uint16 pulses;
const char * const name;
} config[] = {
/* DDB=0 */
{ POLY_CRC12, 6, "CRC-12" },
{ POLY_CRC16, 8, "CRC-16" },
{ POLY_LRC8, 8, "LRC-8" },
{ POLY_LRC16, 8, "LRC-16" },
{ 0, 0, "undefined" },
{ POLY_CCITT, 8, "CRC-CCITT" },
{ 0, 0, "undefined" },
{ 0, 0, "undefined" },
/* DDB=1 */
{ POLY_CRC12, 12, "CRC-12" },
{ POLY_CRC16, 16, "CRC-16" },
{ POLY_LRC8, 16, "LRC-8" },
{ POLY_LRC16, 16, "LRC-16" },
{ 0, 0, "undefined" },
{ POLY_CCITT, 16, "CRC-CCITT" },
{ 0, 0, "undefined" },
{ 0, 0, "undefined" }
};
/* Forward declarations */
static t_stat kg_rd (int32 *, int32, int32);
static t_stat kg_wr (int32, int32, int32);
static t_stat kg_reset (DEVICE *);
static void do_poly (int, t_bool);
static t_stat set_units (UNIT *, int32, CONST char *, void *);
t_stat kg_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr);
const char *kg_description (DEVICE *dptr);
/* 16-bit rotate right */
#define ROR(n,v) (((v >> n) & DMASK) | ((v << (16 - n)) & DMASK))
/* 8-bit rotate right */
#define RORB(n,v) (((v & 0377) >> n) | ((v << (8 - n)) & 0377))
/* KG data structures
kg_dib KG PDP-11 device information block
kg_unit KG unit descriptor
kg_reg KG register list
kg_mod KG modifiers table
kg_debug KG debug names table
kg_dev KG device descriptor
*/
#define IOLN_KG 006
static DIB kg_dib = {
IOBA_AUTO,
(IOLN_KG + 2) * KG_UNITS,
&kg_rd,
&kg_wr,
0, 0, 0, { NULL }, IOLN_KG+2
};
static UNIT kg_unit[KG_UNITS];
static const REG kg_reg[] = {
{ URDATAD (SR, kg_unit[0].u3, DEV_RDX, 16, 0, KG_UNITS, 0, "control and status register; R/W") },
{ URDATAD (BCC, kg_unit[0].u4, DEV_RDX, 16, 0, KG_UNITS, 0, "result block check character; R/O") },
{ URDATAD (DR, kg_unit[0].u5, DEV_RDX, 16, 0, KG_UNITS, 0, "input data register; W/O") },
{ URDATAD (PULSCNT, kg_unit[0].u6, DEV_RDX, 16, 0, KG_UNITS, 0, "polynomial cycle stage") },
{ ORDATA (DEVADDR, kg_dib.ba, 32), REG_HRO },
{ NULL }
};
/* Unit structure redefinitions */
#define SR u3
#define BCC u4
#define DR u5
#define PULSCNT u6
static const MTAB kg_mod[] = {
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 020, "ADDRESS", NULL,
NULL, &show_addr, NULL, "Bus address" },
{ MTAB_XTD|MTAB_VDV, 0, NULL, "UNITS=1..8",
&set_units, NULL, NULL, "Specify number of KG devices" },
{ 0 }
};
#define DBG_REG (01)
#define DBG_POLY (02)
#define DBG_CYCLE (04)
static const DEBTAB kg_debug[] = {
{"REG", DBG_REG},
{"POLY", DBG_POLY},
{"CYCLE", DBG_CYCLE},
{0},
};
DEVICE kg_dev = {
"KG", (UNIT *) &kg_unit, (REG *) kg_reg, (MTAB *) kg_mod,
KG_UNITS, 8, 16, 2, 8, 16,
NULL, /* examine */
NULL, /* deposit */
&kg_reset, /* reset */
NULL, /* boot */
NULL, /* attach */
NULL, /* detach */
&kg_dib,
DEV_DISABLE | DEV_DIS | DEV_UBUS | DEV_DEBUG,
0, /* debug control */
(DEBTAB *) &kg_debug, /* debug flags */
NULL, /* memory size chage */
NULL, /* logical name */
&kg_help, /* help */
NULL, /* attach help */
NULL, /* help context */
&kg_description, /* description */
};
/* KG I/O address routines */
static t_stat kg_rd (int32 *data, int32 PA, int32 access)
{
int unit = (PA >> 3) & 07;
if ((unit >= KG_UNITS) || (kg_unit[unit].flags & UNIT_DIS))
return (SCPE_NXM);
switch ((PA >> 1) & 03) {
case 00: /* SR */
if (DEBUG_PRI(kg_dev, DBG_REG))
fprintf (sim_deb, ">>KG%d: rd SR %06o, PC %06o\n",
unit, kg_unit[unit].SR, PC);
*data = kg_unit[unit].SR & KG_SR_RDMASK;
break;
case 01: /* BCC */
if (DEBUG_PRI(kg_dev, DBG_REG))
fprintf (sim_deb, ">>KG%d rd BCC %06o, PC %06o\n",
unit, kg_unit[unit].BCC, PC);
*data = kg_unit[unit].BCC & DMASK;
break;
case 02: /* DR */
break;
default:
break;
}
return (SCPE_OK);
}
static t_stat kg_wr (int32 data, int32 PA, int32 access)
{
int setup;
int unit = (PA >> 3) & 07;
if ((unit >= KG_UNITS) || (kg_unit[unit].flags & UNIT_DIS))
return (SCPE_NXM);
switch ((PA >> 1) & 03) {
case 00: /* SR */
if (access == WRITEB)
data = (PA & 1) ?
(kg_unit[unit].SR & 0377) | (data << 8) :
(kg_unit[unit].SR & ~0377) | data;
if (DEBUG_PRI(kg_dev, DBG_REG))
fprintf (sim_deb, ">>KG%d: wr SR %06o, PC %06o\n",
unit, data, PC);
if (data & KGSR_M_CLR) {
kg_unit[unit].PULSCNT = 0; /* not sure about this */
kg_unit[unit].BCC = 0;
kg_unit[unit].SR |= KGSR_M_DONE;
}
setup = (kg_unit[unit].SR & 017) ^ (data & 017);
kg_unit[unit].SR = (kg_unit[unit].SR & ~KG_SR_WRMASK) |
(data & KG_SR_WRMASK);
/* if low 4b changed, reset C1 & C2 */
if (setup) {
kg_unit[unit].PULSCNT = 0;
if (DEBUG_PRI(kg_dev, DBG_POLY))
fprintf (sim_deb, ">>KG%d poly %s %d\n",
unit, config[data & 017].name, config[data & 017].pulses);
}
if (data & KGSR_M_SEN)
break;
if (data & KGSR_M_STEP) {
do_poly (unit, TRUE);
break;
}
break;
case 01: /* BCC */
break; /* ignored */
case 02: /* DR */
if (access == WRITEB)
data = (PA & 1) ?
(kg_unit[unit].DR & 0377) | (data << 8) :
(kg_unit[unit].DR & ~0377) | data;
kg_unit[unit].DR = data & DMASK;
if (DEBUG_PRI(kg_dev, DBG_REG))
fprintf (sim_deb, ">>KG%d: wr DR %06o, data %06o, PC %06o\n",
unit, kg_unit[unit].DR, data, PC);
kg_unit[unit].SR &= ~KGSR_M_DONE;
/* In a typical device, this is normally where we would use sim_activate()
to initiate an I/O to be completed later. The KG is a little
different. When it was first introduced, it's computation operation
completed before another instruction could execute (on early PDP-11s),
and software often took "advantage" of this fact by not bothering
to check the status of the DONE bit. In reality, the execution
time of the polynomial is dependent upon the width of the poly; if
8 bits 1us, if 16 bits, 2us. Since known existing software will
break if we actually defer the computation, it is performed immediately
instead. However this could easily be made into a run-time option,
if there were software to validate correct operation. */
if (kg_unit[unit].SR & KGSR_M_SEN)
do_poly (unit, FALSE);
break;
default:
break;
}
return (SCPE_OK);
}
/* KG reset */
static t_stat kg_reset (DEVICE *dptr)
{
int i;
if (DEBUG_PRI(kg_dev, DBG_REG))
fprintf (sim_deb, ">>KG: reset PC %06o\n", PC);
for (i = 0; i < KG_UNITS; i++) {
kg_unit[i].SR = KGSR_M_DONE;
kg_unit[i].BCC = 0;
kg_unit[i].PULSCNT = 0;
kg_unit[i].flags |= UNIT_DISABLE; /* allow SET KGn DISABLE */
}
return auto_config(dptr->name, (dptr->flags & DEV_DIS) ? 0 : kg_dev.numunits);
}
static void cycleOneBit (int unit)
{
int quo;
if (DEBUG_PRI(kg_dev, DBG_CYCLE))
fprintf (sim_deb, ">>KG%d: cycle s BCC %06o DR %06o\n",
unit, kg_unit[unit].BCC, kg_unit[unit].DR);
if (kg_unit[unit].SR & KGSR_M_DONE)
return;
if ((kg_unit[unit].SR & KG_SR_POLYMASK) == 0)
kg_unit[unit].BCC = (kg_unit[unit].BCC & 077) |
((kg_unit[unit].BCC >> 2) & 07700);
kg_unit[unit].SR &= ~KGSR_M_QUO;
quo = (kg_unit[unit].BCC & 01) ^ (kg_unit[unit].DR & 01);
kg_unit[unit].BCC = (kg_unit[unit].BCC & ~01) | quo;
if (kg_unit[unit].SR & KGSR_M_LRC)
kg_unit[unit].BCC = (kg_unit[unit].SR & KGSR_M_16) ?
ROR(1, kg_unit[unit].BCC) :
RORB(1, kg_unit[unit].BCC);
else
kg_unit[unit].BCC = (kg_unit[unit].BCC & 01) ?
(kg_unit[unit].BCC >> 1) ^ config[kg_unit[unit].SR & 07].poly :
kg_unit[unit].BCC >> 1;
kg_unit[unit].DR >>= 1;
kg_unit[unit].SR |= quo << KGSR_V_QUO;
if ((kg_unit[unit].SR & KG_SR_POLYMASK) == 0)
kg_unit[unit].BCC = (kg_unit[unit].BCC & 077) |
((kg_unit[unit].BCC & 07700) << 2);
kg_unit[unit].PULSCNT++;
if (kg_unit[unit].PULSCNT >= config[kg_unit[unit].SR & 017].pulses)
kg_unit[unit].SR |= KGSR_M_DONE;
if (DEBUG_PRI(kg_dev, DBG_CYCLE))
fprintf (sim_deb, ">>KG%d: cycle e BCC %06o DR %06o\n",
unit, kg_unit[unit].BCC, kg_unit[unit].DR);
}
static void do_poly (int unit, t_bool step)
{
if (kg_unit[unit].SR & KGSR_M_DONE)
return;
if (step)
cycleOneBit (unit);
else {
while (!(kg_unit[unit].SR & KGSR_M_DONE))
cycleOneBit (unit);
}
}
static t_stat set_units (UNIT *u, int32 val, CONST char *s, void *desc)
{
uint32 i, units;
t_stat stat;
if (s == NULL)
return (SCPE_ARG);
units = get_uint (s, 10, KG_UNITS, &stat);
if (stat != SCPE_OK)
return (stat);
if (units == 0)
return SCPE_ARG;
if (units == kg_dev.numunits)
return SCPE_OK;
for (i = 0; i < KG_UNITS; i++) {
if (i < units)
kg_unit[i].flags &= ~UNIT_DIS;
else
kg_unit[i].flags |= UNIT_DIS;
}
kg_dev.numunits = units;
kg_dib.lnt = (IOLN_KG + 2) * units;
kg_reset (&kg_dev);
return (SCPE_OK);
}
t_stat kg_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
const char *const text =
/*567901234567890123456789012345678901234567890123456789012345678901234567890*/
" KG11-A Communications Arithmetic Option (KG)\n"
"\n"
" The KG11-A is a programmed I/O, non-interrupting, dedicated arithmetic\n"
" processor for the Unibus. The device is used to compute the block check\n"
" character (BCC) over a block of data, typically in data communication\n"
" applications. The KG11 can compute three different Cyclic Redundancy\n"
" Check (CRC) polynomials (CRC-16, CRC-12, CRC-CCITT) and two Longitudinal\n"
" Redundancy Checks (LRC, Exclusive-OR; LRC-8, LRC-16). Up to eight units\n"
" may be contiguously present in a single machine and are all located at\n"
" fixed addresses. This simulation implements all functionality of the\n"
" device including the ability to single step computation of the BCC.\n"
" The KG is disabled by default.\n"
/*567901234567890123456789012345678901234567890123456789012345678901234567890*/
"\n";
fprintf (st, "%s", text);
fprint_set_help (st, dptr);
fprint_show_help (st, dptr);
fprint_reg_help (st, dptr);
return SCPE_OK;
}
const char *kg_description (DEVICE *dptr)
{
return "KG11-A Communications Arithmetic Option";
}