Rivoreo Source Code Repositories
src.rivoreo.one / emulators / simh / refs/heads/master / . / VAX / vax630_io.c
blob: 1d2535e5f55cd512b539be2621d33c08bd10042b [file] [log] [blame] [raw]
/* vax630_io.c: MicroVAX II Qbus IO simulator
Copyright (c) 2009-2012, Matt Burke
This module incorporates code from SimH, Copyright (c) 1998-2008, Robert M Supnik
Permission is hereby granted, free of charge, to any person obtaining a
copy of this software and associated documentation files (the "Software"),
to deal in the Software without restriction, including without limitation
the rights to use, copy, modify, merge, publish, distribute, sublicense,
and/or sell copies of the Software, and to permit persons to whom the
Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
THE AUTHOR(S) 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(s) of the author(s) 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(s).
qba Qbus adapter
08-Nov-2012 MB First version
*/
#include "vax_defs.h"
/* Qbus IPC register */
#define QBIPC_QPE 0x00008000 /* Qbus dma parity err */
#define QBIPC_AHLT 0x00000100 /* aux halt NI */
#define QBIPC_DBIE 0x00000040 /* dbell int enb NI */
#define QBIPC_LME 0x00000020 /* local mem enb */
#define QBIPC_DB 0x00000001 /* doorbell req NI */
#define QBIPC_RW (QBIPC_AHLT | QBIPC_DBIE | QBIPC_LME | QBIPC_DB)
#define QBIPC_MASK (QBIPC_RW | QBIPC_QPE )
BITFIELD qb_ipc_bits[] = {
BIT(DB), /* doorbell req NI */
BITNCF(4), /* Unused */
BIT(LME), /* local mem enb */
BIT(DBIE), /* dbell int enb NI */
BITNCF(1), /* Unused */
BIT(AHLT), /* aux halt NI */
BITNCF(6), /* Unused */
BIT(QPE), /* Qbus dma parity err */
ENDBITS
};
/* Qbus map registers */
#define QBNMAPR 8192 /* number of map reg */
#define QBMAP_VLD 0x80000000 /* valid */
#define QBMAP_PAG 0x00007FFF /* mem page */
#define QBMAP_RD (QBMAP_VLD | QBMAP_PAG)
#define QBMAP_WR (QBMAP_VLD | QBMAP_PAG)
#define QB_VEC_MASK 0x1FC /* Interrupt Vector value mask */
/* KA630 Memory system error register */
#define MSER_NXM 0x00000080 /* CPU NXM */
int32 int_req[IPL_HLVL] = { 0 }; /* intr, IPL 14-17 */
int32 int_vec_set[IPL_HLVL][32] = { 0 }; /* bits to set in vector */
int32 qb_ipc = 0; /* IPC */
int32 qb_map[QBNMAPR] = { 0 }; /* map registers */
int32 autcon_enb = 1; /* autoconfig enable */
extern int32 ka_mser; /* KA630 mem sys err */
t_stat dbl_rd (int32 *data, int32 addr, int32 access);
t_stat dbl_wr (int32 data, int32 addr, int32 access);
int32 eval_int (void);
t_stat qba_reset (DEVICE *dptr);
t_stat qba_ex (t_value *vptr, t_addr exta, UNIT *uptr, int32 sw);
t_stat qba_dep (t_value val, t_addr exta, UNIT *uptr, int32 sw);
t_bool qba_map_addr (uint32 qa, uint32 *ma);
t_bool qba_map_addr_c (uint32 qa, uint32 *ma);
t_stat set_autocon (UNIT *uptr, int32 val, CONST char *cptr, void *desc);
t_stat show_autocon (FILE *st, UNIT *uptr, int32 val, CONST void *desc);
t_stat show_iospace (FILE *st, UNIT *uptr, int32 val, CONST void *desc);
t_stat qba_show_virt (FILE *of, UNIT *uptr, int32 val, CONST void *desc);
t_stat qba_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr);
const char *qba_description (DEVICE *dptr);
/* Qbus adapter data structures
qba_dev QBA device descriptor
qba_unit QBA units
qba_reg QBA register list
*/
#define IOLN_DBL 002
DIB qba_dib = { IOBA_AUTO, IOLN_DBL, &dbl_rd, &dbl_wr, 0 };
UNIT qba_unit = { UDATA (NULL, 0, 0) };
REG qba_reg[] = {
{ HRDATAD (IPC, qb_ipc, 16, "interprocessor communications register") },
{ HRDATAD (IPL17, int_req[3], 32, "IPL 17 interrupt flags"), REG_RO },
{ HRDATAD (IPL16, int_req[2], 32, "IPL 16 interrupt flags"), REG_RO },
{ HRDATAD (IPL15, int_req[1], 32, "IPL 15 interrupt flags"), REG_RO },
{ HRDATAD (IPL14, int_req[0], 32, "IPL 14 interrupt flags"), REG_RO },
{ BRDATAD (MAP, qb_map, 16, 32, QBNMAPR, "map registers") },
{ FLDATA (AUTOCON, autcon_enb, 0), REG_HRO },
{ NULL }
};
MTAB qba_mod[] = {
{ MTAB_XTD|MTAB_VDV|MTAB_NMO, 0, "IOSPACE", NULL,
NULL, &show_iospace, NULL, "Display I/O space address map" },
{ MTAB_XTD|MTAB_VDV, 1, "AUTOCONFIG", "AUTOCONFIG",
&set_autocon, &show_autocon, NULL, "Enable/Display autoconfiguration" },
{ MTAB_XTD|MTAB_VDV, 0, NULL, "NOAUTOCONFIG",
&set_autocon, NULL, NULL, "Disable autoconfiguration" },
{ MTAB_XTD|MTAB_VDV|MTAB_NMO|MTAB_SHP, 0, "VIRTUAL", NULL,
NULL, &qba_show_virt, NULL, "Display translation for Qbus address arg" },
{ 0 }
};
/* debugging bitmaps */
#define DBG_REG 0x0001 /* trace read/write registers */
#define DBG_IPL 0x0002 /* trace Interrupt */
#define DBG_MAP 0x0004 /* trace Map register changes */
DEBTAB qba_debug[] = {
{"REG", DBG_REG},
{"IPL", DBG_IPL},
{"MAP", DBG_MAP},
{0}
};
DEVICE qba_dev = {
"QBA", &qba_unit, qba_reg, qba_mod,
1, 16, QBMAWIDTH, 2, 16, 16,
&qba_ex, &qba_dep, &qba_reset,
NULL, NULL, NULL,
&qba_dib, DEV_QBUS | DEV_DEBUG, 0, qba_debug, NULL, NULL, &qba_help, NULL, NULL,
&qba_description
};
/* IO page dispatches */
t_stat (*iodispR[IOPAGESIZE >> 1])(int32 *dat, int32 ad, int32 md);
t_stat (*iodispW[IOPAGESIZE >> 1])(int32 dat, int32 ad, int32 md);
/* Interrupt request to interrupt action map */
int32 (*int_ack[IPL_HLVL][32])(void); /* int ack routines */
/* Interrupt request to vector map */
int32 int_vec[IPL_HLVL][32]; /* int req to vector */
/* The KA620/KA630 handles errors in I/O space as follows
- read: machine check
- write: machine check (?)
*/
int32 ReadQb (uint32 pa)
{
int32 idx, val;
idx = (pa & IOPAGEMASK) >> 1;
if (iodispR[idx]) {
iodispR[idx] (&val, pa, READ);
return val;
}
MACH_CHECK (MCHK_READ);
return 0;
}
void WriteQb (uint32 pa, int32 val, int32 mode)
{
int32 idx;
idx = (pa & IOPAGEMASK) >> 1;
if (iodispW[idx]) {
iodispW[idx] (val, pa, mode);
return;
}
MACH_CHECK (MCHK_WRITE);
return;
}
/* ReadIO - read I/O space - aligned access
Inputs:
pa = physical address
lnt = length (BWLQ)
Output:
longword of data
*/
int32 ReadIO (uint32 pa, int32 lnt)
{
int32 iod;
iod = ReadQb (pa); /* wd from Qbus */
if (lnt < L_LONG) /* bw? position */
iod = iod << ((pa & 2)? 16: 0);
else iod = (ReadQb (pa + 2) << 16) | iod; /* lw, get 2nd wd */
SET_IRQL;
return iod;
}
/* ReadIOU - read I/O space - unaligned access
Inputs:
pa = physical address
lnt = length (1, 2, 3 bytes)
Output:
data, not shifted
Note that all of these cases are presented to the existing aligned IO routine:
bo = 0, byte, word, or longword length
bo = 2, word
bo = 1, 2, 3, byte length
All the other cases are end up at ReadIOU and WriteIOU, and they must turn
the request into the exactly correct number of Qbus accesses AND NO MORE,
because Qbus reads can have side-effects, and word read-modify-write is NOT
the same as a byte write.
Note that the sum of the pa offset and the length cannot be greater than 4.
The read cases are:
bo = 0, byte or word - read one word
bo = 0, tribyte - read two words
bo = 1, byte - read one word
bo = 1, word or tribyte - read two words
bo = 2, byte or word - read one word
bo = 3, byte - read one word
*/
int32 ReadIOU (uint32 pa, int32 lnt)
{
int32 iod;
iod = ReadQb (pa); /* wd from Qbus */
if ((lnt + (pa & 1)) <= 2) /* byte or (word & even) */
iod = iod << ((pa & 2)? 16: 0); /* one op */
else iod = (ReadQb (pa + 2) << 16) | iod; /* two ops, get 2nd wd */
SET_IRQL;
return iod;
}
/* WriteIO - write I/O space - aligned access
Inputs:
pa = physical address
val = data to write, right justified in 32b longword
lnt = length (BWLQ)
Outputs:
none
*/
void WriteIO (uint32 pa, int32 val, int32 lnt)
{
if (lnt == L_BYTE)
WriteQb (pa, val, WRITEB);
else if (lnt == L_WORD)
WriteQb (pa, val, WRITE);
else {
WriteQb (pa, val & 0xFFFF, WRITE);
WriteQb (pa + 2, (val >> 16) & 0xFFFF, WRITE);
}
SET_IRQL;
return;
}
/* WriteIOU - write I/O space
Inputs:
pa = physical address
val = data to write, right justified in 32b longword
lnt = length (1, 2, or 3 bytes)
Outputs:
none
The write cases are:
bo = x, lnt = byte - write one byte
bo = 0 or 2, lnt = word - write one word
bo = 1, lnt = word - write two bytes
bo = 0, lnt = tribyte - write word, byte
bo = 1, lnt = tribyte - write byte, word
*/
void WriteIOU (uint32 pa, int32 val, int32 lnt)
{
switch (lnt) {
case L_BYTE: /* byte */
WriteQb (pa, val & BMASK, WRITEB);
break;
case L_WORD: /* word */
if (pa & 1) { /* odd addr? */
WriteQb (pa, val & BMASK, WRITEB);
WriteQb (pa + 1, (val >> 8) & BMASK, WRITEB);
}
else WriteQb (pa, val & WMASK, WRITE);
break;
case 3: /* tribyte */
if (pa & 1) { /* odd addr? */
WriteQb (pa, val & BMASK, WRITEB); /* byte then word */
WriteQb (pa + 1, (val >> 8) & WMASK, WRITE);
}
else { /* even */
WriteQb (pa, val & WMASK, WRITE); /* word then byte */
WriteQb (pa + 2, (val >> 16) & BMASK, WRITEB);
}
break;
}
SET_IRQL;
return;
}
/* Find highest priority outstanding interrupt */
int32 eval_int (void)
{
int32 ipl = PSL_GETIPL (PSL);
int32 i, t;
static const int32 sw_int_mask[IPL_SMAX] = {
0xFFFE, 0xFFFC, 0xFFF8, 0xFFF0, /* 0 - 3 */
0xFFE0, 0xFFC0, 0xFF80, 0xFF00, /* 4 - 7 */
0xFE00, 0xFC00, 0xF800, 0xF000, /* 8 - B */
0xE000, 0xC000, 0x8000 /* C - E */
};
if (hlt_pin) /* hlt pin int */
return IPL_HLTPIN;
for (i = IPL_HMAX; i >= IPL_HMIN; i--) { /* chk hwre int */
if (i <= ipl) /* at ipl? no int */
return 0;
if (int_req[i - IPL_HMIN]) /* req != 0? int */
return i;
}
if (ipl >= IPL_SMAX) /* ipl >= sw max? */
return 0;
if ((t = SISR & sw_int_mask[ipl]) == 0) /* eligible req */
return 0;
for (i = IPL_SMAX; i > ipl; i--) { /* check swre int */
if ((t >> i) & 1) /* req != 0? int */
return i;
}
return 0;
}
/* Return vector for highest priority hardware interrupt at IPL lvl */
int32 get_vector (int32 lvl)
{
int32 i;
int32 l = lvl - IPL_HMIN;
if (lvl > IPL_HMAX) { /* error req lvl? */
ABORT (STOP_UIPL); /* unknown intr */
}
for (i = 0; int_req[l] && (i < 32); i++) {
if ((int_req[l] >> i) & 1) {
int32 vec;
int_req[l] = int_req[l] & ~(1u << i);
if (int_ack[l][i])
vec =int_ack[l][i]();
else
vec = int_vec[l][i];
vec |= int_vec_set[l][i];
vec &= (int_vec_set[l][i] | QB_VEC_MASK);
return vec;
}
}
return 0;
}
/* I/O page routines */
t_stat dbl_rd (int32 *data, int32 addr, int32 access)
{
*data = qb_ipc & QBIPC_MASK;
sim_debug(DBG_REG, &qba_dev, "dbl_rd(addr=0x%08X, data=0x%X) ", addr, *data);
sim_debug_bits(DBG_REG, &qba_dev, qb_ipc_bits, (uint32)*data, (uint32)*data, TRUE);
return SCPE_OK;
}
t_stat dbl_wr (int32 data, int32 addr, int32 access)
{
int32 sc = (addr & 3) << 3;
int32 nval = data << sc;
int32 old_val = qb_ipc;
qb_ipc = nval & QBIPC_RW;
if ((addr & 3) == 0) /* low byte only */
qb_ipc = ((qb_ipc & ~QBIPC_RW) | (data & QBIPC_RW)) & QBIPC_MASK;
qb_ipc = qb_ipc & ~QBIPC_AHLT; /* Read only on arbiter */
if (!(qb_ipc & QBIPC_DBIE))
qb_ipc = qb_ipc & ~QBIPC_DB; /* Read only when not DBIE */
sim_debug(DBG_REG, &qba_dev, "qba_wr(addr=0x%08X, data=0x%X) ", addr, data);
sim_debug_bits(DBG_REG, &qba_dev, qb_ipc_bits, (uint32)old_val, (uint32)qb_ipc, TRUE);
return SCPE_OK;
}
/* Qbus map read and write
Read error: machine check?
Write error: machine check?
*/
int32 qbmap_rd (int32 pa)
{
int32 idx = ((pa - QBMAPBASE) >> 2);
return qb_map[idx] & QBMAP_RD;
}
void qbmap_wr (int32 pa, int32 val, int32 lnt)
{
int32 idx = ((pa - QBMAPBASE) >> 2);
if (idx < QBNMAPR) {
if (lnt < L_LONG) {
int32 sc = (pa & 3) << 3;
int32 mask = (lnt == L_WORD)? 0xFFFF: 0xFF;
int32 t = qb_map[idx];
val = ((val & mask) << sc) | (t & ~(mask << sc));
}
qb_map[idx] = val & QBMAP_WR;
}
else
ka_mser |= MSER_NXM;
return;
}
/* Qbus memory read and write (reflects to main memory)
May give master or slave error, depending on where the failure occurs
*/
int32 qbmem_rd (int32 pa)
{
int32 qa = pa & QBMAMASK; /* Qbus addr */
uint32 ma;
if (qba_map_addr (qa, &ma)) { /* map addr */
return M[ma >> 2];
}
MACH_CHECK (MCHK_READ); /* err? mcheck */
return 0;
}
void qbmem_wr (int32 pa, int32 val, int32 lnt)
{
int32 qa = pa & QBMAMASK; /* Qbus addr */
uint32 ma;
if (qba_map_addr (qa, &ma)) { /* map addr */
if (lnt < L_LONG) {
int32 sc = (pa & 3) << 3;
int32 mask = (lnt == L_WORD)? 0xFFFF: 0xFF;
int32 t = M[ma >> 2];
val = ((val & mask) << sc) | (t & ~(mask << sc));
}
M[ma >> 2] = val;
}
else mem_err = 1;
return;
}
/* Map an address via the translation map */
t_bool qba_map_addr (uint32 qa, uint32 *ma)
{
int32 qblk = (qa >> VA_V_VPN); /* Qbus blk */
if (qblk < QBNMAPR) {
int32 qmap = qb_map[qblk];
if (qmap & QBMAP_VLD) { /* valid? */
*ma = ((qmap & QBMAP_PAG) << VA_V_VPN) + VA_GETOFF (qa);
if (ADDR_IS_MEM (*ma)) /* legit addr */
return TRUE;
ka_mser |= MSER_NXM;
return FALSE;
}
ka_mser |= MSER_NXM;
return FALSE;
}
ka_mser |= MSER_NXM;
return FALSE;
}
/* Map an address via the translation map - console version (no status changes) */
t_bool qba_map_addr_c (uint32 qa, uint32 *ma)
{
int32 qblk = (qa >> VA_V_VPN); /* Qbus blk */
if (qblk < QBNMAPR) {
int32 qmap = qb_map[qblk];
if (qmap & QBMAP_VLD) { /* valid? */
*ma = ((qmap & QBMAP_PAG) << VA_V_VPN) + VA_GETOFF (qa);
return TRUE;
}
}
return FALSE;
}
/* Reset I/O bus */
void ioreset_wr (int32 data)
{
reset_all (5); /* from qba on... */
return;
}
/* Reset Qbus */
t_stat qba_reset (DEVICE *dptr)
{
int32 i;
for (i = 0; i < IPL_HLVL; i++)
int_req[i] = 0;
return SCPE_OK;
}
/* Qbus I/O buffer routines, aligned access
Map_ReadB - fetch byte buffer from memory
Map_ReadW - fetch word buffer from memory
Map_WriteB - store byte buffer into memory
Map_WriteW - store word buffer into memory
*/
int32 Map_ReadB (uint32 ba, int32 bc, uint8 *buf)
{
int32 i;
uint32 ma, dat;
if ((ba | bc) & 03) { /* check alignment */
for (i = ma = 0; i < bc; i++, buf++) { /* by bytes */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
*buf = (uint8)ReadB (ma);
ma = ma + 1;
}
}
else {
for (i = ma = 0; i < bc; i = i + 4, buf++) { /* by longwords */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
dat = ReadL (ma); /* get lw */
*buf++ = dat & BMASK; /* low 8b */
*buf++ = (dat >> 8) & BMASK; /* next 8b */
*buf++ = (dat >> 16) & BMASK; /* next 8b */
*buf = (dat >> 24) & BMASK;
ma = ma + 4;
}
}
return 0;
}
int32 Map_ReadW (uint32 ba, int32 bc, uint16 *buf)
{
int32 i;
uint32 ma,dat;
ba = ba & ~01;
bc = bc & ~01;
if ((ba | bc) & 03) { /* check alignment */
for (i = ma = 0; i < bc; i = i + 2, buf++) { /* by words */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
*buf = (uint16)ReadW (ma);
ma = ma + 2;
}
}
else {
for (i = ma = 0; i < bc; i = i + 4, buf++) { /* by longwords */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
dat = ReadL (ma); /* get lw */
*buf++ = dat & WMASK; /* low 16b */
*buf = (dat >> 16) & WMASK; /* high 16b */
ma = ma + 4;
}
}
return 0;
}
int32 Map_WriteB (uint32 ba, int32 bc, const uint8 *buf)
{
int32 i;
uint32 ma, dat;
if ((ba | bc) & 03) { /* check alignment */
for (i = ma = 0; i < bc; i++, buf++) { /* by bytes */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
WriteB (ma, *buf);
ma = ma + 1;
}
}
else {
for (i = ma = 0; i < bc; i = i + 4, buf++) { /* by longwords */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
dat = (uint32) *buf++; /* get low 8b */
dat = dat | (((uint32) *buf++) << 8); /* merge next 8b */
dat = dat | (((uint32) *buf++) << 16); /* merge next 8b */
dat = dat | (((uint32) *buf) << 24); /* merge hi 8b */
WriteL (ma, dat); /* store lw */
ma = ma + 4;
}
}
return 0;
}
int32 Map_WriteW (uint32 ba, int32 bc, const uint16 *buf)
{
int32 i;
uint32 ma, dat;
ba = ba & ~01;
bc = bc & ~01;
if ((ba | bc) & 03) { /* check alignment */
for (i = ma = 0; i < bc; i = i + 2, buf++) { /* by words */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
WriteW (ma, *buf);
ma = ma + 2;
}
}
else {
for (i = ma = 0; i < bc; i = i + 4, buf++) { /* by longwords */
if ((ma & VA_M_OFF) == 0) { /* need map? */
if (!qba_map_addr (ba + i, &ma)) /* inv or NXM? */
return (bc - i);
}
dat = (uint32) *buf++; /* get low 16b */
dat = dat | (((uint32) *buf) << 16); /* merge hi 16b */
WriteL (ma, dat); /* store lw */
ma = ma + 4;
}
}
return 0;
}
/* Memory examine via map (word only) */
t_stat qba_ex (t_value *vptr, t_addr exta, UNIT *uptr, int32 sw)
{
uint32 qa = (uint32) exta, pa;
if ((vptr == NULL) || (qa >= QBMSIZE))
return SCPE_ARG;
if (qba_map_addr_c (qa, &pa) && ADDR_IS_MEM (pa)) {
*vptr = (uint32) ReadW (pa);
return SCPE_OK;
}
return SCPE_NXM;
}
/* Memory deposit via map (word only) */
t_stat qba_dep (t_value val, t_addr exta, UNIT *uptr, int32 sw)
{
uint32 qa = (uint32) exta, pa;
if (qa >= QBMSIZE)
return SCPE_ARG;
if (qba_map_addr_c (qa, &pa) && ADDR_IS_MEM (pa)) {
WriteW (pa, (int32) val);
return SCPE_OK;
}
return SCPE_NXM;
}
/* Build dib_tab from device list */
t_stat build_dib_tab (void)
{
int32 i;
DEVICE *dptr;
DIB *dibp;
t_stat r;
init_ubus_tab (); /* init bus tables */
for (i = 0; (dptr = sim_devices[i]) != NULL; i++) { /* loop thru dev */
dibp = (DIB *) dptr->ctxt; /* get DIB */
if (dibp && !(dptr->flags & DEV_DIS)) { /* defined, enabled? */
r = build_ubus_tab (dptr, dibp); /* add to bus tab */
if (r)
return r;
} /* end if enabled */
} /* end for */
return SCPE_OK;
}
/* Show QBA virtual address */
t_stat qba_show_virt (FILE *of, UNIT *uptr, int32 val, CONST void *desc)
{
t_stat r;
const char *cptr = (const char *) desc;
uint32 qa, pa;
if (cptr) {
qa = (uint32) get_uint (cptr, 16, QBMSIZE - 1, &r);
if (r == SCPE_OK) {
if (qba_map_addr_c (qa, &pa))
fprintf (of, "Qbus %-X = physical %-X\n", qa, pa);
else fprintf (of, "Qbus %-X: invalid mapping\n", qa);
return SCPE_OK;
}
}
fprintf (of, "Invalid argument\n");
return SCPE_OK;
}
t_stat qba_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
fprintf (st, "Qbus Adapter (QBA)\n\n");
fprintf (st, "The Qbus adapter (QBA) simulates the CQBIC Qbus adapter chip.\n");
fprint_set_help (st, dptr);
fprint_show_help (st, dptr);
fprintf (st, "\nThe QBA implements main memory examination and modification via the Qbus\n");
fprintf (st, "map. The data width is always 16b:\n\n");
fprintf (st, "EXAMINE QBA 0/10 examine main memory words corresponding\n");
fprintf (st, " to Qbus addresses 0-10\n");
fprint_reg_help (st, dptr);
return SCPE_OK;
}
const char *qba_description (DEVICE *dptr)
{
return "Qbus adapter";
}