blob: d1efc84bc6b8e991d2e58fab021593b80a29ce7e [file] [log] [blame] [raw]
/* pdp11_rp.c - RP04/05/06/07 RM02/03/05/80 Massbus disk controller
Copyright (c) 1993-2017, Robert M Supnik
Permission is hereby granted, free of charge, to any person obtaining a
copy of this software and associated documentation files (the "Software"),
to deal in the Software without restriction, including without limitation
the rights to use, copy, modify, merge, publish, distribute, sublicense,
and/or sell copies of the Software, and to permit persons to whom the
Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
Except as contained in this notice, the name of Robert M Supnik shall not be
used in advertising or otherwise to promote the sale, use or other dealings
in this Software without prior written authorization from Robert M Supnik.
rp RH/RP/RM moving head disks
13-Mar-17 RMS Annotated intentional fall through in switch
23-Oct-13 RMS Revised for new boot setup routine
06-Mar-11 MP Converted to using sim_disk library and refactored
for Asynch I/O.
Set STIME value to default of 26 which allows VMS V4.x
to boot.
17-May-07 RMS CS1 DVA resides in device, not MBA
21-Nov-05 RMS Enable/disable device also enables/disables Massbus adapter
12-Nov-05 RMS Fixed DriveClear, does not clear disk address
16-Aug-05 RMS Fixed C++ declaration and cast problems
18-Mar-05 RMS Added attached test to detach routine
12-Sep-04 RMS Cloned from pdp11_rp.c
Note: The VMS driver and the RP controller documentation state that
ER2 = offset 8
SN = offset 12
But the TOPS-10 and TOPS-20 drivers, and the RP schematics state that
SN = offset 8
ER2 = offset 12
The simulation follows the schematics. The VMS drivers defines but does
not use these offsets, and the error logger follows the schematics.
*/
#if defined (VM_PDP10)
#error "PDP-10 uses pdp10_rp.c!"
#elif defined (VM_PDP11)
#include "pdp11_defs.h"
#define INIT_DTYPE RM03_DTYPE
#define INIT_SIZE RM03_SIZE
#elif defined (VM_VAX)
#include "vax_defs.h"
#define INIT_DTYPE RP06_DTYPE
#define INIT_SIZE RP06_SIZE
#define DMASK 0xFFFF
#if (!UNIBUS)
#error "Qbus not supported!"
#endif
#endif
#include "sim_disk.h"
#include <math.h>
#define RP_CTRL 0 /* ctrl is RP */
#define RM_CTRL 1 /* ctrl is RM */
#define RP_NUMDR 8 /* #drives */
#define RP_NUMWD 256 /* words/sector */
#define RP_MAXFR (1 << 16) /* max transfer */
#define GET_SECTOR(x,d) ((int) fmod (sim_gtime() / ((double) (x)), \
((double) drv_tab[d].sect)))
#define RM_OF (MBA_RMASK + 1)
/* Flags in the unit flags word */
#define UNIT_V_WLK (DKUF_V_UF + 0) /* write locked */
#define UNIT_V_DTYPE (DKUF_V_UF + 1) /* disk type */
#define UNIT_M_DTYPE 7
#define UNIT_V_AUTO (DKUF_V_UF + 4) /* autosize */
#define UNIT_V_DUMMY (DKUF_V_UF + 5) /* dummy flag */
#define UNIT_WLK (1 << UNIT_V_WLK)
#define UNIT_DTYPE (UNIT_M_DTYPE << UNIT_V_DTYPE)
#define UNIT_AUTO (1 << UNIT_V_AUTO)
#define UNIT_DUMMY (1 << UNIT_V_DUMMY)
#define GET_DTYPE(x) (((x) >> UNIT_V_DTYPE) & UNIT_M_DTYPE)
#define UNIT_WPRT (UNIT_WLK | UNIT_RO) /* write prot */
/* Parameters in the unit descriptor */
#define CYL u3 /* current cylinder */
#define sectsread u4 /* sectors read */
#define io_status u5 /* io status from callback */
#define io_complete u6 /* io completion flag */
/* RPCS1, RMCS1 - control/status 1 - offset 0 */
#define RP_CS1_OF 0
#define RM_CS1_OF (0 + RM_OF)
#define CS1_GO CSR_GO /* go */
#define CS1_V_FNC 1 /* function pos */
#define CS1_M_FNC 037 /* function mask */
#define CS1_N_FNC (CS1_M_FNC + 1)
#define FNC_NOP 000 /* no operation */
#define FNC_UNLOAD 001 /* unload */
#define FNC_SEEK 002 /* seek */
#define FNC_RECAL 003 /* recalibrate */
#define FNC_DCLR 004 /* drive clear */
#define FNC_RELEASE 005 /* port release */
#define FNC_OFFSET 006 /* offset */
#define FNC_RETURN 007 /* return to center */
#define FNC_PRESET 010 /* read-in preset */
#define FNC_PACK 011 /* pack acknowledge */
#define FNC_SEARCH 014 /* search */
#define FNC_XFER 024 /* >=? data xfr */
#define FNC_WCHK 024 /* write check */
#define FNC_WRITE 030 /* write */
#define FNC_WRITEH 031 /* write w/ headers */
#define FNC_READ 034 /* read */
#define FNC_READH 035 /* read w/ headers */
#define CS1_RW 076
#define CS1_DVA 04000 /* drive avail */
#define GET_FNC(x) (((x) >> CS1_V_FNC) & CS1_M_FNC)
static const char *rp_fname[CS1_N_FNC] = {
"NOP", "UNLD", "SEEK", "RECAL", "DCLR", "RLS", "OFFS", "RETN",
"PRESET", "PACK", "12", "13", "SEARCH", "15", "16", "17",
"20", "21", "22", "23", "WRCHK", "25", "26", "27",
"WRITE", "WRHDR", "32", "33", "READ", "RDHDR", "36", "37"
};
BITFIELD rp_cs1_bits[] = {
BIT(GO), /* Go */
BITFNAM(FUNC,5,rp_fname), /* Function Code */
BIT(IE), /* Interrupt Enable */
BIT(RDY), /* Drive Ready */
BIT(A16), /* Bus Address Extension Bit 16 */
BIT(A17), /* Bus Address Extension Bit 17 */
BIT(PSEL), /* Port Select */
BIT(DVA), /* Drive Available */
BITNCF(1), /* 12 Reserved */
BIT(MCPE), /* Massbus Control Parity Error */
BIT(TRE), /* Transfer Error */
BIT(SC), /* Special Condition */
ENDBITS
};
/* RPDS, RMDS - drive status - offset 1 */
#define RP_DS_OF 1
#define RM_DS_OF (1 + RM_OF)
#define DS_OFM 0000001 /* offset mode */
#define DS_VV 0000100 /* volume valid */
#define DS_RDY 0000200 /* drive ready */
#define DS_DPR 0000400 /* drive present */
#define DS_PGM 0001000 /* programable NI */
#define DS_LST 0002000 /* last sector */
#define DS_WRL 0004000 /* write locked */
#define DS_MOL 0010000 /* medium online */
#define DS_PIP 0020000 /* pos in progress */
#define DS_ERR 0040000 /* error */
#define DS_ATA 0100000 /* attention active */
#define DS_MBZ 0000076
BITFIELD rp_ds_bits[] = {
BIT(OM), /* offset mode */
BITF(MBZ,5), /* must be zero */
BIT(VV), /* volume valid */
BIT(RDY), /* drive ready */
BIT(DPR), /* drive present */
BIT(PGM), /* programmable NI */
BIT(LST), /* write clk fail NI */
BIT(WRL), /* ECC hard err NI */
BIT(MOL), /* hdr comp err NI */
BIT(PIP), /* hdr CRC err NI */
BIT(ERR), /* addr ovflo err */
BIT(ATA), /* invalid addr err */
ENDBITS
};
/* RPER1, RMER1 - error status 1 - offset 2 */
#define RP_ER1_OF 2
#define RM_ER1_OF (2 + RM_OF)
#define ER1_ILF 0000001 /* illegal func */
#define ER1_ILR 0000002 /* illegal register */
#define ER1_RMR 0000004 /* reg mod refused */
#define ER1_PAR 0000010 /* parity err */
#define ER1_FER 0000020 /* format err NI */
#define ER1_WCF 0000040 /* write clk fail NI */
#define ER1_ECH 0000100 /* ECC hard err NI */
#define ER1_HCE 0000200 /* hdr comp err NI */
#define ER1_HCR 0000400 /* hdr CRC err NI */
#define ER1_AOE 0001000 /* addr ovflo err */
#define ER1_IAE 0002000 /* invalid addr err */
#define ER1_WLE 0004000 /* write lock err */
#define ER1_DTE 0010000 /* drive time err NI */
#define ER1_OPI 0020000 /* op incomplete */
#define ER1_UNS 0040000 /* drive unsafe */
#define ER1_DCK 0100000 /* data check NI */
BITFIELD rp_er1_bits[] = {
BIT(ILF), /* Illegal Function */
BIT(ILR), /* Illegal Register */
BIT(RMR), /* reg mod refused */
BIT(PAR), /* parity err */
BIT(FER), /* format err NI */
BIT(WCF), /* write clk fail NI */
BIT(ECH), /* ECC hard err NI */
BIT(HCE), /* hdr comp err NI */
BIT(HCR), /* hdr CRC err NI */
BIT(AOE), /* addr ovflo err */
BIT(IAE), /* invalid addr err */
BIT(WLE), /* write lock err */
BIT(DTE), /* drive time err NI */
BIT(OPI), /* op incomplete */
BIT(UNS), /* drive unsafe */
BIT(DCK), /* data check NI */
ENDBITS
};
/* RPMR, RMMR - maintenace register - offset 3*/
#define RP_MR_OF 3
#define RM_MR_OF (3 + RM_OF)
BITFIELD rp_mr_bits[] = {
BITF(MR,16), /* Maintenance Register */
ENDBITS
};
/* RPAS, RMAS - attention summary - offset 4 */
#define RP_AS_OF 4
#define RM_AS_OF (4 + RM_OF)
#define AS_U0 0000001 /* unit 0 flag */
BITFIELD rp_as_bits[] = {
BIT(ATA0), /* Drive 0 Attention */
BIT(ATA1), /* Drive 1 Attention */
BIT(ATA2), /* Drive 2 Attention */
BIT(ATA3), /* Drive 3 Attention */
BIT(ATA4), /* Drive 4 Attention */
BIT(ATA5), /* Drive 5 Attention */
BIT(ATA6), /* Drive 6 Attention */
BIT(ATA7), /* Drive 7 Attention */
BITNCF(8), /* 08:15 Reserved */
ENDBITS
};
/* RPDA, RMDA - sector/track - offset 5 */
#define RP_DA_OF 5
#define RM_DA_OF (5 + RM_OF)
#define DA_V_SC 0 /* sector pos */
#define DA_M_SC 077 /* sector mask */
#define DA_V_SF 8 /* track pos */
#define DA_M_SF 077 /* track mask */
#define DA_MBZ 0140300
#define GET_SC(x) (((x) >> DA_V_SC) & DA_M_SC)
#define GET_SF(x) (((x) >> DA_V_SF) & DA_M_SF)
BITFIELD rp_da_bits[] = {
BITF(SA,5), /* Sector Address */
BITNCF(3), /* 05:07 Reserved */
BITF(TA,5), /* Track Address */
BITNCF(3), /* 13:15 Reserved */
ENDBITS
};
/* RPDT, RMDT - drive type - offset 6 */
#define RP_DT_OF 6
#define RM_DT_OF (6 + RM_OF)
BITFIELD rp_dt_bits[] = {
BITF(DT,9), /* Drive Type */
BITNCF(2), /* 09:10 Reserved */
BIT(DRQ), /* Drive Request Required */
BITNCF(1), /* 12 Reserved */
BIT(MOH), /* Moving Head */
BITNCF(2), /* 14:15 Reserved */
ENDBITS
};
/* RPLA, RMLA - look ahead register - offset 7 */
#define RP_LA_OF 7
#define RM_LA_OF (7 + RM_OF)
#define LA_V_SC 6 /* sector pos */
BITFIELD rp_la_bits[] = {
BITNCF(6), /* 00:05 Reserved */
BITF(SC,5), /* sector pos */
BITNCF(5), /* 12:15 Reserved */
ENDBITS
};
/* RPSN, RMSN - serial number - offset 8 */
#define RP_SN_OF 8
#define RM_SN_OF (8 + RM_OF)
BITFIELD rp_sn_bits[] = {
BITF(SN,16), /* Serial Number */
ENDBITS
};
/* RPOF, RMOF - offset register - offset 9 */
#define RP_OF_OF 9
#define RM_OF_OF (9 + RM_OF)
#define OF_HCI 0002000 /* hdr cmp inh NI */
#define OF_ECI 0004000 /* ECC inhibit NI */
#define OF_F22 0010000 /* format NI */
#define OF_MBZ 0161400
BITFIELD rp_of_bits[] = {
BITNCF(7), /* 00:06 Reserved */
BIT(OFFDIR), /* Offset Direction */
BITNCF(2), /* 08:09 Reserved */
BIT(HCI), /* hdr comp inh NI */
BIT(ECI), /* ECC inh NI */
BIT(FMT), /* format NI */
BITNCF(3), /* 13:15 Reserved */
ENDBITS
};
/* RPDC, RMDC - desired cylinder - offset 10 */
#define RP_DC_OF 10
#define RM_DC_OF (10 + RM_OF)
#define DC_V_CY 0 /* cylinder pos */
#define DC_M_CY 01777 /* cylinder mask */
#define DC_MBZ 0176000
#define GET_CY(x) (((x) >> DC_V_CY) & DC_M_CY)
#define GET_DA(c,fs,d) ((((GET_CY (c) * drv_tab[d].surf) + \
GET_SF (fs)) * drv_tab[d].sect) + GET_SC (fs))
BITFIELD rp_dc_bits[] = {
BITF(DC,10), /* Offset Direction */
BITNCF(6), /* 10:15 Unused */
ENDBITS
};
/* RPCC - current cylinder - offset 11
RMHR - holding register - offset 11 */
#define RP_CC_OF 11
#define RM_HR_OF (11 + RM_OF)
BITFIELD rp_cc_bits[] = {
BITF(CC,16), /* current cylinder */
ENDBITS
};
/* RPER2 - error status 2 - drive unsafe conditions - unimplemented - offset 12
RMMR2 - maintenance register - unimplemented - offset 12 */
#define RP_ER2_OF 12
#define RM_MR2_OF (12 + RM_OF)
BITFIELD rp_er2_bits[] = {
BITNCF(3), /* 00:02 Unused */
BIT(DPE), /* data parity error */
BITNCF(3), /* 04:06 Unused */
BIT(DVC), /* device check */
BITNCF(2), /* 08:09 Unused */
BIT(LBC), /* Loss of bit clock */
BIT(LSC), /* Loss of system clock */
BIT(IVC), /* Invalid Command */
BIT(OPE), /* Operator Plug Error */
BIT(SKI), /* Seek Incomplete */
BIT(BSE), /* Bad Sector Error */
ENDBITS
};
/* RPER3 - error status 3 - more unsafe conditions - unimplemented - offset 13
RMER2 - error status 2 - unimplemented - offset 13 */
#define RP_ER3_OF 13
#define RM_ER2_OF (13 + RM_OF)
BITFIELD rp_er3_bits[] = {
BITNCF(3), /* 00:02 Unused */
BIT(DPE), /* data parity error */
BITNCF(3), /* 04:06 Unused */
BIT(DVC), /* device check */
BITNCF(2), /* 08:09 Unused */
BIT(LBC), /* Loss of bit clock */
BIT(LSC), /* Loss of system clock */
BIT(IVC), /* Invalid Command */
BIT(OPE), /* Operator Plug Error */
BIT(SKI), /* Seek Incomplete */
BIT(BSE), /* Bad Sector Error */
ENDBITS
};
/* RPEC1, RMEC1 - ECC status 1 - unimplemented - offset 14 */
#define RP_EC1_OF 14
#define RM_EC1_OF (14 + RM_OF)
BITFIELD rp_ec1_bits[] = {
BITF(P,13), /* ECC Position Register */
BITNCF(3), /* 13:15 Unused */
ENDBITS
};
/* RPEC2, RMEC1 - ECC status 2 - unimplemented - offset 15 */
#define RP_EC2_OF 15
#define RM_EC2_OF (15 + RM_OF)
BITFIELD rp_ec2_bits[] = {
BITF(PAT,11), /* ECC Pattern Register */
BITNCF(5), /* 11:15 Unused */
ENDBITS
};
BITFIELD *rp_reg_bits[] = {
rp_cs1_bits,
rp_ds_bits,
rp_er1_bits,
rp_mr_bits,
rp_as_bits,
rp_da_bits,
rp_dt_bits,
rp_la_bits,
rp_sn_bits,
rp_of_bits,
rp_dc_bits,
rp_cc_bits,
rp_er2_bits,
rp_er3_bits,
rp_ec1_bits,
rp_ec2_bits,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
rp_cs1_bits,
rp_ds_bits,
rp_er1_bits,
rp_mr_bits,
rp_as_bits,
rp_da_bits,
rp_dt_bits,
rp_la_bits,
rp_sn_bits,
rp_of_bits,
rp_dc_bits,
rp_cc_bits,
rp_er2_bits,
rp_er3_bits,
rp_ec1_bits,
rp_ec2_bits,
};
/* This controller supports many different disk drive types:
type #sectors/ #surfaces/ #cylinders/
surface cylinder drive
RM02/3 32 5 823 =67MB
RP04/5 22 19 411 =88MB
RM80 31 14 559 =124MB
RP06 22 19 815 =176MB
RM05 32 19 823 =256MB
RP07 50 32 630 =516MB
In theory, each drive can be a different type. The size field in
each unit selects the drive capacity for each drive and thus the
drive type. DISKS MUST BE DECLARED IN ASCENDING SIZE.
Note: the RP07, despite its designation, belongs to the RM family
*/
#define RM03_DTYPE 0
#define RM03_SECT 32
#define RM03_SURF 5
#define RM03_CYL 823
#define RM03_DEV 020024
#define RM03_SIZE (RM03_SECT * RM03_SURF * RM03_CYL * RP_NUMWD)
#define RP04_DTYPE 1
#define RP04_SECT 22
#define RP04_SURF 19
#define RP04_CYL 411
#define RP04_DEV 020020
#define RP04_SIZE (RP04_SECT * RP04_SURF * RP04_CYL * RP_NUMWD)
#define RM80_DTYPE 2
#define RM80_SECT 31
#define RM80_SURF 14
#define RM80_CYL 559
#define RM80_DEV 020026
#define RM80_SIZE (RM80_SECT * RM80_SURF * RM80_CYL * RP_NUMWD)
#define RP06_DTYPE 3
#define RP06_SECT 22
#define RP06_SURF 19
#define RP06_CYL 815
#define RP06_DEV 020022
#define RP06_SIZE (RP06_SECT * RP06_SURF * RP06_CYL * RP_NUMWD)
#define RM05_DTYPE 4
#define RM05_SECT 32
#define RM05_SURF 19
#define RM05_CYL 823
#define RM05_DEV 020027
#define RM05_SIZE (RM05_SECT * RM05_SURF * RM05_CYL * RP_NUMWD)
#define RP07_DTYPE 5
#define RP07_SECT 50
#define RP07_SURF 32
#define RP07_CYL 630
#define RP07_DEV 020042
#define RP07_SIZE (RP07_SECT * RP07_SURF * RP07_CYL * RP_NUMWD)
#define RP_CTRL 0
#define RM_CTRL 1
struct drvtyp {
int32 sect; /* sectors */
int32 surf; /* surfaces */
int32 cyl; /* cylinders */
int32 size; /* #blocks */
int32 devtype; /* device type */
int32 ctrl; /* ctrl type */
const char *name; /* device type name */
};
static struct drvtyp drv_tab[] = {
{ RM03_SECT, RM03_SURF, RM03_CYL, RM03_SIZE, RM03_DEV, RM_CTRL, "RM03" },
{ RP04_SECT, RP04_SURF, RP04_CYL, RP04_SIZE, RP04_DEV, RP_CTRL, "RP04" },
{ RM80_SECT, RM80_SURF, RM80_CYL, RM80_SIZE, RM80_DEV, RM_CTRL, "RM80" },
{ RP06_SECT, RP06_SURF, RP06_CYL, RP06_SIZE, RP06_DEV, RP_CTRL, "RP06" },
{ RM05_SECT, RM05_SURF, RM05_CYL, RM05_SIZE, RM05_DEV, RM_CTRL, "RM05" },
{ RP07_SECT, RP07_SURF, RP07_CYL, RP07_SIZE, RP07_DEV, RM_CTRL, "RP07" },
{ 0 }
};
uint16 *rpxb[RP_NUMDR] = { 0 }; /* xfer buffer */
uint16 rpcs1[RP_NUMDR] = { 0 }; /* control/status 1 */
uint16 rpda[RP_NUMDR] = { 0 }; /* track/sector */
uint16 rpds[RP_NUMDR] = { 0 }; /* drive status */
uint16 rper1[RP_NUMDR] = { 0 }; /* error status 1 */
uint16 rmhr[RP_NUMDR] = { 0 }; /* holding reg */
uint16 rpmr[RP_NUMDR] = { 0 }; /* maint reg */
uint16 rmmr2[RP_NUMDR] = { 0 }; /* maint reg 2 */
uint16 rpof[RP_NUMDR] = { 0 }; /* offset */
uint16 rpdc[RP_NUMDR] = { 0 }; /* cylinder */
uint16 rper2[RP_NUMDR] = { 0 }; /* error status 2 */
uint16 rper3[RP_NUMDR] = { 0 }; /* error status 3 */
uint16 rpec1[RP_NUMDR] = { 0 }; /* ECC correction 1 */
uint16 rpec2[RP_NUMDR] = { 0 }; /* ECC correction 2 */
uint16 rpxbc[RP_NUMDR] = { 0 }; /* Byte Count Copy */
int32 rp_stopioe = 1; /* stop on error */
int32 rp_swait = 26; /* seek time */
int32 rp_rwait = 10; /* rotate time */
t_stat rp_mbrd (int32 *data, int32 ofs, int32 drv);
t_stat rp_mbwr (int32 data, int32 ofs, int32 drv);
t_stat rp_svc (UNIT *uptr);
t_stat rp_reset (DEVICE *dptr);
t_stat rp_attach (UNIT *uptr, CONST char *cptr);
t_stat rp_detach (UNIT *uptr);
t_stat rp_boot (int32 unitno, DEVICE *dptr);
void rp_set_er (int16 flg, int32 drv);
void rp_clr_as (int32 mask);
void rp_update_ds (uint16 flg, int32 drv);
t_stat rp_go (int32 drv);
t_stat rp_set_size (UNIT *uptr, int32 val, CONST char *cptr, void *desc);
t_stat rp_set_bad (UNIT *uptr, int32 val, CONST char *cptr, void *desc);
int32 rp_abort (void);
t_stat rp_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr);
const char *rp_description (DEVICE *dptr);
/* RP data structures
rp_dev RP device descriptor
rp_unit RP unit list
rp_reg RP register list
rp_mod RP modifier list
*/
#define IOLN_RP 054
DIB rp_dib = { MBA_AUTO, IOLN_RP, &rp_mbrd, &rp_mbwr, 0, 0, 0, { &rp_abort } };
UNIT rp_unit[] = {
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) },
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) },
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) },
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) },
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) },
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) },
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) },
{ UDATA (&rp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
UNIT_ROABLE+(INIT_DTYPE << UNIT_V_DTYPE), INIT_SIZE) }
};
REG rp_reg[] = {
{ BRDATADF (CS1, rpcs1, DEV_RDX, 16, RP_NUMDR, "current operation", rp_cs1_bits) },
{ BRDATADF (DA, rpda, DEV_RDX, 16, RP_NUMDR, "desired surface, sector", rp_da_bits) },
{ BRDATADF (DS, rpds, DEV_RDX, 16, RP_NUMDR, "drive status", rp_ds_bits) },
{ BRDATADF (ER1, rper1, DEV_RDX, 16, RP_NUMDR, "drive errors", rp_er1_bits) },
{ BRDATAD (HR, rmhr, DEV_RDX, 16, RP_NUMDR, "holding register") },
{ BRDATADF (OF, rpof, DEV_RDX, 16, RP_NUMDR, "offset", rp_of_bits) },
{ BRDATADF (DC, rpdc, DEV_RDX, 16, RP_NUMDR, "desired cylinder", rp_dc_bits) },
{ BRDATADF (ER2, rper2, DEV_RDX, 16, RP_NUMDR, "error status 2", rp_er2_bits) },
{ BRDATADF (ER3, rper3, DEV_RDX, 16, RP_NUMDR, "error status 3", rp_er3_bits) },
{ BRDATADF (EC1, rpec1, DEV_RDX, 16, RP_NUMDR, "ECC syndrome 1", rp_ec1_bits) },
{ BRDATADF (EC2, rpec2, DEV_RDX, 16, RP_NUMDR, "ECC syndrome 2", rp_ec2_bits) },
{ BRDATADF (MR, rpmr, DEV_RDX, 16, RP_NUMDR, "maintenance register", rp_mr_bits) },
{ BRDATAD (MR2, rmmr2, DEV_RDX, 16, RP_NUMDR, "maintenance register 2 (RM only)") },
{ DRDATAD (STIME, rp_swait, 24, "seek time, per cylinder"), REG_NZ + PV_LEFT },
{ DRDATAD (RTIME, rp_rwait, 24, "rotational delay"), REG_NZ + PV_LEFT },
{ URDATA (CAPAC, rp_unit[0].capac, 10, T_ADDR_W, 0,
RP_NUMDR, PV_LEFT | REG_HRO) },
{ FLDATAD (STOP_IOE, rp_stopioe, 0, "stop on I/O error") },
{ GRDATA (CTRLTYPE, rp_dib.lnt, DEV_RDX, 16, 0), REG_HRO },
{ NULL }
};
MTAB rp_mod[] = {
{ MTAB_XTD|MTAB_VDV, 0, "MASSBUS", NULL,
NULL, &mba_show_num, NULL, "Display Massbus number" },
{ UNIT_WLK, 0, "write enabled", "WRITEENABLED",
NULL, NULL, NULL, "Write enable disk drive" },
{ UNIT_WLK, UNIT_WLK, "write locked", "LOCKED",
NULL, NULL, NULL, "Write lock disk drive" },
{ UNIT_DUMMY, 0, NULL, "BADBLOCK",
&rp_set_bad, NULL, NULL, "write bad block table on last track" },
{ MTAB_XTD|MTAB_VUN|MTAB_VALR, 0, "FORMAT", "FORMAT={SIMH|VHD|RAW}",
&sim_disk_set_fmt, &sim_disk_show_fmt, NULL, "Display disk format" },
{ (UNIT_DTYPE+UNIT_ATT), (RM03_DTYPE << UNIT_V_DTYPE) + UNIT_ATT,
"RM03", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (RP04_DTYPE << UNIT_V_DTYPE) + UNIT_ATT,
"RP04", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (RM80_DTYPE << UNIT_V_DTYPE) + UNIT_ATT,
"RM80", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (RP06_DTYPE << UNIT_V_DTYPE) + UNIT_ATT,
"RP06", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (RM05_DTYPE << UNIT_V_DTYPE) + UNIT_ATT,
"RM05", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (RP07_DTYPE << UNIT_V_DTYPE) + UNIT_ATT,
"RP07", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (RM03_DTYPE << UNIT_V_DTYPE),
"RM03", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (RP04_DTYPE << UNIT_V_DTYPE),
"RP04", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (RM80_DTYPE << UNIT_V_DTYPE),
"RM80", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (RP06_DTYPE << UNIT_V_DTYPE),
"RP06", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (RM05_DTYPE << UNIT_V_DTYPE),
"RM05", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (RP07_DTYPE << UNIT_V_DTYPE),
"RP07", NULL, NULL },
{ (UNIT_AUTO+UNIT_ATT), UNIT_AUTO, "autosize", NULL, NULL },
{ UNIT_AUTO, UNIT_AUTO, NULL, "AUTOSIZE",
NULL, NULL, NULL, "set type based on file size at ATTACH" },
{ (UNIT_AUTO+UNIT_DTYPE), (RM03_DTYPE << UNIT_V_DTYPE), NULL, "RM03",
&rp_set_size, NULL, NULL, "Set type to RM03" },
{ (UNIT_AUTO+UNIT_DTYPE), (RP04_DTYPE << UNIT_V_DTYPE), NULL, "RP04",
&rp_set_size, NULL, NULL, "Set type to RP04" },
{ (UNIT_AUTO+UNIT_DTYPE), (RM80_DTYPE << UNIT_V_DTYPE), NULL, "RM80",
&rp_set_size, NULL, NULL, "Set type to RM80" },
{ (UNIT_AUTO+UNIT_DTYPE), (RP06_DTYPE << UNIT_V_DTYPE), NULL, "RP06",
&rp_set_size, NULL, NULL, "Set type to RP06" },
{ (UNIT_AUTO+UNIT_DTYPE), (RM05_DTYPE << UNIT_V_DTYPE), NULL, "RM05",
&rp_set_size, NULL, NULL, "Set type to RM05" },
{ (UNIT_AUTO+UNIT_DTYPE), (RP07_DTYPE << UNIT_V_DTYPE), NULL, "RP07",
&rp_set_size, NULL, NULL, "Set type to RP07" },
{ 0 }
};
/* debugging bitmaps */
#define DBG_TRC 0x0001 /* trace routine calls */
#define DBG_REG 0x0002 /* trace read/write registers */
#define DBG_REQ 0x0004 /* display transfer requests */
#define DBG_DSK 0x0008 /* display sim_disk activities */
#define DBG_DAT 0x0010 /* display transfer data */
DEBTAB rp_debug[] = {
{"TRACE", DBG_TRC, "trace routine calls"},
{"REG", DBG_REG, "trace read/write registers"},
{"REQ", DBG_REQ, "display transfer requests"},
{"DISK", DBG_DSK, "display sim_disk activities"},
{"DATA", DBG_DAT, "display transfer data"},
{0}
};
DEVICE rp_dev = {
"RP", rp_unit, rp_reg, rp_mod,
RP_NUMDR, DEV_RDX, 30, 1, DEV_RDX, 16,
NULL, NULL, &rp_reset,
&rp_boot, &rp_attach, &rp_detach,
&rp_dib, DEV_DISABLE | DEV_UBUS | DEV_QBUS | DEV_MBUS | DEV_DEBUG | DEV_DISK,
0, rp_debug, NULL, NULL, &rp_help, NULL, NULL,
&rp_description
};
const char *rp_regnam[] =
{
"RP_CS1", /* 0 */
"RP_DS", /* 1 */
"RP_ER1", /* 2 */
"RP_MR", /* 3 */
"RP_AS", /* 4 */
"RP_DA", /* 5 */
"RP_DT", /* 6 */
"RP_LA", /* 7 */
"RP_SN", /* 8 */
"RP_OF", /* 9 */
"RP_DC", /* 10 */
"RP_CC", /* 11 */
"RP_ER2", /* 12 */
"RP_ER3", /* 13 */
"RP_EC1", /* 14 */
"RP_EC2", /* 15 */
"16", /* 16 */
"17", /* 17 */
"18", /* 18 */
"19", /* 19 */
"20", /* 20 */
"21", /* 21 */
"22", /* 22 */
"23", /* 23 */
"24", /* 24 */
"25", /* 25 */
"26", /* 26 */
"27", /* 27 */
"28", /* 28 */
"29", /* 29 */
"30", /* 30 */
"31", /* 31 */
"RM_CS1", /* 32 */
"RM_DS", /* 33 */
"RM_ER1", /* 34 */
"RM_MR", /* 35 */
"RM_AS", /* 36 */
"RM_DA", /* 37 */
"RM_DT", /* 38 */
"RM_LA", /* 39 */
"RM_SN", /* 40 */
"RM_OF", /* 41 */
"RM_DC", /* 42 */
"RM_CC", /* 43 */
"RM_MR2", /* 44 */
"RM_ER2", /* 45 */
"RM_EC1", /* 46 */
"RM_EC2", /* 47 */
"48", /* 48 */
"49", /* 49 */
"50", /* 50 */
"51", /* 51 */
"52", /* 52 */
"53", /* 53 */
"54", /* 54 */
"55", /* 55 */
"56", /* 56 */
"57", /* 57 */
"58", /* 58 */
"59", /* 59 */
"60", /* 60 */
"61", /* 61 */
"62", /* 62 */
"63", /* 63 */
};
/* Massbus register read */
t_stat rp_mbrd (int32 *data, int32 ofs, int32 drv)
{
uint32 val, dtype, i;
UNIT *uptr;
rp_update_ds (0, drv); /* update ds */
uptr = rp_dev.units + drv; /* get unit */
if (uptr->flags & UNIT_DIS) { /* nx disk */
*data = 0;
return MBE_NXD;
}
dtype = GET_DTYPE (uptr->flags); /* get drive type */
ofs = ofs & MBA_RMASK; /* mask offset */
if (drv_tab[dtype].ctrl == RM_CTRL) /* RM? convert */
ofs = ofs + RM_OF;
switch (ofs) { /* decode offset */
case RP_CS1_OF: case RM_CS1_OF: /* RPCS1 */
val = (rpcs1[drv] & CS1_RW) | CS1_DVA; /* DVA always set */
break;
case RP_DA_OF: case RM_DA_OF: /* RPDA */
val = rpda[drv] = rpda[drv] & ~DA_MBZ;
break;
case RP_DS_OF: case RM_DS_OF: /* RPDS */
val = rpds[drv];
break;
case RP_ER1_OF: case RM_ER1_OF: /* RPER1 */
val = rper1[drv];
break;
case RP_AS_OF: case RM_AS_OF: /* RPAS */
val = 0;
for (i = 0; i < RP_NUMDR; i++) {
if (rpds[i] & DS_ATA)
val |= (AS_U0 << i);
}
break;
case RP_LA_OF: case RM_LA_OF: /* RPLA */
val = GET_SECTOR (rp_rwait, dtype) << LA_V_SC;
break;
case RP_MR_OF: case RM_MR_OF: /* RPMR */
val = rpmr[drv];
break;
case RP_DT_OF: case RM_DT_OF: /* RPDT */
val = drv_tab[dtype].devtype;
break;
case RP_SN_OF: case RM_SN_OF: /* RPSN */
val = 020 | (drv + 1);
break;
case RP_OF_OF: case RM_OF_OF: /* RPOF */
val = rpof[drv] = rpof[drv] & ~OF_MBZ;
break;
case RP_DC_OF: case RM_DC_OF: /* RPDC */
val = rpdc[drv] = rpdc[drv] & ~DC_MBZ;
break;
case RP_CC_OF: /* RPCC */
val = rp_unit[drv].CYL;
break;
case RP_ER2_OF: case RM_ER2_OF: /* RPER2 */
val = rper2[drv];
break;
case RP_ER3_OF: /* RPER3 */
val = rper3[drv];
break;
case RP_EC1_OF: case RM_EC1_OF: /* RPEC1 */
val = rpec1[drv];
break;
case RP_EC2_OF: case RM_EC2_OF: /* RPEC2 */
val = rpec2[drv];
break;
case RM_HR_OF: /* RMHR */
val = rmhr[drv] ^ DMASK;
break;
case RM_MR2_OF: /* RHMR2 */
val = rmmr2[drv];
break;
default: /* all others */
*data = 0;
return MBE_NXR;
}
sim_debug(DBG_REG, &rp_dev, "rp_mbrd(drv=%d(%s), %s=0x%X)\n", drv, drv_tab[dtype].name, rp_regnam[ofs], val);
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], val, val, 1);
*data = val;
return SCPE_OK;
}
/* Massbus register write */
t_stat rp_mbwr (int32 data, int32 ofs, int32 drv)
{
uint32 old_reg;
UNIT *uptr = rp_dev.units + drv; /* get unit */
int32 dtype = GET_DTYPE (uptr->flags); /* get drive type */
sim_debug(DBG_REG, &rp_dev, "rp_mbwr(drv=%d(%s), %s=0x%X)\n", drv, drv_tab[dtype].name, rp_regnam[ofs], data);
if (uptr->flags & UNIT_DIS) /* nx disk */
return MBE_NXD;
if ((ofs != RP_AS_OF) && sim_is_active (uptr)) { /* unit busy? */
rp_set_er (ER1_RMR, drv); /* won't write */
rp_update_ds (0, drv);
return SCPE_OK;
}
rmhr[drv] = (uint16)data; /* save write */
ofs = ofs & MBA_RMASK; /* mask offset */
if (drv_tab[dtype].ctrl == RM_CTRL) /* RM? convert */
ofs = ofs + RM_OF;
switch (ofs) { /* decode PA<5:1> */
case RP_CS1_OF: case RM_CS1_OF: /* RPCS1 */
old_reg = rpcs1[drv];
rpcs1[drv] = data & CS1_RW;
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], old_reg, rpcs1[drv], 1);
if (data & CS1_GO) /* start op */
return rp_go (drv);
break;
case RP_DA_OF: case RM_DA_OF: /* RPDA */
old_reg = rpds[drv];
rpda[drv] = (uint16)(data & ~DA_MBZ);
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], old_reg, rpds[drv], 1);
break;
case RP_AS_OF: case RM_AS_OF: /* RPAS */
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], data, data, 1);
rp_clr_as (data);
break;
case RP_MR_OF: case RM_MR_OF: /* RPMR */
old_reg = rpmr[drv];
rpmr[drv] = (uint16)data;
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], old_reg, rpmr[drv], 1);
break;
case RP_OF_OF: case RM_OF_OF: /* RPOF */
old_reg = rpof[drv];
rpof[drv] = (uint16)(data & ~OF_MBZ);
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], old_reg, rpof[drv], 1);
break;
case RP_DC_OF: case RM_DC_OF: /* RPDC */
old_reg = rpdc[drv];
rpdc[drv] = (uint16)(data & ~DC_MBZ);
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], old_reg, rpdc[drv], 1);
break;
case RM_MR2_OF: /* RMMR2 */
old_reg = rmmr2[drv];
rmmr2[drv] = (uint16)data;
sim_debug_bits(DBG_REG, &rp_dev, rp_reg_bits[ofs], old_reg, rmmr2[drv], 1);
break;
case RP_ER1_OF: case RM_ER1_OF: /* RPER1 */
case RP_DS_OF: case RM_DS_OF: /* RPDS */
case RP_LA_OF: case RM_LA_OF: /* RPLA */
case RP_DT_OF: case RM_DT_OF: /* RPDT */
case RP_SN_OF: case RM_SN_OF: /* RPSN */
case RP_CC_OF: /* RPCC */
case RP_ER2_OF: case RM_ER2_OF: /* RPER2 */
case RP_ER3_OF: /* RPER3 */
case RP_EC1_OF: case RM_EC1_OF: /* RPEC1 */
case RP_EC2_OF: case RM_EC2_OF: /* RPEC2 */
case RM_HR_OF: /* RMHR */
break; /* read only */
default: /* all others */
return MBE_NXR;
} /* end switch */
rp_update_ds (0, drv); /* update status */
return SCPE_OK;
}
/* Initiate operation - unit not busy, function set */
t_stat rp_go (int32 drv)
{
int32 dc, fnc, t;
DEVICE *dptr = &rp_dev;
UNIT *uptr = dptr->units + drv; /* get unit */
int32 dtype = GET_DTYPE (uptr->flags); /* get drive type */
sim_debug(DBG_REQ, dptr, "rp_go(drv=%d(%s))\n", drv, drv_tab[dtype].name);
fnc = GET_FNC (rpcs1[drv]); /* get function */
sim_debug(DBG_REQ, dptr, ">>RP%d STRT: fnc=%s, ds=%o, cyl=%o, da=%o, er=%o\n",
drv, rp_fname[fnc], rpds[drv], rpdc[drv], rpda[drv], rper1[drv]);
rp_clr_as (AS_U0 << drv); /* clear attention */
dc = rpdc[drv]; /* assume seek, sch */
if ((fnc != FNC_DCLR) && (rpds[drv] & DS_ERR)) { /* err & ~clear? */
rp_set_er (ER1_ILF, drv); /* not allowed */
rp_update_ds (DS_ATA, drv); /* set attention */
return MBE_GOE;
}
switch (fnc) { /* case on function */
case FNC_RELEASE: /* port release */
case FNC_DCLR: /* drive clear */
rper1[drv] = rper2[drv] = rper3[drv] = 0; /* clear errors */
rpec2[drv] = 0; /* clear EC2 */
if (drv_tab[dtype].ctrl == RM_CTRL) /* RM? */
rpmr[drv] = 0; /* clear maint */
else rpec1[drv] = 0; /* RP, clear EC1 */
rpds[drv] = rpds[drv] & ~DS_ERR; /* Clear ERR */
case FNC_NOP: /* no operation */
sim_debug (DBG_REQ, dptr, ">>RP%d DONE: fnc=%s, ds=%o, cyl=%o, da=%o, er=%d\n",
drv, rp_fname[fnc], rpds[drv], rpdc[drv], rpda[drv], rper1[drv]);
return SCPE_OK;
case FNC_PRESET: /* read-in preset */
rpdc[drv] = 0; /* clear disk addr */
rpda[drv] = 0;
rpof[drv] = 0; /* clear offset */
case FNC_PACK: /* pack acknowledge */
rpds[drv] = rpds[drv] | DS_VV; /* set volume valid */
return SCPE_OK;
case FNC_OFFSET: /* offset mode */
case FNC_RETURN:
if ((uptr->flags & UNIT_ATT) == 0) { /* not attached? */
rp_set_er (ER1_UNS, drv); /* unsafe */
break;
}
rpds[drv] = (rpds[drv] & ~DS_RDY) | DS_PIP; /* set positioning */
sim_activate (uptr, rp_swait); /* time operation */
return SCPE_OK;
case FNC_UNLOAD: /* unload */
if (drv_tab[dtype].ctrl == RM_CTRL) { /* RM? */
rp_set_er (ER1_ILF, drv); /* not supported */
break;
}
rp_detach (uptr); /* detach unit */
return SCPE_OK;
case FNC_RECAL: /* recalibrate */
dc = 0; /* seek to 0 */
case FNC_SEEK: /* seek */
case FNC_SEARCH: /* search */
if ((uptr->flags & UNIT_ATT) == 0) { /* not attached? */
rp_set_er (ER1_UNS, drv); /* unsafe */
break;
}
if ((GET_CY (dc) >= drv_tab[dtype].cyl) || /* bad cylinder */
(GET_SF (rpda[drv]) >= drv_tab[dtype].surf) || /* bad surface */
(GET_SC (rpda[drv]) >= drv_tab[dtype].sect)) { /* or bad sector? */
rp_set_er (ER1_IAE, drv);
break;
}
rpds[drv] = (rpds[drv] & ~DS_RDY) | DS_PIP; /* set positioning */
t = abs (dc - uptr->CYL); /* cyl diff */
if (t == 0) /* min time */
t = 1;
sim_activate (uptr, rp_swait * t); /* schedule */
uptr->CYL = dc; /* save cylinder */
return SCPE_OK;
case FNC_WRITEH: /* write headers */
case FNC_WRITE: /* write */
case FNC_WCHK: /* write check */
case FNC_READ: /* read */
case FNC_READH: /* read headers */
if ((uptr->flags & UNIT_ATT) == 0) { /* not attached? */
rp_set_er (ER1_UNS, drv); /* unsafe */
break;
}
if ((GET_CY (dc) >= drv_tab[dtype].cyl) || /* bad cylinder */
(GET_SF (rpda[drv]) >= drv_tab[dtype].surf) || /* bad surface */
(GET_SC (rpda[drv]) >= drv_tab[dtype].sect)) { /* or bad sector? */
rp_set_er (ER1_IAE, drv);
break;
}
rpds[drv] = rpds[drv] & ~DS_RDY; /* clear drive rdy */
sim_activate (uptr, rp_rwait + (rp_swait * abs (dc - uptr->CYL)));
uptr->CYL = dc; /* save cylinder */
return SCPE_OK;
default: /* all others */
rp_set_er (ER1_ILF, drv); /* not supported */
break;
}
rp_update_ds (DS_ATA, drv); /* set attn, req int */
return MBE_GOE;
}
/* Abort opertion - there is a data transfer in progress */
int32 rp_abort (void)
{
sim_debug(DBG_TRC, &rp_dev, "rp_abort()\n");
return rp_reset (&rp_dev);
}
/* I/O completion callback */
void rp_io_complete (UNIT *uptr, t_stat status)
{
DEVICE *dptr = find_dev_from_unit (uptr);
sim_debug(DBG_TRC, dptr, "rp_io_complete(rp%d, status=%d)\n", (int)(uptr - dptr->units), status);
uptr->io_status = status;
uptr->io_complete = 1;
/* Initiate Bottom End processing */
sim_activate (uptr, 0);
}
/* Service unit timeout
Complete movement or data transfer command
Unit must exist - can't remove an active unit
Unit must be attached - detach cancels in progress operations
*/
t_stat rp_svc (UNIT *uptr)
{
int32 i, fnc, dtype, drv, err;
int32 wc, abc, awc, mbc, da;
DEVICE *dptr = find_dev_from_unit (uptr);
DIB *dibp = (DIB *) dptr->ctxt;
dtype = GET_DTYPE (uptr->flags); /* get drive type */
drv = (int32) (uptr - rp_dev.units); /* get drv number */
da = GET_DA (rpdc[drv], rpda[drv], dtype) * RP_NUMWD; /* get disk addr */
fnc = GET_FNC (rpcs1[drv]); /* get function */
sim_debug(DBG_TRC, dptr, "rp_svc(rp%d(%s), %s, da=0x%X, fnc=%s)\n", drv, drv_tab[dtype].name, uptr->io_complete ? "Bottom" : "Top", da, rp_fname[fnc]);
if ((uptr->flags & UNIT_ATT) == 0) { /* not attached? */
rp_set_er (ER1_UNS, drv); /* set drive error */
if (fnc >= FNC_XFER) /* xfr? set done */
mba_set_don (dibp->ba);
rp_update_ds (DS_ATA, drv); /* set attn */
return (rp_stopioe? SCPE_UNATT: SCPE_OK);
}
if (!uptr->io_complete) { /* Top End (I/O Initiation) Processing */
switch (fnc) { /* case on function */
case FNC_OFFSET: /* offset */
rp_update_ds (DS_OFM | DS_ATA, drv);
break;
case FNC_RETURN: /* return to centerline */
rpds[drv] = rpds[drv] & ~DS_OFM; /* clear offset, set attn */
rp_update_ds (DS_ATA, drv);
break;
case FNC_RECAL: /* recalibrate */
case FNC_SEARCH: /* search */
case FNC_SEEK: /* seek */
rp_update_ds (DS_ATA, drv);
break;
case FNC_WRITE: /* write */
if (uptr->flags & UNIT_WPRT) { /* write locked? */
rp_set_er (ER1_WLE, drv); /* set drive error */
mba_set_exc (dibp->ba); /* set exception */
rp_update_ds (DS_ATA, drv); /* set attn */
return SCPE_OK;
}
/* fall through */
case FNC_WCHK: /* write check */
case FNC_READ: /* read */
case FNC_READH: /* read headers */
mbc = rpxbc[drv] = (uint16)mba_get_bc (dibp->ba);/* get byte count */
wc = (mbc + 1) >> 1; /* convert to words */
if ((da + wc) > drv_tab[dtype].size) { /* disk overrun? */
rp_set_er (ER1_AOE, drv); /* set err */
wc = drv_tab[dtype].size - da; /* trim xfer */
mbc = wc << 1; /* trim mb count */
if (da >= drv_tab[dtype].size) { /* none left? */
mba_set_exc (dibp->ba); /* set exception */
rp_update_ds (DS_ATA, drv); /* set attn */
break;
}
}
if (fnc == FNC_WRITE) { /* write? */
abc = mba_rdbufW (dibp->ba, mbc, rpxb[drv]);/* get buffer */
wc = (abc + 1) >> 1; /* actual # wds */
awc = (wc + (RP_NUMWD - 1)) & ~(RP_NUMWD - 1);
for (i = wc; i < awc; i++) /* fill buf */
rpxb[drv][i] = 0;
sim_disk_data_trace (uptr, (uint8 *)rpxb[drv], da/RP_NUMWD, awc, "sim_disk_wrsect-WR", DBG_DAT & dptr->dctrl, DBG_REQ);
sim_disk_wrsect_a (uptr, da/RP_NUMWD, (uint8 *)rpxb[drv], NULL, awc/RP_NUMWD, rp_io_complete);
return SCPE_OK;
} /* end if wr */
else { /* read or wchk */
awc = (wc + (RP_NUMWD - 1)) & ~(RP_NUMWD - 1);
sim_disk_rdsect_a (uptr, da/RP_NUMWD, (uint8 *)rpxb[drv], (t_seccnt*)&uptr->sectsread, awc/RP_NUMWD, rp_io_complete);
return SCPE_OK;
} /* end if read */
case FNC_WRITEH: /* write headers stub */
mba_set_don (dibp->ba); /* set done */
rp_update_ds (0, drv); /* update ds */
break;
} /* end case func */
}
else { /* Bottom End (After I/O processing) */
uptr->io_complete = 0;
err = uptr->io_status;
switch (fnc) { /* case on function */
/* Functions having no Bottom since they are complete in the Top half */
case FNC_OFFSET: /* offset */
case FNC_RETURN: /* return to centerline */
case FNC_UNLOAD: /* unload */
case FNC_RECAL: /* recalibrate */
case FNC_SEARCH: /* search */
case FNC_SEEK: /* seek */
case FNC_WRITEH: /* write headers stub */
abort (); /* should NEVER happen */
break;
case FNC_WRITE: /* write */
case FNC_WCHK: /* write check */
case FNC_READ: /* read */
case FNC_READH: /* read headers */
mbc = rpxbc[drv]; /* get byte count */
wc = (mbc + 1) >> 1; /* convert to words */
if (fnc == FNC_WRITE) { /* write? */
} /* end if wr */
else { /* read or wchk */
awc = uptr->sectsread * RP_NUMWD;
sim_disk_data_trace (uptr, (uint8*)rpxb[drv], da/RP_NUMWD, awc << 1, "sim_disk_rdsect", DBG_DAT & dptr->dctrl, DBG_REQ);
for (i = awc; i < wc; i++) /* fill buf */
rpxb[drv][i] = 0;
if (fnc == FNC_WCHK) /* write check? */
mba_chbufW (dibp->ba, mbc, rpxb[drv]); /* check vs mem */
else mba_wrbufW (dibp->ba, mbc, rpxb[drv]);/* store in mem */
} /* end if read */
da = da + wc + (RP_NUMWD - 1);
if (da >= drv_tab[dtype].size)
rpds[drv] = rpds[drv] | DS_LST;
da = da / RP_NUMWD;
rpda[drv] = (uint16)(da % drv_tab[dtype].sect);
da = da / drv_tab[dtype].sect;
rpda[drv] = (uint16)(rpda[drv] | ((da % drv_tab[dtype].surf) << DA_V_SF));
rpdc[drv] = (uint16)(da / drv_tab[dtype].surf);
uptr->CYL = rpdc[drv];
if (err != 0) { /* error? */
rp_set_er (ER1_PAR, drv); /* set drive error */
mba_set_exc (dibp->ba); /* set exception */
rp_update_ds (DS_ATA, drv);
sim_perror ("RP I/O error");
return SCPE_IOERR;
}
mba_set_don (dibp->ba); /* set done */
rp_update_ds (0, drv); /* update ds */
break;
} /* end case func */
}
rpds[drv] = (rpds[drv] & ~DS_PIP) | DS_RDY; /* change drive status */
sim_debug (DBG_REQ, dptr, ">>RP%d DONE: fnc=%s, ds=%o, cyl=%o, da=%o, er=%d\n",
drv, rp_fname[fnc], rpds[drv], rpdc[drv], rpda[drv], rper1[drv]);
return SCPE_OK;
}
/* Set drive error */
void rp_set_er (int16 flag, int32 drv)
{
sim_debug(DBG_TRC, &rp_dev, "rp_set_er(rp%d, flag=0x%X)\n", drv, flag);
rper1[drv] = rper1[drv] | flag;
rpds[drv] = rpds[drv] | DS_ATA;
mba_upd_ata (rp_dib.ba, 1);
return;
}
/* Clear attention flags */
void rp_clr_as (int32 mask)
{
uint32 i, as;
for (i = as = 0; i < RP_NUMDR; i++) {
if (mask & (AS_U0 << i))
rpds[i] &= ~DS_ATA;
if (rpds[i] & DS_ATA)
as = 1;
}
sim_debug(DBG_TRC, &rp_dev, "rp_clr_as(mask=0x%X, as=0x%X)\n", mask, as);
mba_upd_ata (rp_dib.ba, as);
return;
}
/* Drive status update */
void rp_update_ds (uint16 flag, int32 drv)
{
uint16 o_ds = rpds[drv];
if (rp_unit[drv].flags & UNIT_DIS)
rpds[drv] = rper1[drv] = 0;
else rpds[drv] = (rpds[drv] | DS_DPR) & ~DS_PGM;
if (rp_unit[drv].flags & UNIT_ATT)
rpds[drv] = rpds[drv] | DS_MOL;
else rpds[drv] = rpds[drv] & ~(DS_MOL | DS_VV | DS_RDY);
if (rper1[drv] | rper2[drv] | rper3[drv])
rpds[drv] = rpds[drv] | DS_ERR;
else rpds[drv] = rpds[drv] & ~DS_ERR;
rpds[drv] = rpds[drv] | flag;
if (flag & DS_ATA)
mba_upd_ata (rp_dib.ba, 1);
if (o_ds != rpds[drv]) {
sim_debug(DBG_TRC, &rp_dev, "rp_update_ds(rp%d, flag=0x%X, ds=0x%X)\n", drv, flag, rpds[drv]);
sim_debug_bits(DBG_TRC, &rp_dev, rp_ds_bits, o_ds, rpds[drv], 1);
}
return;
}
/* Device reset */
t_stat rp_reset (DEVICE *dptr)
{
int32 i;
UNIT *uptr;
sim_debug(DBG_TRC, dptr, "rp_reset()\n");
mba_set_enbdis (dptr);
for (i = 0; i < RP_NUMDR; i++) {
uptr = dptr->units + i;
sim_cancel (uptr);
uptr->CYL = 0;
if (uptr->flags & UNIT_ATT)
rpds[i] = (rpds[i] & DS_VV) | DS_DPR | DS_RDY | DS_MOL |
((uptr->flags & UNIT_WPRT)? DS_WRL: 0);
else if (uptr->flags & UNIT_DIS)
rpds[i] = 0;
else rpds[i] = DS_DPR;
rpcs1[i] = 0;
rper1[i] = 0;
rpof[i] = 0;
rpdc[i] = 0;
rpda[i] = 0;
rpmr[i] = 0;
rper2[i] = 0;
rper3[i] = 0;
rpec1[i] = 0;
rpec2[i] = 0;
rmmr2[i] = 0;
rmhr[i] = 0;
if (rpxb[i] == NULL)
rpxb[i] = (uint16 *) calloc (RP_MAXFR, sizeof (uint16));
if (rpxb[i] == NULL)
return SCPE_MEM;
}
return SCPE_OK;
}
/* Device attach */
t_stat rp_attach (UNIT *uptr, CONST char *cptr)
{
int32 drv, i, p;
t_stat r;
DEVICE *dptr = find_dev_from_unit (uptr);
uptr->capac = drv_tab[GET_DTYPE (uptr->flags)].size;
r = sim_disk_attach (uptr, cptr, RP_NUMWD * sizeof (uint16),
sizeof (uint16), TRUE, 0,
drv_tab[GET_DTYPE (uptr->flags)].name, drv_tab[GET_DTYPE (uptr->flags)].sect, 0);
if (r != SCPE_OK) /* error? */
return r;
drv = (int32) (uptr - dptr->units); /* get drv number */
rpds[drv] = DS_MOL | DS_RDY | DS_DPR | /* upd drv status */
((uptr->flags & UNIT_WPRT)? DS_WRL: 0);
rper1[drv] = 0;
rp_update_ds (DS_ATA, drv); /* upd ctlr status */
if ((uptr->flags & UNIT_AUTO) == 0) /* autosize? */
return SCPE_OK;
p = (int32)sim_disk_size (uptr);
for (i = 0; drv_tab[i].sect != 0; i++) {
if (p <= (drv_tab[i].size * (int) sizeof (int16))) {
uptr->flags = (uptr->flags & ~UNIT_DTYPE) | (i << UNIT_V_DTYPE);
uptr->capac = drv_tab[i].size;
return SCPE_OK;
}
}
return SCPE_OK;
}
/* Device detach */
t_stat rp_detach (UNIT *uptr)
{
int32 drv;
DEVICE *dptr = find_dev_from_unit (uptr);
if (!(uptr->flags & UNIT_ATT)) /* attached? */
return SCPE_OK;
drv = (int32) (uptr - dptr->units); /* get drv number */
rpds[drv] = rpds[drv] & ~(DS_MOL | DS_RDY | DS_WRL | DS_VV | DS_OFM);
if (!sim_is_running) /* from console? */
rp_update_ds (DS_ATA, drv); /* request intr */
return sim_disk_detach (uptr);
}
/* Set size command validation routine */
t_stat rp_set_size (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
{
int32 dtype = GET_DTYPE (val);
if (uptr->flags & UNIT_ATT)
return SCPE_ALATT;
uptr->capac = drv_tab[dtype].size;
return SCPE_OK;
}
/* Set bad block routine */
t_stat rp_set_bad (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
{
return pdp11_bad_block (uptr, drv_tab[GET_DTYPE (uptr->flags)].sect, RP_NUMWD);
}
/* Boot routine */
#if defined (VM_PDP11)
#define BOOT_START 02000 /* start */
#define BOOT_ENTRY (BOOT_START + 002) /* entry */
#define BOOT_UNIT (BOOT_START + 010) /* unit number */
#define BOOT_CSR (BOOT_START + 014) /* CSR */
#define BOOT_LEN (sizeof (boot_rom) / sizeof (uint16))
static const uint16 boot_rom[] = {
0042102, /* "BD" */
0012706, BOOT_START, /* mov #boot_start, sp */
0012700, 0000000, /* mov #unit, r0 */
0012701, 0176700, /* mov #RPCS1, r1 */
0012761, 0000040, 0000010, /* mov #CS2_CLR, 10(r1) ; reset */
0010061, 0000010, /* mov r0, 10(r1) ; set unit */
0012711, 0000021, /* mov #RIP+GO, (r1) ; pack ack */
0012761, 0010000, 0000032, /* mov #FMT16B, 32(r1) ; 16b mode */
0012761, 0177000, 0000002, /* mov #-512., 2(r1) ; set wc */
0005061, 0000004, /* clr 4(r1) ; clr ba */
0005061, 0000006, /* clr 6(r1) ; clr da */
0005061, 0000034, /* clr 34(r1) ; clr cyl */
0012711, 0000071, /* mov #READ+GO, (r1) ; read */
0105711, /* tstb (r1) ; wait */
0100376, /* bpl .-2 */
0005002, /* clr R2 */
0005003, /* clr R3 */
0012704, BOOT_START+020, /* mov #start+020, r4 */
0005005, /* clr R5 */
0105011, /* clrb (r1) */
0005007 /* clr PC */
};
t_stat rp_boot (int32 unitno, DEVICE *dptr)
{
size_t i;
UNIT *uptr = dptr->units + unitno;
for (i = 0; i < BOOT_LEN; i++)
M[(BOOT_START >> 1) + i] = boot_rom[i];
M[BOOT_UNIT >> 1] = unitno & (RP_NUMDR - 1);
M[BOOT_CSR >> 1] = mba_get_csr (rp_dib.ba) & DMASK;
if (drv_tab[GET_DTYPE (uptr->flags)].ctrl == RP_CTRL)
M[BOOT_START >> 1] = 042102; /* "BD" */
else M[BOOT_START >> 1] = 042122; /* "RD" */
cpu_set_boot (BOOT_ENTRY);
return SCPE_OK;
}
#else
t_stat rp_boot (int32 unitno, DEVICE *dptr)
{
return SCPE_NOFNC;
}
#endif
t_stat rp_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
fprintf (st, "RP04/05/06/07, RM02/03/05/80 Disk Pack Drives (RP)\n\n");
fprintf (st, "The RP controller implements the Massbus family of large disk drives. RP\n");
fprintf (st, "options include the ability to set units write enabled or write locked, to\n");
fprintf (st, "set the drive type to one of six disk types or autosize, and to write a DEC\n");
fprintf (st, "standard 044 compliant bad block table on the last track.\n\n");
fprint_set_help (st, dptr);
fprint_show_help (st, dptr);
fprintf (st, "\nThe type options can be used only when a unit is not attached to a file.\n");
fprintf (st, "The bad block option can be used only when a unit is attached to a file.\n");
fprintf (st, "The RP device supports the BOOT command.\n");
fprint_reg_help (st, dptr);
fprintf (st, "\nError handling is as follows:\n\n");
fprintf (st, " error STOP_IOE processed as\n");
fprintf (st, " not attached 1 report error and stop\n");
fprintf (st, " 0 disk not ready\n\n");
fprintf (st, " end of file x assume rest of disk is zero\n");
fprintf (st, " OS I/O error x report error and stop\n");
fprintf (st, "\nDisk drives on the %s device can be attacbed to simulated storage in the\n", dptr->name);
fprintf (st, "following ways:\n\n");
sim_disk_attach_help (st, dptr, uptr, flag, cptr);
return SCPE_OK;
}
const char *rp_description (DEVICE *dptr)
{
return "RP04/05/06/07 RM02/03/05/80 Massbus disk controller";
}