/* vax_sysreg.c: VAX system registers simulator | |
Copyright (c) 1998-2002, 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. | |
This module contains the CVAX system-specific devices implemented in the | |
CMCTL memory controller and the SSC system support chip. (The architecturally | |
specified devices are implemented in module vax_stddev.c.) | |
rom bootstrap ROM (no registers) | |
nvr non-volatile ROM (no registers) | |
csi console storage input | |
cso console storage output | |
sysd system devices (SSC miscellany) | |
19-Aug-02 RMS Removed unused variables (found by David Hittner) | |
Allowed NVR to be attached to file | |
30-May-02 RMS Widened POS to 32b | |
28-Feb-02 RMS Fixed bug, missing end of table (found by Lars Brinkhoff) | |
*/ | |
#include "vax_defs.h" | |
/* Console storage control/status */ | |
#define CSICSR_IMP (CSR_DONE + CSR_IE) /* console input */ | |
#define CSICSR_RW (CSR_IE) | |
#define CSOCSR_IMP (CSR_DONE + CSR_IE) /* console output */ | |
#define CSOCSR_RW (CSR_IE) | |
/* CMCTL configuration registers */ | |
#define CMCNF_VLD 0x80000000 /* addr valid */ | |
#define CMCNF_BA 0x1FF00000 /* base addr */ | |
#define CMCNF_LOCK 0x00000040 /* lock NI */ | |
#define CMCNF_SRQ 0x00000020 /* sig req WO */ | |
#define CMCNF_SIG 0x0000001F /* signature */ | |
#define CMCNF_RW (CMCNF_VLD | CMCNF_BA) /* read/write */ | |
#define CMCNF_MASK (CMCNF_RW | CMCNF_SIG) | |
#define MEM_BANK (1 << 22) /* bank size 4MB */ | |
#define MEM_SIG 0x17; /* ECC, 4 x 4MB */ | |
/* CMCTL error register */ | |
#define CMERR_RDS 0x80000000 /* uncorr err NI */ | |
#define CMERR_FRQ 0x40000000 /* 2nd RDS NI */ | |
#define CMERR_CRD 0x20000000 /* CRD err NI */ | |
#define CMERR_PAG 0x1FFFFC00 /* page addr NI */ | |
#define CMERR_DMA 0x00000100 /* DMA err NI */ | |
#define CMERR_BUS 0x00000080 /* bus err NI */ | |
#define CMERR_SYN 0x0000007F /* syndrome NI */ | |
#define CMERR_W1C (CMERR_RDS | CMERR_FRQ | CMERR_CRD | \ | |
CMERR_DMA | CMERR_BUS) | |
/* CMCTL control/status register */ | |
#define CMCSR_PMI 0x00002000 /* PMI speed NI */ | |
#define CMCSR_CRD 0x00001000 /* enb CRD int NI */ | |
#define CMCSR_FRF 0x00000800 /* force ref WONI */ | |
#define CMCSR_DET 0x00000400 /* dis err NI */ | |
#define CMCSR_FDT 0x00000200 /* fast diag NI */ | |
#define CMCSR_DCM 0x00000080 /* diag mode NI */ | |
#define CMCSR_SYN 0x0000007F /* syndrome NI */ | |
#define CMCSR_MASK (CMCSR_PMI | CMCSR_CRD | CMCSR_DET | \ | |
CMCSR_FDT | CMCSR_DCM | CMCSR_SYN) | |
/* KA655 cache control register */ | |
#define CACR_DRO 0x00FFFF00 /* diag bits RO */ | |
#define CACR_V_DPAR 24 /* data parity */ | |
#define CACR_FIXED 0x00000040 /* fixed bits */ | |
#define CACR_CPE 0x00000020 /* parity err W1C */ | |
#define CACR_CEN 0x00000010 /* enable */ | |
#define CACR_DPE 0x00000004 /* disable par NI */ | |
#define CACR_WWP 0x00000002 /* write wrong par NI */ | |
#define CACR_DIAG 0x00000001 /* diag mode */ | |
#define CACR_W1C (CACR_CPE) | |
#define CACR_RW (CACR_CEN | CACR_DPE | CACR_WWP | CACR_DIAG) | |
/* SSC base register */ | |
#define SSCBASE_MBO 0x20000000 /* must be one */ | |
#define SSCBASE_RW 0x1FFFFC00 /* base address */ | |
/* SSC configuration register */ | |
#define SSCCNF_BLO 0x80000000 /* batt low W1C */ | |
#define SSCCNF_IVD 0x08000000 /* int dsbl NI */ | |
#define SSCCNF_IPL 0x03000000 /* int IPL NI */ | |
#define SSCCNF_ROM 0x00F70000 /* ROM param NI */ | |
#define SSCCNF_CTLP 0x00008000 /* ctrl P enb */ | |
#define SSCCNF_BAUD 0x00007700 /* baud rates NI */ | |
#define SSCCNF_ADS 0x00000077 /* addr strb NI */ | |
#define SSCCNF_W1C SSCCNF_BLO | |
#define SSCCNF_RW 0x0BF7F777 | |
/* SSC timeout register */ | |
#define SSCBTO_BTO 0x80000000 /* timeout W1C */ | |
#define SSCBTO_RWT 0x40000000 /* read/write W1C */ | |
#define SSCBTO_INTV 0x00FFFFFF /* interval NI */ | |
#define SSCBTO_W1C (SSCBTO_BTO | SSCBTO_RWT) | |
#define SSCBTO_RW SSCBTO_INTV | |
/* SSC output port */ | |
#define SSCOTP_MASK 0x0000000F /* output port */ | |
/* SSC timer control/status */ | |
#define TMR_CSR_ERR 0x80000000 /* error W1C */ | |
#define TMR_CSR_DON 0x00000080 /* done W1C */ | |
#define TMR_CSR_IE 0x00000040 /* int enb */ | |
#define TMR_CSR_SGL 0x00000020 /* single WO */ | |
#define TMR_CSR_XFR 0x00000010 /* xfer WO */ | |
#define TMR_CSR_STP 0x00000004 /* stop */ | |
#define TMR_CSR_RUN 0x00000001 /* run */ | |
#define TMR_CSR_W1C (TMR_CSR_ERR | TMR_CSR_DON) | |
#define TMR_CSR_RW (TMR_CSR_IE | TMR_CSR_STP | TMR_CSR_RUN) | |
/* SSC timer intervals */ | |
#define TMR_INC 10000 /* usec/interval */ | |
/* SSC timer vector */ | |
#define TMR_VEC_MASK 0x000003FC /* vector */ | |
/* SSC address strobes */ | |
#define SSCADS_MASK 0x3FFFFFFC /* match or mask */ | |
extern int32 int_req[IPL_HLVL]; | |
extern UNIT cpu_unit; | |
extern jmp_buf save_env; | |
extern int32 p1; | |
extern int32 sim_switches; | |
extern int32 MSER; | |
extern int32 tmr_poll; | |
uint32 *rom = NULL; /* boot ROM */ | |
uint32 *nvr = NULL; /* non-volatile mem */ | |
int32 csi_csr = 0; /* control/status */ | |
int32 cso_csr = 0; /* control/status */ | |
int32 cmctl_reg[CMCTLSIZE >> 2] = { 0 }; /* CMCTL reg */ | |
int32 ka_cacr = 0; /* KA655 cache ctl */ | |
int32 ka_bdr = 0x80; /* KA655 boot diag */ | |
int32 ssc_base = SSCBASE; /* SSC base */ | |
int32 ssc_cnf = 0; /* SSC conf */ | |
int32 ssc_bto = 0; /* SSC timeout */ | |
int32 ssc_otp = 0; /* SSC output port */ | |
int32 tmr_csr[2] = { 0 }; /* SSC timers */ | |
uint32 tmr_tir[2] = { 0 }; /* curr interval */ | |
uint32 tmr_tnir[2] = { 0 }; /* next interval */ | |
int32 tmr_tivr[2] = { 0 }; /* vector */ | |
uint32 tmr_inc[2] = { 0 }; /* tir increment */ | |
uint32 tmr_sav[2] = { 0 }; /* saved inst cnt */ | |
int32 ssc_adsm[2] = { 0 }; /* addr strobes */ | |
int32 ssc_adsk[2] = { 0 }; | |
int32 cdg_dat[CDASIZE >> 2]; /* cache data */ | |
t_stat rom_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat rom_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat rom_reset (DEVICE *dptr); | |
t_stat nvr_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat nvr_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat nvr_reset (DEVICE *dptr); | |
t_stat nvr_attach (UNIT *uptr, char *cptr); | |
t_stat nvr_detach (UNIT *uptr); | |
t_stat csi_reset (DEVICE *dptr); | |
t_stat cso_reset (DEVICE *dptr); | |
t_stat cso_svc (UNIT *uptr); | |
t_stat tmr_svc (UNIT *uptr); | |
t_stat sysd_reset (DEVICE *dptr); | |
int32 rom_rd (int32 pa); | |
int32 nvr_rd (int32 pa); | |
void nvr_wr (int32 pa, int32 val, int32 lnt); | |
int32 csrs_rd (void); | |
int32 csrd_rd (void); | |
int32 csts_rd (void); | |
void csrs_wr (int32 dat); | |
void csts_wr (int32 dat); | |
void cstd_wr (int32 dat); | |
int32 cmctl_rd (int32 pa); | |
void cmctl_wr (int32 pa, int32 val, int32 lnt); | |
int32 ka_rd (int32 pa); | |
void ka_wr (int32 pa, int32 val, int32 lnt); | |
int32 cdg_rd (int32 pa); | |
void cdg_wr (int32 pa, int32 val, int32 lnt); | |
int32 ssc_rd (int32 pa); | |
void ssc_wr (int32 pa, int32 val, int32 lnt); | |
int32 tmr_tir_rd (int32 tmr, t_bool interp); | |
void tmr_csr_wr (int32 tmr, int32 val); | |
void tmr_sched (int32 tmr); | |
void tmr_incr (int32 tmr, uint32 inc); | |
int32 tmr0_inta (void); | |
int32 tmr1_inta (void); | |
int32 parity (int32 val, int32 odd); | |
extern int32 cqmap_rd (int32 pa); | |
extern void cqmap_wr (int32 pa, int32 val, int32 lnt); | |
extern int32 cqipc_rd (int32 pa); | |
extern void cqipc_wr (int32 pa, int32 val, int32 lnt); | |
extern int32 cqbic_rd (int32 pa); | |
extern void cqbic_wr (int32 pa, int32 val, int32 lnt); | |
extern int32 cqmem_rd (int32 pa); | |
extern void cqmem_wr (int32 pa, int32 val, int32 lnt); | |
extern int32 iccs_rd (void); | |
extern int32 todr_rd (void); | |
extern int32 rxcs_rd (void); | |
extern int32 rxdb_rd (void); | |
extern int32 txcs_rd (void); | |
extern void iccs_wr (int32 dat); | |
extern void todr_wr (int32 dat); | |
extern void rxcs_wr (int32 dat); | |
extern void txcs_wr (int32 dat); | |
extern void txdb_wr (int32 dat); | |
extern void ioreset_wr (int32 dat); | |
/* ROM data structures | |
rom_dev ROM device descriptor | |
rom_unit ROM units | |
rom_reg ROM register list | |
*/ | |
UNIT rom_unit = { UDATA (NULL, UNIT_FIX+UNIT_BINK, ROMSIZE) }; | |
REG rom_reg[] = { | |
{ NULL } }; | |
DEVICE rom_dev = { | |
"ROM", &rom_unit, rom_reg, NULL, | |
1, 16, ROMAWIDTH, 4, 16, 32, | |
&rom_ex, &rom_dep, &rom_reset, | |
NULL, NULL, NULL, | |
NULL, 0 }; | |
/* NVR data structures | |
nvr_dev NVR device descriptor | |
nvr_unit NVR units | |
nvr_reg NVR register list | |
*/ | |
UNIT nvr_unit = | |
{ UDATA (NULL, UNIT_FIX+UNIT_BINK, NVRSIZE) }; | |
REG nvr_reg[] = { | |
{ NULL } }; | |
DEVICE nvr_dev = { | |
"NVR", &nvr_unit, nvr_reg, NULL, | |
1, 16, NVRAWIDTH, 4, 16, 32, | |
&nvr_ex, &nvr_dep, &nvr_reset, | |
NULL, &nvr_attach, &nvr_detach, | |
NULL, 0 }; | |
/* CSI data structures | |
csi_dev CSI device descriptor | |
csi_unit CSI unit descriptor | |
csi_reg CSI register list | |
*/ | |
DIB csi_dib = { 0, 0, NULL, NULL, 1, IVCL (CSI), SCB_CSI, { NULL } }; | |
UNIT csi_unit = { UDATA (NULL, 0, 0), KBD_POLL_WAIT }; | |
REG csi_reg[] = { | |
{ ORDATA (BUF, csi_unit.buf, 8) }, | |
{ ORDATA (CSR, csi_csr, 16) }, | |
{ FLDATA (INT, int_req[IPL_CSI], INT_V_CSI) }, | |
{ FLDATA (DONE, csi_csr, CSR_V_DONE) }, | |
{ FLDATA (IE, csi_csr, CSR_V_IE) }, | |
{ DRDATA (POS, csi_unit.pos, 32), PV_LEFT }, | |
{ DRDATA (TIME, csi_unit.wait, 24), REG_NZ + PV_LEFT }, | |
{ NULL } }; | |
MTAB csi_mod[] = { | |
{ MTAB_XTD|MTAB_VDV, 0, "VECTOR", NULL, NULL, &show_vec }, | |
{ 0 } }; | |
DEVICE csi_dev = { | |
"CSI", &csi_unit, csi_reg, csi_mod, | |
1, 10, 31, 1, 8, 8, | |
NULL, NULL, &csi_reset, | |
NULL, NULL, NULL, | |
&csi_dib, 0 }; | |
/* CSO data structures | |
cso_dev CSO device descriptor | |
cso_unit CSO unit descriptor | |
cso_reg CSO register list | |
*/ | |
DIB cso_dib = { 0, 0, NULL, NULL, 1, IVCL (CSO), SCB_CSO, { NULL } }; | |
UNIT cso_unit = { UDATA (&cso_svc, UNIT_SEQ+UNIT_ATTABLE, 0), SERIAL_OUT_WAIT }; | |
REG cso_reg[] = { | |
{ ORDATA (BUF, cso_unit.buf, 8) }, | |
{ ORDATA (CSR, cso_csr, 16) }, | |
{ FLDATA (INT, int_req[IPL_CSO], INT_V_CSO) }, | |
{ FLDATA (DONE, cso_csr, CSR_V_DONE) }, | |
{ FLDATA (IE, cso_csr, CSR_V_IE) }, | |
{ DRDATA (POS, cso_unit.pos, 32), PV_LEFT }, | |
{ DRDATA (TIME, cso_unit.wait, 24), PV_LEFT }, | |
{ NULL } }; | |
MTAB cso_mod[] = { | |
{ MTAB_XTD|MTAB_VDV, 0, "VECTOR", NULL, NULL, &show_vec }, | |
{ 0 } }; | |
DEVICE cso_dev = { | |
"CSO", &cso_unit, cso_reg, cso_mod, | |
1, 10, 31, 1, 8, 8, | |
NULL, NULL, &cso_reset, | |
NULL, NULL, NULL, | |
&cso_dib, 0 }; | |
/* SYSD data structures | |
sysd_dev SYSD device descriptor | |
sysd_unit SYSD units | |
sysd_reg SYSD register list | |
*/ | |
DIB sysd_dib[] = { 0, 0, NULL, NULL, | |
2, IVCL (TMR0), 0, { &tmr0_inta, &tmr1_inta } }; | |
UNIT sysd_unit[] = { | |
{ UDATA (&tmr_svc, 0, 0) }, | |
{ UDATA (&tmr_svc, 0, 0) } }; | |
REG sysd_reg[] = { | |
{ BRDATA (CMCSR, cmctl_reg, 16, 32, CMCTLSIZE >> 2) }, | |
{ HRDATA (CACR, ka_cacr, 8) }, | |
{ HRDATA (BDR, ka_bdr, 8) }, | |
{ HRDATA (BASE, ssc_base, 29) }, | |
{ HRDATA (CNF, ssc_cnf, 32) }, | |
{ HRDATA (BTO, ssc_bto, 32) }, | |
{ HRDATA (OTP, ssc_otp, 4) }, | |
{ HRDATA (TCSR0, tmr_csr[0], 32) }, | |
{ HRDATA (TIR0, tmr_tir[0], 32) }, | |
{ HRDATA (TNIR0, tmr_tnir[0], 32) }, | |
{ HRDATA (TIVEC0, tmr_tivr[0], 9) }, | |
{ HRDATA (TINC0, tmr_inc[0], 32) }, | |
{ HRDATA (TSAV0, tmr_sav[0], 32) }, | |
{ HRDATA (TCSR1, tmr_csr[1], 32) }, | |
{ HRDATA (TIR1, tmr_tir[1], 32) }, | |
{ HRDATA (TNIR1, tmr_tnir[1], 32) }, | |
{ HRDATA (TIVEC1, tmr_tivr[1], 9) }, | |
{ HRDATA (TINC1, tmr_inc[1], 32) }, | |
{ HRDATA (TSAV1, tmr_sav[1], 32) }, | |
{ HRDATA (ADSM0, ssc_adsm[0], 32) }, | |
{ HRDATA (ADSK0, ssc_adsk[0], 32) }, | |
{ HRDATA (ADSM1, ssc_adsm[1], 32) }, | |
{ HRDATA (ADSK1, ssc_adsk[1], 32) }, | |
{ BRDATA (CDGDAT, cdg_dat, 16, 32, CDASIZE >> 2) }, | |
{ NULL } }; | |
DEVICE sysd_dev = { | |
"SYSD", sysd_unit, sysd_reg, NULL, | |
2, 16, 16, 1, 16, 8, | |
NULL, NULL, &sysd_reset, | |
NULL, NULL, NULL, | |
&sysd_dib, 0 }; | |
/* ROM: read only memory - stored in a buffered file | |
Register space access routines see ROM twice | |
*/ | |
int32 rom_rd (int32 pa) | |
{ | |
int32 rg = ((pa - ROMBASE) & ROMAMASK) >> 2; | |
return rom[rg]; | |
} | |
void rom_wr (int32 pa, int32 val, int32 lnt) | |
{ | |
int32 rg = ((pa - ROMBASE) & ROMAMASK) >> 2; | |
if (lnt < L_LONG) { /* byte or word? */ | |
int32 sc = (pa & 3) << 3; /* merge */ | |
int32 mask = (lnt == L_WORD)? 0xFFFF: 0xFF; | |
rom[rg] = ((val & mask) << sc) | (rom[rg] & ~(mask << sc)); } | |
else rom[rg] = val; | |
return; | |
} | |
/* ROM examine */ | |
t_stat rom_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
if ((vptr == NULL) || (addr & 03)) return SCPE_ARG; | |
if (addr >= ROMSIZE) return SCPE_NXM; | |
*vptr = rom[addr >> 2]; | |
return SCPE_OK; | |
} | |
/* ROM deposit */ | |
t_stat rom_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
if (addr & 03) return SCPE_ARG; | |
if (addr >= ROMSIZE) return SCPE_NXM; | |
rom[addr >> 2] = (uint32) val; | |
return SCPE_OK; | |
} | |
/* ROM reset */ | |
t_stat rom_reset (DEVICE *dptr) | |
{ | |
if (rom == NULL) rom = calloc (ROMSIZE >> 2, sizeof (int32)); | |
if (rom == NULL) return SCPE_MEM; | |
return SCPE_OK; | |
} | |
/* NVR: non-volatile RAM - stored in a buffered file */ | |
int32 nvr_rd (int32 pa) | |
{ | |
int32 rg = (pa - NVRBASE) >> 2; | |
return nvr[rg]; | |
} | |
void nvr_wr (int32 pa, int32 val, int32 lnt) | |
{ | |
int32 rg = (pa - NVRBASE) >> 2; | |
if (lnt < L_LONG) { /* byte or word? */ | |
int32 sc = (pa & 3) << 3; /* merge */ | |
int32 mask = (lnt == L_WORD)? 0xFFFF: 0xFF; | |
nvr[rg] = ((val & mask) << sc) | (nvr[rg] & ~(mask << sc)); } | |
else nvr[rg] = val; | |
return; | |
} | |
/* NVR examine */ | |
t_stat nvr_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
if ((vptr == NULL) || (addr & 03)) return SCPE_ARG; | |
if (addr >= NVRSIZE) return SCPE_NXM; | |
*vptr = nvr[addr >> 2]; | |
return SCPE_OK; | |
} | |
/* NVR deposit */ | |
t_stat nvr_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
if (addr & 03) return SCPE_ARG; | |
if (addr >= NVRSIZE) return SCPE_NXM; | |
nvr[addr >> 2] = (uint32) val; | |
return SCPE_OK; | |
} | |
/* NVR reset */ | |
t_stat nvr_reset (DEVICE *dptr) | |
{ | |
if (nvr == NULL) { | |
nvr = calloc (NVRSIZE >> 2, sizeof (int32)); | |
nvr_unit.filebuf = nvr; | |
ssc_cnf = ssc_cnf | SSCCNF_BLO; } | |
if (nvr == NULL) return SCPE_MEM; | |
return SCPE_OK; | |
} | |
/* NVR attach */ | |
t_stat nvr_attach (UNIT *uptr, char *cptr) | |
{ | |
t_stat r; | |
uptr->flags = uptr->flags | (UNIT_ATTABLE | UNIT_BUFABLE); | |
r = attach_unit (uptr, cptr); | |
if (r != SCPE_OK) | |
uptr->flags = uptr->flags & ~(UNIT_ATTABLE | UNIT_BUFABLE); | |
else { uptr->hwmark = uptr->capac; | |
ssc_cnf = ssc_cnf & ~SSCCNF_BLO; } | |
return r; | |
} | |
/* NVR detach */ | |
t_stat nvr_detach (UNIT *uptr) | |
{ | |
t_stat r; | |
r = detach_unit (uptr); | |
if ((uptr->flags & UNIT_ATT) == 0) | |
uptr->flags = uptr->flags & ~(UNIT_ATTABLE | UNIT_BUFABLE); | |
return r; | |
} | |
/* CSI: console storage input */ | |
int32 csrs_rd (void) | |
{ | |
return (csi_csr & CSICSR_IMP); | |
} | |
int32 csrd_rd (void) | |
{ | |
csi_csr = csi_csr & ~CSR_DONE; | |
CLR_INT (CSI); | |
return (csi_unit.buf & 0377); | |
} | |
void csrs_wr (int32 data) | |
{ | |
if ((data & CSR_IE) == 0) CLR_INT (CSI); | |
else if ((csi_csr & (CSR_DONE + CSR_IE)) == CSR_DONE) | |
SET_INT (CSI); | |
csi_csr = (csi_csr & ~CSICSR_RW) | (data & CSICSR_RW); | |
return; | |
} | |
t_stat csi_reset (DEVICE *dptr) | |
{ | |
csi_unit.buf = 0; | |
csi_csr = 0; | |
CLR_INT (CSI); | |
return SCPE_OK; | |
} | |
/* CSO: console storage output */ | |
int32 csts_rd (void) | |
{ | |
return (cso_csr & CSOCSR_IMP); | |
} | |
void csts_wr (int32 data) | |
{ | |
if ((data & CSR_IE) == 0) CLR_INT (CSO); | |
else if ((cso_csr & (CSR_DONE + CSR_IE)) == CSR_DONE) | |
SET_INT (CSO); | |
cso_csr = (cso_csr & ~CSOCSR_RW) | (data & CSOCSR_RW); | |
return; | |
} | |
void cstd_wr (int32 data) | |
{ | |
cso_unit.buf = data & 0377; | |
cso_csr = cso_csr & ~CSR_DONE; | |
CLR_INT (CSO); | |
sim_activate (&cso_unit, cso_unit.wait); | |
return; | |
} | |
t_stat cso_svc (UNIT *uptr) | |
{ | |
cso_csr = cso_csr | CSR_DONE; | |
if (cso_csr & CSR_IE) SET_INT (CSO); | |
if ((cso_unit.flags & UNIT_ATT) == 0) return SCPE_OK; | |
if (putc (cso_unit.buf, cso_unit.fileref) == EOF) { | |
perror ("CSO I/O error"); | |
clearerr (cso_unit.fileref); | |
return SCPE_IOERR; } | |
cso_unit.pos = cso_unit.pos + 1; | |
return SCPE_OK; | |
} | |
t_stat cso_reset (DEVICE *dptr) | |
{ | |
cso_unit.buf = 0; | |
cso_csr = CSR_DONE; | |
CLR_INT (CSO); | |
sim_cancel (&cso_unit); /* deactivate unit */ | |
return SCPE_OK; | |
} | |
/* SYSD: SSC access mechanisms and devices | |
- IPR space read/write routines | |
- register space read/write routines | |
- SSC local register read/write routines | |
- SSC console storage UART | |
- SSC timers | |
- CMCTL local register read/write routines | |
*/ | |
/* Read/write IPR register space | |
These routines implement the SSC's response to IPR's which are | |
sent off the CPU chip for processing. | |
*/ | |
int32 ReadIPR (int32 rg) | |
{ | |
int32 val; | |
switch (rg) { | |
case MT_ICCS: /* ICCS */ | |
val = iccs_rd (); | |
break; | |
case MT_CSRS: /* CSRS */ | |
val = csrs_rd (); | |
break; | |
case MT_CSRD: /* CSRD */ | |
val = csrd_rd (); | |
break; | |
case MT_CSTS: /* CSTS */ | |
val = csts_rd (); | |
break; | |
case MT_CSTD: /* CSTD */ | |
val = 0; | |
break; | |
case MT_RXCS: /* RXCS */ | |
val = rxcs_rd (); | |
break; | |
case MT_RXDB: /* RXDB */ | |
val = rxdb_rd (); | |
break; | |
case MT_TXCS: /* TXCS */ | |
val = txcs_rd (); | |
break; | |
case MT_TXDB: /* TXDB */ | |
val = 0; | |
break; | |
case MT_TODR: | |
val = todr_rd (); | |
break; | |
default: | |
ssc_bto = ssc_bto | SSCBTO_BTO; /* set BTO */ | |
val = 0; | |
break; } | |
return val; | |
} | |
void WriteIPR (int32 rg, int32 val) | |
{ | |
switch (rg) { | |
case MT_ICCS: /* ICCS */ | |
iccs_wr (val); | |
break; | |
case MT_TODR: /* TODR */ | |
todr_wr (val); | |
break; | |
case MT_CSRS: /* CSRS */ | |
csrs_wr (val); | |
break; | |
case MT_CSRD: /* CSRD */ | |
break; | |
case MT_CSTS: /* CSTS */ | |
csts_wr (val); | |
break; | |
case MT_CSTD: /* CSTD */ | |
cstd_wr (val); | |
break; | |
case MT_RXCS: /* RXCS */ | |
rxcs_wr (val); | |
break; | |
case MT_RXDB: /* RXDB */ | |
break; | |
case MT_TXCS: /* TXCS */ | |
txcs_wr (val); | |
break; | |
case MT_TXDB: /* TXDB */ | |
txdb_wr (val); | |
break; | |
case MT_IORESET: /* IORESET */ | |
ioreset_wr (val); | |
break; | |
default: | |
ssc_bto = ssc_bto | SSCBTO_BTO; /* set BTO */ | |
break; } | |
return; | |
} | |
/* Read/write I/O register space | |
These routines are the 'catch all' for address space map. Any | |
address that doesn't explicitly belong to memory, I/O, or ROM | |
is given to these routines for processing. | |
*/ | |
struct reglink { /* register linkage */ | |
int32 low; /* low addr */ | |
int32 high; /* high addr */ | |
t_stat (*read)(); /* read routine */ | |
void (*write)(); }; /* write routine */ | |
struct reglink regtable[] = { | |
{ CQMAPBASE, CQMAPBASE+CQMAPSIZE, &cqmap_rd, &cqmap_wr }, | |
{ ROMBASE, ROMBASE+ROMSIZE+ROMSIZE, &rom_rd, NULL }, | |
{ NVRBASE, NVRBASE+NVRSIZE, &nvr_rd, &nvr_wr }, | |
{ CMCTLBASE, CMCTLBASE+CMCTLSIZE, &cmctl_rd, &cmctl_wr }, | |
{ SSCBASE, SSCBASE+SSCSIZE, &ssc_rd, &ssc_wr }, | |
{ KABASE, KABASE+KASIZE, &ka_rd, &ka_wr }, | |
{ CQBICBASE, CQBICBASE+CQBICSIZE, &cqbic_rd, &cqbic_wr }, | |
{ CQIPCBASE, CQIPCBASE+CQIPCSIZE, &cqipc_rd, &cqipc_wr }, | |
{ CQMBASE, CQMBASE+CQMSIZE, &cqmem_rd, &cqmem_wr }, | |
{ CDGBASE, CDGBASE+CDGSIZE, &cdg_rd, &cdg_wr }, | |
{ 0, 0, NULL, NULL } }; | |
/* ReadReg - read register space | |
Inputs: | |
pa = physical address | |
lnt = length (BWLQ) - ignored | |
Output: | |
longword of data | |
*/ | |
int32 ReadReg (int32 pa, int32 lnt) | |
{ | |
struct reglink *p; | |
for (p = ®table[0]; p->low != 0; p++) { | |
if ((pa >= p->low) && (pa < p->high) && p->read) | |
return p->read (pa); } | |
ssc_bto = ssc_bto | SSCBTO_BTO | SSCBTO_RWT; | |
MACH_CHECK (MCHK_READ); | |
return 0; | |
} | |
/* WriteReg - write register space | |
Inputs: | |
pa = physical address | |
val = data to write, right justified in 32b longword | |
lnt = length (BWLQ) | |
Outputs: | |
none | |
*/ | |
void WriteReg (int32 pa, int32 val, int32 lnt) | |
{ | |
struct reglink *p; | |
for (p = ®table[0]; p->low != 0; p++) { | |
if ((pa >= p->low) && (pa < p->high) && p->write) { | |
p->write (pa, val, lnt); | |
return; } } | |
ssc_bto = ssc_bto | SSCBTO_BTO | SSCBTO_RWT; | |
MACH_CHECK (MCHK_WRITE); | |
return; | |
} | |
/* CMCTL registers | |
CMCTL00 - 15 configure memory banks 00 - 15. Note that they are | |
here merely to entertain the firmware; the actual configuration | |
of memory is unaffected by the settings here. | |
CMCTL16 - error status register | |
CMCTL17 - control/diagnostic status register | |
The CMCTL registers are cleared at power up. | |
*/ | |
int32 cmctl_rd (int32 pa) | |
{ | |
int32 rg = (pa - CMCTLBASE) >> 2; | |
switch (rg) { | |
default: /* config reg */ | |
return cmctl_reg[rg] & CMCNF_MASK; | |
case 16: /* err status */ | |
return cmctl_reg[rg]; | |
case 17: /* csr */ | |
return cmctl_reg[rg] & CMCSR_MASK; } | |
return 0; | |
} | |
void cmctl_wr (int32 pa, int32 val, int32 lnt) | |
{ | |
int32 i, rg = (pa - CMCTLBASE) >> 2; | |
if (lnt < L_LONG) { /* LW write only */ | |
int32 sc = (pa & 3) << 3; /* shift data to */ | |
val = val << sc; } /* proper location */ | |
switch (rg) { | |
default: /* config reg */ | |
if (val & CMCNF_SRQ) { /* sig request? */ | |
for (i = rg; i < (rg + 4); i++) { | |
cmctl_reg[i] = cmctl_reg[i] & ~CMCNF_SIG; | |
if (ADDR_IS_MEM (i * MEM_BANK)) | |
cmctl_reg[i] = cmctl_reg[i] | MEM_SIG; } } | |
cmctl_reg[rg] = (cmctl_reg[rg] & ~CMCNF_RW) | (val & CMCNF_RW); | |
break; | |
case 16: /* err status */ | |
cmctl_reg[rg] = cmctl_reg[rg] & ~(val & CMERR_W1C); | |
break; | |
case 17: /* csr */ | |
cmctl_reg[rg] = val & CMCSR_MASK; | |
break; } | |
return; | |
} | |
/* KA655 registers */ | |
int32 ka_rd (int32 pa) | |
{ | |
int32 rg = (pa - KABASE) >> 2; | |
switch (rg) | |
{ | |
case 0: /* CACR */ | |
return ka_cacr; | |
case 1: /* BDR */ | |
return ka_bdr; } | |
return 0; | |
} | |
void ka_wr (int32 pa, int32 val, int32 lnt) | |
{ | |
int32 rg = (pa - KABASE) >> 2; | |
if ((rg == 0) && ((pa & 3) == 0)) { /* lo byte only */ | |
ka_cacr = (ka_cacr & ~(val & CACR_W1C)) | CACR_FIXED; | |
ka_cacr = (ka_cacr & ~CACR_RW) | (val & CACR_RW); } | |
return; | |
} | |
/* Cache diagnostic space - byte/word merges done in WriteReg */ | |
int32 cdg_rd (int32 pa) | |
{ | |
int32 t, row = CDG_GETROW (pa); | |
t = cdg_dat[row]; | |
ka_cacr = ka_cacr & ~CACR_DRO; /* clear diag */ | |
ka_cacr = ka_cacr | | |
(parity ((t >> 24) & 0xFF, 1) << (CACR_V_DPAR + 3)) | | |
(parity ((t >> 16) & 0xFF, 0) << (CACR_V_DPAR + 2)) | | |
(parity ((t >> 8) & 0xFF, 1) << (CACR_V_DPAR + 1)) | | |
(parity (t & 0xFF, 0) << CACR_V_DPAR); | |
return t; | |
} | |
void cdg_wr (int32 pa, int32 val, int32 lnt) | |
{ | |
int32 row = CDG_GETROW (pa); | |
if (lnt < L_LONG) { /* byte or word? */ | |
int32 sc = (pa & 3) << 3; /* merge */ | |
int32 mask = (lnt == L_WORD)? 0xFFFF: 0xFF; | |
int32 t = cdg_dat[row]; | |
val = ((val & mask) << sc) | (t & ~(mask << sc)); } | |
cdg_dat[row] = val; /* store data */ | |
return; | |
} | |
int32 parity (int32 val, int32 odd) | |
{ | |
for ( ; val != 0; val = val >> 1) { | |
if (val & 1) odd = odd ^ 1; } | |
return odd; | |
} | |
/* SSC registers - byte/word merges done in WriteReg */ | |
int32 ssc_rd (int32 pa) | |
{ | |
int32 rg = (pa - SSCBASE) >> 2; | |
switch (rg) { | |
case 0x00: /* base reg */ | |
return ssc_base; | |
case 0x04: /* conf reg */ | |
return ssc_cnf; | |
case 0x08: /* bus timeout */ | |
return ssc_bto; | |
case 0x0C: /* output port */ | |
return ssc_otp & SSCOTP_MASK; | |
case 0x1B: /* TODR */ | |
return todr_rd (); | |
case 0x1C: /* CSRS */ | |
return csrs_rd (); | |
case 0x1D: /* CSRD */ | |
return csrd_rd (); | |
case 0x1E: /* CSTS */ | |
return csts_rd (); | |
case 0x20: /* RXCS */ | |
return rxcs_rd (); | |
case 0x21: /* RXDB */ | |
return rxdb_rd (); | |
case 0x22: /* TXCS */ | |
return txcs_rd (); | |
case 0x40: /* T0CSR */ | |
return tmr_csr[0]; | |
case 0x41: /* T0INT */ | |
return tmr_tir_rd (0, FALSE); | |
case 0x42: /* T0NI */ | |
return tmr_tnir[0]; | |
case 0x43: /* T0VEC */ | |
return tmr_tivr[0]; | |
case 0x44: /* T1CSR */ | |
return tmr_csr[1]; | |
case 0x45: /* T1INT */ | |
return tmr_tir_rd (1, FALSE); | |
case 0x46: /* T1NI */ | |
return tmr_tnir[1]; | |
case 0x47: /* T1VEC */ | |
return tmr_tivr[1]; | |
case 0x4C: /* ADS0M */ | |
return ssc_adsm[0]; | |
case 0x4D: /* ADS0K */ | |
return ssc_adsk[0]; | |
case 0x50: /* ADS1M */ | |
return ssc_adsm[1]; | |
case 0x51: /* ADS1K */ | |
return ssc_adsk[1]; } | |
return 0; | |
} | |
void ssc_wr (int32 pa, int32 val, int32 lnt) | |
{ | |
int32 rg = (pa - SSCBASE) >> 2; | |
if (lnt < L_LONG) { /* byte or word? */ | |
int32 sc = (pa & 3) << 3; /* merge */ | |
int32 mask = (lnt == L_WORD)? 0xFFFF: 0xFF; | |
int32 t = ssc_rd (pa); | |
val = ((val & mask) << sc) | (t & ~(mask << sc)); } | |
switch (rg) { | |
case 0x00: /* base reg */ | |
ssc_base = (val & SSCBASE_RW) | SSCBASE_MBO; | |
break; | |
case 0x04: /* conf reg */ | |
ssc_cnf = ssc_cnf & ~(val & SSCCNF_W1C); | |
ssc_cnf = (ssc_cnf & ~SSCCNF_RW) | (val & SSCCNF_RW); | |
break; | |
case 0x08: /* bus timeout */ | |
ssc_bto = ssc_bto & ~(val & SSCBTO_W1C); | |
ssc_bto = (ssc_bto & ~SSCBTO_RW) | (val & SSCBTO_RW); | |
break; | |
case 0x0C: /* output port */ | |
ssc_otp = val & SSCOTP_MASK; | |
break; | |
case 0x1B: /* TODR */ | |
todr_wr (val); | |
break; | |
case 0x1C: /* CSRS */ | |
csrs_wr (val); | |
break; | |
case 0x1E: /* CSTS */ | |
csts_wr (val); | |
break; | |
case 0x1F: /* CSTD */ | |
cstd_wr (val); | |
break; | |
case 0x20: /* RXCS */ | |
rxcs_wr (val); | |
break; | |
case 0x22: /* TXCS */ | |
txcs_wr (val); | |
break; | |
case 0x23: /* TXDB */ | |
txdb_wr (val); | |
break; | |
case 0x40: /* T0CSR */ | |
tmr_csr_wr (0, val); | |
break; | |
case 0x42: /* T0NI */ | |
tmr_tnir[0] = val; | |
break; | |
case 0x43: /* T0VEC */ | |
tmr_tivr[0] = val & TMR_VEC_MASK; | |
break; | |
case 0x44: /* T1CSR */ | |
tmr_csr_wr (1, val); | |
break; | |
case 0x46: /* T1NI */ | |
tmr_tnir[1] = val; | |
break; | |
case 0x47: /* T1VEC */ | |
tmr_tivr[1] = val & TMR_VEC_MASK; | |
break; | |
case 0x4C: /* ADS0M */ | |
ssc_adsm[0] = val & SSCADS_MASK; | |
break; | |
case 0x4D: /* ADS0K */ | |
ssc_adsk[0] = val & SSCADS_MASK; | |
break; | |
case 0x50: /* ADS1M */ | |
ssc_adsm[1] = val & SSCADS_MASK; | |
break; | |
case 0x51: /* ADS1K */ | |
ssc_adsk[1] = val & SSCADS_MASK; | |
break; } | |
return; | |
} | |
/* Programmable timers | |
The SSC timers, which increment at 1Mhz, cannot be accurately | |
simulated due to the overhead that would be required for 1M | |
clock events per second. Instead, a gross hack is used. When | |
a timer is started, the clock interval is inspected. | |
if (int < 0 and small) then testing timer, count instructions | |
if (int >= 0 or large) then counting a real interval, schedule | |
clock events at 100Hz using calibrated line clock delay | |
If the interval register is read, then its value between events | |
is interpolated using the current instruction count versus the | |
count when the most recent event started. | |
*/ | |
int32 tmr_tir_rd (int32 tmr, t_bool interp) | |
{ | |
uint32 delta; | |
if (interp || (tmr_csr[tmr] & TMR_CSR_RUN)) { /* interp, running? */ | |
delta = sim_grtime () - tmr_sav[tmr]; /* delta inst */ | |
if (delta >= tmr_inc[tmr]) delta = tmr_inc[tmr] - 1; | |
return tmr_tir[tmr] + delta; } | |
return tmr_tir[tmr]; | |
} | |
void tmr_csr_wr (int32 tmr, int32 val) | |
{ | |
if ((tmr < 0) || (tmr > 1)) return; | |
if ((val & TMR_CSR_RUN) == 0) { /* clearing run? */ | |
sim_cancel (&sysd_unit[tmr]); /* cancel timer */ | |
if (tmr_csr[tmr] & TMR_CSR_RUN) /* run 1 -> 0? */ | |
tmr_tir[tmr] = tmr_tir_rd (tmr, TRUE); } /* update itr */ | |
tmr_csr[tmr] = tmr_csr[tmr] & ~(val & TMR_CSR_W1C); /* W1C csr */ | |
tmr_csr[tmr] = (tmr_csr[tmr] & ~TMR_CSR_RW) | /* new r/w */ | |
(val & TMR_CSR_RW); | |
if (val & TMR_CSR_XFR) tmr_tir[tmr] = tmr_tnir[tmr]; /* xfr set? */ | |
if (val & TMR_CSR_RUN) { /* run? */ | |
if (val & TMR_CSR_XFR) /* new tir? */ | |
sim_cancel (&sysd_unit[tmr]); /* stop prev */ | |
if (!sim_is_active (&sysd_unit[tmr])) /* not running? */ | |
tmr_sched (tmr); } /* activate */ | |
else if (val & TMR_CSR_SGL) { /* single step? */ | |
tmr_incr (tmr, 1); /* incr tmr */ | |
if (tmr_tir[tmr] == 0) /* if ovflo, */ | |
tmr_tir[tmr] = tmr_tnir[tmr]; } /* reload tir */ | |
if ((tmr_csr[tmr] & (TMR_CSR_DON | TMR_CSR_IE)) != /* update int */ | |
(TMR_CSR_DON | TMR_CSR_IE)) { | |
if (tmr) CLR_INT (TMR1); | |
else CLR_INT (TMR0); } | |
return; | |
} | |
/* Unit service */ | |
t_stat tmr_svc (UNIT *uptr) | |
{ | |
int32 tmr = uptr - sysd_dev.units; /* get timer # */ | |
tmr_incr (tmr, tmr_inc[tmr]); /* incr timer */ | |
return SCPE_OK; | |
} | |
/* Timer increment */ | |
void tmr_incr (int32 tmr, uint32 inc) | |
{ | |
uint32 new_tir = tmr_tir[tmr] + inc; /* add incr */ | |
if (new_tir < tmr_tir[tmr]) { /* ovflo? */ | |
tmr_tir[tmr] = 0; /* now 0 */ | |
if (tmr_csr[tmr] & TMR_CSR_DON) /* done? set err */ | |
tmr_csr[tmr] = tmr_csr[tmr] | TMR_CSR_ERR; | |
else tmr_csr[tmr] = tmr_csr[tmr] | TMR_CSR_DON; /* set done */ | |
if (tmr_csr[tmr] & TMR_CSR_STP) /* stop? */ | |
tmr_csr[tmr] = tmr_csr[tmr] & ~TMR_CSR_RUN; /* clr run */ | |
if (tmr_csr[tmr] & TMR_CSR_RUN) { /* run? */ | |
tmr_tir[tmr] = tmr_tnir[tmr]; /* reload */ | |
tmr_sched (tmr); } /* reactivate */ | |
if (tmr_csr[tmr] & TMR_CSR_IE) { /* set int req */ | |
if (tmr) SET_INT (TMR1); | |
else SET_INT (TMR0); } } | |
else { tmr_tir[tmr] = new_tir; /* no, upd tir */ | |
if (tmr_csr[tmr] & TMR_CSR_RUN) /* still running? */ | |
tmr_sched (tmr); } /* reactivate */ | |
return; | |
} | |
/* Timer scheduling */ | |
void tmr_sched (int32 tmr) | |
{ | |
tmr_sav[tmr] = sim_grtime (); /* save intvl base */ | |
if (tmr_tir[tmr] > (0xFFFFFFFFu - TMR_INC)) { /* short interval? */ | |
tmr_inc[tmr] = (~tmr_tir[tmr] + 1); /* inc = interval */ | |
sim_activate (&sysd_unit[tmr], tmr_inc[tmr]); } | |
else { tmr_inc[tmr] = TMR_INC; /* usec/interval */ | |
sim_activate (&sysd_unit[tmr], tmr_poll); } /* use calib clock */ | |
return; | |
} | |
int32 tmr0_inta (void) | |
{ | |
return tmr_tivr[0]; | |
} | |
int32 tmr1_inta (void) | |
{ | |
return tmr_tivr[1]; | |
} | |
/* SYSD reset */ | |
t_stat sysd_reset (DEVICE *dptr) | |
{ | |
int32 i; | |
for (i = 0; i < 2; i++) { | |
tmr_csr[i] = tmr_tnir[i] = tmr_tir[i] = 0; | |
tmr_inc[i] = tmr_sav[i] = 0; | |
sim_cancel (&sysd_unit[i]); } | |
csi_csr = 0; | |
csi_unit.buf = 0; | |
sim_cancel (&csi_unit); | |
CLR_INT (CSI); | |
cso_csr = CSR_DONE; | |
cso_unit.buf = 0; | |
sim_cancel (&cso_unit); | |
CLR_INT (CSO); | |
return SCPE_OK; | |
} | |
/* SYSD powerup */ | |
t_stat sysd_powerup (void) | |
{ | |
int32 i; | |
for (i = 0; i < (CMCTLSIZE >> 2); i++) cmctl_reg[i] = 0; | |
for (i = 0; i < 2; i++) { | |
tmr_tivr[i] = 0; | |
ssc_adsm[i] = ssc_adsk[i] = 0; } | |
ka_cacr = 0; | |
ka_bdr = 0x80; | |
ssc_base = SSCBASE; | |
ssc_cnf = ssc_cnf & SSCCNF_BLO; | |
ssc_bto = 0; | |
ssc_otp = 0; | |
return sysd_reset (&sysd_dev); | |
} | |