/* vax_mm.c - VAX memory management simulator | |
Copyright (c) 1998-2004, 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. | |
19-Sep-03 RMS Fixed upper/lower case linkage problems on VMS | |
01-Jun-03 RMS Fixed compilation problem with USE_ADDR64 | |
This module contains the instruction simulators for | |
Read - read virtual | |
Write - write virtual | |
ReadL(P) - read aligned physical longword (physical context) | |
WriteL(P) - write aligned physical longword (physical context) | |
ReadB(W) - read aligned physical byte (word) | |
WriteB(W) - write aligned physical byte (word) | |
Test - test acccess | |
zap_tb - clear TB | |
zap_tb_ent - clear TB entry | |
chk_tb_ent - check TB entry | |
set_map_reg - set up working map registers | |
*/ | |
#include "vax_defs.h" | |
#include <setjmp.h> | |
struct tlbent { | |
int32 tag; /* tag */ | |
int32 pte; /* pte */ | |
}; | |
typedef struct tlbent TLBENT; | |
extern uint32 *M; | |
extern uint32 align[4]; | |
extern int32 PSL; | |
extern int32 mapen; | |
extern int32 p1, p2; | |
extern int32 P0BR, P0LR; | |
extern int32 P1BR, P1LR; | |
extern int32 SBR, SLR; | |
extern int32 SISR; | |
extern jmp_buf save_env; | |
extern UNIT cpu_unit; | |
int32 d_p0br, d_p0lr; /* dynamic copies */ | |
int32 d_p1br, d_p1lr; /* altered per ucode */ | |
int32 d_sbr, d_slr; | |
extern int32 mchk_va, mchk_ref; /* for mcheck */ | |
TLBENT stlb[VA_TBSIZE], ptlb[VA_TBSIZE]; | |
static const int32 insert[4] = { | |
0x00000000, 0x000000FF, 0x0000FFFF, 0x00FFFFFF }; | |
static const int32 cvtacc[16] = { 0, 0, | |
TLB_ACCW (KERN)+TLB_ACCR (KERN), | |
TLB_ACCR (KERN), | |
TLB_ACCW (KERN)+TLB_ACCW (EXEC)+TLB_ACCW (SUPV)+TLB_ACCW (USER)+ | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV)+TLB_ACCR (USER), | |
TLB_ACCW (KERN)+TLB_ACCW (EXEC)+TLB_ACCR (KERN)+TLB_ACCR (EXEC), | |
TLB_ACCW (KERN)+TLB_ACCR (KERN)+TLB_ACCR (EXEC), | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC), | |
TLB_ACCW (KERN)+TLB_ACCW (EXEC)+TLB_ACCW (SUPV)+ | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV), | |
TLB_ACCW (KERN)+TLB_ACCW (EXEC)+ | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV), | |
TLB_ACCW (KERN)+TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV), | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV), | |
TLB_ACCW (KERN)+TLB_ACCW (EXEC)+TLB_ACCW (SUPV)+ | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV)+TLB_ACCR (USER), | |
TLB_ACCW (KERN)+TLB_ACCW (EXEC)+ | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV)+TLB_ACCR (USER), | |
TLB_ACCW (KERN)+ | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV)+TLB_ACCR (USER), | |
TLB_ACCR (KERN)+TLB_ACCR (EXEC)+TLB_ACCR (SUPV)+TLB_ACCR (USER) | |
}; | |
t_stat tlb_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat tlb_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat tlb_reset (DEVICE *dptr); | |
TLBENT fill (uint32 va, int32 lnt, int32 acc, int32 *stat); | |
int32 ReadB (uint32 pa); | |
void WriteB (uint32 pa, int32 val); | |
int32 ReadW (uint32 pa); | |
void WriteW (uint32 pa, int32 val); | |
int32 ReadL (uint32 pa); | |
void WriteL (uint32 pa, int32 val); | |
int32 ReadLP (uint32 pa); | |
void WriteLP (uint32 pa, int32 val); | |
extern int32 ReadIO (uint32 pa, int32 lnt); | |
extern void WriteIO (uint32 pa, int32 val, int32 lnt); | |
extern int32 ReadReg (uint32 pa, int32 lnt); | |
extern void WriteReg (uint32 pa, int32 val, int32 lnt); | |
/* TLB data structures | |
tlb_dev pager device descriptor | |
tlb_unit pager units | |
pager_reg pager register list | |
*/ | |
UNIT tlb_unit[] = { | |
{ UDATA (NULL, UNIT_FIX, VA_TBSIZE * 2) }, | |
{ UDATA (NULL, UNIT_FIX, VA_TBSIZE * 2) } }; | |
REG tlb_reg[] = { | |
{ NULL } }; | |
DEVICE tlb_dev = { | |
"TLB", tlb_unit, tlb_reg, NULL, | |
2, 16, VA_N_TBI * 2, 1, 16, 32, | |
&tlb_ex, &tlb_dep, &tlb_reset, | |
NULL, NULL, NULL }; | |
/* Read and write virtual | |
These routines logically fall into three phases: | |
1. Look up the virtual address in the translation buffer, calling | |
the fill routine on a tag mismatch or access mismatch (invalid | |
tlb entries have access = 0 and thus always mismatch). The | |
fill routine handles all errors. If the resulting physical | |
address is aligned, do an aligned physical read or write. | |
2. Test for unaligned across page boundaries. If cross page, look | |
up the physical address of the second page. If not cross page, | |
the second physical address is the same as the first. | |
3. Using the two physical addresses, do an unaligned read or | |
write, with three cases: unaligned long, unaligned word within | |
a longword, unaligned word crossing a longword boundary. | |
*/ | |
/* Read virtual | |
Inputs: | |
va = virtual address | |
lnt = length code (BWLQ) | |
acc = access code (KESU) | |
Output: | |
returned data, right justified in 32b longword | |
*/ | |
int32 Read (uint32 va, int32 lnt, int32 acc) | |
{ | |
int32 vpn, off, tbi, pa; | |
int32 pa1, bo, sc, wl, wh; | |
TLBENT xpte; | |
mchk_va = va; | |
if (mapen) { /* mapping on? */ | |
vpn = VA_GETVPN (va); /* get vpn, offset */ | |
off = VA_GETOFF (va); | |
tbi = VA_GETTBI (vpn); | |
xpte = (va & VA_S0)? stlb[tbi]: ptlb[tbi]; /* access tlb */ | |
if (((xpte.pte & acc) == 0) || (xpte.tag != vpn) || | |
((acc & TLB_WACC) && ((xpte.pte & TLB_M) == 0))) | |
xpte = fill (va, lnt, acc, NULL); /* fill if needed */ | |
pa = (xpte.pte & TLB_PFN) | off; } /* get phys addr */ | |
else pa = va & PAMASK; | |
if ((pa & (lnt - 1)) == 0) { /* aligned? */ | |
if (lnt >= L_LONG) return ReadL (pa); /* long, quad? */ | |
if (lnt == L_WORD) return ReadW (pa); /* word? */ | |
return ReadB (pa); } /* byte */ | |
if (mapen && ((off + lnt) > VA_PAGSIZE)) { /* cross page? */ | |
vpn = VA_GETVPN (va + lnt); /* vpn 2nd page */ | |
tbi = VA_GETTBI (vpn); | |
xpte = (va & VA_S0)? stlb[tbi]: ptlb[tbi]; /* access tlb */ | |
if (((xpte.pte & acc) == 0) || (xpte.tag != vpn) || | |
((acc & TLB_WACC) && ((xpte.pte & TLB_M) == 0))) | |
xpte = fill (va + lnt, lnt, acc, NULL); /* fill if needed */ | |
pa1 = (xpte.pte & TLB_PFN) | VA_GETOFF (va + 4); } | |
else pa1 = (pa + 4) & PAMASK; /* not cross page */ | |
bo = pa & 3; | |
if (lnt >= L_LONG) { /* lw unaligned? */ | |
sc = bo << 3; | |
wl = ReadL (pa); /* read both lw */ | |
wh = ReadL (pa1); /* extract */ | |
return (((wl >> sc) & align[bo]) | (wh << (32 - sc))); } | |
else if (bo == 1) return ((ReadL (pa) >> 8) & WMASK); | |
else { wl = ReadL (pa); /* word cross lw */ | |
wh = ReadL (pa1); /* read, extract */ | |
return (((wl >> 24) & 0xFF) | ((wh & 0xFF) << 8)); } | |
} | |
/* Write virtual | |
Inputs: | |
va = virtual address | |
val = data to be written, right justified in 32b lw | |
lnt = length code (BWLQ) | |
acc = access code (KESU) | |
Output: | |
none | |
*/ | |
void Write (uint32 va, int32 val, int32 lnt, int32 acc) | |
{ | |
int32 vpn, off, tbi, pa; | |
int32 pa1, bo, sc, wl, wh; | |
TLBENT xpte; | |
mchk_va = va; | |
if (mapen) { | |
vpn = VA_GETVPN (va); | |
off = VA_GETOFF (va); | |
tbi = VA_GETTBI (vpn); | |
xpte = (va & VA_S0)? stlb[tbi]: ptlb[tbi]; /* access tlb */ | |
if (((xpte.pte & acc) == 0) || (xpte.tag != vpn) || | |
((xpte.pte & TLB_M) == 0)) | |
xpte = fill (va, lnt, acc, NULL); | |
pa = (xpte.pte & TLB_PFN) | off; } | |
else pa = va & PAMASK; | |
if ((pa & (lnt - 1)) == 0) { /* aligned? */ | |
if (lnt >= L_LONG) WriteL (pa, val); /* long, quad? */ | |
else if (lnt == L_WORD) WriteW (pa, val); /* word? */ | |
else WriteB (pa, val); /* byte */ | |
return; } | |
if (mapen && ((off + lnt) > VA_PAGSIZE)) { | |
vpn = VA_GETVPN (va + 4); | |
tbi = VA_GETTBI (vpn); | |
xpte = (va & VA_S0)? stlb[tbi]: ptlb[tbi]; /* access tlb */ | |
if (((xpte.pte & acc) == 0) || (xpte.tag != vpn) || | |
((xpte.pte & TLB_M) == 0)) | |
xpte = fill (va + lnt, lnt, acc, NULL); | |
pa1 = (xpte.pte & TLB_PFN) | VA_GETOFF (va + 4); } | |
else pa1 = (pa + 4) & PAMASK; | |
bo = pa & 3; | |
wl = ReadL (pa); | |
if (lnt >= L_LONG) { | |
sc = bo << 3; | |
wh = ReadL (pa1); | |
wl = (wl & insert[bo]) | (val << sc); | |
wh = (wh & ~insert[bo]) | ((val >> (32 - sc)) & insert[bo]); | |
WriteL (pa, wl); | |
WriteL (pa1, wh); } | |
else if (bo == 1) { | |
wl = (wl & 0xFF0000FF) | (val << 8); | |
WriteL (pa, wl); } | |
else { wh = ReadL (pa1); | |
wl = (wl & 0x00FFFFFF) | (val << 24); | |
wh = (wh & 0xFFFFFF00) | ((val >> 8) & 0xFF); | |
WriteL (pa, wl); | |
WriteL (pa1, wh); } | |
return; | |
} | |
/* Test access to a byte (VAX PROBEx) */ | |
int32 Test (int32 va, int32 acc, int32 *status) | |
{ | |
int32 vpn, off, tbi; | |
TLBENT xpte; | |
*status = PR_OK; /* assume ok */ | |
if (mapen) { /* mapping on? */ | |
vpn = VA_GETVPN (va); /* get vpn, off */ | |
off = VA_GETOFF (va); | |
tbi = VA_GETTBI (vpn); | |
xpte = (va & VA_S0)? stlb[tbi]: ptlb[tbi]; /* access tlb */ | |
if ((xpte.pte & acc) && (xpte.tag == vpn)) /* TB hit, acc ok? */ | |
return (xpte.pte & TLB_PFN) | off; | |
xpte = fill (va, L_BYTE, acc, status); /* fill TB */ | |
if (*status == PR_OK) return (xpte.pte & TLB_PFN) | off; | |
else return -1; } | |
return va & PAMASK; /* ret phys addr */ | |
} | |
/* Read aligned physical (in virtual context, unless indicated) | |
Inputs: | |
pa = physical address, naturally aligned | |
Output: | |
returned data, right justified in 32b longword | |
*/ | |
int32 ReadB (uint32 pa) | |
{ | |
int32 dat; | |
if (ADDR_IS_MEM (pa)) dat = M[pa >> 2]; | |
else { mchk_ref = REF_V; | |
if (ADDR_IS_IO (pa)) dat = ReadIO (pa, L_BYTE); | |
else dat = ReadReg (pa, L_BYTE); } | |
return ((dat >> ((pa & 3) << 3)) & BMASK); | |
} | |
int32 ReadW (uint32 pa) | |
{ | |
int32 dat; | |
if (ADDR_IS_MEM (pa)) dat = M[pa >> 2]; | |
else { mchk_ref = REF_V; | |
if (ADDR_IS_IO (pa)) dat = ReadIO (pa, L_WORD); | |
else dat = ReadReg (pa, L_WORD); } | |
return ((dat >> ((pa & 2)? 16: 0)) & WMASK); | |
} | |
int32 ReadL (uint32 pa) | |
{ | |
if (ADDR_IS_MEM (pa)) return M[pa >> 2]; | |
mchk_ref = REF_V; | |
if (ADDR_IS_IO (pa)) return ReadIO (pa, L_LONG); | |
return ReadReg (pa, L_LONG); | |
} | |
int32 ReadLP (uint32 pa) | |
{ | |
if (ADDR_IS_MEM (pa)) return M[pa >> 2]; | |
mchk_va = pa; | |
mchk_ref = REF_P; | |
if (ADDR_IS_IO (pa)) return ReadIO (pa, L_LONG); | |
return ReadReg (pa, L_LONG); | |
} | |
/* Write aligned physical (in virtual context, unless indicated) | |
Inputs: | |
pa = physical address, naturally aligned | |
val = data to be written, right justified in 32b longword | |
Output: | |
none | |
*/ | |
void WriteB (uint32 pa, int32 val) | |
{ | |
if (ADDR_IS_MEM (pa)) { | |
int32 id = pa >> 2; | |
int32 sc = (pa & 3) << 3; | |
int32 mask = 0xFF << sc; | |
M[id] = (M[id] & ~mask) | (val << sc); } | |
else { mchk_ref = REF_V; | |
if (ADDR_IS_IO (pa)) WriteIO (pa, val, L_BYTE); | |
else WriteReg (pa, val, L_BYTE); } | |
return; | |
} | |
void WriteW (uint32 pa, int32 val) | |
{ | |
if (ADDR_IS_MEM (pa)) { | |
int32 id = pa >> 2; | |
M[id] = (pa & 2)? (M[id] & 0xFFFF) | (val << 16): | |
(M[id] & ~0xFFFF) | val; } | |
else { mchk_ref = REF_V; | |
if (ADDR_IS_IO (pa)) WriteIO (pa, val, L_WORD); | |
else WriteReg (pa, val, L_WORD); } | |
return; | |
} | |
void WriteL (uint32 pa, int32 val) | |
{ | |
if (ADDR_IS_MEM (pa)) M[pa >> 2] = val; | |
else { mchk_ref = REF_V; | |
if (ADDR_IS_IO (pa)) WriteIO (pa, val, L_LONG); | |
else WriteReg (pa, val, L_LONG); } | |
return; | |
} | |
void WriteLP (uint32 pa, int32 val) | |
{ | |
if (ADDR_IS_MEM (pa)) M[pa >> 2] = val; | |
else { mchk_va = pa; | |
mchk_ref = REF_P; | |
if (ADDR_IS_IO (pa)) WriteIO (pa, val, L_LONG); | |
else WriteReg (pa, val, L_LONG); } | |
return; | |
} | |
/* TLB fill | |
This routine fills the TLB after a tag or access mismatch, or | |
on a write if pte<m> = 0. It fills the TLB and returns the | |
pte to the caller. On an error, it aborts directly to the | |
fault handler in the CPU. | |
If called from map (VAX PROBEx), the error status is returned | |
to the caller, and no fault occurs. | |
*/ | |
#define MM_ERR(param) { \ | |
if (stat) { *stat = param; return zero_pte; } \ | |
p1 = MM_PARAM (acc & TLB_WACC, param); \ | |
p2 = va; \ | |
ABORT ((param & PR_TNV)? ABORT_TNV: ABORT_ACV); } | |
TLBENT fill (uint32 va, int32 lnt, int32 acc, int32 *stat) | |
{ | |
int32 ptidx = (((uint32) va) >> 7) & ~03; | |
int32 tlbpte, ptead, pte, tbi, vpn; | |
static TLBENT zero_pte = { 0, 0 }; | |
if (va & VA_S0) { /* system space? */ | |
if (ptidx >= d_slr) MM_ERR (PR_LNV); /* system */ | |
ptead = d_sbr + ptidx; } | |
else { if (va & VA_P1) { /* P1? */ | |
if (ptidx < d_p1lr) MM_ERR (PR_LNV); | |
ptead = d_p1br + ptidx; } | |
else { /* P0 */ | |
if (ptidx >= d_p0lr) | |
MM_ERR (PR_LNV); | |
ptead = d_p0br + ptidx; } | |
if ((ptead & VA_S0) == 0) | |
ABORT (STOP_PPTE); /* ppte must be sys */ | |
vpn = VA_GETVPN (ptead); /* get vpn, tbi */ | |
tbi = VA_GETTBI (vpn); | |
if (stlb[tbi].tag != vpn) { /* in sys tlb? */ | |
ptidx = ((uint32) ptead) >> 7; /* xlate like sys */ | |
if (ptidx >= d_slr) MM_ERR (PR_PLNV); | |
pte = ReadLP (d_sbr + ptidx); /* get system pte */ | |
if ((pte & PTE_V) == 0) MM_ERR (PR_PTNV); /* spte TNV? */ | |
stlb[tbi].tag = vpn; /* set stlb tag */ | |
stlb[tbi].pte = cvtacc[PTE_GETACC (pte)] | | |
((pte << VA_N_OFF) & TLB_PFN); } /* set stlb data */ | |
ptead = (stlb[tbi].pte & TLB_PFN) | VA_GETOFF (ptead); } | |
pte = ReadL (ptead); /* read pte */ | |
tlbpte = cvtacc[PTE_GETACC (pte)] | /* cvt access */ | |
((pte << VA_N_OFF) & TLB_PFN); /* set addr */ | |
if ((tlbpte & acc) == 0) MM_ERR (PR_ACV); /* chk access */ | |
if ((pte & PTE_V) == 0) MM_ERR (PR_TNV); /* check valid */ | |
if (acc & TLB_WACC) { /* write? */ | |
if ((pte & PTE_M) == 0) WriteL (ptead, pte | PTE_M); | |
tlbpte = tlbpte | TLB_M; } /* set M */ | |
vpn = VA_GETVPN (va); | |
tbi = VA_GETTBI (vpn); | |
if ((va & VA_S0) == 0) { /* process space? */ | |
ptlb[tbi].tag = vpn; /* store tlb ent */ | |
ptlb[tbi].pte = tlbpte; | |
return ptlb[tbi]; } | |
stlb[tbi].tag = vpn; /* system space */ | |
stlb[tbi].pte = tlbpte; /* store tlb ent */ | |
return stlb[tbi]; | |
} | |
/* Utility routines */ | |
extern void set_map_reg (void) | |
{ | |
d_p0br = P0BR & ~03; | |
d_p1br = (P1BR - 0x800000) & ~03; /* VA<30> >> 7 */ | |
d_sbr = (SBR - 0x1000000) & ~03; /* VA<31> >> 7 */ | |
d_p0lr = (P0LR << 2); | |
d_p1lr = (P1LR << 2) + 0x800000; /* VA<30> >> 7 */ | |
d_slr = (SLR << 2) + 0x1000000; /* VA<31> >> 7 */ | |
return; | |
} | |
/* Zap process (0) or whole (1) tb */ | |
void zap_tb (int stb) | |
{ | |
int32 i; | |
for (i = 0; i < VA_TBSIZE; i++) { | |
ptlb[i].tag = ptlb[i].pte = -1; | |
if (stb) stlb[i].tag = stlb[i].pte = -1; } | |
return; | |
} | |
/* Zap single tb entry corresponding to va */ | |
void zap_tb_ent (int32 va) | |
{ | |
int32 tbi = VA_GETTBI (VA_GETVPN (va)); | |
if (va & VA_S0) stlb[tbi].tag = stlb[tbi].pte = -1; | |
else ptlb[tbi].tag = ptlb[tbi].pte = -1; | |
return; | |
} | |
/* Check for tlb entry corresponding to va */ | |
t_bool chk_tb_ent (int32 va) | |
{ | |
int32 vpn = VA_GETVPN (va); | |
int32 tbi = VA_GETTBI (vpn); | |
TLBENT xpte; | |
xpte = (va & VA_S0)? stlb[tbi]: ptlb[tbi]; | |
if (xpte.tag == vpn) return TRUE; | |
return FALSE; | |
} | |
/* TLB examine */ | |
t_stat tlb_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
int32 tlbn = uptr - tlb_unit; | |
int32 idx = (uint32) addr >> 1; | |
if (idx >= VA_TBSIZE) return SCPE_NXM; | |
if (addr & 1) *vptr = ((uint32) (tlbn? stlb[idx].pte: ptlb[idx].pte)); | |
else *vptr = ((uint32) (tlbn? stlb[idx].tag: ptlb[idx].tag)); | |
return SCPE_OK; | |
} | |
/* TLB deposit */ | |
t_stat tlb_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
int32 tlbn = uptr - tlb_unit; | |
int32 idx = (uint32) addr >> 1; | |
if (idx >= VA_TBSIZE) return SCPE_NXM; | |
if (addr & 1) { | |
if (tlbn) stlb[idx].pte = (int32) val; | |
else ptlb[idx].pte = (int32) val; } | |
else { if (tlbn) stlb[idx].tag = (int32) val; | |
else ptlb[idx].tag = (int32) val; } | |
return SCPE_OK; | |
} | |
/* TLB reset */ | |
t_stat tlb_reset (DEVICE *dptr) | |
{ | |
int32 i; | |
for (i = 0; i < VA_TBSIZE; i++) | |
stlb[i].tag = ptlb[i].tag = stlb[i].pte = ptlb[i].pte = -1; | |
return SCPE_OK; | |
} |