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m68kmmu.h
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m68kmmu.h
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/*
m68kmmu.h - PMMU implementation for 68851/68030/68040
By R. Belmont
Copyright Nicola Salmoria and the MAME Team.
Visit http://mamedev.org for licensing and usage restrictions.
*/
/*
pmmu_translate_addr: perform 68851/68030-style PMMU address translation
*/
uint pmmu_translate_addr(uint addr_in)
{
uint32 addr_out, tbl_entry = 0, tbl_entry2, tamode = 0, tbmode = 0, tcmode = 0;
uint root_aptr, root_limit, tofs, is, abits, bbits, cbits;
uint resolved, tptr, shift;
resolved = 0;
addr_out = addr_in;
// if SRP is enabled and we're in supervisor mode, use it
if ((m68ki_cpu.mmu_tc & 0x02000000) && (m68ki_get_sr() & 0x2000))
{
root_aptr = m68ki_cpu.mmu_srp_aptr;
root_limit = m68ki_cpu.mmu_srp_limit;
}
else // else use the CRP
{
root_aptr = m68ki_cpu.mmu_crp_aptr;
root_limit = m68ki_cpu.mmu_crp_limit;
}
// get initial shift (# of top bits to ignore)
is = (m68ki_cpu.mmu_tc>>16) & 0xf;
abits = (m68ki_cpu.mmu_tc>>12)&0xf;
bbits = (m68ki_cpu.mmu_tc>>8)&0xf;
cbits = (m68ki_cpu.mmu_tc>>4)&0xf;
// fprintf(stderr,"PMMU: tcr %08x limit %08x aptr %08x is %x abits %d bbits %d cbits %d\n", m68ki_cpu.mmu_tc, root_limit, root_aptr, is, abits, bbits, cbits);
// get table A offset
tofs = (addr_in<<is)>>(32-abits);
// find out what format table A is
switch (root_limit & 3)
{
case 0: // invalid, should cause MMU exception
case 1: // page descriptor, should cause direct mapping
fatalerror("680x0 PMMU: Unhandled root mode\n");
break;
case 2: // valid 4 byte descriptors
tofs *= 4;
// fprintf(stderr,"PMMU: reading table A entry at %08x\n", tofs + (root_aptr & 0xfffffffc));
tbl_entry = m68k_read_memory_32( tofs + (root_aptr & 0xfffffffc));
tamode = tbl_entry & 3;
// fprintf(stderr,"PMMU: addr %08x entry %08x mode %x tofs %x\n", addr_in, tbl_entry, tamode, tofs);
break;
case 3: // valid 8 byte descriptors
tofs *= 8;
// fprintf(stderr,"PMMU: reading table A entries at %08x\n", tofs + (root_aptr & 0xfffffffc));
tbl_entry2 = m68k_read_memory_32( tofs + (root_aptr & 0xfffffffc));
tbl_entry = m68k_read_memory_32( tofs + (root_aptr & 0xfffffffc)+4);
tamode = tbl_entry2 & 3;
// fprintf(stderr,"PMMU: addr %08x entry %08x entry2 %08x mode %x tofs %x\n", addr_in, tbl_entry, tbl_entry2, tamode, tofs);
break;
}
// get table B offset and pointer
tofs = (addr_in<<(is+abits))>>(32-bbits);
tptr = tbl_entry & 0xfffffff0;
// find out what format table B is, if any
switch (tamode)
{
case 0: // invalid, should cause MMU exception
fatalerror("680x0 PMMU: Unhandled Table A mode %d (addr_in %08x)\n", tamode, addr_in);
break;
case 2: // 4-byte table B descriptor
tofs *= 4;
// fprintf(stderr,"PMMU: reading table B entry at %08x\n", tofs + tptr);
tbl_entry = m68k_read_memory_32( tofs + tptr);
tbmode = tbl_entry & 3;
// fprintf(stderr,"PMMU: addr %08x entry %08x mode %x tofs %x\n", addr_in, tbl_entry, tbmode, tofs);
break;
case 3: // 8-byte table B descriptor
tofs *= 8;
// fprintf(stderr,"PMMU: reading table B entries at %08x\n", tofs + tptr);
tbl_entry2 = m68k_read_memory_32( tofs + tptr);
tbl_entry = m68k_read_memory_32( tofs + tptr + 4);
tbmode = tbl_entry2 & 3;
// fprintf(stderr,"PMMU: addr %08x entry %08x entry2 %08x mode %x tofs %x\n", addr_in, tbl_entry, tbl_entry2, tbmode, tofs);
break;
case 1: // early termination descriptor
tbl_entry &= 0xffffff00;
shift = is+abits;
addr_out = ((addr_in<<shift)>>shift) + tbl_entry;
resolved = 1;
break;
}
// if table A wasn't early-out, continue to process table B
if (!resolved)
{
// get table C offset and pointer
tofs = (addr_in<<(is+abits+bbits))>>(32-cbits);
tptr = tbl_entry & 0xfffffff0;
switch (tbmode)
{
case 0: // invalid, should cause MMU exception
fatalerror("680x0 PMMU: Unhandled Table B mode %d (addr_in %08x PC %x)\n", tbmode, addr_in, REG_PC);
break;
case 2: // 4-byte table C descriptor
tofs *= 4;
// fprintf(stderr,"PMMU: reading table C entry at %08x\n", tofs + tptr);
tbl_entry = m68k_read_memory_32(tofs + tptr);
tcmode = tbl_entry & 3;
// fprintf(stderr,"PMMU: addr %08x entry %08x mode %x tofs %x\n", addr_in, tbl_entry, tbmode, tofs);
break;
case 3: // 8-byte table C descriptor
tofs *= 8;
// fprintf(stderr,"PMMU: reading table C entries at %08x\n", tofs + tptr);
tbl_entry2 = m68k_read_memory_32(tofs + tptr);
tbl_entry = m68k_read_memory_32(tofs + tptr + 4);
tcmode = tbl_entry2 & 3;
// fprintf(stderr,"PMMU: addr %08x entry %08x entry2 %08x mode %x tofs %x\n", addr_in, tbl_entry, tbl_entry2, tbmode, tofs);
break;
case 1: // termination descriptor
tbl_entry &= 0xffffff00;
shift = is+abits+bbits;
addr_out = ((addr_in<<shift)>>shift) + tbl_entry;
resolved = 1;
break;
}
}
if (!resolved)
{
switch (tcmode)
{
case 0: // invalid, should cause MMU exception
case 2: // 4-byte ??? descriptor
case 3: // 8-byte ??? descriptor
fatalerror("680x0 PMMU: Unhandled Table B mode %d (addr_in %08x PC %x)\n", tbmode, addr_in, REG_PC);
break;
case 1: // termination descriptor
tbl_entry &= 0xffffff00;
shift = is+abits+bbits+cbits;
addr_out = ((addr_in<<shift)>>shift) + tbl_entry;
resolved = 1;
break;
}
}
// fprintf(stderr,"PMMU: [%08x] => [%08x]\n", addr_in, addr_out);
return addr_out;
}
/*
m68881_mmu_ops: COP 0 MMU opcode handling
*/
void m68881_mmu_ops(void)
{
uint16 modes;
uint32 ea = m68ki_cpu.ir & 0x3f;
uint64 temp64;
// catch the 2 "weird" encodings up front (PBcc)
if ((m68ki_cpu.ir & 0xffc0) == 0xf0c0)
{
fprintf(stderr,"680x0: unhandled PBcc\n");
return;
}
else if ((m68ki_cpu.ir & 0xffc0) == 0xf080)
{
fprintf(stderr,"680x0: unhandled PBcc\n");
return;
}
else // the rest are 1111000xxxXXXXXX where xxx is the instruction family
{
switch ((m68ki_cpu.ir>>9) & 0x7)
{
case 0:
modes = OPER_I_16();
if ((modes & 0xfde0) == 0x2000) // PLOAD
{
fprintf(stderr,"680x0: unhandled PLOAD\n");
return;
}
else if ((modes & 0xe200) == 0x2000) // PFLUSH
{
fprintf(stderr,"680x0: unhandled PFLUSH PC=%x\n", REG_PC);
return;
}
else if (modes == 0xa000) // PFLUSHR
{
fprintf(stderr,"680x0: unhandled PFLUSHR\n");
return;
}
else if (modes == 0x2800) // PVALID (FORMAT 1)
{
fprintf(stderr,"680x0: unhandled PVALID1\n");
return;
}
else if ((modes & 0xfff8) == 0x2c00) // PVALID (FORMAT 2)
{
fprintf(stderr,"680x0: unhandled PVALID2\n");
return;
}
else if ((modes & 0xe000) == 0x8000) // PTEST
{
fprintf(stderr,"680x0: unhandled PTEST\n");
return;
}
else
{
switch ((modes>>13) & 0x7)
{
case 0: // MC68030/040 form with FD bit
case 2: // MC68881 form, FD never set
if (modes & 0x200)
{
switch ((modes>>10) & 7)
{
case 0: // translation control register
WRITE_EA_32(ea, m68ki_cpu.mmu_tc);
break;
case 2: // supervisor root pointer
WRITE_EA_64(ea, (uint64)m68ki_cpu.mmu_srp_limit<<32 | (uint64)m68ki_cpu.mmu_srp_aptr);
break;
case 3: // CPU root pointer
WRITE_EA_64(ea, (uint64)m68ki_cpu.mmu_crp_limit<<32 | (uint64)m68ki_cpu.mmu_crp_aptr);
break;
default:
fprintf(stderr,"680x0: PMOVE from unknown MMU register %x, PC %x\n", (modes>>10) & 7, REG_PC);
break;
}
}
else
{
switch ((modes>>10) & 7)
{
case 0: // translation control register
m68ki_cpu.mmu_tc = READ_EA_32(ea);
if (m68ki_cpu.mmu_tc & 0x80000000)
{
m68ki_cpu.pmmu_enabled = 1;
}
else
{
m68ki_cpu.pmmu_enabled = 0;
}
break;
case 2: // supervisor root pointer
temp64 = READ_EA_64(ea);
m68ki_cpu.mmu_srp_limit = (temp64>>32) & 0xffffffff;
m68ki_cpu.mmu_srp_aptr = temp64 & 0xffffffff;
break;
case 3: // CPU root pointer
temp64 = READ_EA_64(ea);
m68ki_cpu.mmu_crp_limit = (temp64>>32) & 0xffffffff;
m68ki_cpu.mmu_crp_aptr = temp64 & 0xffffffff;
break;
default:
fprintf(stderr,"680x0: PMOVE to unknown MMU register %x, PC %x\n", (modes>>10) & 7, REG_PC);
break;
}
}
break;
case 3: // MC68030 to/from status reg
if (modes & 0x200)
{
WRITE_EA_32(ea, m68ki_cpu.mmu_sr);
}
else
{
m68ki_cpu.mmu_sr = READ_EA_32(ea);
}
break;
default:
fprintf(stderr,"680x0: unknown PMOVE mode %x (modes %04x) (PC %x)\n", (modes>>13) & 0x7, modes, REG_PC);
break;
}
}
break;
default:
fprintf(stderr,"680x0: unknown PMMU instruction group %d\n", (m68ki_cpu.ir>>9) & 0x7);
break;
}
}
}