/* Copyright (C) 1998, Cygnus Solutions
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#ifndef SIM_MAIN_C
#define SIM_MAIN_C
#include "sim-main.h"
#include "sim-assert.h"
/*---------------------------------------------------------------------------*/
/*-- simulator engine -------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Description from page A-22 of the "MIPS IV Instruction Set" manual
(revision 3.1) */
/* Load a value from memory. Use the cache and main memory as
specified in the Cache Coherence Algorithm (CCA) and the sort of
access (IorD) to find the contents of AccessLength memory bytes
starting at physical location pAddr. The data is returned in the
fixed width naturally-aligned memory element (MemElem). The
low-order two (or three) bits of the address and the AccessLength
indicate which of the bytes within MemElem needs to be given to the
processor. If the memory access type of the reference is uncached
then only the referenced bytes are read from memory and valid
within the memory element. If the access type is cached, and the
data is not present in cache, an implementation specific size and
alignment block of memory is read and loaded into the cache to
satisfy a load reference. At a minimum, the block is the entire
memory element. */
INLINE_SIM_MAIN (void)
load_memory (SIM_DESC SD,
sim_cpu *CPU,
address_word cia,
uword64* memvalp,
uword64* memval1p,
int CCA,
unsigned int AccessLength,
address_word pAddr,
address_word vAddr,
int IorD)
{
uword64 value = 0;
uword64 value1 = 0;
#ifdef DEBUG
sim_io_printf(sd,"DBG: LoadMemory(%p,%p,%d,%d,0x%s,0x%s,%s)\n",memvalp,memval1p,CCA,AccessLength,pr_addr(pAddr),pr_addr(vAddr),(IorD ? "isDATA" : "isINSTRUCTION"));
#endif /* DEBUG */
#if defined(WARN_MEM)
if (CCA != uncached)
sim_io_eprintf(sd,"LoadMemory CCA (%d) is not uncached (currently all accesses treated as cached)\n",CCA);
#endif /* WARN_MEM */
if (((pAddr & LOADDRMASK) + AccessLength) > LOADDRMASK)
{
/* In reality this should be a Bus Error */
sim_io_error (SD, "LOAD AccessLength of %d would extend over %d bit aligned boundary for physical address 0x%s\n",
AccessLength,
(LOADDRMASK + 1) << 3,
pr_addr (pAddr));
}
dotrace (SD, CPU, tracefh,((IorD == isDATA) ? 0 : 2),(unsigned int)(pAddr&0xFFFFFFFF),(AccessLength + 1),"load%s",((IorD == isDATA) ? "" : " instruction"));
/* Read the specified number of bytes from memory. Adjust for
host/target byte ordering/ Align the least significant byte
read. */
switch (AccessLength)
{
case AccessLength_QUADWORD:
{
unsigned_16 val = sim_core_read_aligned_16 (CPU, cia, read_map, pAddr);
value1 = VH8_16 (val);
value = VL8_16 (val);
break;
}
case AccessLength_DOUBLEWORD:
value = sim_core_read_aligned_8 (CPU, cia, read_map, pAddr);
break;
case AccessLength_SEPTIBYTE:
value = sim_core_read_misaligned_7 (CPU, cia, read_map, pAddr);
break;
case AccessLength_SEXTIBYTE:
value = sim_core_read_misaligned_6 (CPU, cia, read_map, pAddr);
break;
case AccessLength_QUINTIBYTE:
value = sim_core_read_misaligned_5 (CPU, cia, read_map, pAddr);
break;
case AccessLength_WORD:
value = sim_core_read_aligned_4 (CPU, cia, read_map, pAddr);
break;
case AccessLength_TRIPLEBYTE:
value = sim_core_read_misaligned_3 (CPU, cia, read_map, pAddr);
break;
case AccessLength_HALFWORD:
value = sim_core_read_aligned_2 (CPU, cia, read_map, pAddr);
break;
case AccessLength_BYTE:
value = sim_core_read_aligned_1 (CPU, cia, read_map, pAddr);
break;
default:
abort ();
}
#ifdef DEBUG
printf("DBG: LoadMemory() : (offset %d) : value = 0x%s%s\n",
(int)(pAddr & LOADDRMASK),pr_uword64(value1),pr_uword64(value));
#endif /* DEBUG */
/* See also store_memory. Position data in correct byte lanes. */
if (AccessLength <= LOADDRMASK)
{
if (BigEndianMem)
/* for big endian target, byte (pAddr&LOADDRMASK == 0) is
shifted to the most significant byte position. */
value <<= (((LOADDRMASK - (pAddr & LOADDRMASK)) - AccessLength) * 8);
else
/* For little endian target, byte (pAddr&LOADDRMASK == 0)
is already in the correct postition. */
value <<= ((pAddr & LOADDRMASK) * 8);
}
#ifdef DEBUG
printf("DBG: LoadMemory() : shifted value = 0x%s%s\n",
pr_uword64(value1),pr_uword64(value));
#endif /* DEBUG */
*memvalp = value;
if (memval1p) *memval1p = value1;
}
/* Description from page A-23 of the "MIPS IV Instruction Set" manual
(revision 3.1) */
/* Store a value to memory. The specified data is stored into the
physical location pAddr using the memory hierarchy (data caches and
main memory) as specified by the Cache Coherence Algorithm
(CCA). The MemElem contains the data for an aligned, fixed-width
memory element (word for 32-bit processors, doubleword for 64-bit
processors), though only the bytes that will actually be stored to
memory need to be valid. The low-order two (or three) bits of pAddr
and the AccessLength field indicates which of the bytes within the
MemElem data should actually be stored; only these bytes in memory
will be changed. */
INLINE_SIM_MAIN (void)
store_memory (SIM_DESC SD,
sim_cpu *CPU,
address_word cia,
int CCA,
unsigned int AccessLength,
uword64 MemElem,
uword64 MemElem1, /* High order 64 bits */
address_word pAddr,
address_word vAddr)
{
#ifdef DEBUG
sim_io_printf(sd,"DBG: StoreMemory(%d,%d,0x%s,0x%s,0x%s,0x%s)\n",CCA,AccessLength,pr_uword64(MemElem),pr_uword64(MemElem1),pr_addr(pAddr),pr_addr(vAddr));
#endif /* DEBUG */
#if defined(WARN_MEM)
if (CCA != uncached)
sim_io_eprintf(sd,"StoreMemory CCA (%d) is not uncached (currently all accesses treated as cached)\n",CCA);
#endif /* WARN_MEM */
if (((pAddr & LOADDRMASK) + AccessLength) > LOADDRMASK)
sim_io_error (SD, "STORE AccessLength of %d would extend over %d bit aligned boundary for physical address 0x%s\n",
AccessLength,
(LOADDRMASK + 1) << 3,
pr_addr(pAddr));
dotrace (SD, CPU, tracefh,1,(unsigned int)(pAddr&0xFFFFFFFF),(AccessLength + 1),"store");
#ifdef DEBUG
printf("DBG: StoreMemory: offset = %d MemElem = 0x%s%s\n",(unsigned int)(pAddr & LOADDRMASK),pr_uword64(MemElem1),pr_uword64(MemElem));
#endif /* DEBUG */
/* See also load_memory. Position data in correct byte lanes. */
if (AccessLength <= LOADDRMASK)
{
if (BigEndianMem)
/* for big endian target, byte (pAddr&LOADDRMASK == 0) is
shifted to the most significant byte position. */
MemElem >>= (((LOADDRMASK - (pAddr & LOADDRMASK)) - AccessLength) * 8);
else
/* For little endian target, byte (pAddr&LOADDRMASK == 0)
is already in the correct postition. */
MemElem >>= ((pAddr & LOADDRMASK) * 8);
}
#ifdef DEBUG
printf("DBG: StoreMemory: shift = %d MemElem = 0x%s%s\n",shift,pr_uword64(MemElem1),pr_uword64(MemElem));
#endif /* DEBUG */
switch (AccessLength)
{
case AccessLength_QUADWORD:
{
unsigned_16 val = U16_8 (MemElem1, MemElem);
sim_core_write_aligned_16 (CPU, cia, write_map, pAddr, val);
break;
}
case AccessLength_DOUBLEWORD:
sim_core_write_aligned_8 (CPU, cia, write_map, pAddr, MemElem);
break;
case AccessLength_SEPTIBYTE:
sim_core_write_misaligned_7 (CPU, cia, write_map, pAddr, MemElem);
break;
case AccessLength_SEXTIBYTE:
sim_core_write_misaligned_6 (CPU, cia, write_map, pAddr, MemElem);
break;
case AccessLength_QUINTIBYTE:
sim_core_write_misaligned_5 (CPU, cia, write_map, pAddr, MemElem);
break;
case AccessLength_WORD:
sim_core_write_aligned_4 (CPU, cia, write_map, pAddr, MemElem);
break;
case AccessLength_TRIPLEBYTE:
sim_core_write_misaligned_3 (CPU, cia, write_map, pAddr, MemElem);
break;
case AccessLength_HALFWORD:
sim_core_write_aligned_2 (CPU, cia, write_map, pAddr, MemElem);
break;
case AccessLength_BYTE:
sim_core_write_aligned_1 (CPU, cia, write_map, pAddr, MemElem);
break;
default:
abort ();
}
return;
}
INLINE_SIM_MAIN (unsigned32)
ifetch32 (SIM_DESC SD,
sim_cpu *CPU,
address_word cia,
address_word vaddr)
{
/* Copy the action of the LW instruction */
address_word mask = LOADDRMASK;
address_word access = AccessLength_WORD;
address_word reverseendian = (ReverseEndian ? (mask ^ access) : 0);
address_word bigendiancpu = (BigEndianCPU ? (mask ^ access) : 0);
unsigned int byte;
address_word paddr = vaddr;
unsigned64 memval;
if ((vaddr & access) != 0)
SignalExceptionInstructionFetch ();
paddr = ((paddr & ~mask) | ((paddr & mask) ^ reverseendian));
LoadMemory (&memval, NULL, access, paddr, vaddr, isINSTRUCTION, isREAL);
byte = ((vaddr & mask) ^ bigendiancpu);
return (memval >> (8 * byte));
}
INLINE_SIM_MAIN (unsigned16)
ifetch16 (SIM_DESC SD,
sim_cpu *CPU,
address_word cia,
address_word vaddr)
{
/* Copy the action of the LH instruction */
address_word mask = LOADDRMASK;
address_word access = AccessLength_HALFWORD;
address_word reverseendian = (ReverseEndian ? (mask ^ access) : 0);
address_word bigendiancpu = (BigEndianCPU ? (mask ^ access) : 0);
unsigned int byte;
address_word paddr = vaddr;
unsigned64 memval;
if ((vaddr & access) != 0)
SignalExceptionInstructionFetch ();
paddr = ((paddr & ~mask) | ((paddr & mask) ^ reverseendian));
LoadMemory (&memval, NULL, access, paddr, vaddr, isINSTRUCTION, isREAL);
byte = ((vaddr & mask) ^ bigendiancpu);
return (memval >> (8 * byte));
}
/* Description from page A-26 of the "MIPS IV Instruction Set" manual (revision 3.1) */
/* Order loads and stores to synchronise shared memory. Perform the
action necessary to make the effects of groups of synchronizable
loads and stores indicated by stype occur in the same order for all
processors. */
INLINE_SIM_MAIN (void)
sync_operation (SIM_DESC sd,
sim_cpu *cpu,
address_word cia,
int stype)
{
#ifdef DEBUG
sim_io_printf(sd,"SyncOperation(%d) : TODO\n",stype);
#endif /* DEBUG */
return;
}
INLINE_SIM_MAIN (void)
cache_op (SIM_DESC SD,
sim_cpu *CPU,
address_word cia,
int op,
address_word pAddr,
address_word vAddr,
unsigned int instruction)
{
#if 1 /* stop warning message being displayed (we should really just remove the code) */
static int icache_warning = 1;
static int dcache_warning = 1;
#else
static int icache_warning = 0;
static int dcache_warning = 0;
#endif
/* If CP0 is not useable (User or Supervisor mode) and the CP0
enable bit in the Status Register is clear - a coprocessor
unusable exception is taken. */
#if 0
sim_io_printf(SD,"TODO: Cache availability checking (PC = 0x%s)\n",pr_addr(cia));
#endif
switch (op & 0x3) {
case 0: /* instruction cache */
switch (op >> 2) {
case 0: /* Index Invalidate */
case 1: /* Index Load Tag */
case 2: /* Index Store Tag */
case 4: /* Hit Invalidate */
case 5: /* Fill */
case 6: /* Hit Writeback */
if (!icache_warning)
{
sim_io_eprintf(SD,"Instruction CACHE operation %d to be coded\n",(op >> 2));
icache_warning = 1;
}
break;
default:
SignalException(ReservedInstruction,instruction);
break;
}
break;
case 1: /* data cache */
case 3: /* secondary data cache */
switch (op >> 2) {
case 0: /* Index Writeback Invalidate */
case 1: /* Index Load Tag */
case 2: /* Index Store Tag */
case 3: /* Create Dirty */
case 4: /* Hit Invalidate */
case 5: /* Hit Writeback Invalidate */
case 6: /* Hit Writeback */
if (!dcache_warning)
{
sim_io_eprintf(SD,"Data CACHE operation %d to be coded\n",(op >> 2));
dcache_warning = 1;
}
break;
default:
SignalException(ReservedInstruction,instruction);
break;
}
break;
default: /* unrecognised cache ID */
SignalException(ReservedInstruction,instruction);
break;
}
return;
}
INLINE_SIM_MAIN (void)
pending_tick (SIM_DESC SD,
sim_cpu *CPU,
address_word cia)
{
if (PENDING_TRACE)
sim_io_eprintf (SD, "PENDING_DRAIN - 0x%lx - pending_in = %d, pending_out = %d, pending_total = %d\n", (unsigned long) cia, PENDING_IN, PENDING_OUT, PENDING_TOTAL);
if (PENDING_OUT != PENDING_IN)
{
int loop;
int index = PENDING_OUT;
int total = PENDING_TOTAL;
if (PENDING_TOTAL == 0)
sim_engine_abort (SD, CPU, cia, "PENDING_DRAIN - Mis-match on pending update pointers\n");
for (loop = 0, index = PENDING_OUT;
(loop < total);
loop++, index = (index + 1) % PSLOTS)
{
if (PENDING_SLOT_DEST[index] != NULL)
{
PENDING_SLOT_DELAY[index] -= 1;
if (PENDING_SLOT_DELAY[index] == 0)
{
if (PENDING_TRACE)
sim_io_eprintf (SD, "PENDING_DRAIN - drained - index %d, dest 0x%lx, bit %d, val 0x%lx, size %d\n",
index,
(unsigned long) PENDING_SLOT_DEST[index],
PENDING_SLOT_BIT[index],
(unsigned long) PENDING_SLOT_VALUE[index],
PENDING_SLOT_SIZE[index]);
if (PENDING_SLOT_BIT[index] >= 0)
switch (PENDING_SLOT_SIZE[index])
{
case 4:
if (PENDING_SLOT_VALUE[index])
*(unsigned32*)PENDING_SLOT_DEST[index] |=
BIT32 (PENDING_SLOT_BIT[index]);
else
*(unsigned32*)PENDING_SLOT_DEST[index] &=
BIT32 (PENDING_SLOT_BIT[index]);
break;
case 8:
if (PENDING_SLOT_VALUE[index])
*(unsigned64*)PENDING_SLOT_DEST[index] |=
BIT64 (PENDING_SLOT_BIT[index]);
else
*(unsigned64*)PENDING_SLOT_DEST[index] &=
BIT64 (PENDING_SLOT_BIT[index]);
break;
}
else
switch (PENDING_SLOT_SIZE[index])
{
case 4:
*(unsigned32*)PENDING_SLOT_DEST[index] =
PENDING_SLOT_VALUE[index];
break;
case 8:
*(unsigned64*)PENDING_SLOT_DEST[index] =
PENDING_SLOT_VALUE[index];
break;
}
if (PENDING_OUT == index)
{
PENDING_SLOT_DEST[index] = NULL;
PENDING_OUT = (PENDING_OUT + 1) % PSLOTS;
PENDING_TOTAL--;
}
}
else if (PENDING_TRACE && PENDING_SLOT_DELAY[index] > 0)
sim_io_eprintf (SD, "PENDING_DRAIN - queued - index %d, delay %d, dest 0x%lx, bit %d, val 0x%lx, size %d\n",
index, PENDING_SLOT_DELAY[index],
(unsigned long) PENDING_SLOT_DEST[index],
PENDING_SLOT_BIT[index],
(unsigned long) PENDING_SLOT_VALUE[index],
PENDING_SLOT_SIZE[index]);
}
}
}
}
#endif