static int readMem(int addr, int size) throws MachineException {
int data = 0;
int exception;
int physicalAddress;
if (Debug.isEnabled('a')) {
Debug.printf('a', "Reading VA 0x%x, size %d\n",
new Integer(addr), new Integer(size));
}
try {
//////////////System.out.println("try to read from vir "+addr);
physicalAddress = translate(addr, size, false);
} catch (MachineException e) {
//System.out.println("read mem exe"+e.getMessage());
raiseException(e.exception, addr);
throw e;
}
switch (size) {
case 1:
data = (mainMemory[physicalAddress] & 0xff);
break;
case 2:
data = ((mainMemory[physicalAddress] & 0xff) << 8) |
(mainMemory[physicalAddress+1] & 0xff);
break;
case 4:
data = (mainMemory[physicalAddress+3] << 24) |
((mainMemory[physicalAddress+2] & 0xff) << 16) |
((mainMemory[physicalAddress+1] & 0xff) << 8) |
(mainMemory[physicalAddress] & 0xff);
break;
default:
Debug.ASSERT(false);
}
if (Debug.isEnabled('a')) {
Debug.printf('a', "\tvalue read = 0x%x\n", new Long(data & LOW32BITS));
}
return data;
}
public void print() {
FileHeader hdr = new FileHeader();
System.out.println("Directory contents:");
for (int i = 0; i < tableSize; i++)
if (table[i].inUse) {
Debug.printf('+', "Name: %s, Sector: %d\n", table[i].name, new Integer(table[i].sector));
hdr.fetchFrom(table[i].sector);
hdr.print();
}
System.out.println("");
}
static boolean writeMem(int addr, int size, int value) {
int exception;
int physicalAddress;
if (Debug.isEnabled('a')) {
Debug.printf('a', "Writing VA 0x%x, size %d, value 0x%x\n",
new Integer(addr), new Integer(size), new Integer(value));
}
try {
physicalAddress = translate(addr, size, true);
} catch (MachineException e) {
raiseException(e.exception, addr);
return false;
}
switch (size) {
case 1:
mainMemory[physicalAddress] = (byte) (value & 0xff);
break;
case 2:
mainMemory[physicalAddress] = (byte) ((value >> 8) & 0xff);
mainMemory[physicalAddress+1] = (byte) (value & 0xff);
break;
case 4:
mainMemory[physicalAddress+3] = (byte) ((value >> 24) & 0xff);
mainMemory[physicalAddress+2] = (byte) ((value >> 16) & 0xff);
mainMemory[physicalAddress+1] = (byte) ((value >> 8) & 0xff);
mainMemory[physicalAddress] = (byte) (value & 0xff);
break;
default:
Debug.ASSERT(false);
}
return true;
}
static private void oneInstruction(Instruction instr) {
int raw;
int nextLoadReg = 0;
int nextLoadValue = 0; // record delayed load operation, to apply
// in the future
// Fetch instruction
try {
instr.value = readMem(registers[PCReg], 4);
} catch (MachineException e) {
return; // exception occurred
}
instr.decode();
String str = Instruction.opStrings[instr.opCode];
byte args[] = Instruction.opRegs[instr.opCode];
Debug.ASSERT(instr.opCode <= Instruction.MaxOpcode);
if (Debug.isEnabled('m')) {
Debug.printf('m', "At PC = 0x%x: ", new Integer(registers[PCReg]));
Debug.printf('m', str + "\n",
new Integer(instr.typeToReg(args[0])),
new Integer(instr.typeToReg(args[1])),
new Integer(instr.typeToReg(args[2])));
}
// Compute next pc, but don't install in case there's an error or branch.
int pcAfter = registers[NextPCReg] + 4;
int sum, diff, tmp, value;
long rs, rt, imm;
// Execute the instruction (cf. Kane's book)
switch (instr.opCode) {
case Instruction.OP_ADD:
sum = registers[instr.rs] + registers[instr.rt];
if (((registers[instr.rs] ^ registers[instr.rt]) & SIGN_BIT) == 0 &&
((registers[instr.rs] ^ sum) & SIGN_BIT) != 0) {
raiseException(OverflowException, 0);
return;
}
registers[instr.rd] = sum;
break;
case Instruction.OP_ADDI:
sum = registers[instr.rs] + instr.extra;
if (((registers[instr.rs] ^ instr.extra) & SIGN_BIT) == 0 &&
((instr.extra ^ sum) & SIGN_BIT) != 0) {
raiseException(OverflowException, 0);
return;
}
registers[instr.rt] = sum;
break;
case Instruction.OP_ADDIU:
// the registers are int, so we have to do them unsigned.
// Now, precisely *WHY* didn't java give us unsigned types, again?
rs = registers[instr.rs] & LOW32BITS;
imm = instr.extra & LOW32BITS;
rt = rs + imm;
registers[instr.rt] = (int)rt;
break;
case Instruction.OP_ADDU:
rs = registers[instr.rs] & LOW32BITS;
rt = registers[instr.rt] & LOW32BITS;
registers[instr.rd] = (int)(rs + rt);
break;
case Instruction.OP_AND:
registers[instr.rd] = registers[instr.rs] & registers[instr.rt];
break;
case Instruction.OP_ANDI:
registers[instr.rt] = registers[instr.rs] & (instr.extra & 0xffff);
break;
case Instruction.OP_BEQ:
if (registers[instr.rs] == registers[instr.rt])
pcAfter = registers[NextPCReg] + (instr.extra << 2);
break;
case Instruction.OP_BGEZAL:
registers[R31] = registers[NextPCReg] + 4;
case Instruction.OP_BGEZ:
if ((registers[instr.rs] & SIGN_BIT) == 0)
pcAfter = registers[NextPCReg] + (instr.extra << 2);
break;
case Instruction.OP_BGTZ:
if (registers[instr.rs] > 0)
pcAfter = registers[NextPCReg] + (instr.extra << 2);
break;
case Instruction.OP_BLEZ:
if (registers[instr.rs] <= 0)
pcAfter = registers[NextPCReg] + (instr.extra << 2);
break;
case Instruction.OP_BLTZAL:
registers[R31] = registers[NextPCReg] + 4;
case Instruction.OP_BLTZ:
if ((registers[instr.rs] & SIGN_BIT) != 0)
pcAfter = registers[NextPCReg] + (instr.extra << 2);
break;
case Instruction.OP_BNE:
if (registers[instr.rs] != registers[instr.rt])
pcAfter = registers[NextPCReg] + (instr.extra << 2);
break;
case Instruction.OP_DIV:
if (registers[instr.rt] == 0) {
registers[LoReg] = 0;
registers[HiReg] = 0;
} else {
registers[LoReg] = registers[instr.rs] / registers[instr.rt];
registers[HiReg] = registers[instr.rs] % registers[instr.rt];
}
break;
case Instruction.OP_DIVU:
// don't sign extend
rs = (registers[instr.rs] & LOW32BITS);
rt = (registers[instr.rt] & LOW32BITS);
if (rt == 0) {
registers[LoReg] = 0;
registers[HiReg] = 0;
} else {
tmp = (int) (rs / rt);
registers[LoReg] = tmp;
tmp = (int) (rs % rt);
registers[HiReg] = tmp;
}
break;
case Instruction.OP_JAL:
registers[R31] = registers[NextPCReg] + 4;
case Instruction.OP_J:
pcAfter = (pcAfter & 0xf0000000) | instr.extra << 2;
break;
case Instruction.OP_JALR:
registers[instr.rd] = registers[NextPCReg] + 4;
case Instruction.OP_JR:
pcAfter = registers[instr.rs];
break;
case Instruction.OP_LB:
case Instruction.OP_LBU:
tmp = registers[instr.rs] + instr.extra;
try {
value = readMem(tmp, 1);
} catch (MachineException e) {
return; // exception occurred
}
if ((value & 0x80) != 0 && (instr.opCode == Instruction.OP_LB))
value |= 0xffffff00;
else
value &= 0xff;
nextLoadReg = instr.rt;
nextLoadValue = value;
break;
case Instruction.OP_LH:
case Instruction.OP_LHU:
tmp = registers[instr.rs] + instr.extra;
if ((tmp & 0x1) != 0) {
raiseException(AddressErrorException, tmp);
return;
}
try {
value = readMem(tmp, 2);
} catch (MachineException e) {
return; // exception occurred
}
if ((value & 0x8000) != 0 && (instr.opCode == Instruction.OP_LH))
value |= 0xffff0000;
else
value &= 0xffff;
nextLoadReg = instr.rt;
nextLoadValue = value;
break;
case Instruction.OP_LUI:
if (Debug.isEnabled('m'))
Debug.printf('m', "Executing: LUI r%d,%d\n",
new Integer(instr.rt), new Integer(instr.extra));
registers[instr.rt] = instr.extra << 16;
break;
case Instruction.OP_LW:
tmp = registers[instr.rs] + instr.extra;
if ((tmp & 0x3) != 0) {
raiseException(AddressErrorException, tmp);
return;
}
try {
value = readMem(tmp, 4);
} catch (MachineException e) {
return; // exception occurred
}
nextLoadReg = instr.rt;
nextLoadValue = value;
break;
case Instruction.OP_LWL:
tmp = registers[instr.rs] + instr.extra;
// ReadMem assumes all 4 byte requests are aligned on an even
// word boundary. Also, the little endian/big endian swap code would
// fail (I think) if the other cases are ever exercised.
Debug.ASSERT((tmp & 0x3) == 0);
try {
value = readMem(tmp, 4);
} catch (MachineException e) {
return; // exception occurred
}
if (registers[LoadReg] == instr.rt)
nextLoadValue = registers[LoadValueReg];
else
nextLoadValue = registers[instr.rt];
switch (tmp & 0x3) {
case 0:
nextLoadValue = value;
break;
case 1:
nextLoadValue = (nextLoadValue & 0xff) | (value << 8);
break;
case 2:
nextLoadValue = (nextLoadValue & 0xffff) | (value << 16);
break;
case 3:
nextLoadValue = (nextLoadValue & 0xffffff) | (value << 24);
break;
}
nextLoadReg = instr.rt;
break;
case Instruction.OP_LWR:
tmp = registers[instr.rs] + instr.extra;
// ReadMem assumes all 4 byte requests are aligned on an even
// word boundary. Also, the little endian/big endian swap code would
// fail (I think) if the other cases are ever exercised.
Debug.ASSERT((tmp & 0x3) == 0);
try {
value = readMem(tmp, 4);
} catch (MachineException e) {
return; // exception occurred
}
if (registers[LoadReg] == instr.rt)
nextLoadValue = registers[LoadValueReg];
else
nextLoadValue = registers[instr.rt];
switch (tmp & 0x3) {
case 0:
nextLoadValue = (nextLoadValue & 0xffffff00) |
((value >> 24) & 0xff);
break;
case 1:
nextLoadValue = (nextLoadValue & 0xffff0000) |
((value >> 16) & 0xffff);
break;
case 2:
nextLoadValue = (nextLoadValue & 0xff000000)
| ((value >> 8) & 0xffffff);
break;
case 3:
nextLoadValue = value;
break;
}
nextLoadReg = instr.rt;
break;
case Instruction.OP_MFHI:
registers[instr.rd] = registers[HiReg];
break;
case Instruction.OP_MFLO:
registers[instr.rd] = registers[LoReg];
break;
case Instruction.OP_MTHI:
registers[HiReg] = registers[instr.rs];
break;
case Instruction.OP_MTLO:
registers[LoReg] = registers[instr.rs];
break;
case Instruction.OP_MULT:
mult(registers[instr.rs], registers[instr.rt], true,
mresult);
registers[HiReg] = mresult[0];
registers[LoReg] = mresult[1];
break;
case Instruction.OP_MULTU:
mult(registers[instr.rs], registers[instr.rt], false,
mresult);
registers[HiReg] = mresult[0];
registers[LoReg] = mresult[1];
break;
case Instruction.OP_NOR:
registers[instr.rd] = ~(registers[instr.rs] | registers[instr.rt]);
break;
case Instruction.OP_OR:
registers[instr.rd] = registers[instr.rs] | registers[instr.rt];
break;
case Instruction.OP_ORI:
registers[instr.rt] = registers[instr.rs] | (instr.extra & 0xffff);
break;
case Instruction.OP_SB:
if (!writeMem(
(registers[instr.rs] + instr.extra), 1, registers[instr.rt]))
return;
break;
case Instruction.OP_SH:
if (!writeMem(
(registers[instr.rs] + instr.extra), 2, registers[instr.rt]))
return;
break;
case Instruction.OP_SLL:
registers[instr.rd] = registers[instr.rt] << instr.extra;
break;
case Instruction.OP_SLLV:
registers[instr.rd] = registers[instr.rt] <<
(registers[instr.rs] & 0x1f);
break;
case Instruction.OP_SLT:
if (registers[instr.rs] < registers[instr.rt])
registers[instr.rd] = 1;
else
registers[instr.rd] = 0;
break;
case Instruction.OP_SLTI:
if (registers[instr.rs] < instr.extra)
registers[instr.rt] = 1;
else
registers[instr.rt] = 0;
break;
case Instruction.OP_SLTIU:
rs = (registers[instr.rs] & LOW32BITS);
imm = (instr.extra & LOW32BITS);
if (rs < imm)
registers[instr.rt] = 1;
else
registers[instr.rt] = 0;
break;
case Instruction.OP_SLTU:
rs = registers[instr.rs] & LOW32BITS;
rt = registers[instr.rt] & LOW32BITS;
if (rs < rt)
registers[instr.rd] = 1;
else
registers[instr.rd] = 0;
break;
case Instruction.OP_SRA:
registers[instr.rd] = registers[instr.rt] >> instr.extra;
break;
case Instruction.OP_SRAV:
registers[instr.rd] = registers[instr.rt] >>
(registers[instr.rs] & 0x1f);
break;
case Instruction.OP_SRL:
tmp = registers[instr.rt];
tmp >>= instr.extra;
registers[instr.rd] = tmp;
break;
case Instruction.OP_SRLV:
tmp = registers[instr.rt];
tmp >>= (registers[instr.rs] & 0x1f);
registers[instr.rd] = tmp;
break;
case Instruction.OP_SUB:
diff = registers[instr.rs] - registers[instr.rt];
if (((registers[instr.rs] ^ registers[instr.rt]) & SIGN_BIT) != 0 &&
((registers[instr.rs] ^ diff) & SIGN_BIT) != 0) {
raiseException(OverflowException, 0);
return;
}
registers[instr.rd] = diff;
break;
case Instruction.OP_SUBU:
rs = (registers[instr.rs] & LOW32BITS);
rt = (registers[instr.rt] & LOW32BITS);
registers[instr.rd] = (int)(rs - rt);
break;
case Instruction.OP_SW:
if (!writeMem(
(registers[instr.rs] + instr.extra), 4, registers[instr.rt]))
return;
break;
case Instruction.OP_SWL:
tmp = registers[instr.rs] + instr.extra;
// The little endian/big endian swap code would
// fail (I think) if the other cases are ever exercised.
Debug.ASSERT((tmp & 0x3) == 0);
try {
value = readMem((tmp & ~0x3), 4);
} catch (MachineException e) {
return; // exception occurred
}
switch (tmp & 0x3) {
case 0:
value = registers[instr.rt];
break;
case 1:
value = (value & 0xff000000) | ((registers[instr.rt] >> 8) &
0xffffff);
break;
case 2:
value = (value & 0xffff0000) | ((registers[instr.rt] >> 16) &
0xffff);
break;
case 3:
value = (value & 0xffffff00) | ((registers[instr.rt] >> 24) &
0xff);
break;
}
if (!writeMem((tmp & ~0x3), 4, value))
return;
break;
case Instruction.OP_SWR:
tmp = registers[instr.rs] + instr.extra;
// The little endian/big endian swap code would
// fail (I think) if the other cases are ever exercised.
Debug.ASSERT((tmp & 0x3) == 0);
try {
value = readMem((tmp & ~0x3), 4);
} catch (MachineException e) {
return; // exception occurred
}
switch (tmp & 0x3) {
case 0:
value = (value & 0xffffff) | (registers[instr.rt] << 24);
break;
case 1:
value = (value & 0xffff) | (registers[instr.rt] << 16);
break;
case 2:
value = (value & 0xff) | (registers[instr.rt] << 8);
break;
case 3:
value = registers[instr.rt];
break;
}
if (!writeMem((tmp & ~0x3), 4, value))
return;
break;
case Instruction.OP_SYSCALL:
raiseException(SyscallException, 0);
return;
case Instruction.OP_XOR:
registers[instr.rd] = registers[instr.rs] ^ registers[instr.rt];
break;
case Instruction.OP_XORI:
registers[instr.rt] = registers[instr.rs] ^ (instr.extra & 0xffff);
break;
case Instruction.OP_RES:
case Instruction.OP_UNIMP:
raiseException(IllegalInstrException, 0);
return;
default:
System.out.println("Bogus opcode, should not happen");
return;
}
// Now we have successfully executed the instruction.
// Do any delayed load operation
delayedLoad(nextLoadReg, nextLoadValue);
// Advance program counters.
registers[PrevPCReg] = registers[PCReg]; // for debugging, in case we
// are jumping into lala-land
registers[PCReg] = registers[NextPCReg];
registers[NextPCReg] = pcAfter;
}
static private int translate(int virtAddr, int size, boolean writing)
throws MachineException {
int i = 0;
long vpn, offset;
TranslationEntry entry;
long pageFrame;
int physAddr;
if (Debug.isEnabled('a')) {
if (writing)
Debug.printf('a', "\tTranslate 0x%x, %s: ", new Integer(virtAddr),
"write");
else
Debug.printf('a', "\tTranslate 0x%x, %s: ", new Integer(virtAddr),
"read");
}
// check for alignment errors
if (((size == 4) && (virtAddr & 0x3) != 0) ||
((size == 2) && (virtAddr & 0x1) != 0)) {
Debug.println('a', "alignment problem at " + virtAddr + ", size " + size);
throw new MachineException(exceptionNames[AddressErrorException],
AddressErrorException);
}
// we must have either a TLB or a page table, but not both!
Debug.ASSERT(tlb == null || pageTable == null);
Debug.ASSERT(tlb != null || pageTable != null);
// calculate the virtual page number, and offset within the page,
// from the virtual address
vpn = ((long) virtAddr & LOW32BITS) / PageSize;
offset = ((long) virtAddr & LOW32BITS) % PageSize;
if (tlb == null) { // => page table => vpn is index into table
if (vpn >= pageTableSize) {
Debug.println('a', "virtual page # " + virtAddr +
" too large for page table size " + pageTableSize);
throw new MachineException(exceptionNames[AddressErrorException],
AddressErrorException);
} else if (!pageTable[(int)vpn].valid) {
Debug.println('a', "virtual page # " + virtAddr +
" too large for page table size " + pageTableSize);
throw new MachineException(exceptionNames[PageFaultException],
PageFaultException);
}
entry = pageTable[(int)vpn];
} else {
for (entry = null, i = 0; i < TLBSize; i++)
if (tlb[i].valid && (tlb[i].virtualPage == vpn)) {
entry = tlb[i]; // FOUND!
break;
}
if (entry == null) { // not found
Debug.println('a', "** no valid TLB entry found for this virtual page!");
// really, this is a TLB fault,
// the page may be in memory,
// but not in the TLB
throw new MachineException(exceptionNames[PageFaultException],
PageFaultException);
}
}
if (entry.readOnly && writing) { // trying to write to a read-only page
Debug.println('a', virtAddr + " mapped read-only at " + i + " in TLB!");
throw new MachineException(exceptionNames[ReadOnlyException],
ReadOnlyException);
}
pageFrame = entry.physicalPage;
// if the pageFrame is too big, there is something really wrong!
// An invalid translation was loaded into the page table or TLB.
if (pageFrame >= NumPhysPages) {
Debug.println('a', "*** frame " + pageFrame + " > " + NumPhysPages);
throw new MachineException(exceptionNames[BusErrorException],
BusErrorException);
}
entry.use = true; // set the use, dirty bits
if (writing)
entry.dirty = true;
physAddr = (int) (pageFrame * PageSize + offset);
Debug.ASSERT((physAddr >= 0) && ((physAddr + size) <= MemorySize));
if (Debug.isEnabled('a')) {
Debug.printf('a', "phys addr = 0x%x\n", new Integer(physAddr));
}
return physAddr;
}
