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gem5/arch/alpha/alpha_memory.cc
Steve Reinhardt 368882a847 Fix timing modeling of faults: functionally the very next instruction after 
a faulting instruction is the fault handler, which appears as an independent
instruction to the timing model.  New code will stall fetch and not fetch the
fault handler as long as there's a faulting instruction in the pipeline (i.e.,
the faulting inst has to commit first).

Also fix Ali's bad-address assertion that doesn't apply to full system.

Added some more debugging support in the process.  Hopefully we'll move to the new
cpu model soon and we won't need it anymore.

arch/alpha/alpha_memory.cc:
    Reorganize lookup() so we can trace the result of the lookup as well.
arch/alpha/isa_traits.hh:
    Add NoopMachInst (so we can insert them in the pipeline on ifetch faults).
base/traceflags.py:
    Replace "Dispatch" flag with "Pipeline" (since I added similar
    DPRINTFs in other pipe stages).
cpu/exetrace.cc:
    Change default for printing mis-speculated instructions to true (since
    that's often what we want, and right now you can't change it from the
    command line...).

--HG--
extra : convert_revision : a29a98a373076d62bbbb1d6f40ba51ecae436dbc
2005-02-25 12:41:08 -05:00

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/*
* Copyright (c) 2001-2004 The Regents of The University of Michigan
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <sstream>
#include <string>
#include <vector>
#include "arch/alpha/alpha_memory.hh"
#include "base/inifile.hh"
#include "base/str.hh"
#include "base/trace.hh"
#include "cpu/exec_context.hh"
#include "sim/builder.hh"
using namespace std;
using namespace EV5;
///////////////////////////////////////////////////////////////////////
//
// Alpha TLB
//
#ifdef DEBUG
bool uncacheBit39 = false;
bool uncacheBit40 = false;
#endif
#define MODE2MASK(X) (1 << (X))
AlphaTLB::AlphaTLB(const string &name, int s)
: SimObject(name), size(s), nlu(0)
{
table = new AlphaISA::PTE[size];
memset(table, 0, sizeof(AlphaISA::PTE[size]));
}
AlphaTLB::~AlphaTLB()
{
if (table)
delete [] table;
}
// look up an entry in the TLB
AlphaISA::PTE *
AlphaTLB::lookup(Addr vpn, uint8_t asn) const
{
// assume not found...
AlphaISA::PTE *retval = NULL;
PageTable::const_iterator i = lookupTable.find(vpn);
if (i != lookupTable.end()) {
while (i->first == vpn) {
int index = i->second;
AlphaISA::PTE *pte = &table[index];
assert(pte->valid);
if (vpn == pte->tag && (pte->asma || pte->asn == asn)) {
retval = pte;
break;
}
++i;
}
}
DPRINTF(TLB, "lookup %#x, asn %#x -> %s ppn %#x\n", vpn, (int)asn,
retval ? "hit" : "miss", retval ? retval->ppn : 0);
return retval;
}
void
AlphaTLB::checkCacheability(MemReqPtr &req)
{
// in Alpha, cacheability is controlled by upper-level bits of the
// physical address
/*
* We support having the uncacheable bit in either bit 39 or bit 40.
* The Turbolaser platform (and EV5) support having the bit in 39, but
* Tsunami (which Linux assumes uses an EV6) generates accesses with
* the bit in 40. So we must check for both, but we have debug flags
* to catch a weird case where both are used, which shouldn't happen.
*/
#ifdef ALPHA_TLASER
if (req->paddr & PAddrUncachedBit39) {
#else
if (req->paddr & PAddrUncachedBit43) {
#endif
// IPR memory space not implemented
if (PAddrIprSpace(req->paddr)) {
if (!req->xc->misspeculating()) {
switch (req->paddr) {
case ULL(0xFFFFF00188):
req->data = 0;
break;
default:
panic("IPR memory space not implemented! PA=%x\n",
req->paddr);
}
}
} else {
// mark request as uncacheable
req->flags |= UNCACHEABLE;
#ifndef ALPHA_TLASER
// Clear bits 42:35 of the physical address (10-2 in Tsunami manual)
req->paddr &= PAddrUncachedMask;
#endif
}
}
}
// insert a new TLB entry
void
AlphaTLB::insert(Addr addr, AlphaISA::PTE &pte)
{
AlphaISA::VAddr vaddr = addr;
if (table[nlu].valid) {
Addr oldvpn = table[nlu].tag;
PageTable::iterator i = lookupTable.find(oldvpn);
if (i == lookupTable.end())
panic("TLB entry not found in lookupTable");
int index;
while ((index = i->second) != nlu) {
if (table[index].tag != oldvpn)
panic("TLB entry not found in lookupTable");
++i;
}
DPRINTF(TLB, "remove @%d: %#x -> %#x\n", nlu, oldvpn, table[nlu].ppn);
lookupTable.erase(i);
}
DPRINTF(TLB, "insert @%d: %#x -> %#x\n", nlu, vaddr.vpn(), pte.ppn);
table[nlu] = pte;
table[nlu].tag = vaddr.vpn();
table[nlu].valid = true;
lookupTable.insert(make_pair(vaddr.vpn(), nlu));
nextnlu();
}
void
AlphaTLB::flushAll()
{
memset(table, 0, sizeof(AlphaISA::PTE[size]));
lookupTable.clear();
nlu = 0;
}
void
AlphaTLB::flushProcesses()
{
PageTable::iterator i = lookupTable.begin();
PageTable::iterator end = lookupTable.end();
while (i != end) {
int index = i->second;
AlphaISA::PTE *pte = &table[index];
assert(pte->valid);
if (!pte->asma) {
DPRINTF(TLB, "flush @%d: %#x -> %#x\n", index, pte->tag, pte->ppn);
pte->valid = false;
lookupTable.erase(i);
}
++i;
}
}
void
AlphaTLB::flushAddr(Addr addr, uint8_t asn)
{
AlphaISA::VAddr vaddr = addr;
PageTable::iterator i = lookupTable.find(vaddr.vpn());
if (i == lookupTable.end())
return;
while (i->first == vaddr.vpn()) {
int index = i->second;
AlphaISA::PTE *pte = &table[index];
assert(pte->valid);
if (vaddr.vpn() == pte->tag && (pte->asma || pte->asn == asn)) {
DPRINTF(TLB, "flushaddr @%d: %#x -> %#x\n", index, vaddr.vpn(),
pte->ppn);
// invalidate this entry
pte->valid = false;
lookupTable.erase(i);
}
++i;
}
}
void
AlphaTLB::serialize(ostream &os)
{
SERIALIZE_SCALAR(size);
SERIALIZE_SCALAR(nlu);
for (int i = 0; i < size; i++) {
nameOut(os, csprintf("%s.PTE%d", name(), i));
table[i].serialize(os);
}
}
void
AlphaTLB::unserialize(Checkpoint *cp, const string &section)
{
UNSERIALIZE_SCALAR(size);
UNSERIALIZE_SCALAR(nlu);
for (int i = 0; i < size; i++) {
table[i].unserialize(cp, csprintf("%s.PTE%d", section, i));
if (table[i].valid) {
lookupTable.insert(make_pair(table[i].tag, i));
}
}
}
///////////////////////////////////////////////////////////////////////
//
// Alpha ITB
//
AlphaITB::AlphaITB(const std::string &name, int size)
: AlphaTLB(name, size)
{}
void
AlphaITB::regStats()
{
hits
.name(name() + ".hits")
.desc("ITB hits");
misses
.name(name() + ".misses")
.desc("ITB misses");
acv
.name(name() + ".acv")
.desc("ITB acv");
accesses
.name(name() + ".accesses")
.desc("ITB accesses");
accesses = hits + misses;
}
void
AlphaITB::fault(Addr pc, ExecContext *xc) const
{
uint64_t *ipr = xc->regs.ipr;
if (!xc->misspeculating()) {
ipr[AlphaISA::IPR_ITB_TAG] = pc;
ipr[AlphaISA::IPR_IFAULT_VA_FORM] =
ipr[AlphaISA::IPR_IVPTBR] | (AlphaISA::VAddr(pc).vpn() << 3);
}
}
Fault
AlphaITB::translate(MemReqPtr &req) const
{
InternalProcReg *ipr = req->xc->regs.ipr;
if (AlphaISA::PcPAL(req->vaddr)) {
// strip off PAL PC marker (lsb is 1)
req->paddr = (req->vaddr & ~3) & PAddrImplMask;
hits++;
return No_Fault;
}
if (req->flags & PHYSICAL) {
req->paddr = req->vaddr;
} else {
// verify that this is a good virtual address
if (!validVirtualAddress(req->vaddr)) {
fault(req->vaddr, req->xc);
acv++;
return ITB_Acv_Fault;
}
// VA<42:41> == 2, VA<39:13> maps directly to PA<39:13> for EV5
// VA<47:41> == 0x7e, VA<40:13> maps directly to PA<40:13> for EV6
#ifdef ALPHA_TLASER
if ((MCSR_SP(ipr[AlphaISA::IPR_MCSR]) & 2) &&
VAddrSpaceEV5(req->vaddr) == 2) {
#else
if (VAddrSpaceEV6(req->vaddr) == 0x7e) {
#endif
// only valid in kernel mode
if (ICM_CM(ipr[AlphaISA::IPR_ICM]) !=
AlphaISA::mode_kernel) {
fault(req->vaddr, req->xc);
acv++;
return ITB_Acv_Fault;
}
req->paddr = req->vaddr & PAddrImplMask;
#ifndef ALPHA_TLASER
// sign extend the physical address properly
if (req->paddr & PAddrUncachedBit40)
req->paddr |= ULL(0xf0000000000);
else
req->paddr &= ULL(0xffffffffff);
#endif
} else {
// not a physical address: need to look up pte
AlphaISA::PTE *pte = lookup(AlphaISA::VAddr(req->vaddr).vpn(),
DTB_ASN_ASN(ipr[AlphaISA::IPR_DTB_ASN]));
if (!pte) {
fault(req->vaddr, req->xc);
misses++;
return ITB_Fault_Fault;
}
req->paddr = (pte->ppn << AlphaISA::PageShift) +
(AlphaISA::VAddr(req->vaddr).offset() & ~3);
// check permissions for this access
if (!(pte->xre & (1 << ICM_CM(ipr[AlphaISA::IPR_ICM])))) {
// instruction access fault
fault(req->vaddr, req->xc);
acv++;
return ITB_Acv_Fault;
}
hits++;
}
}
// check that the physical address is ok (catch bad physical addresses)
if (req->paddr & ~PAddrImplMask)
return Machine_Check_Fault;
checkCacheability(req);
return No_Fault;
}
///////////////////////////////////////////////////////////////////////
//
// Alpha DTB
//
AlphaDTB::AlphaDTB(const std::string &name, int size)
: AlphaTLB(name, size)
{}
void
AlphaDTB::regStats()
{
read_hits
.name(name() + ".read_hits")
.desc("DTB read hits")
;
read_misses
.name(name() + ".read_misses")
.desc("DTB read misses")
;
read_acv
.name(name() + ".read_acv")
.desc("DTB read access violations")
;
read_accesses
.name(name() + ".read_accesses")
.desc("DTB read accesses")
;
write_hits
.name(name() + ".write_hits")
.desc("DTB write hits")
;
write_misses
.name(name() + ".write_misses")
.desc("DTB write misses")
;
write_acv
.name(name() + ".write_acv")
.desc("DTB write access violations")
;
write_accesses
.name(name() + ".write_accesses")
.desc("DTB write accesses")
;
hits
.name(name() + ".hits")
.desc("DTB hits")
;
misses
.name(name() + ".misses")
.desc("DTB misses")
;
acv
.name(name() + ".acv")
.desc("DTB access violations")
;
accesses
.name(name() + ".accesses")
.desc("DTB accesses")
;
hits = read_hits + write_hits;
misses = read_misses + write_misses;
acv = read_acv + write_acv;
accesses = read_accesses + write_accesses;
}
void
AlphaDTB::fault(MemReqPtr &req, uint64_t flags) const
{
ExecContext *xc = req->xc;
AlphaISA::VAddr vaddr = req->vaddr;
uint64_t *ipr = xc->regs.ipr;
// Set fault address and flags. Even though we're modeling an
// EV5, we use the EV6 technique of not latching fault registers
// on VPTE loads (instead of locking the registers until IPR_VA is
// read, like the EV5). The EV6 approach is cleaner and seems to
// work with EV5 PAL code, but not the other way around.
if (!xc->misspeculating()
&& !(req->flags & VPTE) && !(req->flags & NO_FAULT)) {
// set VA register with faulting address
ipr[AlphaISA::IPR_VA] = req->vaddr;
// set MM_STAT register flags
ipr[AlphaISA::IPR_MM_STAT] =
(((Opcode(xc->getInst()) & 0x3f) << 11)
| ((Ra(xc->getInst()) & 0x1f) << 6)
| (flags & 0x3f));
// set VA_FORM register with faulting formatted address
ipr[AlphaISA::IPR_VA_FORM] =
ipr[AlphaISA::IPR_MVPTBR] | (vaddr.vpn() << 3);
}
}
Fault
AlphaDTB::translate(MemReqPtr &req, bool write) const
{
RegFile *regs = &req->xc->regs;
Addr pc = regs->pc;
InternalProcReg *ipr = regs->ipr;
AlphaISA::mode_type mode =
(AlphaISA::mode_type)DTB_CM_CM(ipr[AlphaISA::IPR_DTB_CM]);
/**
* Check for alignment faults
*/
if (req->vaddr & (req->size - 1)) {
fault(req, write ? MM_STAT_WR_MASK : 0);
DPRINTF(TLB, "Alignment Fault on %#x, size = %d", req->vaddr,
req->size);
return Alignment_Fault;
}
if (pc & 0x1) {
mode = (req->flags & ALTMODE) ?
(AlphaISA::mode_type)ALT_MODE_AM(ipr[AlphaISA::IPR_ALT_MODE])
: AlphaISA::mode_kernel;
}
if (req->flags & PHYSICAL) {
req->paddr = req->vaddr;
} else {
// verify that this is a good virtual address
if (!validVirtualAddress(req->vaddr)) {
fault(req, (write ? MM_STAT_WR_MASK : 0) |
MM_STAT_BAD_VA_MASK |
MM_STAT_ACV_MASK);
if (write) { write_acv++; } else { read_acv++; }
return DTB_Fault_Fault;
}
// Check for "superpage" mapping
#ifdef ALPHA_TLASER
if ((MCSR_SP(ipr[AlphaISA::IPR_MCSR]) & 2) &&
VAddrSpaceEV5(req->vaddr) == 2) {
#else
if (VAddrSpaceEV6(req->vaddr) == 0x7e) {
#endif
// only valid in kernel mode
if (DTB_CM_CM(ipr[AlphaISA::IPR_DTB_CM]) !=
AlphaISA::mode_kernel) {
fault(req, ((write ? MM_STAT_WR_MASK : 0) |
MM_STAT_ACV_MASK));
if (write) { write_acv++; } else { read_acv++; }
return DTB_Acv_Fault;
}
req->paddr = req->vaddr & PAddrImplMask;
#ifndef ALPHA_TLASER
// sign extend the physical address properly
if (req->paddr & PAddrUncachedBit40)
req->paddr |= ULL(0xf0000000000);
else
req->paddr &= ULL(0xffffffffff);
#endif
} else {
if (write)
write_accesses++;
else
read_accesses++;
// not a physical address: need to look up pte
AlphaISA::PTE *pte = lookup(AlphaISA::VAddr(req->vaddr).vpn(),
DTB_ASN_ASN(ipr[AlphaISA::IPR_DTB_ASN]));
if (!pte) {
// page fault
fault(req, (write ? MM_STAT_WR_MASK : 0) |
MM_STAT_DTB_MISS_MASK);
if (write) { write_misses++; } else { read_misses++; }
return (req->flags & VPTE) ? Pdtb_Miss_Fault : Ndtb_Miss_Fault;
}
req->paddr = (pte->ppn << AlphaISA::PageShift) +
AlphaISA::VAddr(req->vaddr).offset();
if (write) {
if (!(pte->xwe & MODE2MASK(mode))) {
// declare the instruction access fault
fault(req, MM_STAT_WR_MASK |
MM_STAT_ACV_MASK |
(pte->fonw ? MM_STAT_FONW_MASK : 0));
write_acv++;
return DTB_Fault_Fault;
}
if (pte->fonw) {
fault(req, MM_STAT_WR_MASK |
MM_STAT_FONW_MASK);
write_acv++;
return DTB_Fault_Fault;
}
} else {
if (!(pte->xre & MODE2MASK(mode))) {
fault(req, MM_STAT_ACV_MASK |
(pte->fonr ? MM_STAT_FONR_MASK : 0));
read_acv++;
return DTB_Acv_Fault;
}
if (pte->fonr) {
fault(req, MM_STAT_FONR_MASK);
read_acv++;
return DTB_Fault_Fault;
}
}
}
if (write)
write_hits++;
else
read_hits++;
}
// check that the physical address is ok (catch bad physical addresses)
if (req->paddr & ~PAddrImplMask)
return Machine_Check_Fault;
checkCacheability(req);
return No_Fault;
}
AlphaISA::PTE &
AlphaTLB::index(bool advance)
{
AlphaISA::PTE *pte = &table[nlu];
if (advance)
nextnlu();
return *pte;
}
DEFINE_SIM_OBJECT_CLASS_NAME("AlphaTLB", AlphaTLB)
BEGIN_DECLARE_SIM_OBJECT_PARAMS(AlphaITB)
Param<int> size;
END_DECLARE_SIM_OBJECT_PARAMS(AlphaITB)
BEGIN_INIT_SIM_OBJECT_PARAMS(AlphaITB)
INIT_PARAM_DFLT(size, "TLB size", 48)
END_INIT_SIM_OBJECT_PARAMS(AlphaITB)
CREATE_SIM_OBJECT(AlphaITB)
{
return new AlphaITB(getInstanceName(), size);
}
REGISTER_SIM_OBJECT("AlphaITB", AlphaITB)
BEGIN_DECLARE_SIM_OBJECT_PARAMS(AlphaDTB)
Param<int> size;
END_DECLARE_SIM_OBJECT_PARAMS(AlphaDTB)
BEGIN_INIT_SIM_OBJECT_PARAMS(AlphaDTB)
INIT_PARAM_DFLT(size, "TLB size", 64)
END_INIT_SIM_OBJECT_PARAMS(AlphaDTB)
CREATE_SIM_OBJECT(AlphaDTB)
{
return new AlphaDTB(getInstanceName(), size);
}
REGISTER_SIM_OBJECT("AlphaDTB", AlphaDTB)
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