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/*
* Copyright (c) 2010-2015 ARM Limited
* All rights reserved.
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Copyright (c) 2002-2005 The Regents of The University of Michigan
* Copyright (c) 2010,2015 Advanced Micro Devices, Inc.
* 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.
*
* Authors: Erik Hallnor
* Dave Greene
* Nathan Binkert
* Steve Reinhardt
* Ron Dreslinski
* Andreas Sandberg
*/
#ifndef __MEM_CACHE_CACHE_IMPL_HH__
#define __MEM_CACHE_CACHE_IMPL_HH__
/**
* @file
* Cache definitions.
*/
#include "base/misc.hh"
#include "base/types.hh"
#include "debug/Cache.hh"
#include "debug/CachePort.hh"
#include "debug/CacheTags.hh"
#include "mem/cache/prefetch/base.hh"
#include "mem/cache/blk.hh"
#include "mem/cache/cache.hh"
#include "mem/cache/mshr.hh"
#include "sim/sim_exit.hh"
template<class TagStore>
Cache<TagStore>::Cache(const Params *p)
: BaseCache(p),
tags(dynamic_cast<TagStore*>(p->tags)),
prefetcher(p->prefetcher),
doFastWrites(true),
prefetchOnAccess(p->prefetch_on_access)
{
tempBlock = new BlkType();
tempBlock->data = new uint8_t[blkSize];
cpuSidePort = new CpuSidePort(p->name + ".cpu_side", this,
"CpuSidePort");
memSidePort = new MemSidePort(p->name + ".mem_side", this,
"MemSidePort");
tags->setCache(this);
if (prefetcher)
prefetcher->setCache(this);
}
template<class TagStore>
Cache<TagStore>::~Cache()
{
delete [] tempBlock->data;
delete tempBlock;
delete cpuSidePort;
delete memSidePort;
}
template<class TagStore>
void
Cache<TagStore>::regStats()
{
BaseCache::regStats();
}
template<class TagStore>
void
Cache<TagStore>::cmpAndSwap(BlkType *blk, PacketPtr pkt)
{
assert(pkt->isRequest());
uint64_t overwrite_val;
bool overwrite_mem;
uint64_t condition_val64;
uint32_t condition_val32;
int offset = tags->extractBlkOffset(pkt->getAddr());
uint8_t *blk_data = blk->data + offset;
assert(sizeof(uint64_t) >= pkt->getSize());
overwrite_mem = true;
// keep a copy of our possible write value, and copy what is at the
// memory address into the packet
pkt->writeData((uint8_t *)&overwrite_val);
pkt->setData(blk_data);
if (pkt->req->isCondSwap()) {
if (pkt->getSize() == sizeof(uint64_t)) {
condition_val64 = pkt->req->getExtraData();
overwrite_mem = !std::memcmp(&condition_val64, blk_data,
sizeof(uint64_t));
} else if (pkt->getSize() == sizeof(uint32_t)) {
condition_val32 = (uint32_t)pkt->req->getExtraData();
overwrite_mem = !std::memcmp(&condition_val32, blk_data,
sizeof(uint32_t));
} else
panic("Invalid size for conditional read/write\n");
}
if (overwrite_mem) {
std::memcpy(blk_data, &overwrite_val, pkt->getSize());
blk->status |= BlkDirty;
}
}
template<class TagStore>
void
Cache<TagStore>::satisfyCpuSideRequest(PacketPtr pkt, BlkType *blk,
bool deferred_response,
bool pending_downgrade)
{
assert(pkt->isRequest());
assert(blk && blk->isValid());
// Occasionally this is not true... if we are a lower-level cache
// satisfying a string of Read and ReadEx requests from
// upper-level caches, a Read will mark the block as shared but we
// can satisfy a following ReadEx anyway since we can rely on the
// Read requester(s) to have buffered the ReadEx snoop and to
// invalidate their blocks after receiving them.
// assert(!pkt->needsExclusive() || blk->isWritable());
assert(pkt->getOffset(blkSize) + pkt->getSize() <= blkSize);
// Check RMW operations first since both isRead() and
// isWrite() will be true for them
if (pkt->cmd == MemCmd::SwapReq) {
cmpAndSwap(blk, pkt);
} else if (pkt->isWrite() &&
(!pkt->isWriteInvalidate() || isTopLevel)) {
assert(blk->isWritable());
// Write or WriteInvalidate at the first cache with block in Exclusive
if (blk->checkWrite(pkt)) {
pkt->writeDataToBlock(blk->data, blkSize);
}
// Always mark the line as dirty even if we are a failed
// StoreCond so we supply data to any snoops that have
// appended themselves to this cache before knowing the store
// will fail.
blk->status |= BlkDirty;
DPRINTF(Cache, "%s for %s addr %#llx size %d (write)\n", __func__,
pkt->cmdString(), pkt->getAddr(), pkt->getSize());
} else if (pkt->isRead()) {
if (pkt->isLLSC()) {
blk->trackLoadLocked(pkt);
}
pkt->setDataFromBlock(blk->data, blkSize);
if (pkt->getSize() == blkSize) {
// special handling for coherent block requests from
// upper-level caches
if (pkt->needsExclusive()) {
// if we have a dirty copy, make sure the recipient
// keeps it marked dirty
if (blk->isDirty()) {
pkt->assertMemInhibit();
}
// on ReadExReq we give up our copy unconditionally
if (blk != tempBlock)
tags->invalidate(blk);
blk->invalidate();
} else if (blk->isWritable() && !pending_downgrade
&& !pkt->sharedAsserted() && !pkt->req->isInstFetch()) {
// we can give the requester an exclusive copy (by not
// asserting shared line) on a read request if:
// - we have an exclusive copy at this level (& below)
// - we don't have a pending snoop from below
// signaling another read request
// - no other cache above has a copy (otherwise it
// would have asseretd shared line on request)
// - we are not satisfying an instruction fetch (this
// prevents dirty data in the i-cache)
if (blk->isDirty()) {
// special considerations if we're owner:
if (!deferred_response && !isTopLevel) {
// if we are responding immediately and can
// signal that we're transferring ownership
// along with exclusivity, do so
pkt->assertMemInhibit();
blk->status &= ~BlkDirty;
} else {
// if we're responding after our own miss,
// there's a window where the recipient didn't
// know it was getting ownership and may not
// have responded to snoops correctly, so we
// can't pass off ownership *or* exclusivity
pkt->assertShared();
}
}
} else {
// otherwise only respond with a shared copy
pkt->assertShared();
}
}
} else {
// Upgrade or WriteInvalidate at a different cache than received it.
// Since we have it Exclusively (E or M), we ack then invalidate.
assert(pkt->isUpgrade() ||
(pkt->isWriteInvalidate() && !isTopLevel));
assert(blk != tempBlock);
tags->invalidate(blk);
blk->invalidate();
DPRINTF(Cache, "%s for %s addr %#llx size %d (invalidation)\n",
__func__, pkt->cmdString(), pkt->getAddr(), pkt->getSize());
}
}
/////////////////////////////////////////////////////
//
// MSHR helper functions
//
/////////////////////////////////////////////////////
template<class TagStore>
void
Cache<TagStore>::markInService(MSHR *mshr, bool pending_dirty_resp)
{
markInServiceInternal(mshr, pending_dirty_resp);
#if 0
if (mshr->originalCmd == MemCmd::HardPFReq) {
DPRINTF(HWPrefetch, "Marking a HW_PF in service\n");
//Also clear pending if need be
if (!prefetcher->havePending())
{
deassertMemSideBusRequest(Request_PF);
}
}
#endif
}
template<class TagStore>
void
Cache<TagStore>::squash(int threadNum)
{
bool unblock = false;
BlockedCause cause = NUM_BLOCKED_CAUSES;
if (noTargetMSHR && noTargetMSHR->threadNum == threadNum) {
noTargetMSHR = NULL;
unblock = true;
cause = Blocked_NoTargets;
}
if (mshrQueue.isFull()) {
unblock = true;
cause = Blocked_NoMSHRs;
}
mshrQueue.squash(threadNum);
if (unblock && !mshrQueue.isFull()) {
clearBlocked(cause);
}
}
/////////////////////////////////////////////////////
//
// Access path: requests coming in from the CPU side
//
/////////////////////////////////////////////////////
template<class TagStore>
bool
Cache<TagStore>::access(PacketPtr pkt, BlkType *&blk,
Cycles &lat, PacketList &writebacks)
{
// sanity check
assert(pkt->isRequest());
DPRINTF(Cache, "%s for %s addr %#llx size %d\n", __func__,
pkt->cmdString(), pkt->getAddr(), pkt->getSize());
if (pkt->req->isUncacheable()) {
uncacheableFlush(pkt);
blk = NULL;
// lookupLatency is the latency in case the request is uncacheable.
lat = lookupLatency;
return false;
}
int id = pkt->req->hasContextId() ? pkt->req->contextId() : -1;
// Here lat is the value passed as parameter to accessBlock() function
// that can modify its value.
blk = tags->accessBlock(pkt->getAddr(), pkt->isSecure(), lat, id);
DPRINTF(Cache, "%s%s addr %#llx size %d (%s) %s\n", pkt->cmdString(),
pkt->req->isInstFetch() ? " (ifetch)" : "",
pkt->getAddr(), pkt->getSize(), pkt->isSecure() ? "s" : "ns",
blk ? "hit " + blk->print() : "miss");
// Writeback handling is special case. We can write the block into
// the cache without having a writeable copy (or any copy at all).
if (pkt->cmd == MemCmd::Writeback) {
assert(blkSize == pkt->getSize());
if (blk == NULL) {
// need to do a replacement
blk = allocateBlock(pkt->getAddr(), pkt->isSecure(), writebacks);
if (blk == NULL) {
// no replaceable block available: give up, fwd to next level.
incMissCount(pkt);
return false;
}
tags->insertBlock(pkt, blk);
blk->status = (BlkValid | BlkReadable);
if (pkt->isSecure()) {
blk->status |= BlkSecure;
}
}
blk->status |= BlkDirty;
if (pkt->isSupplyExclusive()) {
blk->status |= BlkWritable;
}
// nothing else to do; writeback doesn't expect response
assert(!pkt->needsResponse());
std::memcpy(blk->data, pkt->getConstPtr<uint8_t>(), blkSize);
DPRINTF(Cache, "%s new state is %s\n", __func__, blk->print());
incHitCount(pkt);
return true;
} else if ((blk != NULL) &&
(pkt->needsExclusive() ? blk->isWritable()
: blk->isReadable())) {
// OK to satisfy access
incHitCount(pkt);
satisfyCpuSideRequest(pkt, blk);
return true;
}
// Can't satisfy access normally... either no block (blk == NULL)
// or have block but need exclusive & only have shared.
incMissCount(pkt);
if (blk == NULL && pkt->isLLSC() && pkt->isWrite()) {
// complete miss on store conditional... just give up now
pkt->req->setExtraData(0);
return true;
}
return false;
}
class ForwardResponseRecord : public Packet::SenderState
{
public:
ForwardResponseRecord() {}
};
template<class TagStore>
void
Cache<TagStore>::recvTimingSnoopResp(PacketPtr pkt)
{
DPRINTF(Cache, "%s for %s addr %#llx size %d\n", __func__,
pkt->cmdString(), pkt->getAddr(), pkt->getSize());
assert(pkt->isResponse());
// must be cache-to-cache response from upper to lower level
ForwardResponseRecord *rec =
dynamic_cast<ForwardResponseRecord *>(pkt->senderState);
assert(!system->bypassCaches());
if (rec == NULL) {
// @todo What guarantee do we have that this HardPFResp is
// actually for this cache, and not a cache closer to the
// memory?
assert(pkt->cmd == MemCmd::HardPFResp);
// Check if it's a prefetch response and handle it. We shouldn't
// get any other kinds of responses without FRRs.
DPRINTF(Cache, "Got prefetch response from above for addr %#llx (%s)\n",
pkt->getAddr(), pkt->isSecure() ? "s" : "ns");
recvTimingResp(pkt);
return;
}
pkt->popSenderState();
delete rec;
// forwardLatency is set here because there is a response from an
// upper level cache.
// To pay the delay that occurs if the packet comes from the bus,
// we charge also headerDelay.
Tick snoop_resp_time = clockEdge(forwardLatency) + pkt->headerDelay;
// Reset the timing of the packet.
pkt->headerDelay = pkt->payloadDelay = 0;
memSidePort->schedTimingSnoopResp(pkt, snoop_resp_time);
}
template<class TagStore>
void
Cache<TagStore>::promoteWholeLineWrites(PacketPtr pkt)
{
// Cache line clearing instructions
if (doFastWrites && (pkt->cmd == MemCmd::WriteReq) &&
(pkt->getSize() == blkSize) && (pkt->getOffset(blkSize) == 0)) {
pkt->cmd = MemCmd::WriteInvalidateReq;
DPRINTF(Cache, "packet promoted from Write to WriteInvalidate\n");
assert(isTopLevel); // should only happen at L1 or I/O cache
}
}
template<class TagStore>
bool
Cache<TagStore>::recvTimingReq(PacketPtr pkt)
{
DPRINTF(CacheTags, "%s tags: %s\n", __func__, tags->print());
//@todo Add back in MemDebug Calls
// MemDebug::cacheAccess(pkt);
/// @todo temporary hack to deal with memory corruption issue until
/// 4-phase transactions are complete
for (int x = 0; x < pendingDelete.size(); x++)
delete pendingDelete[x];
pendingDelete.clear();
assert(pkt->isRequest());
// Just forward the packet if caches are disabled.
if (system->bypassCaches()) {
// @todo This should really enqueue the packet rather
bool M5_VAR_USED success = memSidePort->sendTimingReq(pkt);
assert(success);
return true;
}
promoteWholeLineWrites(pkt);
if (pkt->memInhibitAsserted()) {
// a cache above us (but not where the packet came from) is
// responding to the request
DPRINTF(Cache, "mem inhibited on addr %#llx (%s): not responding\n",
pkt->getAddr(), pkt->isSecure() ? "s" : "ns");
assert(!pkt->req->isUncacheable());
// if the packet needs exclusive, and the cache that has
// promised to respond (setting the inhibit flag) is not
// providing exclusive (it is in O vs M state), we know that
// there may be other shared copies in the system; go out and
// invalidate them all
if (pkt->needsExclusive() && !pkt->isSupplyExclusive()) {
// create a downstream express snoop with cleared packet
// flags, there is no need to allocate any data as the
// packet is merely used to co-ordinate state transitions
Packet *snoop_pkt = new Packet(pkt, true, false);
// also reset the bus time that the original packet has
// not yet paid for
snoop_pkt->headerDelay = snoop_pkt->payloadDelay = 0;
// make this an instantaneous express snoop, and let the
// other caches in the system know that the packet is
// inhibited, because we have found the authorative copy
// (O) that will supply the right data
snoop_pkt->setExpressSnoop();
snoop_pkt->assertMemInhibit();
// this express snoop travels towards the memory, and at
// every crossbar it is snooped upwards thus reaching
// every cache in the system
bool M5_VAR_USED success = memSidePort->sendTimingReq(snoop_pkt);
// express snoops always succeed
assert(success);
// main memory will delete the packet
}
/// @todo nominally we should just delete the packet here,
/// however, until 4-phase stuff we can't because sending
/// cache is still relying on it
pendingDelete.push_back(pkt);
// no need to take any action in this particular cache as the
// caches along the path to memory are allowed to keep lines
// in a shared state, and a cache above us already committed
// to responding
return true;
}
if (pkt->req->isUncacheable()) {
uncacheableFlush(pkt);
// writes go in write buffer, reads use MSHR,
// prefetches are acknowledged (responded to) and dropped
if (pkt->cmd.isPrefetch()) {
// prefetching (cache loading) uncacheable data is nonsensical
pkt->makeTimingResponse();
std::memset(pkt->getPtr<uint8_t>(), 0xFF, pkt->getSize());
// We use lookupLatency here because the request is uncacheable.
// We pay also for headerDelay that is charged of bus latencies if
// the packet comes from the bus.
Tick time = clockEdge(lookupLatency) + pkt->headerDelay;
// Reset the timing of the packet.
pkt->headerDelay = pkt->payloadDelay = 0;
cpuSidePort->schedTimingResp(pkt, time);
return true;
} else if (pkt->isWrite() && !pkt->isRead()) {
// We pay also for headerDelay that is charged of bus latencies if
// the packet comes from the bus.
Tick allocate_wr_buffer_time = clockEdge(forwardLatency) +
pkt->headerDelay;
// Reset the timing of the packet.
pkt->headerDelay = pkt->payloadDelay = 0;
allocateWriteBuffer(pkt, allocate_wr_buffer_time, true);
} else {
// We use forwardLatency here because there is an uncached
// memory read, allocateded to MSHR queue (it requires the same
// time of forwarding to WriteBuffer, in our assumption). It
// specifies the latency to allocate an internal buffer and to
// schedule an event to the queued port.
// We pay also for headerDelay that is charged of bus latencies if
// the packet comes from the bus.
Tick allocate_rd_buffer_time = clockEdge(forwardLatency) +
pkt->headerDelay;
// Reset the timing of the packet.
pkt->headerDelay = pkt->payloadDelay = 0;
allocateUncachedReadBuffer(pkt, allocate_rd_buffer_time, true);
}
assert(pkt->needsResponse()); // else we should delete it here??
return true;
}
// We use lookupLatency here because it is used to specify the latency
// to access.
Cycles lat = lookupLatency;
BlkType *blk = NULL;
PacketList writebacks;
// Note that lat is passed by reference here. The function access() calls
// accessBlock() which can modify lat value.
bool satisfied = access(pkt, blk, lat, writebacks);
// Here we charge the headerDelay that takes into account the latencies
// of the bus, if the packet comes from it.
// The latency charged it is just lat that is the value of lookupLatency
// modified by access() function, or if not just lookupLatency.
// In case of a hit we are neglecting response latency.
// In case of a miss we are neglecting forward latency.
Tick request_time = clockEdge(lat) + pkt->headerDelay;
// Here we condiser forward_time, paying for just forward latency and
// also charging the delay provided by the xbar.
// forward_time is used in allocateWriteBuffer() function, called
// in case of writeback.
Tick forward_time = clockEdge(forwardLatency) + pkt->headerDelay;
// Here we reset the timing of the packet.
pkt->headerDelay = pkt->payloadDelay = 0;
// track time of availability of next prefetch, if any
Tick next_pf_time = MaxTick;
bool needsResponse = pkt->needsResponse();
if (satisfied) {
// hit (for all other request types)
if (prefetcher && (prefetchOnAccess || (blk && blk->wasPrefetched()))) {
if (blk)
blk->status &= ~BlkHWPrefetched;
// Don't notify on SWPrefetch
if (!pkt->cmd.isSWPrefetch())
next_pf_time = prefetcher->notify(pkt);
}
if (needsResponse) {
pkt->makeTimingResponse();
// @todo: Make someone pay for this
pkt->headerDelay = pkt->payloadDelay = 0;
// In this case we are considering request_time that takes
// into account the delay of the xbar, if any, and just
// lat, neglecting responseLatency, modelling hit latency
// just as lookupLatency or or the value of lat overriden
// by access(), that calls accessBlock() function.
cpuSidePort->schedTimingResp(pkt, request_time);
} else {
/// @todo nominally we should just delete the packet here,
/// however, until 4-phase stuff we can't because sending
/// cache is still relying on it
pendingDelete.push_back(pkt);
}
} else {
// miss
Addr blk_addr = blockAlign(pkt->getAddr());
MSHR *mshr = mshrQueue.findMatch(blk_addr, pkt->isSecure());
// Software prefetch handling:
// To keep the core from waiting on data it won't look at
// anyway, send back a response with dummy data. Miss handling
// will continue asynchronously. Unfortunately, the core will
// insist upon freeing original Packet/Request, so we have to
// create a new pair with a different lifecycle. Note that this
// processing happens before any MSHR munging on the behalf of
// this request because this new Request will be the one stored
// into the MSHRs, not the original.
if (pkt->cmd.isSWPrefetch() && isTopLevel) {
assert(needsResponse);
assert(pkt->req->hasPaddr());
// There's no reason to add a prefetch as an additional target
// to an existing MSHR. If an outstanding request is already
// in progress, there is nothing for the prefetch to do.
// If this is the case, we don't even create a request at all.
PacketPtr pf = nullptr;
if (!mshr) {
// copy the request and create a new SoftPFReq packet
RequestPtr req = new Request(pkt->req->getPaddr(),
pkt->req->getSize(),
pkt->req->getFlags(),
pkt->req->masterId());
pf = new Packet(req, pkt->cmd);
pf->allocate();
assert(pf->getAddr() == pkt->getAddr());
assert(pf->getSize() == pkt->getSize());
}
pkt->makeTimingResponse();
// for debugging, set all the bits in the response data
// (also keeps valgrind from complaining when debugging settings
// print out instruction results)
std::memset(pkt->getPtr<uint8_t>(), 0xFF, pkt->getSize());
// request_time is used here, taking into account lat and the delay
// charged if the packet comes from the xbar.
cpuSidePort->schedTimingResp(pkt, request_time);
// If an outstanding request is in progress (we found an
// MSHR) this is set to null
pkt = pf;
}
if (mshr) {
/// MSHR hit
/// @note writebacks will be checked in getNextMSHR()
/// for any conflicting requests to the same block
//@todo remove hw_pf here
// Coalesce unless it was a software prefetch (see above).
if (pkt) {
DPRINTF(Cache, "%s coalescing MSHR for %s addr %#llx size %d\n",
__func__, pkt->cmdString(), pkt->getAddr(),
pkt->getSize());
assert(pkt->req->masterId() < system->maxMasters());
mshr_hits[pkt->cmdToIndex()][pkt->req->masterId()]++;
if (mshr->threadNum != 0/*pkt->req->threadId()*/) {
mshr->threadNum = -1;
}
// We use forward_time here because it is the same
// considering new targets. We have multiple requests for the
// same address here. It specifies the latency to allocate an
// internal buffer and to schedule an event to the queued
// port and also takes into account the additional delay of
// the xbar.
mshr->allocateTarget(pkt, forward_time, order++);
if (mshr->getNumTargets() == numTarget) {
noTargetMSHR = mshr;
setBlocked(Blocked_NoTargets);
// need to be careful with this... if this mshr isn't
// ready yet (i.e. time > curTick()), we don't want to
// move it ahead of mshrs that are ready
// mshrQueue.moveToFront(mshr);
}
// We should call the prefetcher reguardless if the request is
// satisfied or not, reguardless if the request is in the MSHR or
// not. The request could be a ReadReq hit, but still not
// satisfied (potentially because of a prior write to the same
// cache line. So, even when not satisfied, tehre is an MSHR
// already allocated for this, we need to let the prefetcher know
// about the request
if (prefetcher) {
// Don't notify on SWPrefetch
if (!pkt->cmd.isSWPrefetch())
next_pf_time = prefetcher->notify(pkt);
}
}
} else {
// no MSHR
assert(pkt->req->masterId() < system->maxMasters());
mshr_misses[pkt->cmdToIndex()][pkt->req->masterId()]++;
// always mark as cache fill for now... if we implement
// no-write-allocate or bypass accesses this will have to
// be changed.
if (pkt->cmd == MemCmd::Writeback) {
// We use forward_time here because there is an
// uncached memory write, forwarded to WriteBuffer. It
// specifies the latency to allocate an internal buffer and to
// schedule an event to the queued port and also takes into
// account the additional delay of the xbar.
allocateWriteBuffer(pkt, forward_time, true);
} else {
if (blk && blk->isValid()) {
// If we have a write miss to a valid block, we
// need to mark the block non-readable. Otherwise
// if we allow reads while there's an outstanding
// write miss, the read could return stale data
// out of the cache block... a more aggressive
// system could detect the overlap (if any) and
// forward data out of the MSHRs, but we don't do
// that yet. Note that we do need to leave the
// block valid so that it stays in the cache, in
// case we get an upgrade response (and hence no
// new data) when the write miss completes.
// As long as CPUs do proper store/load forwarding
// internally, and have a sufficiently weak memory
// model, this is probably unnecessary, but at some
// point it must have seemed like we needed it...
assert(pkt->needsExclusive());
assert(!blk->isWritable());
blk->status &= ~BlkReadable;
}
// Here we are using forward_time, modelling the latency of
// a miss (outbound) just as forwardLatency, neglecting the
// lookupLatency component. In this case this latency value
// specifies the latency to allocate an internal buffer and to
// schedule an event to the queued port, when a cacheable miss
// is forwarded to MSHR queue.
// We take also into account the additional delay of the xbar.
allocateMissBuffer(pkt, forward_time, true);
}
if (prefetcher) {
// Don't notify on SWPrefetch
if (!pkt->cmd.isSWPrefetch())
next_pf_time = prefetcher->notify(pkt);
}
}
}
// Here we condiser just forward_time.
if (next_pf_time != MaxTick)
requestMemSideBus(Request_PF, std::max(clockEdge(forwardLatency),
next_pf_time));
// copy writebacks to write buffer
while (!writebacks.empty()) {
PacketPtr wbPkt = writebacks.front();
// We use forwardLatency here because we are copying writebacks
// to write buffer. It specifies the latency to allocate an internal
// buffer and to schedule an event to the queued port.
allocateWriteBuffer(wbPkt, forward_time, true);
writebacks.pop_front();
}
return true;
}
// See comment in cache.hh.
template<class TagStore>
PacketPtr
Cache<TagStore>::getBusPacket(PacketPtr cpu_pkt, BlkType *blk,
bool needsExclusive) const
{
bool blkValid = blk && blk->isValid();
if (cpu_pkt->req->isUncacheable()) {
//assert(blk == NULL);
return NULL;
}
if (!blkValid &&
(cpu_pkt->cmd == MemCmd::Writeback || cpu_pkt->isUpgrade())) {
// Writebacks that weren't allocated in access() and upgrades
// from upper-level caches that missed completely just go
// through.
return NULL;
}
assert(cpu_pkt->needsResponse());
MemCmd cmd;
// @TODO make useUpgrades a parameter.
// Note that ownership protocols require upgrade, otherwise a
// write miss on a shared owned block will generate a ReadExcl,
// which will clobber the owned copy.
const bool useUpgrades = true;
if (blkValid && useUpgrades) {
// only reason to be here is that blk is shared
// (read-only) and we need exclusive
assert(needsExclusive);
assert(!blk->isWritable());
cmd = cpu_pkt->isLLSC() ? MemCmd::SCUpgradeReq : MemCmd::UpgradeReq;
} else if (cpu_pkt->cmd == MemCmd::SCUpgradeFailReq ||
cpu_pkt->cmd == MemCmd::StoreCondFailReq) {
// Even though this SC will fail, we still need to send out the
// request and get the data to supply it to other snoopers in the case
// where the determination the StoreCond fails is delayed due to
// all caches not being on the same local bus.
cmd = MemCmd::SCUpgradeFailReq;
} else if (cpu_pkt->isWriteInvalidate()) {
cmd = cpu_pkt->cmd;
} else {
// block is invalid
cmd = needsExclusive ? MemCmd::ReadExReq : MemCmd::ReadReq;
}
PacketPtr pkt = new Packet(cpu_pkt->req, cmd, blkSize);
// the packet should be block aligned
assert(pkt->getAddr() == blockAlign(pkt->getAddr()));
pkt->allocate();
DPRINTF(Cache, "%s created %s addr %#llx size %d\n",
__func__, pkt->cmdString(), pkt->getAddr(), pkt->getSize());
return pkt;
}
template<class TagStore>
Tick
Cache<TagStore>::recvAtomic(PacketPtr pkt)
{
// We are in atomic mode so we pay just for lookupLatency here.
Cycles lat = lookupLatency;
// @TODO: make this a parameter
bool last_level_cache = false;
// Forward the request if the system is in cache bypass mode.
if (system->bypassCaches())
return ticksToCycles(memSidePort->sendAtomic(pkt));
promoteWholeLineWrites(pkt);
if (pkt->memInhibitAsserted()) {
assert(!pkt->req->isUncacheable());
// have to invalidate ourselves and any lower caches even if
// upper cache will be responding
if (pkt->isInvalidate()) {
BlkType *blk = tags->findBlock(pkt->getAddr(), pkt->isSecure());
if (blk && blk->isValid()) {
tags->invalidate(blk);
blk->invalidate();
DPRINTF(Cache, "rcvd mem-inhibited %s on %#llx (%s):"
" invalidating\n",
pkt->cmdString(), pkt->getAddr(),
pkt->isSecure() ? "s" : "ns");
}
if (!last_level_cache) {
DPRINTF(Cache, "forwarding mem-inhibited %s on %#llx (%s)\n",
pkt->cmdString(), pkt->getAddr(),
pkt->isSecure() ? "s" : "ns");
lat += ticksToCycles(memSidePort->sendAtomic(pkt));
}
} else {
DPRINTF(Cache, "rcvd mem-inhibited %s on %#llx: not responding\n",
pkt->cmdString(), pkt->getAddr());
}
return lat * clockPeriod();
}
// should assert here that there are no outstanding MSHRs or
// writebacks... that would mean that someone used an atomic
// access in timing mode
BlkType *blk = NULL;
PacketList writebacks;
if (!access(pkt, blk, lat, writebacks)) {
// MISS
PacketPtr bus_pkt = getBusPacket(pkt, blk, pkt->needsExclusive());
bool is_forward = (bus_pkt == NULL);
if (is_forward) {
// just forwarding the same request to the next level
// no local cache operation involved
bus_pkt = pkt;
}
DPRINTF(Cache, "Sending an atomic %s for %#llx (%s)\n",
bus_pkt->cmdString(), bus_pkt->getAddr(),
bus_pkt->isSecure() ? "s" : "ns");
#if TRACING_ON
CacheBlk::State old_state = blk ? blk->status : 0;
#endif
lat += ticksToCycles(memSidePort->sendAtomic(bus_pkt));
DPRINTF(Cache, "Receive response: %s for addr %#llx (%s) in state %i\n",
bus_pkt->cmdString(), bus_pkt->getAddr(),
bus_pkt->isSecure() ? "s" : "ns",
old_state);
// If packet was a forward, the response (if any) is already
// in place in the bus_pkt == pkt structure, so we don't need
// to do anything. Otherwise, use the separate bus_pkt to
// generate response to pkt and then delete it.
if (!is_forward) {
if (pkt->needsResponse()) {
assert(bus_pkt->isResponse());
if (bus_pkt->isError()) {
pkt->makeAtomicResponse();
pkt->copyError(bus_pkt);
} else if (pkt->isWriteInvalidate()) {
// note the use of pkt, not bus_pkt here.
if (isTopLevel) {
blk = handleFill(pkt, blk, writebacks);
satisfyCpuSideRequest(pkt, blk);
} else if (blk) {
satisfyCpuSideRequest(pkt, blk);
}
} else if (bus_pkt->isRead() ||
bus_pkt->cmd == MemCmd::UpgradeResp) {
// we're updating cache state to allow us to
// satisfy the upstream request from the cache
blk = handleFill(bus_pkt, blk, writebacks);
satisfyCpuSideRequest(pkt, blk);
} else {
// we're satisfying the upstream request without
// modifying cache state, e.g., a write-through
pkt->makeAtomicResponse();
}
}
delete bus_pkt;
}
}
// Note that we don't invoke the prefetcher at all in atomic mode.
// It's not clear how to do it properly, particularly for
// prefetchers that aggressively generate prefetch candidates and
// rely on bandwidth contention to throttle them; these will tend
// to pollute the cache in atomic mode since there is no bandwidth
// contention. If we ever do want to enable prefetching in atomic
// mode, though, this is the place to do it... see timingAccess()
// for an example (though we'd want to issue the prefetch(es)
// immediately rather than calling requestMemSideBus() as we do
// there).
// Handle writebacks if needed
while (!writebacks.empty()){
PacketPtr wbPkt = writebacks.front();
memSidePort->sendAtomic(wbPkt);
writebacks.pop_front();
delete wbPkt;
}
if (pkt->needsResponse()) {
pkt->makeAtomicResponse();
}
return lat * clockPeriod();
}
template<class TagStore>
void
Cache<TagStore>::functionalAccess(PacketPtr pkt, bool fromCpuSide)
{
if (system->bypassCaches()) {
// Packets from the memory side are snoop request and
// shouldn't happen in bypass mode.
assert(fromCpuSide);
// The cache should be flushed if we are in cache bypass mode,
// so we don't need to check if we need to update anything.
memSidePort->sendFunctional(pkt);
return;
}
Addr blk_addr = blockAlign(pkt->getAddr());
bool is_secure = pkt->isSecure();
BlkType *blk = tags->findBlock(pkt->getAddr(), is_secure);
MSHR *mshr = mshrQueue.findMatch(blk_addr, is_secure);
pkt->pushLabel(name());
CacheBlkPrintWrapper cbpw(blk);
// Note that just because an L2/L3 has valid data doesn't mean an
// L1 doesn't have a more up-to-date modified copy that still
// needs to be found. As a result we always update the request if
// we have it, but only declare it satisfied if we are the owner.
// see if we have data at all (owned or otherwise)
bool have_data = blk && blk->isValid()
&& pkt->checkFunctional(&cbpw, blk_addr, is_secure, blkSize,
blk->data);
// data we have is dirty if marked as such or if valid & ownership
// pending due to outstanding UpgradeReq
bool have_dirty =
have_data && (blk->isDirty() ||
(mshr && mshr->inService && mshr->isPendingDirty()));
bool done = have_dirty
|| cpuSidePort->checkFunctional(pkt)
|| mshrQueue.checkFunctional(pkt, blk_addr)
|| writeBuffer.checkFunctional(pkt, blk_addr)
|| memSidePort->checkFunctional(pkt);
DPRINTF(Cache, "functional %s %#llx (%s) %s%s%s\n",
pkt->cmdString(), pkt->getAddr(), is_secure ? "s" : "ns",
(blk && blk->isValid()) ? "valid " : "",
have_data ? "data " : "", done ? "done " : "");
// We're leaving the cache, so pop cache->name() label
pkt->popLabel();
if (done) {
pkt->makeResponse();
} else {
// if it came as a request from the CPU side then make sure it
// continues towards the memory side
if (fromCpuSide) {
memSidePort->sendFunctional(pkt);
} else if (forwardSnoops && cpuSidePort->isSnooping()) {
// if it came from the memory side, it must be a snoop request
// and we should only forward it if we are forwarding snoops
cpuSidePort->sendFunctionalSnoop(pkt);
}
}
}
/////////////////////////////////////////////////////
//
// Response handling: responses from the memory side
//
/////////////////////////////////////////////////////
template<class TagStore>
void
Cache<TagStore>::recvTimingResp(PacketPtr pkt)
{
assert(pkt->isResponse());
MSHR *mshr = dynamic_cast<MSHR*>(pkt->senderState);
bool is_error = pkt->isError();
assert(mshr);
if (is_error) {
DPRINTF(Cache, "Cache received packet with error for addr %#llx (%s), "
"cmd: %s\n", pkt->getAddr(), pkt->isSecure() ? "s" : "ns",
pkt->cmdString());
}
DPRINTF(Cache, "Handling response %s for addr %#llx size %d (%s)\n",
pkt->cmdString(), pkt->getAddr(), pkt->getSize(),
pkt->isSecure() ? "s" : "ns");
MSHRQueue *mq = mshr->queue;
bool wasFull = mq->isFull();
if (mshr == noTargetMSHR) {
// we always clear at least one target
clearBlocked(Blocked_NoTargets);
noTargetMSHR = NULL;
}
// Initial target is used just for stats
MSHR::Target *initial_tgt = mshr->getTarget();
BlkType *blk = tags->findBlock(pkt->getAddr(), pkt->isSecure());
int stats_cmd_idx = initial_tgt->pkt->cmdToIndex();
Tick miss_latency = curTick() - initial_tgt->recvTime;
PacketList writebacks;
// We need forward_time here because we have a call of
// allocateWriteBuffer() that need this parameter to specify the
// time to request the bus. In this case we use forward latency
// because there is a writeback. We pay also here for headerDelay
// that is charged of bus latencies if the packet comes from the
// bus.
Tick forward_time = clockEdge(forwardLatency) + pkt->headerDelay;
if (pkt->req->isUncacheable()) {
assert(pkt->req->masterId() < system->maxMasters());
mshr_uncacheable_lat[stats_cmd_idx][pkt->req->masterId()] +=
miss_latency;
} else {
assert(pkt->req->masterId() < system->maxMasters());
mshr_miss_latency[stats_cmd_idx][pkt->req->masterId()] +=
miss_latency;
}
bool is_fill = !mshr->isForward &&
(pkt->isRead() || pkt->cmd == MemCmd::UpgradeResp);
if (is_fill && !is_error) {
DPRINTF(Cache, "Block for addr %#llx being updated in Cache\n",
pkt->getAddr());
// give mshr a chance to do some dirty work
mshr->handleFill(pkt, blk);
blk = handleFill(pkt, blk, writebacks);
assert(blk != NULL);
}
// First offset for critical word first calculations
int initial_offset = initial_tgt->pkt->getOffset(blkSize);
while (mshr->hasTargets()) {
MSHR::Target *target = mshr->getTarget();
Packet *tgt_pkt = target->pkt;
switch (target->source) {
case MSHR::Target::FromCPU:
Tick completion_time;
// Here we charge on completion_time the delay of the xbar if the
// packet comes from it, charged on headerDelay.
completion_time = pkt->headerDelay;
// Software prefetch handling for cache closest to core
if (tgt_pkt->cmd.isSWPrefetch() && isTopLevel) {
// a software prefetch would have already been ack'd immediately
// with dummy data so the core would be able to retire it.
// this request completes right here, so we deallocate it.
delete tgt_pkt->req;
delete tgt_pkt;
break; // skip response
}
// unlike the other packet flows, where data is found in other
// caches or memory and brought back, write invalidates always
// have the data right away, so the above check for "is fill?"
// cannot actually be determined until examining the stored MSHR
// state. We "catch up" with that logic here, which is duplicated
// from above.
if (tgt_pkt->isWriteInvalidate() && isTopLevel) {
assert(!is_error);
// NB: we use the original packet here and not the response!
mshr->handleFill(tgt_pkt, blk);
blk = handleFill(tgt_pkt, blk, writebacks);
assert(blk != NULL);
is_fill = true;
}
if (is_fill) {
satisfyCpuSideRequest(tgt_pkt, blk,
true, mshr->hasPostDowngrade());
// How many bytes past the first request is this one
int transfer_offset =
tgt_pkt->getOffset(blkSize) - initial_offset;
if (transfer_offset < 0) {
transfer_offset += blkSize;
}
// If not critical word (offset) return payloadDelay.
// responseLatency is the latency of the return path
// from lower level caches/memory to an upper level cache or
// the core.
completion_time += clockEdge(responseLatency) +
(transfer_offset ? pkt->payloadDelay : 0);
assert(!tgt_pkt->req->isUncacheable());
assert(tgt_pkt->req->masterId() < system->maxMasters());
missLatency[tgt_pkt->cmdToIndex()][tgt_pkt->req->masterId()] +=
completion_time - target->recvTime;
} else if (pkt->cmd == MemCmd::UpgradeFailResp) {
// failed StoreCond upgrade
assert(tgt_pkt->cmd == MemCmd::StoreCondReq ||
tgt_pkt->cmd == MemCmd::StoreCondFailReq ||
tgt_pkt->cmd == MemCmd::SCUpgradeFailReq);
// responseLatency is the latency of the return path
// from lower level caches/memory to an upper level cache or
// the core.
completion_time += clockEdge(responseLatency) +
pkt->payloadDelay;
tgt_pkt->req->setExtraData(0);
} else {
// not a cache fill, just forwarding response
// responseLatency is the latency of the return path
// from lower level cahces/memory to the core.
completion_time += clockEdge(responseLatency) +
pkt->payloadDelay;
if (pkt->isRead() && !is_error) {
// sanity check
assert(pkt->getAddr() == tgt_pkt->getAddr());
assert(pkt->getSize() >= tgt_pkt->getSize());
tgt_pkt->setData(pkt->getConstPtr<uint8_t>());
}
}
tgt_pkt->makeTimingResponse();
// if this packet is an error copy that to the new packet
if (is_error)
tgt_pkt->copyError(pkt);
if (tgt_pkt->cmd == MemCmd::ReadResp &&
(pkt->isInvalidate() || mshr->hasPostInvalidate())) {
// If intermediate cache got ReadRespWithInvalidate,
// propagate that. Response should not have
// isInvalidate() set otherwise.
tgt_pkt->cmd = MemCmd::ReadRespWithInvalidate;
DPRINTF(Cache, "%s updated cmd to %s for addr %#llx\n",
__func__, tgt_pkt->cmdString(), tgt_pkt->getAddr());
}
// Reset the bus additional time as it is now accounted for
tgt_pkt->headerDelay = tgt_pkt->payloadDelay = 0;
cpuSidePort->schedTimingResp(tgt_pkt, completion_time);
break;
case MSHR::Target::FromPrefetcher:
assert(tgt_pkt->cmd == MemCmd::HardPFReq);
if (blk)
blk->status |= BlkHWPrefetched;
delete tgt_pkt->req;
delete tgt_pkt;
break;
case MSHR::Target::FromSnoop:
// I don't believe that a snoop can be in an error state
assert(!is_error);
// response to snoop request
DPRINTF(Cache, "processing deferred snoop...\n");
assert(!(pkt->isInvalidate() && !mshr->hasPostInvalidate()));
handleSnoop(tgt_pkt, blk, true, true, mshr->hasPostInvalidate());
break;
default:
panic("Illegal target->source enum %d\n", target->source);
}
mshr->popTarget();
}
if (blk && blk->isValid()) {
if ((pkt->isInvalidate() || mshr->hasPostInvalidate()) &&
(!pkt->isWriteInvalidate() || !isTopLevel)) {
assert(blk != tempBlock);
tags->invalidate(blk);
blk->invalidate();
} else if (mshr->hasPostDowngrade()) {
blk->status &= ~BlkWritable;
}
}
if (mshr->promoteDeferredTargets()) {
// avoid later read getting stale data while write miss is
// outstanding.. see comment in timingAccess()
if (blk) {
blk->status &= ~BlkReadable;
}
mq = mshr->queue;
mq->markPending(mshr);
requestMemSideBus((RequestCause)mq->index, clockEdge() +
pkt->payloadDelay);
} else {
mq->deallocate(mshr);
if (wasFull && !mq->isFull()) {
clearBlocked((BlockedCause)mq->index);
}
// Request the bus for a prefetch if this deallocation freed enough
// MSHRs for a prefetch to take place
if (prefetcher && mq == &mshrQueue && mshrQueue.canPrefetch()) {
Tick next_pf_time = std::max(prefetcher->nextPrefetchReadyTime(),
curTick());
if (next_pf_time != MaxTick)
requestMemSideBus(Request_PF, next_pf_time);
}
}
// reset the xbar additional timinig as it is now accounted for
pkt->headerDelay = pkt->payloadDelay = 0;
// copy writebacks to write buffer
while (!writebacks.empty()) {
PacketPtr wbPkt = writebacks.front();
allocateWriteBuffer(wbPkt, clockEdge(forwardLatency), true);
writebacks.pop_front();
}
// if we used temp block, clear it out
if (blk == tempBlock) {
if (blk->isDirty()) {
// We use forwardLatency here because we are copying
// writebacks to write buffer. It specifies the latency to
// allocate an internal buffer and to schedule an event to the
// queued port.
allocateWriteBuffer(writebackBlk(blk), forward_time, true);
}
blk->invalidate();
}
DPRINTF(Cache, "Leaving %s with %s for addr %#llx\n", __func__,
pkt->cmdString(), pkt->getAddr());
delete pkt;
}
template<class TagStore>
PacketPtr
Cache<TagStore>::writebackBlk(BlkType *blk)
{
assert(blk && blk->isValid() && blk->isDirty());
writebacks[Request::wbMasterId]++;
Request *writebackReq =
new Request(tags->regenerateBlkAddr(blk->tag, blk->set), blkSize, 0,
Request::wbMasterId);
if (blk->isSecure())
writebackReq->setFlags(Request::SECURE);
writebackReq->taskId(blk->task_id);
blk->task_id= ContextSwitchTaskId::Unknown;
blk->tickInserted = curTick();
PacketPtr writeback = new Packet(writebackReq, MemCmd::Writeback);
if (blk->isWritable()) {
writeback->setSupplyExclusive();
}
writeback->allocate();
std::memcpy(writeback->getPtr<uint8_t>(), blk->data, blkSize);
blk->status &= ~BlkDirty;
return writeback;
}
template<class TagStore>
void
Cache<TagStore>::memWriteback()
{
WrappedBlkVisitor visitor(*this, &Cache<TagStore>::writebackVisitor);
tags->forEachBlk(visitor);
}
template<class TagStore>
void
Cache<TagStore>::memInvalidate()
{
WrappedBlkVisitor visitor(*this, &Cache<TagStore>::invalidateVisitor);
tags->forEachBlk(visitor);
}
template<class TagStore>
bool
Cache<TagStore>::isDirty() const
{
CacheBlkIsDirtyVisitor<BlkType> visitor;
tags->forEachBlk(visitor);
return visitor.isDirty();
}
template<class TagStore>
bool
Cache<TagStore>::writebackVisitor(BlkType &blk)
{
if (blk.isDirty()) {
assert(blk.isValid());
Request request(tags->regenerateBlkAddr(blk.tag, blk.set),
blkSize, 0, Request::funcMasterId);
request.taskId(blk.task_id);
Packet packet(&request, MemCmd::WriteReq);
packet.dataStatic(blk.data);
memSidePort->sendFunctional(&packet);
blk.status &= ~BlkDirty;
}
return true;
}
template<class TagStore>
bool
Cache<TagStore>::invalidateVisitor(BlkType &blk)
{
if (blk.isDirty())
warn_once("Invalidating dirty cache lines. Expect things to break.\n");
if (blk.isValid()) {
assert(!blk.isDirty());
tags->invalidate(dynamic_cast< BlkType *>(&blk));
blk.invalidate();
}
return true;
}
template<class TagStore>
void
Cache<TagStore>::uncacheableFlush(PacketPtr pkt)
{
DPRINTF(Cache, "%s%s addr %#llx uncacheable\n", pkt->cmdString(),
pkt->req->isInstFetch() ? " (ifetch)" : "",
pkt->getAddr());
if (pkt->req->isClearLL())
tags->clearLocks();
BlkType *blk(tags->findBlock(pkt->getAddr(), pkt->isSecure()));
if (blk) {
writebackVisitor(*blk);
invalidateVisitor(*blk);
}
}
template<class TagStore>
typename Cache<TagStore>::BlkType*
Cache<TagStore>::allocateBlock(Addr addr, bool is_secure,
PacketList &writebacks)
{
BlkType *blk = tags->findVictim(addr);
if (blk->isValid()) {
Addr repl_addr = tags->regenerateBlkAddr(blk->tag, blk->set);
MSHR *repl_mshr = mshrQueue.findMatch(repl_addr, blk->isSecure());
if (repl_mshr) {
// must be an outstanding upgrade request
// on a block we're about to replace...
assert(!blk->isWritable() || blk->isDirty());
assert(repl_mshr->needsExclusive());
// too hard to replace block with transient state
// allocation failed, block not inserted
return NULL;
} else {
DPRINTF(Cache, "replacement: replacing %#llx (%s) with %#llx (%s): %s\n",
repl_addr, blk->isSecure() ? "s" : "ns",
addr, is_secure ? "s" : "ns",
blk->isDirty() ? "writeback" : "clean");
if (blk->isDirty()) {
// Save writeback packet for handling by caller
writebacks.push_back(writebackBlk(blk));
}
}
}
return blk;
}
// Note that the reason we return a list of writebacks rather than
// inserting them directly in the write buffer is that this function
// is called by both atomic and timing-mode accesses, and in atomic
// mode we don't mess with the write buffer (we just perform the
// writebacks atomically once the original request is complete).
template<class TagStore>
typename Cache<TagStore>::BlkType*
Cache<TagStore>::handleFill(PacketPtr pkt, BlkType *blk,
PacketList &writebacks)
{
assert(pkt->isResponse() || pkt->isWriteInvalidate());
Addr addr = pkt->getAddr();
bool is_secure = pkt->isSecure();
#if TRACING_ON
CacheBlk::State old_state = blk ? blk->status : 0;
#endif
if (blk == NULL) {
// better have read new data...
assert(pkt->hasData());
// only read responses and (original) write invalidate req's have data;
// note that we don't write the data here for write invalidate - that
// happens in the subsequent satisfyCpuSideRequest.
assert(pkt->isRead() || pkt->isWriteInvalidate());
// need to do a replacement
blk = allocateBlock(addr, is_secure, writebacks);
if (blk == NULL) {
// No replaceable block... just use temporary storage to
// complete the current request and then get rid of it
assert(!tempBlock->isValid());
blk = tempBlock;
tempBlock->set = tags->extractSet(addr);
tempBlock->tag = tags->extractTag(addr);
// @todo: set security state as well...
DPRINTF(Cache, "using temp block for %#llx (%s)\n", addr,
is_secure ? "s" : "ns");
} else {
tags->insertBlock(pkt, blk);
}
// we should never be overwriting a valid block
assert(!blk->isValid());
} else {
// existing block... probably an upgrade
assert(blk->tag == tags->extractTag(addr));
// either we're getting new data or the block should already be valid
assert(pkt->hasData() || blk->isValid());
// don't clear block status... if block is already dirty we
// don't want to lose that
}
if (is_secure)
blk->status |= BlkSecure;
blk->status |= BlkValid | BlkReadable;
if (!pkt->sharedAsserted()) {
blk->status |= BlkWritable;
// If we got this via cache-to-cache transfer (i.e., from a
// cache that was an owner) and took away that owner's copy,
// then we need to write it back. Normally this happens
// anyway as a side effect of getting a copy to write it, but
// there are cases (such as failed store conditionals or
// compare-and-swaps) where we'll demand an exclusive copy but
// end up not writing it.
if (pkt->memInhibitAsserted())
blk->status |= BlkDirty;
}
DPRINTF(Cache, "Block addr %#llx (%s) moving from state %x to %s\n",
addr, is_secure ? "s" : "ns", old_state, blk->print());
// if we got new data, copy it in (checking for a read response
// and a response that has data is the same in the end)
if (pkt->isRead()) {
// sanity checks
assert(pkt->hasData());
assert(pkt->getSize() == blkSize);
std::memcpy(blk->data, pkt->getConstPtr<uint8_t>(), blkSize);
}
// We pay for fillLatency here.
blk->whenReady = clockEdge() + fillLatency * clockPeriod() +
pkt->payloadDelay;
return blk;
}
/////////////////////////////////////////////////////
//
// Snoop path: requests coming in from the memory side
//
/////////////////////////////////////////////////////
template<class TagStore>
void
Cache<TagStore>::
doTimingSupplyResponse(PacketPtr req_pkt, const uint8_t *blk_data,
bool already_copied, bool pending_inval)
{
// sanity check
assert(req_pkt->isRequest());
assert(req_pkt->needsResponse());
DPRINTF(Cache, "%s for %s addr %#llx size %d\n", __func__,
req_pkt->cmdString(), req_pkt->getAddr(), req_pkt->getSize());
// timing-mode snoop responses require a new packet, unless we
// already made a copy...
PacketPtr pkt = req_pkt;
if (!already_copied)
// do not clear flags, and allocate space for data if the
// packet needs it (the only packets that carry data are read
// responses)
pkt = new Packet(req_pkt, false, req_pkt->isRead());
assert(req_pkt->isInvalidate() || pkt->sharedAsserted());
pkt->makeTimingResponse();
if (pkt->isRead()) {
pkt->setDataFromBlock(blk_data, blkSize);
}
if (pkt->cmd == MemCmd::ReadResp && pending_inval) {
// Assume we defer a response to a read from a far-away cache
// A, then later defer a ReadExcl from a cache B on the same
// bus as us. We'll assert MemInhibit in both cases, but in
// the latter case MemInhibit will keep the invalidation from
// reaching cache A. This special response tells cache A that
// it gets the block to satisfy its read, but must immediately
// invalidate it.
pkt->cmd = MemCmd::ReadRespWithInvalidate;
}
// Here we consider forward_time, paying for just forward latency and
// also charging the delay provided by the xbar.
// forward_time is used as send_time in next allocateWriteBuffer().
Tick forward_time = clockEdge(forwardLatency) + pkt->headerDelay;
// Here we reset the timing of the packet.
pkt->headerDelay = pkt->payloadDelay = 0;
DPRINTF(Cache, "%s created response: %s addr %#llx size %d tick: %lu\n",
__func__, pkt->cmdString(), pkt->getAddr(), pkt->getSize(),
forward_time);
memSidePort->schedTimingSnoopResp(pkt, forward_time, true);
}
template<class TagStore>
void
Cache<TagStore>::handleSnoop(PacketPtr pkt, BlkType *blk,
bool is_timing, bool is_deferred,
bool pending_inval)
{
DPRINTF(Cache, "%s for %s addr %#llx size %d\n", __func__,
pkt->cmdString(), pkt->getAddr(), pkt->getSize());
// deferred snoops can only happen in timing mode
assert(!(is_deferred && !is_timing));
// pending_inval only makes sense on deferred snoops
assert(!(pending_inval && !is_deferred));
assert(pkt->isRequest());
// the packet may get modified if we or a forwarded snooper
// responds in atomic mode, so remember a few things about the
// original packet up front
bool invalidate = pkt->isInvalidate();
bool M5_VAR_USED needs_exclusive = pkt->needsExclusive();
if (forwardSnoops) {
// first propagate snoop upward to see if anyone above us wants to
// handle it. save & restore packet src since it will get
// rewritten to be relative to cpu-side bus (if any)
bool alreadyResponded = pkt->memInhibitAsserted();
if (is_timing) {
Packet snoopPkt(pkt, true, false); // clear flags, no allocation
snoopPkt.setExpressSnoop();
snoopPkt.pushSenderState(new ForwardResponseRecord());
// the snoop packet does not need to wait any additional
// time
snoopPkt.headerDelay = snoopPkt.payloadDelay = 0;
cpuSidePort->sendTimingSnoopReq(&snoopPkt);
if (snoopPkt.memInhibitAsserted()) {
// cache-to-cache response from some upper cache
assert(!alreadyResponded);
pkt->assertMemInhibit();
} else {
delete snoopPkt.popSenderState();
}
if (snoopPkt.sharedAsserted()) {
pkt->assertShared();
}
// If this request is a prefetch or clean evict and an
// upper level signals block present, make sure to
// propagate the block presence to the requester.
if (snoopPkt.isBlockCached()) {
pkt->setBlockCached();
}
} else {
cpuSidePort->sendAtomicSnoop(pkt);
if (!alreadyResponded && pkt->memInhibitAsserted()) {
// cache-to-cache response from some upper cache:
// forward response to original requester
assert(pkt->isResponse());
}
}
}
if (!blk || !blk->isValid()) {
DPRINTF(Cache, "%s snoop miss for %s addr %#llx size %d\n",
__func__, pkt->cmdString(), pkt->getAddr(), pkt->getSize());
return;
} else {
DPRINTF(Cache, "%s snoop hit for %s for addr %#llx size %d, "
"old state is %s\n", __func__, pkt->cmdString(),
pkt->getAddr(), pkt->getSize(), blk->print());
}
// we may end up modifying both the block state and the packet (if
// we respond in atomic mode), so just figure out what to do now
// and then do it later. If we find dirty data while snooping for a
// WriteInvalidate, we don't care, since no merging needs to take place.
// We need the eviction to happen as normal, but the data needn't be
// sent anywhere. nor should the writeback be inhibited at the memory
// controller for any reason.
bool respond = blk->isDirty() && pkt->needsResponse()
&& !pkt->isWriteInvalidate();
bool have_exclusive = blk->isWritable();
// Invalidate any prefetch's from below that would strip write permissions
// MemCmd::HardPFReq is only observed by upstream caches. After missing
// above and in it's own cache, a new MemCmd::ReadReq is created that
// downstream caches observe.
if (pkt->cmd == MemCmd::HardPFReq) {
DPRINTF(Cache, "Squashing prefetch from lower cache %#x\n",
pkt->getAddr());
pkt->setBlockCached();
return;
}
if (pkt->isRead() && !invalidate) {
assert(!needs_exclusive);
pkt->assertShared();
int bits_to_clear = BlkWritable;
const bool haveOwnershipState = true; // for now
if (!haveOwnershipState) {
// if we don't support pure ownership (dirty && !writable),
// have to clear dirty bit here, assume memory snarfs data
// on cache-to-cache xfer
bits_to_clear |= BlkDirty;
}
blk->status &= ~bits_to_clear;
}
if (respond) {
// prevent anyone else from responding, cache as well as
// memory, and also prevent any memory from even seeing the
// request (with current inhibited semantics), note that this
// applies both to reads and writes and that for writes it
// works thanks to the fact that we still have dirty data and
// will write it back at a later point
pkt->assertMemInhibit();
if (have_exclusive) {
pkt->setSupplyExclusive();
}
if (is_timing) {
doTimingSupplyResponse(pkt, blk->data, is_deferred, pending_inval);
} else {
pkt->makeAtomicResponse();
pkt->setDataFromBlock(blk->data, blkSize);
}
} else if (is_timing && is_deferred) {
// if it's a deferred timing snoop then we've made a copy of
// the packet, and so if we're not using that copy to respond
// then we need to delete it here.
delete pkt;
}
// Do this last in case it deallocates block data or something
// like that
if (invalidate) {
if (blk != tempBlock)
tags->invalidate(blk);
blk->invalidate();
}
DPRINTF(Cache, "new state is %s\n", blk->print());
}
template<class TagStore>
void
Cache<TagStore>::recvTimingSnoopReq(PacketPtr pkt)
{
DPRINTF(Cache, "%s for %s addr %#llx size %d\n", __func__,
pkt->cmdString(), pkt->getAddr(), pkt->getSize());
// Snoops shouldn't happen when bypassing caches
assert(!system->bypassCaches());
// check if the packet is for an address range covered by this
// cache, partly to not waste time looking for it, but also to
// ensure that we only forward the snoop upwards if it is within
// our address ranges
bool in_range = false;
for (AddrRangeList::const_iterator r = addrRanges.begin();
r != addrRanges.end(); ++r) {
if (r->contains(pkt->getAddr())) {
in_range = true;
break;
}
}
// Note that some deferred snoops don't have requests, since the
// original access may have already completed
if ((pkt->req && pkt->req->isUncacheable()) ||
pkt->cmd == MemCmd::Writeback || !in_range) {
//Can't get a hit on an uncacheable address
//Revisit this for multi level coherence
return;
}
bool is_secure = pkt->isSecure();
BlkType *blk = tags->findBlock(pkt->getAddr(), is_secure);
Addr blk_addr = blockAlign(pkt->getAddr());
MSHR *mshr = mshrQueue.findMatch(blk_addr, is_secure);
// Squash any prefetch requests from below on MSHR hits
if (mshr && pkt->cmd == MemCmd::HardPFReq) {
DPRINTF(Cache, "Setting block present to squash prefetch from"
"lower cache on mshr hit %#x\n",
pkt->getAddr());
pkt->setBlockCached();
return;
}
// Let the MSHR itself track the snoop and decide whether we want
// to go ahead and do the regular cache snoop
if (mshr && mshr->handleSnoop(pkt, order++)) {
DPRINTF(Cache, "Deferring snoop on in-service MSHR to blk %#llx (%s)."
"mshrs: %s\n", blk_addr, is_secure ? "s" : "ns",
mshr->print());
if (mshr->getNumTargets() > numTarget)
warn("allocating bonus target for snoop"); //handle later
return;
}
//We also need to check the writeback buffers and handle those
std::vector<MSHR *> writebacks;
if (writeBuffer.findMatches(blk_addr, is_secure, writebacks)) {
DPRINTF(Cache, "Snoop hit in writeback to addr %#llx (%s)\n",
pkt->getAddr(), is_secure ? "s" : "ns");
// Look through writebacks for any cachable writes.
// We should only ever find a single match
assert(writebacks.size() == 1);
MSHR *wb_entry = writebacks[0];
assert(!wb_entry->isUncacheable());
assert(wb_entry->getNumTargets() == 1);
PacketPtr wb_pkt = wb_entry->getTarget()->pkt;
assert(wb_pkt->cmd == MemCmd::Writeback);
assert(!pkt->memInhibitAsserted());
pkt->assertMemInhibit();
if (!pkt->needsExclusive()) {
pkt->assertShared();
// the writeback is no longer the exclusive copy in the system
wb_pkt->clearSupplyExclusive();
} else {
// if we're not asserting the shared line, we need to
// invalidate our copy. we'll do that below as long as
// the packet's invalidate flag is set...
assert(pkt->isInvalidate());
}
doTimingSupplyResponse(pkt, wb_pkt->getConstPtr<uint8_t>(),
false, false);
if (pkt->isInvalidate()) {
// Invalidation trumps our writeback... discard here
markInService(wb_entry, false);
delete wb_pkt;
}
}
// If this was a shared writeback, there may still be
// other shared copies above that require invalidation.
// We could be more selective and return here if the
// request is non-exclusive or if the writeback is
// exclusive.
handleSnoop(pkt, blk, true, false, false);
}
template<class TagStore>
bool
Cache<TagStore>::CpuSidePort::recvTimingSnoopResp(PacketPtr pkt)
{
// Express snoop responses from master to slave, e.g., from L1 to L2
cache->recvTimingSnoopResp(pkt);
return true;
}
template<class TagStore>
Tick
Cache<TagStore>::recvAtomicSnoop(PacketPtr pkt)
{
// Snoops shouldn't happen when bypassing caches
assert(!system->bypassCaches());
if (pkt->req->isUncacheable() || pkt->cmd == MemCmd::Writeback) {
// Can't get a hit on an uncacheable address
// Revisit this for multi level coherence
return 0;
}
BlkType *blk = tags->findBlock(pkt->getAddr(), pkt->isSecure());
handleSnoop(pkt, blk, false, false, false);
// We consider forwardLatency here because a snoop occurs in atomic mode
return forwardLatency * clockPeriod();
}
template<class TagStore>
MSHR *
Cache<TagStore>::getNextMSHR()
{
// Check both MSHR queue and write buffer for potential requests,
// note that null does not mean there is no request, it could
// simply be that it is not ready
MSHR *miss_mshr = mshrQueue.getNextMSHR();
MSHR *write_mshr = writeBuffer.getNextMSHR();
// If we got a write buffer request ready, first priority is a
// full write buffer, otherwhise we favour the miss requests
if (write_mshr &&
((writeBuffer.isFull() && writeBuffer.inServiceEntries == 0) ||
!miss_mshr)) {
// need to search MSHR queue for conflicting earlier miss.
MSHR *conflict_mshr =
mshrQueue.findPending(write_mshr->blkAddr,
write_mshr->isSecure);
if (conflict_mshr && conflict_mshr->order < write_mshr->order) {
// Service misses in order until conflict is cleared.
return conflict_mshr;
// @todo Note that we ignore the ready time of the conflict here
}
// No conflicts; issue write
return write_mshr;
} else if (miss_mshr) {
// need to check for conflicting earlier writeback
MSHR *conflict_mshr =
writeBuffer.findPending(miss_mshr->blkAddr,
miss_mshr->isSecure);
if (conflict_mshr) {
// not sure why we don't check order here... it was in the
// original code but commented out.
// The only way this happens is if we are
// doing a write and we didn't have permissions
// then subsequently saw a writeback (owned got evicted)
// We need to make sure to perform the writeback first
// To preserve the dirty data, then we can issue the write
// should we return write_mshr here instead? I.e. do we
// have to flush writes in order? I don't think so... not
// for Alpha anyway. Maybe for x86?
return conflict_mshr;
// @todo Note that we ignore the ready time of the conflict here
}
// No conflicts; issue read
return miss_mshr;
}
// fall through... no pending requests. Try a prefetch.
assert(!miss_mshr && !write_mshr);
if (prefetcher && mshrQueue.canPrefetch()) {
// If we have a miss queue slot, we can try a prefetch
PacketPtr pkt = prefetcher->getPacket();
if (pkt) {
Addr pf_addr = blockAlign(pkt->getAddr());
if (!tags->findBlock(pf_addr, pkt->isSecure()) &&
!mshrQueue.findMatch(pf_addr, pkt->isSecure()) &&
!writeBuffer.findMatch(pf_addr, pkt->isSecure())) {
// Update statistic on number of prefetches issued
// (hwpf_mshr_misses)
assert(pkt->req->masterId() < system->maxMasters());
mshr_misses[pkt->cmdToIndex()][pkt->req->masterId()]++;
// Don't request bus, since we already have it
return allocateMissBuffer(pkt, curTick(), false);
} else {
// free the request and packet
delete pkt->req;
delete pkt;
}
}
}
return NULL;
}
template<class TagStore>
PacketPtr
Cache<TagStore>::getTimingPacket()
{
MSHR *mshr = getNextMSHR();
if (mshr == NULL) {
return NULL;
}
// use request from 1st target
PacketPtr tgt_pkt = mshr->getTarget()->pkt;
PacketPtr pkt = NULL;
DPRINTF(CachePort, "%s %s for addr %#llx size %d\n", __func__,
tgt_pkt->cmdString(), tgt_pkt->getAddr(), tgt_pkt->getSize());
if (mshr->isForwardNoResponse()) {
// no response expected, just forward packet as it is
assert(tags->findBlock(mshr->blkAddr, mshr->isSecure) == NULL);
pkt = tgt_pkt;
} else {
BlkType *blk = tags->findBlock(mshr->blkAddr, mshr->isSecure);
if (tgt_pkt->cmd == MemCmd::HardPFReq) {
// We need to check the caches above us to verify that
// they don't have a copy of this block in the dirty state
// at the moment. Without this check we could get a stale
// copy from memory that might get used in place of the
// dirty one.
Packet snoop_pkt(tgt_pkt, true, false);
snoop_pkt.setExpressSnoop();
snoop_pkt.senderState = mshr;
cpuSidePort->sendTimingSnoopReq(&snoop_pkt);
// Check to see if the prefetch was squashed by an upper cache (to
// prevent us from grabbing the line) or if a Check to see if a
// writeback arrived between the time the prefetch was placed in
// the MSHRs and when it was selected to be sent or if the
// prefetch was squashed by an upper cache.
// It is important to check msmInhibitAsserted before
// prefetchSquashed. If another cache has asserted MEM_INGIBIT, it
// will be sending a response which will arrive at the MSHR
// allocated ofr this request. Checking the prefetchSquash first
// may result in the MSHR being prematurely deallocated.
if (snoop_pkt.memInhibitAsserted()) {
// If we are getting a non-shared response it is dirty
bool pending_dirty_resp = !snoop_pkt.sharedAsserted();
markInService(mshr, pending_dirty_resp);
DPRINTF(Cache, "Upward snoop of prefetch for addr"
" %#x (%s) hit\n",
tgt_pkt->getAddr(), tgt_pkt->isSecure()? "s": "ns");
return NULL;
}
if (snoop_pkt.isBlockCached() || blk != NULL) {
DPRINTF(Cache, "Block present, prefetch squashed by cache. "
"Deallocating mshr target %#x.\n",
mshr->blkAddr);
// Deallocate the mshr target
if (mshr->queue->forceDeallocateTarget(mshr)) {
// Clear block if this deallocation resulted freed an
// mshr when all had previously been utilized
clearBlocked((BlockedCause)(mshr->queue->index));
}
return NULL;
}
}
pkt = getBusPacket(tgt_pkt, blk, mshr->needsExclusive());
mshr->isForward = (pkt == NULL);
if (mshr->isForward) {
// not a cache block request, but a response is expected
// make copy of current packet to forward, keep current
// copy for response handling
pkt = new Packet(tgt_pkt, false, true);
if (pkt->isWrite()) {
pkt->setData(tgt_pkt->getConstPtr<uint8_t>());
}
}
}
assert(pkt != NULL);
pkt->senderState = mshr;
return pkt;
}
template<class TagStore>
Tick
Cache<TagStore>::nextMSHRReadyTime() const
{
Tick nextReady = std::min(mshrQueue.nextMSHRReadyTime(),
writeBuffer.nextMSHRReadyTime());
// Don't signal prefetch ready time if no MSHRs available
// Will signal once enoguh MSHRs are deallocated
if (prefetcher && mshrQueue.canPrefetch()) {
nextReady = std::min(nextReady,
prefetcher->nextPrefetchReadyTime());
}
return nextReady;
}
template<class TagStore>
void
Cache<TagStore>::serialize(std::ostream &os)
{
bool dirty(isDirty());
if (dirty) {
warn("*** The cache still contains dirty data. ***\n");
warn(" Make sure to drain the system using the correct flags.\n");
warn(" This checkpoint will not restore correctly and dirty data in "
"the cache will be lost!\n");
}
// Since we don't checkpoint the data in the cache, any dirty data
// will be lost when restoring from a checkpoint of a system that
// wasn't drained properly. Flag the checkpoint as invalid if the
// cache contains dirty data.
bool bad_checkpoint(dirty);
SERIALIZE_SCALAR(bad_checkpoint);
}
template<class TagStore>
void
Cache<TagStore>::unserialize(Checkpoint *cp, const std::string §ion)
{
bool bad_checkpoint;
UNSERIALIZE_SCALAR(bad_checkpoint);
if (bad_checkpoint) {
fatal("Restoring from checkpoints with dirty caches is not supported "
"in the classic memory system. Please remove any caches or "
" drain them properly before taking checkpoints.\n");
}
}
///////////////
//
// CpuSidePort
//
///////////////
template<class TagStore>
AddrRangeList
Cache<TagStore>::CpuSidePort::getAddrRanges() const
{
return cache->getAddrRanges();
}
template<class TagStore>
bool
Cache<TagStore>::CpuSidePort::recvTimingReq(PacketPtr pkt)
{
assert(!cache->system->bypassCaches());
bool success = false;
// always let inhibited requests through, even if blocked,
// ultimately we should check if this is an express snoop, but at
// the moment that flag is only set in the cache itself
if (pkt->memInhibitAsserted()) {
// do not change the current retry state
bool M5_VAR_USED bypass_success = cache->recvTimingReq(pkt);
assert(bypass_success);
return true;
} else if (blocked || mustSendRetry) {
// either already committed to send a retry, or blocked
success = false;
} else {
// pass it on to the cache, and let the cache decide if we
// have to retry or not
success = cache->recvTimingReq(pkt);
}
// remember if we have to retry
mustSendRetry = !success;
return success;
}
template<class TagStore>
Tick
Cache<TagStore>::CpuSidePort::recvAtomic(PacketPtr pkt)
{
return cache->recvAtomic(pkt);
}
template<class TagStore>
void
Cache<TagStore>::CpuSidePort::recvFunctional(PacketPtr pkt)
{
// functional request
cache->functionalAccess(pkt, true);
}
template<class TagStore>
Cache<TagStore>::
CpuSidePort::CpuSidePort(const std::string &_name, Cache<TagStore> *_cache,
const std::string &_label)
: BaseCache::CacheSlavePort(_name, _cache, _label), cache(_cache)
{
}
///////////////
//
// MemSidePort
//
///////////////
template<class TagStore>
bool
Cache<TagStore>::MemSidePort::recvTimingResp(PacketPtr pkt)
{
cache->recvTimingResp(pkt);
return true;
}
// Express snooping requests to memside port
template<class TagStore>
void
Cache<TagStore>::MemSidePort::recvTimingSnoopReq(PacketPtr pkt)
{
// handle snooping requests
cache->recvTimingSnoopReq(pkt);
}
template<class TagStore>
Tick
Cache<TagStore>::MemSidePort::recvAtomicSnoop(PacketPtr pkt)
{
return cache->recvAtomicSnoop(pkt);
}
template<class TagStore>
void
Cache<TagStore>::MemSidePort::recvFunctionalSnoop(PacketPtr pkt)
{
// functional snoop (note that in contrast to atomic we don't have
// a specific functionalSnoop method, as they have the same
// behaviour regardless)
cache->functionalAccess(pkt, false);
}
template<class TagStore>
void
Cache<TagStore>::CacheReqPacketQueue::sendDeferredPacket()
{
// sanity check
assert(!waitingOnRetry);
// there should never be any deferred request packets in the
// queue, instead we resly on the cache to provide the packets
// from the MSHR queue or write queue
assert(deferredPacketReadyTime() == MaxTick);
// check for request packets (requests & writebacks)
PacketPtr pkt = cache.getTimingPacket();
if (pkt == NULL) {
// can happen if e.g. we attempt a writeback and fail, but
// before the retry, the writeback is eliminated because
// we snoop another cache's ReadEx.
} else {
MSHR *mshr = dynamic_cast<MSHR*>(pkt->senderState);
// in most cases getTimingPacket allocates a new packet, and
// we must delete it unless it is successfully sent
bool delete_pkt = !mshr->isForwardNoResponse();
// let our snoop responses go first if there are responses to
// the same addresses we are about to writeback, note that
// this creates a dependency between requests and snoop
// responses, but that should not be a problem since there is
// a chain already and the key is that the snoop responses can
// sink unconditionally
if (snoopRespQueue.hasAddr(pkt->getAddr())) {
DPRINTF(CachePort, "Waiting for snoop response to be sent\n");
Tick when = snoopRespQueue.deferredPacketReadyTime();
schedSendEvent(when);
if (delete_pkt)
delete pkt;
return;
}
waitingOnRetry = !masterPort.sendTimingReq(pkt);
if (waitingOnRetry) {
DPRINTF(CachePort, "now waiting on a retry\n");
if (delete_pkt) {
// we are awaiting a retry, but we
// delete the packet and will be creating a new packet
// when we get the opportunity
delete pkt;
}
// note that we have now masked any requestBus and
// schedSendEvent (we will wait for a retry before
// doing anything), and this is so even if we do not
// care about this packet and might override it before
// it gets retried
} else {
// As part of the call to sendTimingReq the packet is
// forwarded to all neighbouring caches (and any
// caches above them) as a snoop. The packet is also
// sent to any potential cache below as the
// interconnect is not allowed to buffer the
// packet. Thus at this point we know if any of the
// neighbouring, or the downstream cache is
// responding, and if so, if it is with a dirty line
// or not.
bool pending_dirty_resp = !pkt->sharedAsserted() &&
pkt->memInhibitAsserted();
cache.markInService(mshr, pending_dirty_resp);
}
}
// if we succeeded and are not waiting for a retry, schedule the
// next send considering when the next MSHR is ready, note that
// snoop responses have their own packet queue and thus schedule
// their own events
if (!waitingOnRetry) {
schedSendEvent(cache.nextMSHRReadyTime());
}
}
template<class TagStore>
Cache<TagStore>::
MemSidePort::MemSidePort(const std::string &_name, Cache<TagStore> *_cache,
const std::string &_label)
: BaseCache::CacheMasterPort(_name, _cache, _reqQueue, _snoopRespQueue),
_reqQueue(*_cache, *this, _snoopRespQueue, _label),
_snoopRespQueue(*_cache, *this, _label), cache(_cache)
{
}
#endif//__MEM_CACHE_CACHE_IMPL_HH__
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