gem5/src/cpu/inorder/resources/cache_unit.cc

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/*
* Copyright (c) 2007 MIPS Technologies, 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: Korey Sewell
*
*/
#include <vector>
#include <list>
#include "arch/isa_traits.hh"
#include "arch/locked_mem.hh"
#include "arch/utility.hh"
#include "cpu/inorder/resources/cache_unit.hh"
#include "cpu/inorder/pipeline_traits.hh"
#include "cpu/inorder/cpu.hh"
#include "mem/request.hh"
using namespace std;
using namespace TheISA;
using namespace ThePipeline;
Tick
CacheUnit::CachePort::recvAtomic(PacketPtr pkt)
{
panic("DefaultFetch doesn't expect recvAtomic callback!");
return curTick;
}
void
CacheUnit::CachePort::recvFunctional(PacketPtr pkt)
{
panic("DefaultFetch doesn't expect recvFunctional callback!");
}
void
CacheUnit::CachePort::recvStatusChange(Status status)
{
if (status == RangeChange)
return;
panic("DefaultFetch doesn't expect recvStatusChange callback!");
}
bool
CacheUnit::CachePort::recvTiming(Packet *pkt)
{
cachePortUnit->processCacheCompletion(pkt);
return true;
}
void
CacheUnit::CachePort::recvRetry()
{
cachePortUnit->recvRetry();
}
CacheUnit::CacheUnit(string res_name, int res_id, int res_width,
int res_latency, InOrderCPU *_cpu, ThePipeline::Params *params)
: Resource(res_name, res_id, res_width, res_latency, _cpu),
retryPkt(NULL), retrySlot(-1), cacheBlocked(false)
{
cachePort = new CachePort(this);
}
Port *
CacheUnit::getPort(const string &if_name, int idx)
{
if (if_name == resName)
return cachePort;
else
return NULL;
}
int
CacheUnit::getSlot(DynInstPtr inst)
{
if (!inst->validMemAddr()) {
panic("Mem. Addr. must be set before requesting cache access\n");
}
Addr req_addr = inst->getMemAddr();
if (resName == "icache_port" ||
find(addrList.begin(), addrList.end(), req_addr) == addrList.end()) {
int new_slot = Resource::getSlot(inst);
if (new_slot == -1)
return -1;
inst->memTime = curTick;
addrList.push_back(req_addr);
addrMap[req_addr] = inst->seqNum;
DPRINTF(InOrderCachePort,
"[tid:%i]: [sn:%i]: Address %08p added to dependency list\n",
inst->readTid(), inst->seqNum, req_addr);
return new_slot;
} else {
DPRINTF(InOrderCachePort,
"Denying request because there is an outstanding"
" request to/for addr. %08p. by [sn:%i] @ tick %i\n",
req_addr, addrMap[req_addr], inst->memTime);
return -1;
}
}
void
CacheUnit::freeSlot(int slot_num)
{
vector<Addr>::iterator vect_it = find(addrList.begin(), addrList.end(),
reqMap[slot_num]->inst->getMemAddr());
assert(vect_it != addrList.end());
DPRINTF(InOrderCachePort,
"[tid:%i]: Address %08p removed from dependency list\n",
reqMap[slot_num]->inst->readTid(), (*vect_it));
addrList.erase(vect_it);
Resource::freeSlot(slot_num);
}
ResReqPtr
CacheUnit::getRequest(DynInstPtr inst, int stage_num, int res_idx,
int slot_num, unsigned cmd)
{
ScheduleEntry* sched_entry = inst->resSched.top();
if (!inst->validMemAddr()) {
panic("Mem. Addr. must be set before requesting cache access\n");
}
int req_size = 0;
MemCmd::Command pkt_cmd;
if (sched_entry->cmd == InitiateReadData) {
pkt_cmd = MemCmd::ReadReq;
req_size = inst->getMemAccSize();
DPRINTF(InOrderCachePort,
"[tid:%i]: %i byte Read request from [sn:%i] for addr %08p\n",
inst->readTid(), req_size, inst->seqNum, inst->getMemAddr());
} else if (sched_entry->cmd == InitiateWriteData) {
pkt_cmd = MemCmd::WriteReq;
req_size = inst->getMemAccSize();
DPRINTF(InOrderCachePort,
"[tid:%i]: %i byte Write request from [sn:%i] for addr %08p\n",
inst->readTid(), req_size, inst->seqNum, inst->getMemAddr());
} else if (sched_entry->cmd == InitiateFetch){
pkt_cmd = MemCmd::ReadReq;
req_size = sizeof(MachInst); //@TODO: mips16e
DPRINTF(InOrderCachePort,
"[tid:%i]: %i byte Fetch request from [sn:%i] for addr %08p\n",
inst->readTid(), req_size, inst->seqNum, inst->getMemAddr());
} else {
panic("%i: Unexpected request type (%i) to %s", curTick,
sched_entry->cmd, name());
}
return new CacheRequest(this, inst, stage_num, id, slot_num,
sched_entry->cmd, req_size, pkt_cmd,
0/*flags*/, this->cpu->readCpuId());
}
void
CacheUnit::requestAgain(DynInstPtr inst, bool &service_request)
{
//service_request = false;
CacheReqPtr cache_req = dynamic_cast<CacheReqPtr>(findRequest(inst));
assert(cache_req);
// Check to see if this instruction is requesting the same command
// or a different one
if (cache_req->cmd != inst->resSched.top()->cmd) {
// If different, then update command in the request
cache_req->cmd = inst->resSched.top()->cmd;
DPRINTF(InOrderCachePort,
"[tid:%i]: [sn:%i]: the command for this instruction\n",
inst->readTid(), inst->seqNum);
service_request = true;
} else {
// If same command, just check to see if memory access was completed
// but dont try to re-execute
DPRINTF(InOrderCachePort,
"[tid:%i]: [sn:%i]: requesting this resource again\n",
inst->readTid(), inst->seqNum);
service_request = true;
}
}
void
CacheUnit::execute(int slot_num)
{
if (cacheBlocked) {
DPRINTF(InOrderCachePort, "Cache Blocked. Cannot Access\n");
return;
}
CacheReqPtr cache_req = dynamic_cast<CacheReqPtr>(reqMap[slot_num]);
assert(cache_req);
DynInstPtr inst = cache_req->inst;
int tid;
tid = inst->readTid();
int seq_num;
seq_num = inst->seqNum;
//int stage_num = cache_req->getStageNum();
cache_req->fault = NoFault;
switch (cache_req->cmd)
{
case InitiateFetch:
DPRINTF(InOrderCachePort,
"[tid:%u]: Initiating fetch access to %s for addr. %08p\n",
tid, name(), cache_req->inst->getMemAddr());
DPRINTF(InOrderCachePort,
"[tid:%u]: Fetching new cache block from addr: %08p\n",
tid, cache_req->memReq->getVaddr());
inst->setCurResSlot(slot_num);
doDataAccess(inst);
break;
case CompleteFetch:
if (cache_req->isMemAccComplete()) {
DPRINTF(InOrderCachePort,
"[tid:%i]: Completing Fetch Access for [sn:%i]\n",
tid, inst->seqNum);
MachInst mach_inst = cache_req->dataPkt->get<MachInst>();
/**
* @TODO: May Need This Function for Endianness-Compatibility
* mach_inst =
* gtoh(*reinterpret_cast<MachInst *>(&cacheData[tid][offset]));
*/
DPRINTF(InOrderCachePort,
"[tid:%i]: Fetched instruction is %08p\n",
tid, mach_inst);
// ExtMachInst ext_inst = makeExtMI(mach_inst, cpu->tcBase(tid));
inst->setMachInst(mach_inst);
inst->setASID(tid);
inst->setThreadState(cpu->thread[tid]);
DPRINTF(InOrderStage, "[tid:%i]: Instruction [sn:%i] is: %s\n",
tid, seq_num, inst->staticInst->disassemble(inst->PC));
// Set Up More TraceData info
if (inst->traceData) {
inst->traceData->setStaticInst(inst->staticInst);
inst->traceData->setPC(inst->readPC());
}
cache_req->done();
} else {
DPRINTF(InOrderCachePort,
"[tid:%i]: [sn:%i]: Unable to Complete Fetch Access\n",
tid, inst->seqNum);
DPRINTF(InOrderStall,
"STALL: [tid:%i]: Fetch miss from %08p\n",
tid, cache_req->inst->readPC());
cache_req->setCompleted(false);
}
break;
case InitiateReadData:
case InitiateWriteData:
DPRINTF(InOrderCachePort,
"[tid:%u]: Initiating data access to %s for addr. %08p\n",
tid, name(), cache_req->inst->getMemAddr());
inst->setCurResSlot(slot_num);
//inst->memAccess();
inst->initiateAcc();
break;
case CompleteReadData:
case CompleteWriteData:
DPRINTF(InOrderCachePort,
"[tid:%i]: [sn:%i]: Trying to Complete Data Access\n",
tid, inst->seqNum);
if (cache_req->isMemAccComplete()) {
cache_req->done();
} else {
DPRINTF(InOrderStall, "STALL: [tid:%i]: Data miss from %08p\n",
tid, cache_req->inst->getMemAddr());
cache_req->setCompleted(false);
}
break;
default:
fatal("Unrecognized command to %s", resName);
}
}
Fault
CacheUnit::doDataAccess(DynInstPtr inst)
{
Fault fault = NoFault;
int tid = 0;
tid = inst->readTid();
CacheReqPtr cache_req
= dynamic_cast<CacheReqPtr>(reqMap[inst->getCurResSlot()]);
assert(cache_req);
cache_req->dataPkt = new CacheReqPacket(cache_req, cache_req->pktCmd,
Packet::Broadcast);
if (cache_req->dataPkt->isRead()) {
cache_req->dataPkt->dataStatic(cache_req->reqData);
} else if (cache_req->dataPkt->isWrite()) {
cache_req->dataPkt->dataStatic(&cache_req->inst->storeData);
}
cache_req->dataPkt->time = curTick;
bool do_access = true; // flag to suppress cache access
Request *memReq = cache_req->dataPkt->req;
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if (cache_req->dataPkt->isWrite() && memReq->isLLSC()) {
assert(cache_req->inst->isStoreConditional());
DPRINTF(InOrderCachePort, "Evaluating Store Conditional access\n");
do_access = TheISA::handleLockedWrite(cpu, memReq);
}
DPRINTF(InOrderCachePort,
"[tid:%i] [sn:%i] attempting to access cache\n",
tid, inst->seqNum);
//@TODO: If you want to ignore failed store conditional accesses, then
// enable this. However, this might skew memory stats because
// the failed store conditional access will get ignored.
// - Remove optionality here ...
if (1/*do_access*/) {
if (!cachePort->sendTiming(cache_req->dataPkt)) {
DPRINTF(InOrderCachePort,
"[tid:%i] [sn:%i] is waiting to retry request\n",
tid, inst->seqNum);
retrySlot = cache_req->getSlot();
retryReq = cache_req;
retryPkt = cache_req->dataPkt;
cacheStatus = cacheWaitRetry;
//cacheBlocked = true;
DPRINTF(InOrderStall, "STALL: \n");
cache_req->setCompleted(false);
} else {
DPRINTF(InOrderCachePort,
"[tid:%i] [sn:%i] is now waiting for cache response\n",
tid, inst->seqNum);
cache_req->setCompleted();
cache_req->setMemAccPending();
cacheStatus = cacheWaitResponse;
cacheBlocked = false;
}
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} else if (!do_access && memReq->isLLSC()){
// Store-Conditional instructions complete even if they "failed"
assert(cache_req->inst->isStoreConditional());
cache_req->setCompleted(true);
DPRINTF(LLSC,
"[tid:%i]: T%i Ignoring Failed Store Conditional Access\n",
tid, tid);
cache_req->dataPkt->req->setExtraData(0);
processCacheCompletion(cache_req->dataPkt);
// Automatically set these since we ignored the memory access
//cache_req->setMemAccPending(false);
//cache_req->setMemAccCompleted();
} else {
// Make cache request again since access due to
// inability to access
DPRINTF(InOrderStall, "STALL: \n");
cache_req->setCompleted(false);
}
return fault;
}
void
CacheUnit::processCacheCompletion(PacketPtr pkt)
{
// Cast to correct packet type
CacheReqPacket* cache_pkt = dynamic_cast<CacheReqPacket*>(pkt);
assert(cache_pkt);
if (cache_pkt->cacheReq->isSquashed()) {
DPRINTF(InOrderCachePort,
"Ignoring completion of squashed access, [tid:%i] [sn:%i]\n",
cache_pkt->cacheReq->getInst()->readTid(),
cache_pkt->cacheReq->getInst()->seqNum);
cache_pkt->cacheReq->done();
return;
}
DPRINTF(InOrderCachePort,
"[tid:%u]: [sn:%i]: Waking from cache access to addr. %08p\n",
cache_pkt->cacheReq->getInst()->readTid(),
cache_pkt->cacheReq->getInst()->seqNum,
cache_pkt->cacheReq->getInst()->getMemAddr());
// Cast to correct request type
CacheRequest *cache_req = dynamic_cast<CacheReqPtr>(
findRequest(cache_pkt->cacheReq->getInst()));
assert(cache_req);
// Get resource request info
// @todo: SMT needs to figure out where to get thread # from.
unsigned tid = 0;
unsigned stage_num = cache_req->getStageNum();
DynInstPtr inst = cache_req->inst;
if (!cache_req->isSquashed()) {
if (inst->resSched.top()->cmd == CompleteFetch) {
DPRINTF(InOrderCachePort,
"[tid:%u]: [sn:%i]: Processing fetch access\n",
tid, inst->seqNum);
} else if (inst->staticInst && inst->isMemRef()) {
DPRINTF(InOrderCachePort,
"[tid:%u]: [sn:%i]: Processing cache access\n",
tid, inst->seqNum);
inst->completeAcc(pkt);
if (inst->isLoad()) {
assert(cache_pkt->isRead());
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if (cache_pkt->req->isLLSC()) {
DPRINTF(InOrderCachePort,
"[tid:%u]: Handling Load-Linked for [sn:%u]\n",
tid, inst->seqNum);
TheISA::handleLockedRead(cpu, cache_pkt->req);
}
// @TODO: Hardcoded to for load instructions. Assumes that
// the dest. idx 0 is always where the data is loaded to.
DPRINTF(InOrderCachePort,
"[tid:%u]: [sn:%i]: Data loaded was: %08p\n",
tid, inst->seqNum, inst->readIntResult(0));
DPRINTF(InOrderCachePort,
"[tid:%u]: [sn:%i]: FP Data loaded was: %08p\n",
tid, inst->seqNum, inst->readFloatResult(0));
} else if(inst->isStore()) {
assert(cache_pkt->isWrite());
DPRINTF(InOrderCachePort,
"[tid:%u]: [sn:%i]: Data stored was: %08p\n",
tid, inst->seqNum,
getMemData(cache_pkt));
}
}
cache_req->setMemAccPending(false);
cache_req->setMemAccCompleted();
// Wake up the CPU (if it went to sleep and was waiting on this
// completion event).
cpu->wakeCPU();
DPRINTF(Activity, "[tid:%u] Activating %s due to cache completion\n",
tid, cpu->pipelineStage[stage_num]->name());
cpu->switchToActive(stage_num);
} else {
DPRINTF(InOrderCachePort,
"[tid:%u] Miss on block @ %08p completed, but squashed\n",
tid, cache_req->inst->readPC());
cache_req->setMemAccCompleted();
}
inst->unsetMemAddr();
}
void
CacheUnit::recvRetry()
{
DPRINTF(InOrderCachePort, "Retrying Request for [tid:%i] [sn:%i]\n",
retryReq->inst->readTid(), retryReq->inst->seqNum);
assert(retryPkt != NULL);
assert(cacheBlocked);
assert(cacheStatus == cacheWaitRetry);
if (cachePort->sendTiming(retryPkt)) {
cacheStatus = cacheWaitResponse;
retryPkt = NULL;
cacheBlocked = false;
} else {
DPRINTF(InOrderCachePort,
"Retry Request for [tid:%i] [sn:%i] failed\n",
retryReq->inst->readTid(), retryReq->inst->seqNum);
}
}
void
CacheUnit::squash(DynInstPtr inst, int stage_num,
InstSeqNum squash_seq_num, unsigned tid)
{
vector<int> slot_remove_list;
map<int, ResReqPtr>::iterator map_it = reqMap.begin();
map<int, ResReqPtr>::iterator map_end = reqMap.end();
while (map_it != map_end) {
ResReqPtr req_ptr = (*map_it).second;
if (req_ptr &&
req_ptr->getInst()->readTid() == tid &&
req_ptr->getInst()->seqNum > squash_seq_num) {
DPRINTF(InOrderCachePort,
"[tid:%i] Squashing request from [sn:%i]\n",
req_ptr->getInst()->readTid(), req_ptr->getInst()->seqNum);
req_ptr->setSquashed();
req_ptr->getInst()->setSquashed();
CacheReqPtr cache_req = dynamic_cast<CacheReqPtr>(req_ptr);
assert(cache_req);
if (!cache_req->isMemAccPending()) {
// Mark request for later removal
cpu->reqRemoveList.push(req_ptr);
// Mark slot for removal from resource
slot_remove_list.push_back(req_ptr->getSlot());
}
}
map_it++;
}
// Now Delete Slot Entry from Req. Map
for (int i = 0; i < slot_remove_list.size(); i++)
freeSlot(slot_remove_list[i]);
}
uint64_t
CacheUnit::getMemData(Packet *packet)
{
switch (packet->getSize())
{
case 8:
return packet->get<uint8_t>();
case 16:
return packet->get<uint16_t>();
case 32:
return packet->get<uint32_t>();
case 64:
return packet->get<uint64_t>();
default:
panic("bad store data size = %d\n", packet->getSize());
}
}