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gem5/src/cpu/o3/inst_queue_impl.hh
Nathan Binkert abc76f20cb Major changes to how SimObjects are created and initialized. Almost all 
creation and initialization now happens in python.  Parameter objects
are generated and initialized by python.  The .ini file is now solely for
debugging purposes and is not used in construction of the objects in any
way.

--HG--
extra : convert_revision : 7e722873e417cb3d696f2e34c35ff488b7bff4ed
2007-07-23 21:51:38 -07:00

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/*
* Copyright (c) 2004-2006 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.
*
* Authors: Kevin Lim
* Korey Sewell
*/
#include <limits>
#include <vector>
#include "cpu/o3/fu_pool.hh"
#include "cpu/o3/inst_queue.hh"
#include "enums/OpClass.hh"
#include "sim/core.hh"
template <class Impl>
InstructionQueue<Impl>::FUCompletion::FUCompletion(DynInstPtr &_inst,
int fu_idx,
InstructionQueue<Impl> *iq_ptr)
: Event(&mainEventQueue, Stat_Event_Pri),
inst(_inst), fuIdx(fu_idx), iqPtr(iq_ptr), freeFU(false)
{
this->setFlags(Event::AutoDelete);
}
template <class Impl>
void
InstructionQueue<Impl>::FUCompletion::process()
{
iqPtr->processFUCompletion(inst, freeFU ? fuIdx : -1);
inst = NULL;
}
template <class Impl>
const char *
InstructionQueue<Impl>::FUCompletion::description()
{
return "Functional unit completion event";
}
template <class Impl>
InstructionQueue<Impl>::InstructionQueue(O3CPU *cpu_ptr, IEW *iew_ptr,
Params *params)
: cpu(cpu_ptr),
iewStage(iew_ptr),
fuPool(params->fuPool),
numEntries(params->numIQEntries),
totalWidth(params->issueWidth),
numPhysIntRegs(params->numPhysIntRegs),
numPhysFloatRegs(params->numPhysFloatRegs),
commitToIEWDelay(params->commitToIEWDelay)
{
assert(fuPool);
switchedOut = false;
numThreads = params->numberOfThreads;
// Set the number of physical registers as the number of int + float
numPhysRegs = numPhysIntRegs + numPhysFloatRegs;
//Create an entry for each physical register within the
//dependency graph.
dependGraph.resize(numPhysRegs);
// Resize the register scoreboard.
regScoreboard.resize(numPhysRegs);
//Initialize Mem Dependence Units
for (int i = 0; i < numThreads; i++) {
memDepUnit[i].init(params,i);
memDepUnit[i].setIQ(this);
}
resetState();
std::string policy = params->smtIQPolicy;
//Convert string to lowercase
std::transform(policy.begin(), policy.end(), policy.begin(),
(int(*)(int)) tolower);
//Figure out resource sharing policy
if (policy == "dynamic") {
iqPolicy = Dynamic;
//Set Max Entries to Total ROB Capacity
for (int i = 0; i < numThreads; i++) {
maxEntries[i] = numEntries;
}
} else if (policy == "partitioned") {
iqPolicy = Partitioned;
//@todo:make work if part_amt doesnt divide evenly.
int part_amt = numEntries / numThreads;
//Divide ROB up evenly
for (int i = 0; i < numThreads; i++) {
maxEntries[i] = part_amt;
}
DPRINTF(IQ, "IQ sharing policy set to Partitioned:"
"%i entries per thread.\n",part_amt);
} else if (policy == "threshold") {
iqPolicy = Threshold;
double threshold = (double)params->smtIQThreshold / 100;
int thresholdIQ = (int)((double)threshold * numEntries);
//Divide up by threshold amount
for (int i = 0; i < numThreads; i++) {
maxEntries[i] = thresholdIQ;
}
DPRINTF(IQ, "IQ sharing policy set to Threshold:"
"%i entries per thread.\n",thresholdIQ);
} else {
assert(0 && "Invalid IQ Sharing Policy.Options Are:{Dynamic,"
"Partitioned, Threshold}");
}
}
template <class Impl>
InstructionQueue<Impl>::~InstructionQueue()
{
dependGraph.reset();
#ifdef DEBUG
cprintf("Nodes traversed: %i, removed: %i\n",
dependGraph.nodesTraversed, dependGraph.nodesRemoved);
#endif
}
template <class Impl>
std::string
InstructionQueue<Impl>::name() const
{
return cpu->name() + ".iq";
}
template <class Impl>
void
InstructionQueue<Impl>::regStats()
{
using namespace Stats;
iqInstsAdded
.name(name() + ".iqInstsAdded")
.desc("Number of instructions added to the IQ (excludes non-spec)")
.prereq(iqInstsAdded);
iqNonSpecInstsAdded
.name(name() + ".iqNonSpecInstsAdded")
.desc("Number of non-speculative instructions added to the IQ")
.prereq(iqNonSpecInstsAdded);
iqInstsIssued
.name(name() + ".iqInstsIssued")
.desc("Number of instructions issued")
.prereq(iqInstsIssued);
iqIntInstsIssued
.name(name() + ".iqIntInstsIssued")
.desc("Number of integer instructions issued")
.prereq(iqIntInstsIssued);
iqFloatInstsIssued
.name(name() + ".iqFloatInstsIssued")
.desc("Number of float instructions issued")
.prereq(iqFloatInstsIssued);
iqBranchInstsIssued
.name(name() + ".iqBranchInstsIssued")
.desc("Number of branch instructions issued")
.prereq(iqBranchInstsIssued);
iqMemInstsIssued
.name(name() + ".iqMemInstsIssued")
.desc("Number of memory instructions issued")
.prereq(iqMemInstsIssued);
iqMiscInstsIssued
.name(name() + ".iqMiscInstsIssued")
.desc("Number of miscellaneous instructions issued")
.prereq(iqMiscInstsIssued);
iqSquashedInstsIssued
.name(name() + ".iqSquashedInstsIssued")
.desc("Number of squashed instructions issued")
.prereq(iqSquashedInstsIssued);
iqSquashedInstsExamined
.name(name() + ".iqSquashedInstsExamined")
.desc("Number of squashed instructions iterated over during squash;"
" mainly for profiling")
.prereq(iqSquashedInstsExamined);
iqSquashedOperandsExamined
.name(name() + ".iqSquashedOperandsExamined")
.desc("Number of squashed operands that are examined and possibly "
"removed from graph")
.prereq(iqSquashedOperandsExamined);
iqSquashedNonSpecRemoved
.name(name() + ".iqSquashedNonSpecRemoved")
.desc("Number of squashed non-spec instructions that were removed")
.prereq(iqSquashedNonSpecRemoved);
/*
queueResDist
.init(Num_OpClasses, 0, 99, 2)
.name(name() + ".IQ:residence:")
.desc("cycles from dispatch to issue")
.flags(total | pdf | cdf )
;
for (int i = 0; i < Num_OpClasses; ++i) {
queueResDist.subname(i, opClassStrings[i]);
}
*/
numIssuedDist
.init(0,totalWidth,1)
.name(name() + ".ISSUE:issued_per_cycle")
.desc("Number of insts issued each cycle")
.flags(pdf)
;
/*
dist_unissued
.init(Num_OpClasses+2)
.name(name() + ".ISSUE:unissued_cause")
.desc("Reason ready instruction not issued")
.flags(pdf | dist)
;
for (int i=0; i < (Num_OpClasses + 2); ++i) {
dist_unissued.subname(i, unissued_names[i]);
}
*/
statIssuedInstType
.init(numThreads,Enums::Num_OpClass)
.name(name() + ".ISSUE:FU_type")
.desc("Type of FU issued")
.flags(total | pdf | dist)
;
statIssuedInstType.ysubnames(Enums::OpClassStrings);
//
// How long did instructions for a particular FU type wait prior to issue
//
/*
issueDelayDist
.init(Num_OpClasses,0,99,2)
.name(name() + ".ISSUE:")
.desc("cycles from operands ready to issue")
.flags(pdf | cdf)
;
for (int i=0; i<Num_OpClasses; ++i) {
std::stringstream subname;
subname << opClassStrings[i] << "_delay";
issueDelayDist.subname(i, subname.str());
}
*/
issueRate
.name(name() + ".ISSUE:rate")
.desc("Inst issue rate")
.flags(total)
;
issueRate = iqInstsIssued / cpu->numCycles;
statFuBusy
.init(Num_OpClasses)
.name(name() + ".ISSUE:fu_full")
.desc("attempts to use FU when none available")
.flags(pdf | dist)
;
for (int i=0; i < Num_OpClasses; ++i) {
statFuBusy.subname(i, Enums::OpClassStrings[i]);
}
fuBusy
.init(numThreads)
.name(name() + ".ISSUE:fu_busy_cnt")
.desc("FU busy when requested")
.flags(total)
;
fuBusyRate
.name(name() + ".ISSUE:fu_busy_rate")
.desc("FU busy rate (busy events/executed inst)")
.flags(total)
;
fuBusyRate = fuBusy / iqInstsIssued;
for ( int i=0; i < numThreads; i++) {
// Tell mem dependence unit to reg stats as well.
memDepUnit[i].regStats();
}
}
template <class Impl>
void
InstructionQueue<Impl>::resetState()
{
//Initialize thread IQ counts
for (int i = 0; i <numThreads; i++) {
count[i] = 0;
instList[i].clear();
}
// Initialize the number of free IQ entries.
freeEntries = numEntries;
// Note that in actuality, the registers corresponding to the logical
// registers start off as ready. However this doesn't matter for the
// IQ as the instruction should have been correctly told if those
// registers are ready in rename. Thus it can all be initialized as
// unready.
for (int i = 0; i < numPhysRegs; ++i) {
regScoreboard[i] = false;
}
for (int i = 0; i < numThreads; ++i) {
squashedSeqNum[i] = 0;
}
for (int i = 0; i < Num_OpClasses; ++i) {
while (!readyInsts[i].empty())
readyInsts[i].pop();
queueOnList[i] = false;
readyIt[i] = listOrder.end();
}
nonSpecInsts.clear();
listOrder.clear();
}
template <class Impl>
void
InstructionQueue<Impl>::setActiveThreads(std::list<unsigned> *at_ptr)
{
activeThreads = at_ptr;
}
template <class Impl>
void
InstructionQueue<Impl>::setIssueToExecuteQueue(TimeBuffer<IssueStruct> *i2e_ptr)
{
issueToExecuteQueue = i2e_ptr;
}
template <class Impl>
void
InstructionQueue<Impl>::setTimeBuffer(TimeBuffer<TimeStruct> *tb_ptr)
{
timeBuffer = tb_ptr;
fromCommit = timeBuffer->getWire(-commitToIEWDelay);
}
template <class Impl>
void
InstructionQueue<Impl>::switchOut()
{
/*
if (!instList[0].empty() || (numEntries != freeEntries) ||
!readyInsts[0].empty() || !nonSpecInsts.empty() || !listOrder.empty()) {
dumpInsts();
// assert(0);
}
*/
resetState();
dependGraph.reset();
instsToExecute.clear();
switchedOut = true;
for (int i = 0; i < numThreads; ++i) {
memDepUnit[i].switchOut();
}
}
template <class Impl>
void
InstructionQueue<Impl>::takeOverFrom()
{
switchedOut = false;
}
template <class Impl>
int
InstructionQueue<Impl>::entryAmount(int num_threads)
{
if (iqPolicy == Partitioned) {
return numEntries / num_threads;
} else {
return 0;
}
}
template <class Impl>
void
InstructionQueue<Impl>::resetEntries()
{
if (iqPolicy != Dynamic || numThreads > 1) {
int active_threads = activeThreads->size();
std::list<unsigned>::iterator threads = activeThreads->begin();
std::list<unsigned>::iterator end = activeThreads->end();
while (threads != end) {
unsigned tid = *threads++;
if (iqPolicy == Partitioned) {
maxEntries[tid] = numEntries / active_threads;
} else if(iqPolicy == Threshold && active_threads == 1) {
maxEntries[tid] = numEntries;
}
}
}
}
template <class Impl>
unsigned
InstructionQueue<Impl>::numFreeEntries()
{
return freeEntries;
}
template <class Impl>
unsigned
InstructionQueue<Impl>::numFreeEntries(unsigned tid)
{
return maxEntries[tid] - count[tid];
}
// Might want to do something more complex if it knows how many instructions
// will be issued this cycle.
template <class Impl>
bool
InstructionQueue<Impl>::isFull()
{
if (freeEntries == 0) {
return(true);
} else {
return(false);
}
}
template <class Impl>
bool
InstructionQueue<Impl>::isFull(unsigned tid)
{
if (numFreeEntries(tid) == 0) {
return(true);
} else {
return(false);
}
}
template <class Impl>
bool
InstructionQueue<Impl>::hasReadyInsts()
{
if (!listOrder.empty()) {
return true;
}
for (int i = 0; i < Num_OpClasses; ++i) {
if (!readyInsts[i].empty()) {
return true;
}
}
return false;
}
template <class Impl>
void
InstructionQueue<Impl>::insert(DynInstPtr &new_inst)
{
// Make sure the instruction is valid
assert(new_inst);
DPRINTF(IQ, "Adding instruction [sn:%lli] PC %#x to the IQ.\n",
new_inst->seqNum, new_inst->readPC());
assert(freeEntries != 0);
instList[new_inst->threadNumber].push_back(new_inst);
--freeEntries;
new_inst->setInIQ();
// Look through its source registers (physical regs), and mark any
// dependencies.
addToDependents(new_inst);
// Have this instruction set itself as the producer of its destination
// register(s).
addToProducers(new_inst);
if (new_inst->isMemRef()) {
memDepUnit[new_inst->threadNumber].insert(new_inst);
} else {
addIfReady(new_inst);
}
++iqInstsAdded;
count[new_inst->threadNumber]++;
assert(freeEntries == (numEntries - countInsts()));
}
template <class Impl>
void
InstructionQueue<Impl>::insertNonSpec(DynInstPtr &new_inst)
{
// @todo: Clean up this code; can do it by setting inst as unable
// to issue, then calling normal insert on the inst.
assert(new_inst);
nonSpecInsts[new_inst->seqNum] = new_inst;
DPRINTF(IQ, "Adding non-speculative instruction [sn:%lli] PC %#x "
"to the IQ.\n",
new_inst->seqNum, new_inst->readPC());
assert(freeEntries != 0);
instList[new_inst->threadNumber].push_back(new_inst);
--freeEntries;
new_inst->setInIQ();
// Have this instruction set itself as the producer of its destination
// register(s).
addToProducers(new_inst);
// If it's a memory instruction, add it to the memory dependency
// unit.
if (new_inst->isMemRef()) {
memDepUnit[new_inst->threadNumber].insertNonSpec(new_inst);
}
++iqNonSpecInstsAdded;
count[new_inst->threadNumber]++;
assert(freeEntries == (numEntries - countInsts()));
}
template <class Impl>
void
InstructionQueue<Impl>::insertBarrier(DynInstPtr &barr_inst)
{
memDepUnit[barr_inst->threadNumber].insertBarrier(barr_inst);
insertNonSpec(barr_inst);
}
template <class Impl>
typename Impl::DynInstPtr
InstructionQueue<Impl>::getInstToExecute()
{
assert(!instsToExecute.empty());
DynInstPtr inst = instsToExecute.front();
instsToExecute.pop_front();
return inst;
}
template <class Impl>
void
InstructionQueue<Impl>::addToOrderList(OpClass op_class)
{
assert(!readyInsts[op_class].empty());
ListOrderEntry queue_entry;
queue_entry.queueType = op_class;
queue_entry.oldestInst = readyInsts[op_class].top()->seqNum;
ListOrderIt list_it = listOrder.begin();
ListOrderIt list_end_it = listOrder.end();
while (list_it != list_end_it) {
if ((*list_it).oldestInst > queue_entry.oldestInst) {
break;
}
list_it++;
}
readyIt[op_class] = listOrder.insert(list_it, queue_entry);
queueOnList[op_class] = true;
}
template <class Impl>
void
InstructionQueue<Impl>::moveToYoungerInst(ListOrderIt list_order_it)
{
// Get iterator of next item on the list
// Delete the original iterator
// Determine if the next item is either the end of the list or younger
// than the new instruction. If so, then add in a new iterator right here.
// If not, then move along.
ListOrderEntry queue_entry;
OpClass op_class = (*list_order_it).queueType;
ListOrderIt next_it = list_order_it;
++next_it;
queue_entry.queueType = op_class;
queue_entry.oldestInst = readyInsts[op_class].top()->seqNum;
while (next_it != listOrder.end() &&
(*next_it).oldestInst < queue_entry.oldestInst) {
++next_it;
}
readyIt[op_class] = listOrder.insert(next_it, queue_entry);
}
template <class Impl>
void
InstructionQueue<Impl>::processFUCompletion(DynInstPtr &inst, int fu_idx)
{
DPRINTF(IQ, "Processing FU completion [sn:%lli]\n", inst->seqNum);
// The CPU could have been sleeping until this op completed (*extremely*
// long latency op). Wake it if it was. This may be overkill.
if (isSwitchedOut()) {
DPRINTF(IQ, "FU completion not processed, IQ is switched out [sn:%lli]\n",
inst->seqNum);
return;
}
iewStage->wakeCPU();
if (fu_idx > -1)
fuPool->freeUnitNextCycle(fu_idx);
// @todo: Ensure that these FU Completions happen at the beginning
// of a cycle, otherwise they could add too many instructions to
// the queue.
issueToExecuteQueue->access(0)->size++;
instsToExecute.push_back(inst);
}
// @todo: Figure out a better way to remove the squashed items from the
// lists. Checking the top item of each list to see if it's squashed
// wastes time and forces jumps.
template <class Impl>
void
InstructionQueue<Impl>::scheduleReadyInsts()
{
DPRINTF(IQ, "Attempting to schedule ready instructions from "
"the IQ.\n");
IssueStruct *i2e_info = issueToExecuteQueue->access(0);
// Have iterator to head of the list
// While I haven't exceeded bandwidth or reached the end of the list,
// Try to get a FU that can do what this op needs.
// If successful, change the oldestInst to the new top of the list, put
// the queue in the proper place in the list.
// Increment the iterator.
// This will avoid trying to schedule a certain op class if there are no
// FUs that handle it.
ListOrderIt order_it = listOrder.begin();
ListOrderIt order_end_it = listOrder.end();
int total_issued = 0;
while (total_issued < totalWidth &&
iewStage->canIssue() &&
order_it != order_end_it) {
OpClass op_class = (*order_it).queueType;
assert(!readyInsts[op_class].empty());
DynInstPtr issuing_inst = readyInsts[op_class].top();
assert(issuing_inst->seqNum == (*order_it).oldestInst);
if (issuing_inst->isSquashed()) {
readyInsts[op_class].pop();
if (!readyInsts[op_class].empty()) {
moveToYoungerInst(order_it);
} else {
readyIt[op_class] = listOrder.end();
queueOnList[op_class] = false;
}
listOrder.erase(order_it++);
++iqSquashedInstsIssued;
continue;
}
int idx = -2;
int op_latency = 1;
int tid = issuing_inst->threadNumber;
if (op_class != No_OpClass) {
idx = fuPool->getUnit(op_class);
if (idx > -1) {
op_latency = fuPool->getOpLatency(op_class);
}
}
// If we have an instruction that doesn't require a FU, or a
// valid FU, then schedule for execution.
if (idx == -2 || idx != -1) {
if (op_latency == 1) {
i2e_info->size++;
instsToExecute.push_back(issuing_inst);
// Add the FU onto the list of FU's to be freed next
// cycle if we used one.
if (idx >= 0)
fuPool->freeUnitNextCycle(idx);
} else {
int issue_latency = fuPool->getIssueLatency(op_class);
// Generate completion event for the FU
FUCompletion *execution = new FUCompletion(issuing_inst,
idx, this);
execution->schedule(curTick + cpu->cycles(issue_latency - 1));
// @todo: Enforce that issue_latency == 1 or op_latency
if (issue_latency > 1) {
// If FU isn't pipelined, then it must be freed
// upon the execution completing.
execution->setFreeFU();
} else {
// Add the FU onto the list of FU's to be freed next cycle.
fuPool->freeUnitNextCycle(idx);
}
}
DPRINTF(IQ, "Thread %i: Issuing instruction PC %#x "
"[sn:%lli]\n",
tid, issuing_inst->readPC(),
issuing_inst->seqNum);
readyInsts[op_class].pop();
if (!readyInsts[op_class].empty()) {
moveToYoungerInst(order_it);
} else {
readyIt[op_class] = listOrder.end();
queueOnList[op_class] = false;
}
issuing_inst->setIssued();
++total_issued;
if (!issuing_inst->isMemRef()) {
// Memory instructions can not be freed from the IQ until they
// complete.
++freeEntries;
count[tid]--;
issuing_inst->clearInIQ();
} else {
memDepUnit[tid].issue(issuing_inst);
}
listOrder.erase(order_it++);
statIssuedInstType[tid][op_class]++;
iewStage->incrWb(issuing_inst->seqNum);
} else {
statFuBusy[op_class]++;
fuBusy[tid]++;
++order_it;
}
}
numIssuedDist.sample(total_issued);
iqInstsIssued+= total_issued;
// If we issued any instructions, tell the CPU we had activity.
if (total_issued) {
cpu->activityThisCycle();
} else {
DPRINTF(IQ, "Not able to schedule any instructions.\n");
}
}
template <class Impl>
void
InstructionQueue<Impl>::scheduleNonSpec(const InstSeqNum &inst)
{
DPRINTF(IQ, "Marking nonspeculative instruction [sn:%lli] as ready "
"to execute.\n", inst);
NonSpecMapIt inst_it = nonSpecInsts.find(inst);
assert(inst_it != nonSpecInsts.end());
unsigned tid = (*inst_it).second->threadNumber;
(*inst_it).second->setAtCommit();
(*inst_it).second->setCanIssue();
if (!(*inst_it).second->isMemRef()) {
addIfReady((*inst_it).second);
} else {
memDepUnit[tid].nonSpecInstReady((*inst_it).second);
}
(*inst_it).second = NULL;
nonSpecInsts.erase(inst_it);
}
template <class Impl>
void
InstructionQueue<Impl>::commit(const InstSeqNum &inst, unsigned tid)
{
DPRINTF(IQ, "[tid:%i]: Committing instructions older than [sn:%i]\n",
tid,inst);
ListIt iq_it = instList[tid].begin();
while (iq_it != instList[tid].end() &&
(*iq_it)->seqNum <= inst) {
++iq_it;
instList[tid].pop_front();
}
assert(freeEntries == (numEntries - countInsts()));
}
template <class Impl>
int
InstructionQueue<Impl>::wakeDependents(DynInstPtr &completed_inst)
{
int dependents = 0;
DPRINTF(IQ, "Waking dependents of completed instruction.\n");
assert(!completed_inst->isSquashed());
// Tell the memory dependence unit to wake any dependents on this
// instruction if it is a memory instruction. Also complete the memory
// instruction at this point since we know it executed without issues.
// @todo: Might want to rename "completeMemInst" to something that
// indicates that it won't need to be replayed, and call this
// earlier. Might not be a big deal.
if (completed_inst->isMemRef()) {
memDepUnit[completed_inst->threadNumber].wakeDependents(completed_inst);
completeMemInst(completed_inst);
} else if (completed_inst->isMemBarrier() ||
completed_inst->isWriteBarrier()) {
memDepUnit[completed_inst->threadNumber].completeBarrier(completed_inst);
}
for (int dest_reg_idx = 0;
dest_reg_idx < completed_inst->numDestRegs();
dest_reg_idx++)
{
PhysRegIndex dest_reg =
completed_inst->renamedDestRegIdx(dest_reg_idx);
// Special case of uniq or control registers. They are not
// handled by the IQ and thus have no dependency graph entry.
// @todo Figure out a cleaner way to handle this.
if (dest_reg >= numPhysRegs) {
continue;
}
DPRINTF(IQ, "Waking any dependents on register %i.\n",
(int) dest_reg);
//Go through the dependency chain, marking the registers as
//ready within the waiting instructions.
DynInstPtr dep_inst = dependGraph.pop(dest_reg);
while (dep_inst) {
DPRINTF(IQ, "Waking up a dependent instruction, PC%#x.\n",
dep_inst->readPC());
// Might want to give more information to the instruction
// so that it knows which of its source registers is
// ready. However that would mean that the dependency
// graph entries would need to hold the src_reg_idx.
dep_inst->markSrcRegReady();
addIfReady(dep_inst);
dep_inst = dependGraph.pop(dest_reg);
++dependents;
}
// Reset the head node now that all of its dependents have
// been woken up.
assert(dependGraph.empty(dest_reg));
dependGraph.clearInst(dest_reg);
// Mark the scoreboard as having that register ready.
regScoreboard[dest_reg] = true;
}
return dependents;
}
template <class Impl>
void
InstructionQueue<Impl>::addReadyMemInst(DynInstPtr &ready_inst)
{
OpClass op_class = ready_inst->opClass();
readyInsts[op_class].push(ready_inst);
// Will need to reorder the list if either a queue is not on the list,
// or it has an older instruction than last time.
if (!queueOnList[op_class]) {
addToOrderList(op_class);
} else if (readyInsts[op_class].top()->seqNum <
(*readyIt[op_class]).oldestInst) {
listOrder.erase(readyIt[op_class]);
addToOrderList(op_class);
}
DPRINTF(IQ, "Instruction is ready to issue, putting it onto "
"the ready list, PC %#x opclass:%i [sn:%lli].\n",
ready_inst->readPC(), op_class, ready_inst->seqNum);
}
template <class Impl>
void
InstructionQueue<Impl>::rescheduleMemInst(DynInstPtr &resched_inst)
{
DPRINTF(IQ, "Rescheduling mem inst [sn:%lli]\n", resched_inst->seqNum);
resched_inst->clearCanIssue();
memDepUnit[resched_inst->threadNumber].reschedule(resched_inst);
}
template <class Impl>
void
InstructionQueue<Impl>::replayMemInst(DynInstPtr &replay_inst)
{
memDepUnit[replay_inst->threadNumber].replay(replay_inst);
}
template <class Impl>
void
InstructionQueue<Impl>::completeMemInst(DynInstPtr &completed_inst)
{
int tid = completed_inst->threadNumber;
DPRINTF(IQ, "Completing mem instruction PC:%#x [sn:%lli]\n",
completed_inst->readPC(), completed_inst->seqNum);
++freeEntries;
completed_inst->memOpDone = true;
memDepUnit[tid].completed(completed_inst);
count[tid]--;
}
template <class Impl>
void
InstructionQueue<Impl>::violation(DynInstPtr &store,
DynInstPtr &faulting_load)
{
memDepUnit[store->threadNumber].violation(store, faulting_load);
}
template <class Impl>
void
InstructionQueue<Impl>::squash(unsigned tid)
{
DPRINTF(IQ, "[tid:%i]: Starting to squash instructions in "
"the IQ.\n", tid);
// Read instruction sequence number of last instruction out of the
// time buffer.
squashedSeqNum[tid] = fromCommit->commitInfo[tid].doneSeqNum;
// Call doSquash if there are insts in the IQ
if (count[tid] > 0) {
doSquash(tid);
}
// Also tell the memory dependence unit to squash.
memDepUnit[tid].squash(squashedSeqNum[tid], tid);
}
template <class Impl>
void
InstructionQueue<Impl>::doSquash(unsigned tid)
{
// Start at the tail.
ListIt squash_it = instList[tid].end();
--squash_it;
DPRINTF(IQ, "[tid:%i]: Squashing until sequence number %i!\n",
tid, squashedSeqNum[tid]);
// Squash any instructions younger than the squashed sequence number
// given.
while (squash_it != instList[tid].end() &&
(*squash_it)->seqNum > squashedSeqNum[tid]) {
DynInstPtr squashed_inst = (*squash_it);
// Only handle the instruction if it actually is in the IQ and
// hasn't already been squashed in the IQ.
if (squashed_inst->threadNumber != tid ||
squashed_inst->isSquashedInIQ()) {
--squash_it;
continue;
}
if (!squashed_inst->isIssued() ||
(squashed_inst->isMemRef() &&
!squashed_inst->memOpDone)) {
DPRINTF(IQ, "[tid:%i]: Instruction [sn:%lli] PC %#x "
"squashed.\n",
tid, squashed_inst->seqNum, squashed_inst->readPC());
// Remove the instruction from the dependency list.
if (!squashed_inst->isNonSpeculative() &&
!squashed_inst->isStoreConditional() &&
!squashed_inst->isMemBarrier() &&
!squashed_inst->isWriteBarrier()) {
for (int src_reg_idx = 0;
src_reg_idx < squashed_inst->numSrcRegs();
src_reg_idx++)
{
PhysRegIndex src_reg =
squashed_inst->renamedSrcRegIdx(src_reg_idx);
// Only remove it from the dependency graph if it
// was placed there in the first place.
// Instead of doing a linked list traversal, we
// can just remove these squashed instructions
// either at issue time, or when the register is
// overwritten. The only downside to this is it
// leaves more room for error.
if (!squashed_inst->isReadySrcRegIdx(src_reg_idx) &&
src_reg < numPhysRegs) {
dependGraph.remove(src_reg, squashed_inst);
}
++iqSquashedOperandsExamined;
}
} else if (!squashed_inst->isStoreConditional() ||
!squashed_inst->isCompleted()) {
NonSpecMapIt ns_inst_it =
nonSpecInsts.find(squashed_inst->seqNum);
assert(ns_inst_it != nonSpecInsts.end());
if (ns_inst_it == nonSpecInsts.end()) {
assert(squashed_inst->getFault() != NoFault);
} else {
(*ns_inst_it).second = NULL;
nonSpecInsts.erase(ns_inst_it);
++iqSquashedNonSpecRemoved;
}
}
// Might want to also clear out the head of the dependency graph.
// Mark it as squashed within the IQ.
squashed_inst->setSquashedInIQ();
// @todo: Remove this hack where several statuses are set so the
// inst will flow through the rest of the pipeline.
squashed_inst->setIssued();
squashed_inst->setCanCommit();
squashed_inst->clearInIQ();
//Update Thread IQ Count
count[squashed_inst->threadNumber]--;
++freeEntries;
}
instList[tid].erase(squash_it--);
++iqSquashedInstsExamined;
}
}
template <class Impl>
bool
InstructionQueue<Impl>::addToDependents(DynInstPtr &new_inst)
{
// Loop through the instruction's source registers, adding
// them to the dependency list if they are not ready.
int8_t total_src_regs = new_inst->numSrcRegs();
bool return_val = false;
for (int src_reg_idx = 0;
src_reg_idx < total_src_regs;
src_reg_idx++)
{
// Only add it to the dependency graph if it's not ready.
if (!new_inst->isReadySrcRegIdx(src_reg_idx)) {
PhysRegIndex src_reg = new_inst->renamedSrcRegIdx(src_reg_idx);
// Check the IQ's scoreboard to make sure the register
// hasn't become ready while the instruction was in flight
// between stages. Only if it really isn't ready should
// it be added to the dependency graph.
if (src_reg >= numPhysRegs) {
continue;
} else if (regScoreboard[src_reg] == false) {
DPRINTF(IQ, "Instruction PC %#x has src reg %i that "
"is being added to the dependency chain.\n",
new_inst->readPC(), src_reg);
dependGraph.insert(src_reg, new_inst);
// Change the return value to indicate that something
// was added to the dependency graph.
return_val = true;
} else {
DPRINTF(IQ, "Instruction PC %#x has src reg %i that "
"became ready before it reached the IQ.\n",
new_inst->readPC(), src_reg);
// Mark a register ready within the instruction.
new_inst->markSrcRegReady(src_reg_idx);
}
}
}
return return_val;
}
template <class Impl>
void
InstructionQueue<Impl>::addToProducers(DynInstPtr &new_inst)
{
// Nothing really needs to be marked when an instruction becomes
// the producer of a register's value, but for convenience a ptr
// to the producing instruction will be placed in the head node of
// the dependency links.
int8_t total_dest_regs = new_inst->numDestRegs();
for (int dest_reg_idx = 0;
dest_reg_idx < total_dest_regs;
dest_reg_idx++)
{
PhysRegIndex dest_reg = new_inst->renamedDestRegIdx(dest_reg_idx);
// Instructions that use the misc regs will have a reg number
// higher than the normal physical registers. In this case these
// registers are not renamed, and there is no need to track
// dependencies as these instructions must be executed at commit.
if (dest_reg >= numPhysRegs) {
continue;
}
if (!dependGraph.empty(dest_reg)) {
dependGraph.dump();
panic("Dependency graph %i not empty!", dest_reg);
}
dependGraph.setInst(dest_reg, new_inst);
// Mark the scoreboard to say it's not yet ready.
regScoreboard[dest_reg] = false;
}
}
template <class Impl>
void
InstructionQueue<Impl>::addIfReady(DynInstPtr &inst)
{
// If the instruction now has all of its source registers
// available, then add it to the list of ready instructions.
if (inst->readyToIssue()) {
//Add the instruction to the proper ready list.
if (inst->isMemRef()) {
DPRINTF(IQ, "Checking if memory instruction can issue.\n");
// Message to the mem dependence unit that this instruction has
// its registers ready.
memDepUnit[inst->threadNumber].regsReady(inst);
return;
}
OpClass op_class = inst->opClass();
DPRINTF(IQ, "Instruction is ready to issue, putting it onto "
"the ready list, PC %#x opclass:%i [sn:%lli].\n",
inst->readPC(), op_class, inst->seqNum);
readyInsts[op_class].push(inst);
// Will need to reorder the list if either a queue is not on the list,
// or it has an older instruction than last time.
if (!queueOnList[op_class]) {
addToOrderList(op_class);
} else if (readyInsts[op_class].top()->seqNum <
(*readyIt[op_class]).oldestInst) {
listOrder.erase(readyIt[op_class]);
addToOrderList(op_class);
}
}
}
template <class Impl>
int
InstructionQueue<Impl>::countInsts()
{
#if 0
//ksewell:This works but definitely could use a cleaner write
//with a more intuitive way of counting. Right now it's
//just brute force ....
// Change the #if if you want to use this method.
int total_insts = 0;
for (int i = 0; i < numThreads; ++i) {
ListIt count_it = instList[i].begin();
while (count_it != instList[i].end()) {
if (!(*count_it)->isSquashed() && !(*count_it)->isSquashedInIQ()) {
if (!(*count_it)->isIssued()) {
++total_insts;
} else if ((*count_it)->isMemRef() &&
!(*count_it)->memOpDone) {
// Loads that have not been marked as executed still count
// towards the total instructions.
++total_insts;
}
}
++count_it;
}
}
return total_insts;
#else
return numEntries - freeEntries;
#endif
}
template <class Impl>
void
InstructionQueue<Impl>::dumpLists()
{
for (int i = 0; i < Num_OpClasses; ++i) {
cprintf("Ready list %i size: %i\n", i, readyInsts[i].size());
cprintf("\n");
}
cprintf("Non speculative list size: %i\n", nonSpecInsts.size());
NonSpecMapIt non_spec_it = nonSpecInsts.begin();
NonSpecMapIt non_spec_end_it = nonSpecInsts.end();
cprintf("Non speculative list: ");
while (non_spec_it != non_spec_end_it) {
cprintf("%#x [sn:%lli]", (*non_spec_it).second->readPC(),
(*non_spec_it).second->seqNum);
++non_spec_it;
}
cprintf("\n");
ListOrderIt list_order_it = listOrder.begin();
ListOrderIt list_order_end_it = listOrder.end();
int i = 1;
cprintf("List order: ");
while (list_order_it != list_order_end_it) {
cprintf("%i OpClass:%i [sn:%lli] ", i, (*list_order_it).queueType,
(*list_order_it).oldestInst);
++list_order_it;
++i;
}
cprintf("\n");
}
template <class Impl>
void
InstructionQueue<Impl>::dumpInsts()
{
for (int i = 0; i < numThreads; ++i) {
int num = 0;
int valid_num = 0;
ListIt inst_list_it = instList[i].begin();
while (inst_list_it != instList[i].end())
{
cprintf("Instruction:%i\n",
num);
if (!(*inst_list_it)->isSquashed()) {
if (!(*inst_list_it)->isIssued()) {
++valid_num;
cprintf("Count:%i\n", valid_num);
} else if ((*inst_list_it)->isMemRef() &&
!(*inst_list_it)->memOpDone) {
// Loads that have not been marked as executed
// still count towards the total instructions.
++valid_num;
cprintf("Count:%i\n", valid_num);
}
}
cprintf("PC:%#x\n[sn:%lli]\n[tid:%i]\n"
"Issued:%i\nSquashed:%i\n",
(*inst_list_it)->readPC(),
(*inst_list_it)->seqNum,
(*inst_list_it)->threadNumber,
(*inst_list_it)->isIssued(),
(*inst_list_it)->isSquashed());
if ((*inst_list_it)->isMemRef()) {
cprintf("MemOpDone:%i\n", (*inst_list_it)->memOpDone);
}
cprintf("\n");
inst_list_it++;
++num;
}
}
cprintf("Insts to Execute list:\n");
int num = 0;
int valid_num = 0;
ListIt inst_list_it = instsToExecute.begin();
while (inst_list_it != instsToExecute.end())
{
cprintf("Instruction:%i\n",
num);
if (!(*inst_list_it)->isSquashed()) {
if (!(*inst_list_it)->isIssued()) {
++valid_num;
cprintf("Count:%i\n", valid_num);
} else if ((*inst_list_it)->isMemRef() &&
!(*inst_list_it)->memOpDone) {
// Loads that have not been marked as executed
// still count towards the total instructions.
++valid_num;
cprintf("Count:%i\n", valid_num);
}
}
cprintf("PC:%#x\n[sn:%lli]\n[tid:%i]\n"
"Issued:%i\nSquashed:%i\n",
(*inst_list_it)->readPC(),
(*inst_list_it)->seqNum,
(*inst_list_it)->threadNumber,
(*inst_list_it)->isIssued(),
(*inst_list_it)->isSquashed());
if ((*inst_list_it)->isMemRef()) {
cprintf("MemOpDone:%i\n", (*inst_list_it)->memOpDone);
}
cprintf("\n");
inst_list_it++;
++num;
}
}
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