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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 "config/the_isa.hh"
#include "cpu/inorder/pipeline_traits.hh"
#include "cpu/inorder/resources/use_def.hh"
#include "cpu/inorder/cpu.hh"
using namespace std;
using namespace TheISA;
using namespace ThePipeline;
UseDefUnit::UseDefUnit(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),
maxSeqNum((InstSeqNum)-1)
{
for (ThreadID tid = 0; tid < ThePipeline::MaxThreads; tid++) {
nonSpecInstActive[tid] = &cpu->nonSpecInstActive[tid];
nonSpecSeqNum[tid] = &cpu->nonSpecSeqNum[tid];
outReadSeqNum[tid] = maxSeqNum;
outWriteSeqNum[tid] = maxSeqNum;
regDepMap[tid] = &cpu->archRegDepMap[tid];
}
}
void
UseDefUnit::regStats()
{
uniqueRegsPerSwitch
.name(name() + ".uniqueRegsPerSwitch")
.desc("Number of Unique Registers Needed Per Context Switch")
.prereq(uniqueRegsPerSwitch);
Resource::regStats();
}
ResReqPtr
UseDefUnit::getRequest(DynInstPtr inst, int stage_num, int res_idx,
int slot_num, unsigned cmd)
{
return new UseDefRequest(this, inst, stage_num, id, slot_num, cmd,
inst->resSched.top()->idx);
}
ResReqPtr
UseDefUnit::findRequest(DynInstPtr inst)
{
map<int, ResReqPtr>::iterator map_it = reqMap.begin();
map<int, ResReqPtr>::iterator map_end = reqMap.end();
while (map_it != map_end) {
UseDefRequest* ud_req =
dynamic_cast<UseDefRequest*>((*map_it).second);
assert(ud_req);
if (ud_req &&
ud_req->getInst() == inst &&
ud_req->cmd == inst->resSched.top()->cmd &&
ud_req->useDefIdx == inst->resSched.top()->idx) {
return ud_req;
}
map_it++;
}
return NULL;
}
void
UseDefUnit::execute(int slot_idx)
{
// After this is working, change this to a reinterpret cast
// for performance considerations
UseDefRequest* ud_req = dynamic_cast<UseDefRequest*>(reqMap[slot_idx]);
assert(ud_req);
DynInstPtr inst = ud_req->inst;
ThreadID tid = inst->readTid();
int seq_num = inst->seqNum;
int ud_idx = ud_req->useDefIdx;
// If there is a non-speculative instruction
// in the pipeline then stall instructions here
if (*nonSpecInstActive[tid] == true &&
seq_num > *nonSpecSeqNum[tid]) {
DPRINTF(InOrderUseDef, "[tid:%i]: [sn:%i] cannot execute because"
"there is non-speculative instruction [sn:%i] has not "
"graduated.\n", tid, seq_num, *nonSpecSeqNum[tid]);
return;
} else if (inst->isNonSpeculative()) {
*nonSpecInstActive[tid] = true;
*nonSpecSeqNum[tid] = seq_num;
}
switch (ud_req->cmd)
{
case ReadSrcReg:
{
int reg_idx = inst->_srcRegIdx[ud_idx];
DPRINTF(InOrderUseDef, "[tid:%i]: Attempting to read source "
"register idx %i (reg #%i).\n",
tid, ud_idx, reg_idx);
// Ask register dependency map if it is OK to read from Arch.
// Reg. File
if (regDepMap[tid]->canRead(reg_idx, inst)) {
uniqueRegMap[reg_idx] = true;
if (inst->seqNum <= outReadSeqNum[tid]) {
if (reg_idx < FP_Base_DepTag) {
DPRINTF(InOrderUseDef, "[tid:%i]: Reading Int Reg %i"
"from Register File:%i.\n",
tid,
reg_idx,
cpu->readIntReg(reg_idx,inst->readTid()));
inst->setIntSrc(ud_idx,
cpu->readIntReg(reg_idx,
inst->readTid()));
} else if (reg_idx < Ctrl_Base_DepTag) {
reg_idx -= FP_Base_DepTag;
DPRINTF(InOrderUseDef, "[tid:%i]: Reading Float Reg %i"
"from Register File:%x (%08f).\n",
tid,
reg_idx,
cpu->readFloatRegBits(reg_idx,
inst->readTid()),
cpu->readFloatReg(reg_idx,
inst->readTid()));
inst->setFloatSrc(ud_idx,
cpu->readFloatReg(reg_idx,
inst->readTid()));
} else {
reg_idx -= Ctrl_Base_DepTag;
DPRINTF(InOrderUseDef, "[tid:%i]: Reading Misc Reg %i "
"from Register File:%i.\n",
tid,
reg_idx,
cpu->readMiscReg(reg_idx,
inst->readTid()));
inst->setIntSrc(ud_idx,
cpu->readMiscReg(reg_idx,
inst->readTid()));
}
outReadSeqNum[tid] = maxSeqNum;
ud_req->done();
} else {
DPRINTF(InOrderUseDef, "[tid:%i]: Unable to read because "
"of [sn:%i] hasnt read it's registers yet.\n",
tid, outReadSeqNum[tid]);
DPRINTF(InOrderStall, "STALL: [tid:%i]: waiting for "
"[sn:%i] to write\n",
tid, outReadSeqNum[tid]);
ud_req->done(false);
}
} else {
// Look for forwarding opportunities
DynInstPtr forward_inst = regDepMap[tid]->canForward(reg_idx,
inst);
if (forward_inst) {
if (inst->seqNum <= outReadSeqNum[tid]) {
int dest_reg_idx =
forward_inst->getDestIdxNum(reg_idx);
if (reg_idx < FP_Base_DepTag) {
DPRINTF(InOrderUseDef, "[tid:%i]: Forwarding dest."
" reg value 0x%x from "
"[sn:%i] to [sn:%i] source #%i.\n",
tid,
forward_inst->readIntResult(dest_reg_idx),
forward_inst->seqNum,
inst->seqNum, ud_idx);
inst->setIntSrc(ud_idx,
forward_inst->
readIntResult(dest_reg_idx));
} else if (reg_idx < Ctrl_Base_DepTag) {
DPRINTF(InOrderUseDef, "[tid:%i]: Forwarding dest."
" reg value 0x%x from "
"[sn:%i] to [sn:%i] source #%i.\n",
tid,
forward_inst->readFloatResult(dest_reg_idx),
forward_inst->seqNum, inst->seqNum, ud_idx);
inst->setFloatSrc(ud_idx,
forward_inst->
readFloatResult(dest_reg_idx));
} else {
DPRINTF(InOrderUseDef, "[tid:%i]: Forwarding dest."
" reg value 0x%x from "
"[sn:%i] to [sn:%i] source #%i.\n",
tid,
forward_inst->readIntResult(dest_reg_idx),
forward_inst->seqNum,
inst->seqNum, ud_idx);
inst->setIntSrc(ud_idx,
forward_inst->
readIntResult(dest_reg_idx));
}
outReadSeqNum[tid] = maxSeqNum;
ud_req->done();
} else {
DPRINTF(InOrderUseDef, "[tid:%i]: Unable to read "
"because of [sn:%i] hasnt read it's"
" registers yet.\n", tid, outReadSeqNum[tid]);
DPRINTF(InOrderStall, "STALL: [tid:%i]: waiting for "
"[sn:%i] to forward\n",
tid, outReadSeqNum[tid]);
ud_req->done(false);
}
} else {
DPRINTF(InOrderUseDef, "[tid:%i]: Source register idx: %i"
"is not ready to read.\n",
tid, reg_idx);
DPRINTF(InOrderStall, "STALL: [tid:%i]: waiting to read "
"register (idx=%i)\n",
tid, reg_idx);
outReadSeqNum[tid] = inst->seqNum;
ud_req->done(false);
}
}
}
break;
case WriteDestReg:
{
int reg_idx = inst->_destRegIdx[ud_idx];
if (regDepMap[tid]->canWrite(reg_idx, inst)) {
DPRINTF(InOrderUseDef, "[tid:%i]: Flattening register idx %i &"
"Attempting to write to Register File.\n",
tid, reg_idx);
uniqueRegMap[reg_idx] = true;
if (inst->seqNum <= outReadSeqNum[tid]) {
if (reg_idx < FP_Base_DepTag) {
DPRINTF(InOrderUseDef, "[tid:%i]: Writing Int. Result "
"0x%x to register idx %i.\n",
tid, inst->readIntResult(ud_idx), reg_idx);
// Remove Dependencies
regDepMap[tid]->removeFront(reg_idx, inst);
cpu->setIntReg(reg_idx,
inst->readIntResult(ud_idx),
inst->readTid());
} else if(reg_idx < Ctrl_Base_DepTag) {
// Remove Dependencies
regDepMap[tid]->removeFront(reg_idx, inst);
reg_idx -= FP_Base_DepTag;
if (inst->resultType(ud_idx) ==
InOrderDynInst::Integer) {
DPRINTF(InOrderUseDef, "[tid:%i]: Writing FP-Bits "
"Result 0x%x (bits:0x%x) to register "
"idx %i.\n",
tid,
inst->readFloatResult(ud_idx),
inst->readIntResult(ud_idx),
reg_idx);
// Check for FloatRegBits Here
cpu->setFloatRegBits(reg_idx,
inst->readIntResult(ud_idx),
inst->readTid());
} else if (inst->resultType(ud_idx) ==
InOrderDynInst::Float) {
DPRINTF(InOrderUseDef, "[tid:%i]: Writing Float "
"Result 0x%x (bits:0x%x) to register "
"idx %i.\n",
tid, inst->readFloatResult(ud_idx),
inst->readIntResult(ud_idx),
reg_idx);
cpu->setFloatReg(reg_idx,
inst->readFloatResult(ud_idx),
inst->readTid());
} else if (inst->resultType(ud_idx) ==
InOrderDynInst::Double) {
DPRINTF(InOrderUseDef, "[tid:%i]: Writing Double "
"Result 0x%x (bits:0x%x) to register "
"idx %i.\n",
tid,
inst->readFloatResult(ud_idx),
inst->readIntResult(ud_idx),
reg_idx);
// Check for FloatRegBits Here
cpu->setFloatReg(reg_idx,
inst->readFloatResult(ud_idx),
inst->readTid());
} else {
panic("Result Type Not Set For [sn:%i] %s.\n",
inst->seqNum, inst->instName());
}
} else {
DPRINTF(InOrderUseDef, "[tid:%i]: Writing Misc. 0x%x "
"to register idx %i.\n",
tid, inst->readIntResult(ud_idx), reg_idx);
// Remove Dependencies
regDepMap[tid]->removeFront(reg_idx, inst);
reg_idx -= Ctrl_Base_DepTag;
cpu->setMiscReg(reg_idx,
inst->readIntResult(ud_idx),
inst->readTid());
}
outWriteSeqNum[tid] = maxSeqNum;
ud_req->done();
} else {
DPRINTF(InOrderUseDef, "[tid:%i]: Unable to write because "
"of [sn:%i] hasnt read it's"
" registers yet.\n", tid, outReadSeqNum);
DPRINTF(InOrderStall, "STALL: [tid:%i]: waiting for "
"[sn:%i] to read\n",
tid, outReadSeqNum);
ud_req->done(false);
}
} else {
DPRINTF(InOrderUseDef, "[tid:%i]: Dest. register idx: %i is "
"not ready to write.\n",
tid, reg_idx);
DPRINTF(InOrderStall, "STALL: [tid:%i]: waiting to write "
"register (idx=%i)\n",
tid, reg_idx);
outWriteSeqNum[tid] = inst->seqNum;
ud_req->done(false);
}
}
break;
default:
fatal("Unrecognized command to %s", resName);
}
}
void
UseDefUnit::squash(DynInstPtr inst, int stage_num, InstSeqNum squash_seq_num,
ThreadID tid)
{
DPRINTF(InOrderUseDef, "[tid:%i]: Updating Due To Squash After [sn:%i].\n",
tid, squash_seq_num);
std::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(InOrderUseDef, "[tid:%i]: Squashing [sn:%i].\n",
req_ptr->getInst()->readTid(),
req_ptr->getInst()->seqNum);
int req_slot_num = req_ptr->getSlot();
if (latency > 0) {
assert(0);
unscheduleEvent(req_slot_num);
}
// 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]);
}
if (outReadSeqNum[tid] >= squash_seq_num) {
DPRINTF(InOrderUseDef, "[tid:%i]: Outstanding Read Seq Num Reset.\n",
tid);
outReadSeqNum[tid] = maxSeqNum;
} else if (outReadSeqNum[tid] != maxSeqNum) {
DPRINTF(InOrderUseDef, "[tid:%i]: No need to reset Outstanding Read "
"Seq Num %i\n",
tid, outReadSeqNum[tid]);
}
if (outWriteSeqNum[tid] >= squash_seq_num) {
DPRINTF(InOrderUseDef, "[tid:%i]: Outstanding Write Seq Num Reset.\n",
tid);
outWriteSeqNum[tid] = maxSeqNum;
} else if (outWriteSeqNum[tid] != maxSeqNum) {
DPRINTF(InOrderUseDef, "[tid:%i]: No need to reset Outstanding Write "
"Seq Num %i\n",
tid, outWriteSeqNum[tid]);
}
}
void
UseDefUnit::updateAfterContextSwitch(DynInstPtr inst, ThreadID tid)
{
uniqueRegsPerSwitch = uniqueRegMap.size();
uniqueRegMap.clear();
}
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