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gem5 / public / gem5 / dc33a16993d1b13977eebfe19119b931dddd17db / . / src / mem / ruby / protocol / chi / CHI-cache-funcs.sm
blob: f990c0b3b529843ea5dc7011e4e82937c54be297 [file] [log] [blame]
/*
* Copyright (c) 2021-2022 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.
*
* 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.
*/
////////////////////////////////////////////////////////////////////////////
// CHI-cache function definitions
////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////
// External functions
Tick clockEdge();
Tick curTick();
Tick cyclesToTicks(Cycles c);
Cycles ticksToCycles(Tick t);
void set_cache_entry(AbstractCacheEntry b);
void unset_cache_entry();
void set_tbe(TBE b);
void unset_tbe();
MachineID mapAddressToDownstreamMachine(Addr addr);
MachineID mapAddressToMachine(Addr addr, MachineType mtype);
void incomingTransactionStart(Addr, Event, State, bool);
void incomingTransactionEnd(Addr, State);
void outgoingTransactionStart(Addr, Event);
void outgoingTransactionEnd(Addr, bool);
// Overloads for transaction-measuring functions
// final bool = isAddressed
// if false, uses a "unaddressed" table with unique IDs
void incomingTransactionStart(Addr, Event, State, bool, bool);
void incomingTransactionEnd(Addr, State, bool);
void outgoingTransactionStart(Addr, Event, bool);
void outgoingTransactionEnd(Addr, bool, bool);
Event curTransitionEvent();
State curTransitionNextState();
// Placeholders for future prefetch support
void notifyPfHit(RequestPtr req, bool is_read, DataBlock blk) { }
void notifyPfMiss(RequestPtr req, bool is_read, DataBlock blk) { }
void notifyPfFill(RequestPtr req, DataBlock blk, bool from_pf) { }
void notifyPfEvict(Addr blkAddr, bool hwPrefetched) { }
void notifyPfComplete(Addr addr) { }
////////////////////////////////////////////////////////////////////////////
// Interface functions required by SLICC
CacheEntry getCacheEntry(Addr addr), return_by_pointer="yes" {
return static_cast(CacheEntry, "pointer", cache.lookup(addr));
}
CacheEntry nullCacheEntry(), return_by_pointer="yes" {
return OOD;
}
DirEntry getDirEntry(Addr addr), return_by_pointer = "yes" {
if (directory.isTagPresent(addr)) {
return directory.lookup(addr);
} else {
return OOD;
}
}
State getState(TBE tbe, CacheEntry cache_entry, Addr addr) {
if (is_valid(tbe)) {
return tbe.state;
} else if (is_valid(cache_entry)) {
return cache_entry.state;
} else {
DirEntry dir_entry := getDirEntry(addr);
if (is_valid(dir_entry)) {
return dir_entry.state;
} else {
return State:I;
}
}
}
void setState(TBE tbe, CacheEntry cache_entry, Addr addr, State state) {
if (is_valid(tbe)) {
tbe.state := state;
}
if (is_valid(cache_entry)) {
cache_entry.state := state;
}
DirEntry dir_entry := getDirEntry(addr);
if (is_valid(dir_entry)) {
dir_entry.state := state;
}
}
TBE nullTBE(), return_by_pointer="yes" {
return OOD;
}
TBE getDvmTBE(Addr txnId), return_by_pointer="yes" {
TBE dvm_tbe := dvmTBEs[txnId];
if (is_valid(dvm_tbe)) {
return dvm_tbe;
}
TBE dvm_snp_tbe := dvmSnpTBEs[txnId];
if (is_valid(dvm_snp_tbe)) {
return dvm_snp_tbe;
}
return OOD;
}
TBE getCurrentActiveTBE(Addr addr), return_by_pointer="yes" {
// snoops take precedence over wbs and reqs
// it's invalid to have a replacement and a req active at the same time
// for the same line
TBE snp_tbe := snpTBEs[addr];
if (is_valid(snp_tbe)) {
return snp_tbe;
}
TBE req_tbe := TBEs[addr];
TBE repl_tbe := replTBEs[addr];
if (is_valid(req_tbe)) {
assert(is_invalid(repl_tbe));
return req_tbe;
}
if (is_valid(repl_tbe)) {
assert(is_invalid(req_tbe));
return repl_tbe;
}
return OOD;
}
AccessPermission getAccessPermission(Addr addr) {
TBE tbe := getCurrentActiveTBE(addr);
if(is_valid(tbe)) {
assert(Cache_State_to_permission(tbe.state) == AccessPermission:Busy);
// It's assumed that if all caches are in transient state, the latest data
// is 1) within an inflight message, then 2 ) in memory. But with
// CleanUnique there may be no inflight messages with data, so it needs
// special handling.
bool cu_requester_or_responder :=
(tbe.reqType == CHIRequestType:CleanUnique) ||
(tbe.pendReqType == CHIRequestType:CleanUnique);
if ((tbe.expected_req_resp.hasExpected() ||
tbe.expected_snp_resp.hasExpected()) && !cu_requester_or_responder) {
DPRINTF(RubySlicc, "%x %s,%s\n", addr, tbe.state, AccessPermission:Busy);
return AccessPermission:Busy;
}
else if (tbe.dataValid && (tbe.dataMaybeDirtyUpstream == false)) {
if (tbe.dataUnique) {
DPRINTF(RubySlicc, "%x %s,%s\n", addr, tbe.state, AccessPermission:Read_Write);
return AccessPermission:Read_Write;
} else {
DPRINTF(RubySlicc, "%x %s,%s\n", addr, tbe.state, AccessPermission:Read_Only);
return AccessPermission:Read_Only;
}
} else {
DPRINTF(RubySlicc, "%x %s,%s\n", addr, tbe.state, AccessPermission:Busy);
return AccessPermission:Busy;
}
}
CacheEntry cache_entry := getCacheEntry(addr);
if(is_valid(cache_entry)) {
DPRINTF(RubySlicc, "%x %s,%s\n", addr, cache_entry.state, Cache_State_to_permission(cache_entry.state));
return Cache_State_to_permission(cache_entry.state);
}
DPRINTF(RubySlicc, "%x %s,%s\n", addr, State:I, AccessPermission:NotPresent);
return AccessPermission:NotPresent;
}
void setAccessPermission(CacheEntry cache_entry, Addr addr, State state) {
if (is_valid(cache_entry)) {
cache_entry.changePermission(Cache_State_to_permission(state));
}
}
void functionalRead(Addr addr, Packet *pkt, WriteMask &mask) {
// read if bitmask has bytes not in mask or if data is dirty
TBE tbe := getCurrentActiveTBE(addr);
CacheEntry cache_entry := getCacheEntry(addr);
DPRINTF(RubySlicc, "functionalRead %x\n", addr);
WriteMask read_mask;
bool dirty := false;
bool from_tbe := false;
if (is_valid(tbe)) {
from_tbe := true;
dirty := tbe.dataDirty;
if (tbe.dataValid) {
read_mask.fillMask();
} else {
read_mask := tbe.dataBlkValid;
// could have received dirty data but tbe.dataDirty not set yet because
// some data is pending, so check for dirty received message types
dirty := dirty ||
tbe.expected_req_resp.receivedDataType(CHIDataType:CompData_UD_PD) ||
tbe.expected_req_resp.receivedDataType(CHIDataType:CompData_SD_PD) ||
tbe.expected_req_resp.receivedDataType(CHIDataType:CBWrData_UD_PD) ||
tbe.expected_req_resp.receivedDataType(CHIDataType:CBWrData_SD_PD) ||
tbe.expected_req_resp.receivedDataType(CHIDataType:NCBWrData) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_I_PD) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_SC_PD) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_SD) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_UD) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_SC_Fwded_SD_PD) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_SC_PD_Fwded_SC) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_I_Fwded_SD_PD) ||
tbe.expected_snp_resp.receivedDataType(CHIDataType:SnpRespData_I_PD_Fwded_SC);
}
} else if (is_valid(cache_entry) &&
((Cache_State_to_permission(cache_entry.state) == AccessPermission:Read_Write) ||
(Cache_State_to_permission(cache_entry.state) == AccessPermission:Read_Only))) {
from_tbe := false;
read_mask.fillMask();
dirty := (cache_entry.state == State:UD) || (cache_entry.state == State:UD_RSC) ||
(cache_entry.state == State:SD) || (cache_entry.state == State:SD_RSC) ||
(cache_entry.state == State:UD_RU) || (cache_entry.state == State:UD_RSD) ||
(cache_entry.state == State:SD_RSD) || (cache_entry.state == State:UD_T);
}
WriteMask test_mask := mask;
test_mask.orMask(read_mask);
if ((mask.containsMask(test_mask) == false) || dirty) {
if (from_tbe) {
if(testAndReadMask(addr, tbe.dataBlk, read_mask, pkt)) {
DPRINTF(RubySlicc, "functionalRead tbe %x %s dirty=%d %s %s\n", addr, tbe.dataBlk, tbe.dataDirty, read_mask, mask);
mask.orMask(read_mask);
}
} else {
if (testAndReadMask(addr, cache_entry.DataBlk, read_mask, pkt)) {
DPRINTF(RubySlicc, "functionalRead cache %x %s dirty=%d %s %s\n", addr, cache_entry.DataBlk, dirty, read_mask, mask);
mask.orMask(read_mask);
}
}
}
}
int functionalWrite(Addr addr, Packet *pkt) {
int num_functional_writes := 0;
TBE tbe := getCurrentActiveTBE(addr);
if(is_valid(tbe)) {
num_functional_writes := num_functional_writes +
testAndWrite(addr, tbe.dataBlk, pkt);
DPRINTF(RubySlicc, "functionalWrite tbe %x %s\n", addr, tbe.dataBlk);
}
CacheEntry cache_entry := getCacheEntry(addr);
if (is_valid(cache_entry)) {
num_functional_writes := num_functional_writes +
testAndWrite(addr, cache_entry.DataBlk, pkt);
DPRINTF(RubySlicc, "functionalWrite cache %x %s\n", addr, cache_entry.DataBlk);
}
return num_functional_writes;
}
Cycles mandatoryQueueLatency(RubyRequestType type) {
return intToCycles(1);
}
Cycles tagLatency(bool from_sequencer) {
if (from_sequencer) {
//mandatoryQueueLatency accounts for 1 cy
return cache.getTagLatency() - intToCycles(1);
} else {
return cache.getTagLatency();
}
}
Cycles dataLatency() {
return cache.getDataLatency();
}
bool inCache(Addr addr) {
CacheEntry entry := getCacheEntry(makeLineAddress(addr));
// NOTE: we consider data for the addr to be in cache if it exists in local,
// upstream, or both caches.
if ((is_valid(entry) == false) || (entry.state == State:I)) {
return false;
} else {
return true;
}
}
bool hasBeenPrefetched(Addr addr) {
CacheEntry entry := getCacheEntry(makeLineAddress(addr));
if (is_valid(entry)) {
return entry.HWPrefetched;
} else {
return false;
}
}
bool inMissQueue(Addr addr) {
Addr line_addr := makeLineAddress(addr);
TBE tbe := getCurrentActiveTBE(line_addr);
return is_valid(tbe);
}
void notifyCoalesced(Addr addr, RubyRequestType type, RequestPtr req,
DataBlock data_blk, bool was_miss) {
DPRINTF(RubySlicc, "notifyCoalesced(addr=%#x, type=%s, was_miss=%d)\n",
addr, type, was_miss);
if (was_miss) {
cache.profileDemandMiss();
} else {
cache.profileDemandHit();
}
if (use_prefetcher) {
bool is_read := (type == RubyRequestType:LD) ||
(type == RubyRequestType:Load_Linked) ||
(type == RubyRequestType:IFETCH);
if (was_miss) {
notifyPfMiss(req, is_read, data_blk);
} else {
notifyPfHit(req, is_read, data_blk);
}
}
}
////////////////////////////////////////////////////////////////////////////
// Helper functions
void clearExpectedReqResp(TBE tbe) {
assert(blockSize >= data_channel_size);
assert((blockSize % data_channel_size) == 0);
tbe.expected_req_resp.clear(blockSize / data_channel_size);
}
void clearExpectedSnpResp(TBE tbe) {
assert(blockSize >= data_channel_size);
assert((blockSize % data_channel_size) == 0);
tbe.expected_snp_resp.clear(blockSize / data_channel_size);
}
void initializeTBE(TBE tbe, Addr addr, int storSlot) {
assert(is_valid(tbe));
tbe.wakeup_pending_req := false;
tbe.wakeup_pending_snp := false;
tbe.wakeup_pending_tgr := false;
tbe.addr := addr;
tbe.storSlot := storSlot;
clearExpectedReqResp(tbe);
clearExpectedSnpResp(tbe);
tbe.defer_expected_comp := false;
tbe.requestorToBeOwner := false;
tbe.requestorToBeExclusiveOwner := false;
tbe.updateDirOnCompAck := true;
tbe.dataToBeInvalid := false;
tbe.dataToBeSharedClean := false;
tbe.doCacheFill := false;
tbe.pendReqType := CHIRequestType:null;
tbe.pendAction := Event:null;
tbe.finalState := State:null;
tbe.delayNextAction := intToTick(0);
tbe.is_stale := false;
}
TBE allocateRequestTBE(Addr addr, CHIRequestMsg in_msg), return_by_pointer="yes" {
// We must have reserved resources for this allocation
storTBEs.decrementReserved();
assert(storTBEs.areNSlotsAvailable(1));
TBEs.allocate(addr);
TBE tbe := TBEs[addr];
initializeTBE(tbe, addr, storTBEs.addEntryToNewSlot());
assert(tbe.is_snp_tbe == false);
assert(tbe.is_repl_tbe == false);
assert(tbe.is_dvm_tbe == false);
assert(tbe.is_dvm_snp_tbe == false);
tbe.is_req_tbe := true;
tbe.accAddr := in_msg.accAddr;
tbe.accSize := in_msg.accSize;
tbe.requestor := in_msg.requestor;
tbe.reqType := in_msg.type;
tbe.isSeqReqValid := in_msg.isSeqReqValid;
tbe.seqReq := in_msg.seqReq;
tbe.is_local_pf := in_msg.is_local_pf;
tbe.is_remote_pf := in_msg.is_remote_pf;
tbe.use_DMT := false;
tbe.use_DCT := false;
tbe.hasUseTimeout := false;
return tbe;
}
TBE allocateDvmRequestTBE(Addr txnId, CHIRequestMsg in_msg), return_by_pointer="yes" {
// We must have reserved resources for this allocation
storDvmTBEs.decrementReserved();
assert(storDvmTBEs.areNSlotsAvailable(1));
dvmTBEs.allocate(txnId);
TBE tbe := dvmTBEs[txnId];
// Setting .addr = txnId
initializeTBE(tbe, txnId, storDvmTBEs.addEntryToNewSlot());
assert(tbe.is_snp_tbe == false);
assert(tbe.is_repl_tbe == false);
assert(tbe.is_req_tbe == false);
assert(tbe.is_dvm_snp_tbe == false);
tbe.is_dvm_tbe := true;
// TODO - zero these out?
tbe.accAddr := txnId;
tbe.accSize := blockSize;
tbe.requestor := in_msg.requestor;
tbe.reqType := in_msg.type;
tbe.isSeqReqValid := in_msg.isSeqReqValid;
tbe.seqReq := in_msg.seqReq;
tbe.is_local_pf := in_msg.is_local_pf;
tbe.is_remote_pf := in_msg.is_remote_pf;
tbe.use_DMT := false;
tbe.use_DCT := false;
tbe.hasUseTimeout := false;
return tbe;
}
TBE allocateSnoopTBE(Addr addr, CHIRequestMsg in_msg), return_by_pointer="yes" {
// We must have reserved resources for this allocation
storSnpTBEs.decrementReserved();
assert(storSnpTBEs.areNSlotsAvailable(1));
snpTBEs.allocate(addr);
TBE tbe := snpTBEs[addr];
initializeTBE(tbe, addr, storSnpTBEs.addEntryToNewSlot());
assert(tbe.is_req_tbe == false);
assert(tbe.is_repl_tbe == false);
assert(tbe.is_dvm_tbe == false);
assert(tbe.is_dvm_snp_tbe == false);
tbe.is_snp_tbe := true;
tbe.accAddr := addr;
tbe.accSize := blockSize;
tbe.requestor := in_msg.requestor;
tbe.fwdRequestor := in_msg.fwdRequestor;
tbe.reqType := in_msg.type;
tbe.snpNeedsData := in_msg.retToSrc;
tbe.use_DMT := false;
tbe.use_DCT := false;
return tbe;
}
TBE allocateDvmSnoopTBE(Addr txnId, CHIRequestMsg in_msg), return_by_pointer="yes" {
// We must have reserved resources for this allocation
storDvmSnpTBEs.decrementReserved();
assert(storDvmSnpTBEs.areNSlotsAvailable(1));
dvmSnpTBEs.allocate(txnId);
TBE tbe := dvmSnpTBEs[txnId];
initializeTBE(tbe, txnId, storDvmSnpTBEs.addEntryToNewSlot());
assert(tbe.is_req_tbe == false);
assert(tbe.is_repl_tbe == false);
assert(tbe.is_dvm_tbe == false);
assert(tbe.is_snp_tbe == false);
tbe.is_dvm_snp_tbe := true;
// TODO - zero these out?
tbe.accAddr := txnId;
tbe.accSize := blockSize;
tbe.requestor := in_msg.requestor;
tbe.fwdRequestor := in_msg.fwdRequestor;
tbe.reqType := in_msg.type;
tbe.snpNeedsData := in_msg.retToSrc;
tbe.use_DMT := false;
tbe.use_DCT := false;
return tbe;
}
TBE _allocateReplacementTBE(Addr addr, int storSlot), return_by_pointer="yes" {
TBE tbe := replTBEs[addr];
initializeTBE(tbe, addr, storSlot);
assert(tbe.is_req_tbe == false);
assert(tbe.is_snp_tbe == false);
assert(tbe.is_dvm_tbe == false);
tbe.is_repl_tbe := true;
tbe.accAddr := addr;
tbe.accSize := blockSize;
tbe.requestor := machineID;
tbe.reqType := CHIRequestType:null;
tbe.use_DMT := false;
tbe.use_DCT := false;
return tbe;
}
TBE allocateReplacementTBE(Addr addr), return_by_pointer="yes" {
// We must have resources for this allocation
assert(storReplTBEs.areNSlotsAvailable(1));
replTBEs.allocate(addr);
return _allocateReplacementTBE(addr, storReplTBEs.addEntryToNewSlot());
}
TBE allocateReplacementTBEOnSlot(Addr addr, int slot), return_by_pointer="yes" {
// only when reusing slot from main TBE table
assert(unify_repl_TBEs);
storTBEs.addEntryToSlot(slot);
replTBEs.allocate(addr);
return _allocateReplacementTBE(addr, slot);
}
TBE getHazardTBE(TBE tbe), return_by_pointer="yes" {
assert(is_valid(tbe));
assert(tbe.is_snp_tbe);
TBE hazard_tbe := TBEs[tbe.addr];
if (tbe.is_req_hazard) {
assert(tbe.is_repl_hazard == false);
} else {
assert(tbe.is_repl_hazard);
hazard_tbe := replTBEs[tbe.addr];
}
assert(is_valid(hazard_tbe));
return hazard_tbe;
}
void scheduleSendData(TBE tbe, int when) {
if (tbe.snd_pendBytes.count() > 0) {
assert(tbe.snd_pendEv == false);
tbe.snd_pendEv := true;
// enqueue send event
tbe.pendAction := Event:TX_Data;
enqueue(triggerOutPort, TriggerMsg, intToCycles(when)) {
out_msg.addr := tbe.addr;
out_msg.from_hazard := tbe.is_req_hazard || tbe.is_repl_hazard;
}
}
}
void setupPendingSend(TBE tbe) {
assert(blockSize >= data_channel_size);
assert((blockSize % data_channel_size) == 0);
// data must be complete in the TBE
assert(tbe.dataBlkValid.isFull());
tbe.snd_pendBytes.fillMask();
scheduleSendData(tbe, 0);
}
void setupPendingPartialSend(TBE tbe) {
assert(blockSize >= data_channel_size);
assert((blockSize % data_channel_size) == 0);
// data must be complete in the TBE
assert(tbe.dataBlkValid.count() > 0);
tbe.snd_pendBytes := tbe.dataBlkValid;
scheduleSendData(tbe, 0);
}
// common code for downstream requests
void prepareRequest(TBE tbe, CHIRequestType type, CHIRequestMsg & out_msg) {
out_msg.addr := tbe.addr;
out_msg.accAddr := tbe.addr;
out_msg.accSize := blockSize;
out_msg.requestor := machineID;
out_msg.fwdRequestor := tbe.requestor;
out_msg.type := type;
out_msg.allowRetry := false;
tbe.pendReqAllowRetry := false;
tbe.rcvdRetryAck := false;
tbe.rcvdRetryCredit := false;
tbe.pendReqType := type;
out_msg.isSeqReqValid := tbe.isSeqReqValid;
out_msg.seqReq := tbe.seqReq;
out_msg.is_local_pf := false;
out_msg.is_remote_pf := tbe.is_local_pf || tbe.is_remote_pf;
}
void allowRequestRetry(TBE tbe, CHIRequestMsg & out_msg) {
out_msg.allowRetry := true;
tbe.pendReqAllowRetry := true;
tbe.pendReqAccAddr := out_msg.accAddr;
tbe.pendReqAccSize := out_msg.accSize;
tbe.pendReqDest := out_msg.Destination;
tbe.pendReqD2OrigReq := out_msg.dataToFwdRequestor;
tbe.pendReqRetToSrc := out_msg.retToSrc;
}
void prepareRequestRetry(TBE tbe, CHIRequestMsg & out_msg) {
assert(tbe.pendReqAllowRetry);
tbe.pendReqAllowRetry := false;
out_msg.allowRetry := false;
out_msg.addr := tbe.addr;
out_msg.requestor := machineID;
out_msg.fwdRequestor := tbe.requestor;
out_msg.accAddr := tbe.pendReqAccAddr;
out_msg.accSize := tbe.pendReqAccSize;
out_msg.type := tbe.pendReqType;
out_msg.Destination := tbe.pendReqDest;
out_msg.dataToFwdRequestor := tbe.pendReqD2OrigReq;
out_msg.retToSrc := tbe.pendReqRetToSrc;
out_msg.isSeqReqValid := tbe.isSeqReqValid;
out_msg.seqReq := tbe.seqReq;
out_msg.is_local_pf := false;
out_msg.is_remote_pf := tbe.is_local_pf || tbe.is_remote_pf;
}
void prepareRequestRetryDVM(TBE tbe, CHIRequestMsg & out_msg) {
assert(tbe.pendReqAllowRetry);
tbe.pendReqAllowRetry := false;
out_msg.allowRetry := false;
out_msg.addr := tbe.addr;
out_msg.usesTxnId := true;
out_msg.txnId := tbe.addr;
out_msg.requestor := machineID;
out_msg.fwdRequestor := tbe.requestor;
out_msg.accAddr := tbe.pendReqAccAddr;
out_msg.accSize := tbe.pendReqAccSize;
out_msg.type := tbe.pendReqType;
out_msg.Destination := tbe.pendReqDest;
out_msg.dataToFwdRequestor := tbe.pendReqD2OrigReq;
out_msg.retToSrc := tbe.pendReqRetToSrc;
out_msg.isSeqReqValid := tbe.isSeqReqValid;
out_msg.seqReq := tbe.seqReq;
out_msg.is_local_pf := false;
out_msg.is_remote_pf := tbe.is_local_pf || tbe.is_remote_pf;
}
void enqueueDoRetry(TBE tbe) {
if (tbe.rcvdRetryAck && tbe.rcvdRetryCredit) {
enqueue(retryTriggerOutPort, RetryTriggerMsg, 0) {
out_msg.addr := tbe.addr;
out_msg.usesTxnId := tbe.is_dvm_tbe || tbe.is_dvm_snp_tbe;
out_msg.event := Event:DoRetry;
}
destsWaitingRetry.removeNetDest(tbe.pendReqDest);
}
}
void processRetryQueue() {
// send credit if requestor waiting for it and we have resources
bool has_avail := storTBEs.areNSlotsAvailable(1);
assert(unify_repl_TBEs || has_avail);
// the slot might still be used by a replacement if unify_repl_TBEs is set
if (retryQueue.empty() == false && has_avail) {
storTBEs.incrementReserved();
RetryQueueEntry e := retryQueue.next();
retryQueue.pop();
enqueue(retryTriggerOutPort, RetryTriggerMsg, 0) {
out_msg.addr := e.addr;
out_msg.usesTxnId := e.usesTxnId;
out_msg.retryDest := e.retryDest;
out_msg.event := Event:SendPCrdGrant;
}
}
}
void printResources() {
if (unify_repl_TBEs) {
assert(storReplTBEs.size() == 0);
assert(storReplTBEs.reserved() == 0);
DPRINTF(RubySlicc, "Resources(used/rsvd/max): TBEs=%d/%d/%d snpTBEs=%d/%d/%d replTBEs=%d/%d/%d dvmTBEs=%d/%d/%d\n",
storTBEs.size(), storTBEs.reserved(), storTBEs.capacity(),
storSnpTBEs.size(), storSnpTBEs.reserved(), storSnpTBEs.capacity(),
storTBEs.size(), storTBEs.reserved(), storTBEs.capacity(),
storDvmTBEs.size(), storDvmTBEs.reserved(), storDvmTBEs.capacity());
} else {
DPRINTF(RubySlicc, "Resources(used/rsvd/max): TBEs=%d/%d/%d snpTBEs=%d/%d/%d replTBEs=%d/%d/%d dvmTBEs=%d/%d/%d\n",
storTBEs.size(), storTBEs.reserved(), storTBEs.capacity(),
storSnpTBEs.size(), storSnpTBEs.reserved(), storSnpTBEs.capacity(),
storReplTBEs.size(), storReplTBEs.reserved(), storReplTBEs.capacity(),
storDvmTBEs.size(), storDvmTBEs.reserved(), storDvmTBEs.capacity());
}
DPRINTF(RubySlicc, "Resources(in/out size): req=%d/%d rsp=%d/%d dat=%d/%d snp=%d/%d trigger=%d\n",
reqIn.getSize(curTick()), reqOut.getSize(curTick()),
rspIn.getSize(curTick()), rspOut.getSize(curTick()),
datIn.getSize(curTick()), datOut.getSize(curTick()),
snpIn.getSize(curTick()), snpOut.getSize(curTick()),
triggerQueue.getSize(curTick()));
}
bool needCacheEntry(CHIRequestType req_type,
CacheEntry cache_entry, DirEntry dir_entry,
bool is_prefetch) {
// never allocates:
// - if entry already valid
// - if using DMT; the request is a Read*; and dir entry is invalid
// oterwise follow config params
if (is_valid(cache_entry) ||
(enable_DMT && is_invalid(dir_entry) &&
((req_type == CHIRequestType:ReadShared) ||
(req_type == CHIRequestType:ReadUnique) ||
(req_type == CHIRequestType:ReadOnce)))) {
return false;
} else {
return is_prefetch ||
(alloc_on_readshared && ((req_type == CHIRequestType:ReadShared) ||
(req_type == CHIRequestType:ReadNotSharedDirty))) ||
(alloc_on_readunique && (req_type == CHIRequestType:ReadUnique)) ||
(alloc_on_readonce && (req_type == CHIRequestType:ReadOnce)) ||
(alloc_on_writeback && ((req_type == CHIRequestType:WriteBackFull) ||
(req_type == CHIRequestType:WriteCleanFull) ||
(req_type == CHIRequestType:WriteEvictFull) ||
(is_HN && (req_type == CHIRequestType:WriteUniqueFull)))) ||
(alloc_on_seq_acc && ((req_type == CHIRequestType:Load) ||
(req_type == CHIRequestType:Store))) ||
(alloc_on_seq_line_write && (req_type == CHIRequestType:StoreLine));
}
}
bool needDeallocCacheEntry(CHIRequestType req_type) {
return (dealloc_on_shared && ((req_type == CHIRequestType:ReadShared) ||
(req_type == CHIRequestType:ReadNotSharedDirty))) ||
(dealloc_on_unique && ((req_type == CHIRequestType:ReadUnique) ||
(req_type == CHIRequestType:CleanUnique)));
}
bool upstreamHasUnique(State state) {
return (state == State:RU) || (state == State:UD_RU) || (state == State:UC_RU);
}
bool upstreamHasShared(State state) {
return (state == State:RSC) || (state == State:RSD) ||
(state == State:RUSD) || (state == State:RUSC) ||
(state == State:UD_RSD) || (state == State:SD_RSD) ||
(state == State:UD_RSC) || (state == State:SD_RSC) ||
(state == State:UC_RSC) || (state == State:SC_RSC);
}
void printTBEState(TBE tbe) {
DPRINTF(RubySlicc, "STATE: addr: %#x data present=%d valid=%d unique=%d dirty=%d mu_dirty=%d dir ownerV=%d ownerE=%d sharers=%d tobe_I=%d tobe_SC=%d doFill=%d pendAction=%s\n",
tbe.addr, tbe.dataBlkValid.isFull(), tbe.dataValid, tbe.dataUnique,
tbe.dataDirty, tbe.dataMaybeDirtyUpstream, tbe.dir_ownerExists,
tbe.dir_ownerIsExcl,tbe.dir_sharers.count(),
tbe.dataToBeInvalid, tbe.dataToBeSharedClean,
tbe.doCacheFill, tbe.pendAction);
DPRINTF(RubySlicc, "dataBlkValid = %s\n", tbe.dataBlkValid);
}
void printDvmTBEState(TBE tbe) {
DPRINTF(RubySlicc, "STATE: addr=%#x reqType=%d state=%d pendAction=%s isDvmTBE=%d isReplTBE=%d isReqTBE=%d isSnpTBE=%d\n",
tbe.addr, tbe.reqType, tbe.state, tbe.pendAction,
tbe.is_dvm_tbe, tbe.is_repl_tbe, tbe.is_req_tbe, tbe.is_snp_tbe);
}
MachineID getMiscNodeMachine() {
// return the MachineID of the misc node
return mapAddressToMachine(intToAddress(0), MachineType:MiscNode);
}
void copyCacheAndDir(CacheEntry cache_entry, DirEntry dir_entry,
TBE tbe, State initialState) {
assert(is_valid(tbe));
// have dir entry
if (is_valid(dir_entry)) {
assert((initialState == State:UD_RSC) || (initialState == State:SD_RSC) ||
(initialState == State:UC_RSC) || (initialState == State:SC_RSC) ||
(initialState == State:UD_RU) || (initialState == State:UC_RU) ||
(initialState == State:RU) || (initialState == State:RSC) ||
(initialState == State:RSD) || (initialState == State:RUSD) ||
(initialState == State:RUSC) ||
(initialState == State:UD_RSD) || (initialState == State:SD_RSD));
tbe.dir_sharers := dir_entry.sharers;
tbe.dir_owner := dir_entry.owner;
tbe.dir_ownerExists := dir_entry.ownerExists;
tbe.dir_ownerIsExcl := dir_entry.ownerIsExcl;
assert(tbe.dir_sharers.count() > 0);
} else {
tbe.dir_sharers.clear();
tbe.dir_ownerExists := false;
}
// Sanity checks
assert((tbe.dir_ownerExists && tbe.dir_ownerIsExcl) ==
((initialState == State:UD_RU) || (initialState == State:UC_RU) ||
(initialState == State:RU)));
assert((tbe.dir_ownerExists && (tbe.dir_ownerIsExcl == false)) ==
((initialState == State:RSD) || (initialState == State:RUSD) ||
(initialState == State:UD_RSD) || (initialState == State:SD_RSD)));
// have usable data
if (is_valid(cache_entry) &&
((initialState == State:UD) || (initialState == State:SD) ||
(initialState == State:UC) || (initialState == State:SC) ||
(initialState == State:UD_RSC) || (initialState == State:SD_RSC) ||
(initialState == State:UC_RSC) || (initialState == State:SC_RSC) ||
(initialState == State:UD_RSD) || (initialState == State:SD_RSD) ||
(initialState == State:UD_T))) {
tbe.dataBlk := cache_entry.DataBlk;
tbe.dataBlkValid.fillMask();
tbe.dataValid := true;
DPRINTF(RubySlicc, "Cached data %s\n", tbe.dataBlk);
} else {
assert(is_invalid(cache_entry) ||
(is_valid(cache_entry) && (initialState == State:UD_RU) ||
(initialState == State:UC_RU)));
tbe.dataBlkValid.clear();
tbe.dataValid := false;
}
// set MRU for accessed block
if (is_valid(cache_entry) && ((tbe.is_local_pf || tbe.is_remote_pf) == false)) {
cache.setMRU(cache_entry);
}
// data is dirty here
tbe.dataDirty := (initialState == State:UD) || (initialState == State:UD_RSC) ||
(initialState == State:SD) || (initialState == State:SD_RSC) ||
(initialState == State:UD_RU) || (initialState == State:UD_RSD) ||
(initialState == State:SD_RSD) || (initialState == State:UD_T);
// maybe dirty upstream
tbe.dataMaybeDirtyUpstream := (initialState == State:UD_RU) || (initialState == State:UC_RU) ||
(initialState == State:UD_RSD) || (initialState == State:SD_RSD) ||
(initialState == State:RU) || (initialState == State:RSD) ||
(initialState == State:RUSD);
assert(tbe.dir_ownerExists == tbe.dataMaybeDirtyUpstream);
// data is unique here or upstream
tbe.dataUnique := (initialState == State:UD) || (initialState == State:UD_RSC) ||
(initialState == State:UD_RU) || (initialState == State:UC) ||
(initialState == State:UC_RSC) || (initialState == State:UC_RU) ||
(initialState == State:RU) || (initialState == State:RUSD) ||
(initialState == State:RUSC) ||
(initialState == State:UD_RSD) || (initialState == State:UD_T);
// it is locked until timeout ?
tbe.hasUseTimeout := initialState == State:UD_T;
tbe.dataToBeSharedClean := false;
tbe.dataToBeInvalid := false;
printTBEState(tbe);
}
void copyCacheAndDirTBEs(TBE src, TBE dst) {
assert(is_valid(src));
assert(is_valid(dst));
dst.dataBlk := src.dataBlk;
dst.dataBlkValid := src.dataBlkValid;
dst.dataValid := src.dataValid;
dst.dataDirty := src.dataDirty;
dst.dataMaybeDirtyUpstream := src.dataMaybeDirtyUpstream;
dst.dataUnique := src.dataUnique;
dst.dir_sharers := src.dir_sharers;
dst.dir_owner := src.dir_owner;
dst.dir_ownerExists := src.dir_ownerExists;
dst.dir_ownerIsExcl := src.dir_ownerIsExcl;
printTBEState(dst);
}
void deallocateReqTBE(TBE tbe) {
assert(is_valid(tbe));
assert(tbe.is_req_tbe);
storTBEs.removeEntryFromSlot(tbe.storSlot);
TBEs.deallocate(tbe.addr);
}
void deallocateSnpTBE(TBE tbe) {
assert(is_valid(tbe));
assert(tbe.is_snp_tbe);
storSnpTBEs.removeEntryFromSlot(tbe.storSlot);
snpTBEs.deallocate(tbe.addr);
}
void deallocateReplacementTBE(TBE tbe) {
assert(is_valid(tbe));
assert(tbe.is_repl_tbe);
if (unify_repl_TBEs) {
storTBEs.removeEntryFromSlot(tbe.storSlot);
} else {
storReplTBEs.removeEntryFromSlot(tbe.storSlot);
}
replTBEs.deallocate(tbe.addr);
}
void deallocateDvmTBE(TBE tbe) {
assert(is_valid(tbe));
assert(tbe.is_dvm_tbe);
storDvmTBEs.removeEntryFromSlot(tbe.storSlot);
dvmTBEs.deallocate(tbe.addr);
}
void deallocateDvmSnoopTBE(TBE tbe) {
assert(is_valid(tbe));
assert(tbe.is_dvm_snp_tbe);
storDvmSnpTBEs.removeEntryFromSlot(tbe.storSlot);
dvmSnpTBEs.deallocate(tbe.addr);
}
void setDataToBeStates(TBE tbe) {
assert(is_valid(tbe));
if (tbe.dataToBeInvalid) {
tbe.dataValid := false;
tbe.dataBlkValid.clear();
}
if (tbe.dataToBeSharedClean) {
tbe.dataUnique := false;
tbe.dataDirty := false;
assert(tbe.dataMaybeDirtyUpstream == false);
}
tbe.dataToBeInvalid := false;
tbe.dataToBeSharedClean := false;
}
void setExpectedForInvSnoop(TBE tbe, bool expectCleanWB) {
assert(tbe.expected_snp_resp.hasExpected() == false);
assert(tbe.dir_sharers.count() > 0);
clearExpectedSnpResp(tbe);
if (expectCleanWB) {
tbe.expected_snp_resp.addExpectedDataType(CHIDataType:SnpRespData_I);
}
if (tbe.dataMaybeDirtyUpstream) {
assert(tbe.dir_ownerExists);
tbe.expected_snp_resp.addExpectedDataType(CHIDataType:SnpRespData_I_PD);
if ((expectCleanWB == false) || (tbe.dir_sharers.count() > 1)) {
tbe.expected_snp_resp.addExpectedRespType(CHIResponseType:SnpResp_I);
}
} else {
tbe.expected_snp_resp.addExpectedRespType(CHIResponseType:SnpResp_I);
}
tbe.expected_snp_resp.setExpectedCount(tbe.dir_sharers.count());
}
State makeFinalStateHelper(State cs, State ds) {
if (ds == State:RSC) {
if (cs == State:UD) {
return State:UD_RSC;
} else if (cs == State:SD) {
return State:SD_RSC;
} else if (cs == State:UC) {
return State:UC_RSC;
} else if (cs == State:SC) {
return State:SC_RSC;
} else {
return State:RSC;
}
} else if (ds == State:RU) {
if (cs == State:UD) {
return State:UD_RU;
} else if (cs == State:UC) {
return State:UC_RU;
} else {
assert(cs != State:SC);
assert(cs != State:SD);
return State:RU;
}
} else if (ds == State:RSD) {
if (cs == State:UD) {
return State:UD_RSD;
} else if (cs == State:SD) {
return State:SD_RSD;
} else {
assert(cs == State:I);
return State:RSD;
}
} else if (ds == State:RUSD) {
if (cs == State:UD) {
return State:UD_RSD;
} else {
assert(cs == State:I);
return State:RUSD;
}
} else if (ds == State:RUSC) {
if (cs == State:UC) {
return State:UC_RSC;
} else if (cs == State:UD) {
return State:UD_RSC;
} else {
assert(cs == State:I);
return State:RUSC;
}
} else {
assert(ds == State:I);
return cs;
}
}
State makeFinalState(TBE tbe, CacheEntry cache_entry, DirEntry dir_entry) {
setDataToBeStates(tbe);
printTBEState(tbe);
State cache_state := State:I;
State dir_state := State:I;
if (tbe.dir_ownerExists) {
assert(is_valid(dir_entry));
assert(tbe.dataMaybeDirtyUpstream);
if (tbe.dir_ownerIsExcl) {
assert(tbe.dir_sharers.count() == 1);
dir_state := State:RU;
} else {
assert(tbe.dir_sharers.count() >= 1);
if (tbe.dataUnique) {
dir_state := State:RUSD;
} else {
dir_state := State:RSD;
}
}
} else if (tbe.dir_sharers.count() > 0) {
assert(is_valid(dir_entry));
assert(tbe.dataMaybeDirtyUpstream == false);
if (tbe.dataUnique) {
dir_state := State:RUSC;
} else {
dir_state := State:RSC;
}
}
if (tbe.dataValid && is_valid(cache_entry)) {
if (tbe.dataUnique && tbe.dataDirty) {
if (tbe.hasUseTimeout) {
cache_state := State:UD_T;
} else {
cache_state := State:UD;
}
} else if (tbe.dataUnique && (tbe.dataDirty == false)) {
cache_state := State:UC;
} else if ((tbe.dataUnique == false) && tbe.dataDirty) {
assert(allow_SD);
cache_state := State:SD;
} else {
cache_state := State:SC;
}
}
return makeFinalStateHelper(cache_state, dir_state);
}
// This is used only with the finalization transitions
State getNextState(Addr address) {
TBE tbe := getCurrentActiveTBE(address);
assert(is_valid(tbe));
assert(tbe.pendAction == Event:Final);
tbe.finalState := makeFinalState(tbe, getCacheEntry(address), getDirEntry(address));
assert(tbe.finalState != State:null);
return tbe.finalState;
}
int scLockLatency() {
return sc_lock_multiplier * sc_lock_base_latency_cy;
}
void scLockIncLatency()
{
sc_lock_multiplier := sc_lock_multiplier + sc_lock_multiplier_inc;
if (sc_lock_multiplier > sc_lock_multiplier_max) {
sc_lock_multiplier := sc_lock_multiplier_max;
}
DPRINTF(LLSC, "SC lock latency increased to %d cy\n", scLockLatency());
}
void scLockDecayLatency()
{
sc_lock_multiplier := sc_lock_multiplier - sc_lock_multiplier_decay;
if (sc_lock_multiplier < 0) {
sc_lock_multiplier := 0;
}
DPRINTF(LLSC, "SC lock latency decayed to %d cy\n", scLockLatency());
}
void clearPendingAction(TBE tbe) {
// only clear pendAction if snd_pendEv not set
if (tbe.snd_pendEv) {
assert(tbe.pendAction == Event:TX_Data);
} else {
tbe.pendAction := Event:null;
}
}
bool isReadReqType(CHIRequestType type) {
if (type == CHIRequestType:Load ||
type == CHIRequestType:ReadShared ||
type == CHIRequestType:ReadNotSharedDirty ||
type == CHIRequestType:ReadOnce) {
return true;
}
return false;
}
bool isWriteReqType(CHIRequestType type) {
if (type == CHIRequestType:Store ||
type == CHIRequestType:StoreLine ||
type == CHIRequestType:WriteUniquePtl ||
type == CHIRequestType:WriteUniqueFull ||
type == CHIRequestType:ReadUnique) {
return true;
}
return false;
}
////////////////////////////////////////////////////////////////////////////
// State->Event converters
Event reqToEvent(CHIRequestType type, bool is_prefetch) {
if (type == CHIRequestType:Load) {
if (is_prefetch == false) {
return Event:Load;
} else {
return Event:Prefetch;
}
} else if (type == CHIRequestType:Store) {
return Event:Store;
} else if (type == CHIRequestType:StoreLine) {
return Event:Store;
} else if (type == CHIRequestType:ReadShared) {
return Event:ReadShared;
} else if (type == CHIRequestType:ReadNotSharedDirty) {
return Event:ReadNotSharedDirty;
} else if (type == CHIRequestType:ReadUnique) {
if (is_HN) {
return Event:ReadUnique_PoC;
} else {
return Event:ReadUnique;
}
} else if (type == CHIRequestType:CleanUnique) {
return Event:CleanUnique;
} else if (type == CHIRequestType:ReadOnce) {
return Event:ReadOnce;
} else if (type == CHIRequestType:Evict) {
return Event:Evict;
} else if (type == CHIRequestType:WriteBackFull) {
return Event:WriteBackFull;
} else if (type == CHIRequestType:WriteEvictFull) {
return Event:WriteEvictFull;
} else if (type == CHIRequestType:WriteCleanFull) {
return Event:WriteCleanFull;
} else if (type == CHIRequestType:WriteUniquePtl) {
if (is_HN) {
return Event:WriteUniquePtl_PoC;
} else {
return Event:WriteUnique; // all WriteUnique handled the same when ~PoC
}
} else if (type == CHIRequestType:WriteUniqueFull) {
if (is_HN && alloc_on_writeback) {
return Event:WriteUniqueFull_PoC_Alloc;
} else if (is_HN) {
return Event:WriteUniqueFull_PoC;
} else {
return Event:WriteUnique; // all WriteUnique handled the same when ~PoC
}
} else if (type == CHIRequestType:DvmTlbi_Initiate) {
return Event:DvmTlbi_Initiate;
} else if (type == CHIRequestType:DvmSync_Initiate) {
return Event:DvmSync_Initiate;
} else {
error("Invalid CHIRequestType");
}
}
Event respToEvent (CHIResponseType type, TBE tbe) {
bool on_hazard := is_valid(tbe) && (tbe.is_req_hazard || tbe.is_repl_hazard);
if (type == CHIResponseType:Comp_I) {
return Event:Comp_I;
} else if (type == CHIResponseType:Comp_UC) {
return Event:Comp_UC;
} else if (type == CHIResponseType:Comp_SC) {
return Event:Comp_SC;
} else if (type == CHIResponseType:CompDBIDResp) {
return Event:CompDBIDResp;
} else if (type == CHIResponseType:DBIDResp) {
return Event:DBIDResp;
} else if (type == CHIResponseType:Comp) {
return Event:Comp;
} else if (type == CHIResponseType:CompAck) {
return Event:CompAck;
} else if (type == CHIResponseType:ReadReceipt) {
return Event:ReadReceipt;
} else if (type == CHIResponseType:RespSepData) {
return Event:RespSepData;
} else if (type == CHIResponseType:SnpResp_I) {
return Event:SnpResp_I;
} else if (type == CHIResponseType:SnpResp_I_Fwded_UC) {
return Event:SnpResp_I_Fwded_UC;
} else if (type == CHIResponseType:SnpResp_I_Fwded_UD_PD) {
return Event:SnpResp_I_Fwded_UD_PD;
} else if (type == CHIResponseType:SnpResp_SC) {
return Event:SnpResp_SC;
} else if (type == CHIResponseType:SnpResp_SC_Fwded_SC) {
return Event:SnpResp_SC_Fwded_SC;
} else if (type == CHIResponseType:SnpResp_SC_Fwded_SD_PD) {
return Event:SnpResp_SC_Fwded_SD_PD;
} else if (type == CHIResponseType:SnpResp_SD_Fwded_I) {
return Event:SnpResp_SD_Fwded_I;
} else if (type == CHIResponseType:SnpResp_SC_Fwded_I) {
return Event:SnpResp_SC_Fwded_I;
} else if (type == CHIResponseType:SnpResp_UD_Fwded_I) {
return Event:SnpResp_UD_Fwded_I;
} else if (type == CHIResponseType:SnpResp_UC_Fwded_I) {
return Event:SnpResp_UC_Fwded_I;
} else if (type == CHIResponseType:RetryAck) {
if (is_HN) {
if (on_hazard) {
return Event:RetryAck_PoC_Hazard;
} else {
return Event:RetryAck_PoC;
}
} else {
if (on_hazard) {
return Event:RetryAck_Hazard;
} else {
return Event:RetryAck;
}
}
} else if (type == CHIResponseType:PCrdGrant) {
if (is_HN) {
if (on_hazard) {
return Event:PCrdGrant_PoC_Hazard;
} else {
return Event:PCrdGrant_PoC;
}
} else {
if (on_hazard) {
return Event:PCrdGrant_Hazard;
} else {
return Event:PCrdGrant;
}
}
} else {
error("Invalid CHIResponseType");
}
}
Event dataToEvent (CHIDataType type) {
if (type == CHIDataType:CompData_I) {
return Event:CompData_I;
} else if (type == CHIDataType:CompData_UC) {
return Event:CompData_UC;
} else if (type == CHIDataType:CompData_SC) {
return Event:CompData_SC;
} else if (type == CHIDataType:CompData_UD_PD) {
return Event:CompData_UD_PD;
} else if (type == CHIDataType:CompData_SD_PD) {
return Event:CompData_SD_PD;
} else if (type == CHIDataType:DataSepResp_UC) {
return Event:DataSepResp_UC;
} else if (type == CHIDataType:CBWrData_I) {
return Event:CBWrData_I;
} else if (type == CHIDataType:CBWrData_UC) {
return Event:CBWrData_UC;
} else if (type == CHIDataType:CBWrData_SC) {
return Event:CBWrData_SC;
} else if (type == CHIDataType:CBWrData_UD_PD) {
return Event:CBWrData_UD_PD;
} else if (type == CHIDataType:CBWrData_SD_PD) {
return Event:CBWrData_SD_PD;
} else if (type == CHIDataType:NCBWrData) {
return Event:NCBWrData;
} else if (type == CHIDataType:SnpRespData_I_PD) {
return Event:SnpRespData_I_PD;
} else if (type == CHIDataType:SnpRespData_I) {
return Event:SnpRespData_I;
} else if (type == CHIDataType:SnpRespData_SC_PD) {
return Event:SnpRespData_SC_PD;
} else if (type == CHIDataType:SnpRespData_SC) {
return Event:SnpRespData_SC;
} else if (type == CHIDataType:SnpRespData_SD) {
return Event:SnpRespData_SD;
} else if (type == CHIDataType:SnpRespData_UC) {
return Event:SnpRespData_UC;
} else if (type == CHIDataType:SnpRespData_UD) {
return Event:SnpRespData_UD;
} else if (type == CHIDataType:SnpRespData_SC_Fwded_SC) {
return Event:SnpRespData_SC_Fwded_SC;
} else if (type == CHIDataType:SnpRespData_SC_Fwded_SD_PD) {
return Event:SnpRespData_SC_Fwded_SD_PD;
} else if (type == CHIDataType:SnpRespData_SC_PD_Fwded_SC) {
return Event:SnpRespData_SC_PD_Fwded_SC;
} else if (type == CHIDataType:SnpRespData_I_Fwded_SD_PD) {
return Event:SnpRespData_I_Fwded_SD_PD;
} else if (type == CHIDataType:SnpRespData_I_PD_Fwded_SC) {
return Event:SnpRespData_I_PD_Fwded_SC;
} else if (type == CHIDataType:SnpRespData_I_Fwded_SC) {
return Event:SnpRespData_I_Fwded_SC;
} else {
error("Invalid CHIDataType");
}
}
Event snpToEvent (CHIRequestType type) {
if (type == CHIRequestType:SnpCleanInvalid) {
return Event:SnpCleanInvalid;
} else if (type == CHIRequestType:SnpShared) {
return Event:SnpShared;
} else if (type == CHIRequestType:SnpUnique) {
return Event:SnpUnique;
} else if (type == CHIRequestType:SnpSharedFwd) {
return Event:SnpSharedFwd;
} else if (type == CHIRequestType:SnpNotSharedDirtyFwd) {
return Event:SnpNotSharedDirtyFwd;
} else if (type == CHIRequestType:SnpUniqueFwd) {
return Event:SnpUniqueFwd;
} else if (type == CHIRequestType:SnpOnce) {
return Event:SnpOnce;
} else if (type == CHIRequestType:SnpOnceFwd) {
return Event:SnpOnceFwd;
} else if (type == CHIRequestType:SnpDvmOpSync_P1) {
return Event:SnpDvmOpSync_P1;
} else if (type == CHIRequestType:SnpDvmOpSync_P2) {
return Event:SnpDvmOpSync_P2;
} else if (type == CHIRequestType:SnpDvmOpNonSync_P1) {
return Event:SnpDvmOpNonSync_P1;
} else if (type == CHIRequestType:SnpDvmOpNonSync_P2) {
return Event:SnpDvmOpNonSync_P2;
} else {
error("Invalid CHIRequestType");
}
}
//////////////////////////////////////////
// Cache bank utilization tracking
enumeration(RequestType, desc="To communicate stats from transitions to recordStats") {
TagArrayRead, desc="Read or write the dir/cache tag/data array";
TagArrayWrite, desc="Read or write the dir/cache tag/data array";
DataArrayRead, desc="Read or write the dir/cache tag/data array";
DataArrayWrite, desc="Read or write the dir/cache tag/data array";
DestinationAvailable, desc="Check if there is a pending retry from the destination";
ReplTBEAvailable, desc="Check if a replacement TBE is available";
}
void recordRequestType(RequestType request_type, Addr addr) {
if (request_type == RequestType:DataArrayRead) {
cache.recordRequestType(CacheRequestType:DataArrayRead, addr);
} else if (request_type == RequestType:DataArrayWrite) {
cache.recordRequestType(CacheRequestType:DataArrayWrite, addr);
} else if (request_type == RequestType:TagArrayRead) {
cache.recordRequestType(CacheRequestType:TagArrayRead, addr);
} else if (request_type == RequestType:TagArrayWrite) {
cache.recordRequestType(CacheRequestType:TagArrayWrite, addr);
}
}
bool _checkResourceAvailable(RequestType request_type, Addr addr) {
if (request_type == RequestType:DataArrayRead) {
return cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:DataArrayWrite) {
return cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:TagArrayRead) {
return cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:TagArrayWrite) {
return cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:DestinationAvailable) {
if (throttle_req_on_retry) {
MachineID dest := mapAddressToDownstreamMachine(addr);
DPRINTF(RubySlicc, "Checking %s for addr %#x dest %s\n", request_type, addr, dest);
return destsWaitingRetry.isElement(dest) == false;
} else {
return true;
}
} else if (request_type == RequestType:ReplTBEAvailable) {
// if unify_repl_TBEs the replacement uses the same slot as the request
// that initiated it, so the resource is always available
return unify_repl_TBEs || storReplTBEs.areNSlotsAvailable(1);
} else {
error("Invalid RequestType type in checkResourceAvailable");
return true;
}
}
bool checkResourceAvailable(RequestType request_type, Addr addr) {
bool avail := _checkResourceAvailable(request_type, addr);
if (avail == false) {
DPRINTF(RubySlicc, "Resource %s not available for addr: %#x\n", request_type, addr);
}
return avail;
}