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gem5 / testing / jenkins-gem5-prod / 4fc7dfb7fbcf124461adc9df382695418a2b9dda / . / src / mem / protocol / MOESI_AMD_Base-Region-CorePair.sm
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/*
* Copyright (c) 2010-2015 Advanced Micro Devices, Inc.
* All rights reserved.
*
* For use for simulation and test purposes only
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. 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.
*
* 3. Neither the name of the copyright holder 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 HOLDER 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: Lisa Hsu
*/
machine(MachineType:CorePair, "CP-like Core Coherence")
: Sequencer * sequencer;
Sequencer * sequencer1;
CacheMemory * L1Icache;
CacheMemory * L1D0cache;
CacheMemory * L1D1cache;
CacheMemory * L2cache;
int regionBufferNum;
bool send_evictions := "False";
Cycles issue_latency := 5;
Cycles l2_hit_latency := 18;
// BEGIN Core Buffers
// To the Network
MessageBuffer * requestFromCore, network="To", virtual_network="0", ordered="true", vnet_type="request";
MessageBuffer * responseFromCore, network="To", virtual_network="2", ordered="false", vnet_type="response";
MessageBuffer * unblockFromCore, network="To", virtual_network="4", ordered="false", vnet_type="unblock";
// From the Network
MessageBuffer * probeToCore, network="From", virtual_network="0", ordered="false", vnet_type="request";
MessageBuffer * responseToCore, network="From", virtual_network="2", ordered="false", vnet_type="response";
MessageBuffer * mandatoryQueue, ordered="false";
MessageBuffer * triggerQueue, ordered="true";
// END Core Buffers
{
// BEGIN STATES
state_declaration(State, desc="Cache states", default="CorePair_State_I") {
I, AccessPermission:Invalid, desc="Invalid";
S, AccessPermission:Read_Only, desc="Shared";
E0, AccessPermission:Read_Write, desc="Exclusive with Cluster 0 ownership";
E1, AccessPermission:Read_Write, desc="Exclusive with Cluster 1 ownership";
Es, AccessPermission:Read_Write, desc="Exclusive in core";
O, AccessPermission:Read_Only, desc="Owner state in core, both clusters and other cores may be sharing line";
Ms, AccessPermission:Read_Write, desc="Modified in core, both clusters may be sharing line";
M0, AccessPermission:Read_Write, desc="Modified with cluster ownership";
M1, AccessPermission:Read_Write, desc="Modified with cluster ownership";
// Transient States
I_M0, AccessPermission:Busy, desc="Invalid, issued RdBlkM, have not seen response yet";
I_M1, AccessPermission:Busy, desc="Invalid, issued RdBlkM, have not seen response yet";
I_M0M1, AccessPermission:Busy, desc="Was in I_M0, got a store request from other cluster as well";
I_M1M0, AccessPermission:Busy, desc="Was in I_M1, got a store request from other cluster as well";
I_M0Ms, AccessPermission:Busy, desc="Was in I_M0, got a load request from other cluster as well";
I_M1Ms, AccessPermission:Busy, desc="Was in I_M1, got a load request from other cluster as well";
I_E0S, AccessPermission:Busy, desc="Invalid, issued RdBlk, have not seen response yet";
I_E1S, AccessPermission:Busy, desc="Invalid, issued RdBlk, have not seen response yet";
I_ES, AccessPermission:Busy, desc="S_F got hit by invalidating probe, RdBlk response needs to go to both clusters";
IF_E0S, AccessPermission:Busy, desc="something got hit with Probe Invalidate, now just I_E0S but expecting a L2_to_L1D0 trigger, just drop when receive";
IF_E1S, AccessPermission:Busy, desc="something got hit with Probe Invalidate, now just I_E1S but expecting a L2_to_L1D1 trigger, just drop when receive";
IF_ES, AccessPermission:Busy, desc="same, but waiting for two fills";
IF0_ES, AccessPermission:Busy, desc="same, but waiting for two fills, got one";
IF1_ES, AccessPermission:Busy, desc="same, but waiting for two fills, got one";
F_S0, AccessPermission:Busy, desc="same, but going to S0 when trigger received";
F_S1, AccessPermission:Busy, desc="same, but going to S1 when trigger received";
ES_I, AccessPermission:Read_Only, desc="L2 replacement, waiting for clean writeback ack";
MO_I, AccessPermission:Read_Only, desc="L2 replacement, waiting for dirty writeback ack";
MO_S0, AccessPermission:Read_Only, desc="M/O got Ifetch Miss, must write back first, then send RdBlkS";
MO_S1, AccessPermission:Read_Only, desc="M/O got Ifetch Miss, must write back first, then send RdBlkS";
S_F0, AccessPermission:Read_Only, desc="Shared, filling L1";
S_F1, AccessPermission:Read_Only, desc="Shared, filling L1";
S_F, AccessPermission:Read_Only, desc="Shared, filling L1";
O_F0, AccessPermission:Read_Only, desc="Owned, filling L1";
O_F1, AccessPermission:Read_Only, desc="Owned, filling L1";
O_F, AccessPermission:Read_Only, desc="Owned, filling L1";
Si_F0, AccessPermission:Read_Only, desc="Shared, filling icache";
Si_F1, AccessPermission:Read_Only, desc="Shared, filling icache";
S_M0, AccessPermission:Read_Only, desc="Shared, issued CtoD, have not seen response yet";
S_M1, AccessPermission:Read_Only, desc="Shared, issued CtoD, have not seen response yet";
O_M0, AccessPermission:Read_Only, desc="Shared, issued CtoD, have not seen response yet";
O_M1, AccessPermission:Read_Only, desc="Shared, issued CtoD, have not seen response yet";
S0, AccessPermission:Busy, desc="RdBlkS on behalf of cluster 0, waiting for response";
S1, AccessPermission:Busy, desc="RdBlkS on behalf of cluster 1, waiting for response";
Es_F0, AccessPermission:Read_Write, desc="Es, Cluster read, filling";
Es_F1, AccessPermission:Read_Write, desc="Es, Cluster read, filling";
Es_F, AccessPermission:Read_Write, desc="Es, other cluster read, filling";
E0_F, AccessPermission:Read_Write, desc="E0, cluster read, filling";
E1_F, AccessPermission:Read_Write, desc="...";
E0_Es, AccessPermission:Read_Write, desc="...";
E1_Es, AccessPermission:Read_Write, desc="...";
Ms_F0, AccessPermission:Read_Write, desc="...";
Ms_F1, AccessPermission:Read_Write, desc="...";
Ms_F, AccessPermission:Read_Write, desc="...";
M0_F, AccessPermission:Read_Write, desc="...";
M0_Ms, AccessPermission:Read_Write, desc="...";
M1_F, AccessPermission:Read_Write, desc="...";
M1_Ms, AccessPermission:Read_Write, desc="...";
I_C, AccessPermission:Invalid, desc="Invalid, but waiting for WBAck from NB from canceled writeback";
S0_C, AccessPermission:Busy, desc="MO_S0 hit by invalidating probe, waiting for WBAck form NB for canceled WB";
S1_C, AccessPermission:Busy, desc="MO_S1 hit by invalidating probe, waiting for WBAck form NB for canceled WB";
S_C, AccessPermission:Busy, desc="S*_C got NB_AckS, still waiting for WBAck";
} // END STATES
// BEGIN EVENTS
enumeration(Event, desc="CP Events") {
// CP Initiated events
C0_Load_L1miss, desc="Cluster 0 load, L1 missed";
C0_Load_L1hit, desc="Cluster 0 load, L1 hit";
C1_Load_L1miss, desc="Cluster 1 load L1 missed";
C1_Load_L1hit, desc="Cluster 1 load L1 hit";
Ifetch0_L1hit, desc="Instruction fetch, hit in the L1";
Ifetch1_L1hit, desc="Instruction fetch, hit in the L1";
Ifetch0_L1miss, desc="Instruction fetch, missed in the L1";
Ifetch1_L1miss, desc="Instruction fetch, missed in the L1";
C0_Store_L1miss, desc="Cluster 0 store missed in L1";
C0_Store_L1hit, desc="Cluster 0 store hit in L1";
C1_Store_L1miss, desc="Cluster 1 store missed in L1";
C1_Store_L1hit, desc="Cluster 1 store hit in L1";
// NB Initiated events
NB_AckS, desc="NB Ack to Core Request";
NB_AckM, desc="NB Ack to Core Request";
NB_AckE, desc="NB Ack to Core Request";
NB_AckWB, desc="NB Ack for writeback";
// Memory System initiatied events
L1I_Repl, desc="Replace address from L1I"; // Presumed clean
L1D0_Repl, desc="Replace address from L1D0"; // Presumed clean
L1D1_Repl, desc="Replace address from L1D1"; // Presumed clean
L2_Repl, desc="Replace address from L2";
L2_to_L1D0, desc="L1 fill from L2";
L2_to_L1D1, desc="L1 fill from L2";
L2_to_L1I, desc="L1 fill from L2";
// Probe Events
PrbInvData, desc="probe, return O or M data";
PrbInvDataDemand, desc="probe, return O or M data. Demand request";
PrbInv, desc="probe, no need for data";
PrbShrData, desc="probe downgrade, return O or M data";
PrbShrDataDemand, desc="probe downgrade, return O or M data. Demand request";
ForceRepl, desc="probe from r-buf. Act as though a repl";
ForceDowngrade, desc="probe from r-buf. Act as though a repl";
} // END EVENTS
enumeration(RequestType, desc="To communicate stats from transitions to recordStats") {
L1D0DataArrayRead, desc="Read the data array";
L1D0DataArrayWrite, desc="Write the data array";
L1D0TagArrayRead, desc="Read the data array";
L1D0TagArrayWrite, desc="Write the data array";
L1D1DataArrayRead, desc="Read the data array";
L1D1DataArrayWrite, desc="Write the data array";
L1D1TagArrayRead, desc="Read the data array";
L1D1TagArrayWrite, desc="Write the data array";
L1IDataArrayRead, desc="Read the data array";
L1IDataArrayWrite, desc="Write the data array";
L1ITagArrayRead, desc="Read the data array";
L1ITagArrayWrite, desc="Write the data array";
L2DataArrayRead, desc="Read the data array";
L2DataArrayWrite, desc="Write the data array";
L2TagArrayRead, desc="Read the data array";
L2TagArrayWrite, desc="Write the data array";
}
// BEGIN STRUCTURE DEFINITIONS
// Cache Entry
structure(Entry, desc="...", interface="AbstractCacheEntry") {
State CacheState, desc="cache state";
bool Dirty, desc="Is the data dirty (diff than memory)?";
DataBlock DataBlk, desc="data for the block";
bool FromL2, default="false", desc="block just moved from L2";
}
structure(TBE, desc="...") {
State TBEState, desc="Transient state";
DataBlock DataBlk, desc="data for the block, required for concurrent writebacks";
bool Dirty, desc="Is the data dirty (different than memory)?";
int NumPendingMsgs, desc="Number of acks/data messages that this processor is waiting for";
bool Shared, desc="Victim hit by shared probe";
bool AckNeeded, desc="True if need to ack r-dir";
}
structure(TBETable, external="yes") {
TBE lookup(Addr);
void allocate(Addr);
void deallocate(Addr);
bool isPresent(Addr);
}
TBETable TBEs, template="<CorePair_TBE>", constructor="m_number_of_TBEs";
Tick clockEdge();
Tick cyclesToTicks(Cycles c);
void set_cache_entry(AbstractCacheEntry b);
void unset_cache_entry();
void set_tbe(TBE b);
void unset_tbe();
void wakeUpAllBuffers();
void wakeUpBuffers(Addr a);
Cycles curCycle();
MachineID mapAddressToMachine(Addr addr, MachineType mtype);
// END STRUCTURE DEFINITIONS
// BEGIN INTERNAL FUNCTIONS
MachineID getPeer(MachineID mach) {
return createMachineID(MachineType:RegionBuffer, intToID(regionBufferNum));
}
bool addressInCore(Addr addr) {
return (L2cache.isTagPresent(addr) || L1Icache.isTagPresent(addr) || L1D0cache.isTagPresent(addr) || L1D1cache.isTagPresent(addr));
}
Entry getCacheEntry(Addr address), return_by_pointer="yes" {
Entry L2cache_entry := static_cast(Entry, "pointer", L2cache.lookup(address));
return L2cache_entry;
}
DataBlock getDataBlock(Addr addr), return_by_ref="yes" {
TBE tbe := TBEs.lookup(addr);
if(is_valid(tbe)) {
return tbe.DataBlk;
} else {
return getCacheEntry(addr).DataBlk;
}
}
Entry getL1CacheEntry(Addr addr, int cluster), return_by_pointer="yes" {
if (cluster == 0) {
Entry L1D0_entry := static_cast(Entry, "pointer", L1D0cache.lookup(addr));
return L1D0_entry;
} else {
Entry L1D1_entry := static_cast(Entry, "pointer", L1D1cache.lookup(addr));
return L1D1_entry;
}
}
Entry getICacheEntry(Addr addr), return_by_pointer="yes" {
Entry c_entry := static_cast(Entry, "pointer", L1Icache.lookup(addr));
return c_entry;
}
bool presentOrAvail2(Addr addr) {
return L2cache.isTagPresent(addr) || L2cache.cacheAvail(addr);
}
bool presentOrAvailI(Addr addr) {
return L1Icache.isTagPresent(addr) || L1Icache.cacheAvail(addr);
}
bool presentOrAvailD0(Addr addr) {
return L1D0cache.isTagPresent(addr) || L1D0cache.cacheAvail(addr);
}
bool presentOrAvailD1(Addr addr) {
return L1D1cache.isTagPresent(addr) || L1D1cache.cacheAvail(addr);
}
State getState(TBE tbe, Entry cache_entry, Addr addr) {
if(is_valid(tbe)) {
return tbe.TBEState;
} else if (is_valid(cache_entry)) {
return cache_entry.CacheState;
}
return State:I;
}
void setState(TBE tbe, Entry cache_entry, Addr addr, State state) {
if (is_valid(tbe)) {
tbe.TBEState := state;
}
if (is_valid(cache_entry)) {
cache_entry.CacheState := state;
}
}
AccessPermission getAccessPermission(Addr addr) {
TBE tbe := TBEs.lookup(addr);
if(is_valid(tbe)) {
return CorePair_State_to_permission(tbe.TBEState);
}
Entry cache_entry := getCacheEntry(addr);
if(is_valid(cache_entry)) {
return CorePair_State_to_permission(cache_entry.CacheState);
}
return AccessPermission:NotPresent;
}
void functionalRead(Addr addr, Packet *pkt) {
TBE tbe := TBEs.lookup(addr);
if(is_valid(tbe)) {
testAndRead(addr, tbe.DataBlk, pkt);
} else {
functionalMemoryRead(pkt);
}
}
int functionalWrite(Addr addr, Packet *pkt) {
int num_functional_writes := 0;
TBE tbe := TBEs.lookup(addr);
if(is_valid(tbe)) {
num_functional_writes := num_functional_writes +
testAndWrite(addr, tbe.DataBlk, pkt);
}
num_functional_writes := num_functional_writes + functionalMemoryWrite(pkt);
return num_functional_writes;
}
bool isValid(Addr addr) {
AccessPermission perm := getAccessPermission(addr);
if (perm == AccessPermission:NotPresent ||
perm == AccessPermission:Invalid ||
perm == AccessPermission:Busy) {
return false;
} else {
return true;
}
}
void setAccessPermission(Entry cache_entry, Addr addr, State state) {
if (is_valid(cache_entry)) {
cache_entry.changePermission(CorePair_State_to_permission(state));
}
}
MachineType testAndClearLocalHit(Entry cache_entry) {
assert(is_valid(cache_entry));
if (cache_entry.FromL2) {
cache_entry.FromL2 := false;
return MachineType:L2Cache;
} else {
return MachineType:L1Cache;
}
}
void recordRequestType(RequestType request_type, Addr addr) {
if (request_type == RequestType:L1D0DataArrayRead) {
L1D0cache.recordRequestType(CacheRequestType:DataArrayRead, addr);
} else if (request_type == RequestType:L1D0DataArrayWrite) {
L1D0cache.recordRequestType(CacheRequestType:DataArrayWrite, addr);
} else if (request_type == RequestType:L1D0TagArrayRead) {
L1D0cache.recordRequestType(CacheRequestType:TagArrayRead, addr);
} else if (request_type == RequestType:L1D0TagArrayWrite) {
L1D0cache.recordRequestType(CacheRequestType:TagArrayWrite, addr);
} else if (request_type == RequestType:L1D1DataArrayRead) {
L1D1cache.recordRequestType(CacheRequestType:DataArrayRead, addr);
} else if (request_type == RequestType:L1D1DataArrayWrite) {
L1D1cache.recordRequestType(CacheRequestType:DataArrayWrite, addr);
} else if (request_type == RequestType:L1D1TagArrayRead) {
L1D1cache.recordRequestType(CacheRequestType:TagArrayRead, addr);
} else if (request_type == RequestType:L1D1TagArrayWrite) {
L1D1cache.recordRequestType(CacheRequestType:TagArrayWrite, addr);
} else if (request_type == RequestType:L1IDataArrayRead) {
L1Icache.recordRequestType(CacheRequestType:DataArrayRead, addr);
} else if (request_type == RequestType:L1IDataArrayWrite) {
L1Icache.recordRequestType(CacheRequestType:DataArrayWrite, addr);
} else if (request_type == RequestType:L1ITagArrayRead) {
L1Icache.recordRequestType(CacheRequestType:TagArrayRead, addr);
} else if (request_type == RequestType:L1ITagArrayWrite) {
L1Icache.recordRequestType(CacheRequestType:TagArrayWrite, addr);
} else if (request_type == RequestType:L2DataArrayRead) {
L2cache.recordRequestType(CacheRequestType:DataArrayRead, addr);
} else if (request_type == RequestType:L2DataArrayWrite) {
L2cache.recordRequestType(CacheRequestType:DataArrayWrite, addr);
} else if (request_type == RequestType:L2TagArrayRead) {
L2cache.recordRequestType(CacheRequestType:TagArrayRead, addr);
} else if (request_type == RequestType:L2TagArrayWrite) {
L2cache.recordRequestType(CacheRequestType:TagArrayWrite, addr);
}
}
bool checkResourceAvailable(RequestType request_type, Addr addr) {
if (request_type == RequestType:L2DataArrayRead) {
return L2cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L2DataArrayWrite) {
return L2cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L2TagArrayRead) {
return L2cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:L2TagArrayWrite) {
return L2cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:L1D0DataArrayRead) {
return L1D0cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L1D0DataArrayWrite) {
return L1D0cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L1D0TagArrayRead) {
return L1D0cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:L1D0TagArrayWrite) {
return L1D0cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:L1D1DataArrayRead) {
return L1D1cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L1D1DataArrayWrite) {
return L1D1cache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L1D1TagArrayRead) {
return L1D1cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:L1D1TagArrayWrite) {
return L1D1cache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:L1IDataArrayRead) {
return L1Icache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L1IDataArrayWrite) {
return L1Icache.checkResourceAvailable(CacheResourceType:DataArray, addr);
} else if (request_type == RequestType:L1ITagArrayRead) {
return L1Icache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else if (request_type == RequestType:L1ITagArrayWrite) {
return L1Icache.checkResourceAvailable(CacheResourceType:TagArray, addr);
} else {
return true;
}
}
// END INTERNAL FUNCTIONS
// ** OUT_PORTS **
out_port(requestNetwork_out, CPURequestMsg, requestFromCore);
out_port(responseNetwork_out, ResponseMsg, responseFromCore);
out_port(triggerQueue_out, TriggerMsg, triggerQueue);
out_port(unblockNetwork_out, UnblockMsg, unblockFromCore);
// ** IN_PORTS **
in_port(triggerQueue_in, TriggerMsg, triggerQueue, block_on="addr") {
if (triggerQueue_in.isReady(clockEdge())) {
peek(triggerQueue_in, TriggerMsg) {
Entry cache_entry := getCacheEntry(in_msg.addr);
TBE tbe := TBEs.lookup(in_msg.addr);
if (in_msg.Type == TriggerType:L2_to_L1) {
if (in_msg.Dest == CacheId:L1I) {
trigger(Event:L2_to_L1I, in_msg.addr, cache_entry, tbe);
} else if (in_msg.Dest == CacheId:L1D0) {
trigger(Event:L2_to_L1D0, in_msg.addr, cache_entry, tbe);
} else if (in_msg.Dest == CacheId:L1D1) {
trigger(Event:L2_to_L1D1, in_msg.addr, cache_entry, tbe);
} else {
error("unexpected trigger dest");
}
}
}
}
}
in_port(probeNetwork_in, NBProbeRequestMsg, probeToCore) {
if (probeNetwork_in.isReady(clockEdge())) {
peek(probeNetwork_in, NBProbeRequestMsg, block_on="addr") {
Entry cache_entry := getCacheEntry(in_msg.addr);
TBE tbe := TBEs.lookup(in_msg.addr);
if (in_msg.Type == ProbeRequestType:PrbInv) {
if (in_msg.DemandRequest) {
trigger(Event:PrbInvDataDemand, in_msg.addr, cache_entry, tbe);
} else if (in_msg.ReturnData) {
trigger(Event:PrbInvData, in_msg.addr, cache_entry, tbe);
} else {
trigger(Event:PrbInv, in_msg.addr, cache_entry, tbe);
}
} else if (in_msg.Type == ProbeRequestType:PrbDowngrade) {
if (in_msg.DemandRequest) {
trigger(Event:PrbShrDataDemand, in_msg.addr, cache_entry, tbe);
} else {
assert(in_msg.ReturnData);
trigger(Event:PrbShrData, in_msg.addr, cache_entry, tbe);
}
} else if (in_msg.Type == ProbeRequestType:PrbRepl) {
trigger(Event:ForceRepl, in_msg.addr, cache_entry, tbe);
} else if (in_msg.Type == ProbeRequestType:PrbRegDowngrade) {
trigger(Event:ForceDowngrade, in_msg.addr, cache_entry, tbe);
} else {
error("Unknown probe request");
}
}
}
}
// ResponseNetwork
in_port(responseToCore_in, ResponseMsg, responseToCore) {
if (responseToCore_in.isReady(clockEdge())) {
peek(responseToCore_in, ResponseMsg, block_on="addr") {
Entry cache_entry := getCacheEntry(in_msg.addr);
TBE tbe := TBEs.lookup(in_msg.addr);
if (in_msg.Type == CoherenceResponseType:NBSysResp) {
if (in_msg.State == CoherenceState:Modified) {
trigger(Event:NB_AckM, in_msg.addr, cache_entry, tbe);
} else if (in_msg.State == CoherenceState:Shared) {
trigger(Event:NB_AckS, in_msg.addr, cache_entry, tbe);
} else if (in_msg.State == CoherenceState:Exclusive) {
trigger(Event:NB_AckE, in_msg.addr, cache_entry, tbe);
}
} else if (in_msg.Type == CoherenceResponseType:NBSysWBAck) {
trigger(Event:NB_AckWB, in_msg.addr, cache_entry, tbe);
} else {
error("Unexpected Response Message to Core");
}
}
}
}
// Nothing from the Unblock Network
// Mandatory Queue
in_port(mandatoryQueue_in, RubyRequest, mandatoryQueue, desc="...") {
if (mandatoryQueue_in.isReady(clockEdge())) {
peek(mandatoryQueue_in, RubyRequest, block_on="LineAddress") {
Entry cache_entry := getCacheEntry(in_msg.LineAddress);
TBE tbe := TBEs.lookup(in_msg.LineAddress);
if (in_msg.Type == RubyRequestType:IFETCH) {
// FETCH ACCESS
if (L1Icache.isTagPresent(in_msg.LineAddress)) {
if (mod(in_msg.contextId, 2) == 0) {
trigger(Event:Ifetch0_L1hit, in_msg.LineAddress, cache_entry, tbe);
} else {
trigger(Event:Ifetch1_L1hit, in_msg.LineAddress, cache_entry, tbe);
}
} else {
if (presentOrAvail2(in_msg.LineAddress)) {
if (presentOrAvailI(in_msg.LineAddress)) {
if (mod(in_msg.contextId, 2) == 0) {
trigger(Event:Ifetch0_L1miss, in_msg.LineAddress, cache_entry,
tbe);
} else {
trigger(Event:Ifetch1_L1miss, in_msg.LineAddress, cache_entry,
tbe);
}
} else {
Addr victim := L1Icache.cacheProbe(in_msg.LineAddress);
trigger(Event:L1I_Repl, victim,
getCacheEntry(victim), TBEs.lookup(victim));
}
} else { // Not present or avail in L2
Addr victim := L2cache.cacheProbe(in_msg.LineAddress);
DPRINTF(RubySlicc, "Victim for %s L2_Repl(0) is %s\n", in_msg.LineAddress, victim);
trigger(Event:L2_Repl, victim, getCacheEntry(victim),
TBEs.lookup(victim));
}
}
} else {
// DATA ACCESS
if (mod(in_msg.contextId, 2) == 1) {
if (L1D1cache.isTagPresent(in_msg.LineAddress)) {
if (in_msg.Type == RubyRequestType:LD) {
trigger(Event:C1_Load_L1hit, in_msg.LineAddress, cache_entry,
tbe);
} else {
// Stores must write through, make sure L2 avail.
if (presentOrAvail2(in_msg.LineAddress)) {
trigger(Event:C1_Store_L1hit, in_msg.LineAddress, cache_entry,
tbe);
} else {
Addr victim := L2cache.cacheProbe(in_msg.LineAddress);
DPRINTF(RubySlicc, "Victim for %s L2_Repl(1) is %s\n", in_msg.LineAddress, victim);
trigger(Event:L2_Repl, victim, getCacheEntry(victim),
TBEs.lookup(victim));
}
}
} else {
if (presentOrAvail2(in_msg.LineAddress)) {
if (presentOrAvailD1(in_msg.LineAddress)) {
if (in_msg.Type == RubyRequestType:LD) {
trigger(Event:C1_Load_L1miss, in_msg.LineAddress,
cache_entry, tbe);
} else {
trigger(Event:C1_Store_L1miss, in_msg.LineAddress,
cache_entry, tbe);
}
} else {
Addr victim := L1D1cache.cacheProbe(in_msg.LineAddress);
DPRINTF(RubySlicc, "Victim for %s L1D1_Repl is %s\n", in_msg.LineAddress, victim);
trigger(Event:L1D1_Repl, victim,
getCacheEntry(victim), TBEs.lookup(victim));
}
} else { // not present or avail in L2
Addr victim := L2cache.cacheProbe(in_msg.LineAddress);
DPRINTF(RubySlicc, "Victim for %s L2_Repl(2) is %s\n", in_msg.LineAddress, victim);
trigger(Event:L2_Repl, victim, getCacheEntry(victim), TBEs.lookup(victim));
}
}
} else {
Entry L1D0cache_entry := getL1CacheEntry(in_msg.LineAddress, 0);
if (is_valid(L1D0cache_entry)) {
if (in_msg.Type == RubyRequestType:LD) {
trigger(Event:C0_Load_L1hit, in_msg.LineAddress, cache_entry,
tbe);
} else {
if (presentOrAvail2(in_msg.LineAddress)) {
trigger(Event:C0_Store_L1hit, in_msg.LineAddress, cache_entry,
tbe);
} else {
Addr victim := L2cache.cacheProbe(in_msg.LineAddress);
DPRINTF(RubySlicc, "Victim for %s L2_Repl(3) is %s\n", in_msg.LineAddress, victim);
trigger(Event:L2_Repl, victim, getCacheEntry(victim),
TBEs.lookup(victim));
}
}
} else {
if (presentOrAvail2(in_msg.LineAddress)) {
if (presentOrAvailD0(in_msg.LineAddress)) {
if (in_msg.Type == RubyRequestType:LD) {
trigger(Event:C0_Load_L1miss, in_msg.LineAddress,
cache_entry, tbe);
} else {
trigger(Event:C0_Store_L1miss, in_msg.LineAddress,
cache_entry, tbe);
}
} else {
Addr victim := L1D0cache.cacheProbe(in_msg.LineAddress);
DPRINTF(RubySlicc, "Victim for %s L1D0_Repl is %s\n", in_msg.LineAddress, victim);
trigger(Event:L1D0_Repl, victim, getCacheEntry(victim),
TBEs.lookup(victim));
}
} else {
Addr victim := L2cache.cacheProbe(in_msg.LineAddress);
DPRINTF(RubySlicc, "Victim for %s L2_Repl(4) is %s\n", in_msg.LineAddress, victim);
trigger(Event:L2_Repl, victim, getCacheEntry(victim),
TBEs.lookup(victim));
}
}
}
}
}
}
}
// ACTIONS
action(ii_invIcache, "ii", desc="invalidate iCache") {
if (L1Icache.isTagPresent(address)) {
L1Icache.deallocate(address);
}
}
action(i0_invCluster, "i0", desc="invalidate cluster 0") {
if (L1D0cache.isTagPresent(address)) {
L1D0cache.deallocate(address);
}
}
action(i1_invCluster, "i1", desc="invalidate cluster 1") {
if (L1D1cache.isTagPresent(address)) {
L1D1cache.deallocate(address);
}
}
action(ib_invBothClusters, "ib", desc="invalidate both clusters") {
if (L1D0cache.isTagPresent(address)) {
L1D0cache.deallocate(address);
}
if (L1D1cache.isTagPresent(address)) {
L1D1cache.deallocate(address);
}
}
action(i2_invL2, "i2", desc="invalidate L2") {
if(is_valid(cache_entry)) {
L2cache.deallocate(address);
}
unset_cache_entry();
}
action(n_issueRdBlk, "n", desc="Issue RdBlk") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceRequestType:RdBlk;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.InitialRequestTime := curCycle();
}
}
action(nM_issueRdBlkM, "nM", desc="Issue RdBlkM") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceRequestType:RdBlkM;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.InitialRequestTime := curCycle();
}
}
action(nMs_issueRdBlkMSinked, "nMs", desc="Issue RdBlkM with CtoDSinked") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceRequestType:RdBlkM;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.CtoDSinked := true;
}
}
action(nS_issueRdBlkS, "nS", desc="Issue RdBlkS") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceRequestType:RdBlkS;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.InitialRequestTime := curCycle();
}
}
action(nSs_issueRdBlkSSinked, "nSs", desc="Issue RdBlkS with CtoDSinked") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceRequestType:RdBlkS;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.CtoDSinked := true;
out_msg.MessageSize := MessageSizeType:Request_Control;
}
}
action(vd_victim, "vd", desc="Victimize M/O L2 Data") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Requestor := machineID;
assert(is_valid(cache_entry));
out_msg.DataBlk := cache_entry.DataBlk;
assert(cache_entry.Dirty);
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.Type := CoherenceRequestType:VicDirty;
out_msg.InitialRequestTime := curCycle();
if (cache_entry.CacheState == State:O) {
out_msg.Shared := true;
} else {
out_msg.Shared := false;
}
}
}
action(vc_victim, "vc", desc="Victimize E/S L2 Data") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.Type := CoherenceRequestType:VicClean;
out_msg.InitialRequestTime := curCycle();
if (cache_entry.CacheState == State:S) {
out_msg.Shared := true;
} else {
out_msg.Shared := false;
}
}
}
// Could send these two directly to dir if we made a new out network on channel 0
action(vdf_victimForce, "vdf", desc="Victimize M/O L2 Data") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Requestor := machineID;
assert(is_valid(cache_entry));
out_msg.DataBlk := cache_entry.DataBlk;
assert(cache_entry.Dirty);
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.Type := CoherenceRequestType:VicDirty;
out_msg.InitialRequestTime := curCycle();
if (cache_entry.CacheState == State:O) {
out_msg.Shared := true;
} else {
out_msg.Shared := false;
}
out_msg.Private := true;
}
}
action(vcf_victimForce, "vcf", desc="Victimize E/S L2 Data") {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
out_msg.Type := CoherenceRequestType:VicClean;
out_msg.InitialRequestTime := curCycle();
if (cache_entry.CacheState == State:S) {
out_msg.Shared := true;
} else {
out_msg.Shared := false;
}
out_msg.Private := true;
}
}
action(a0_allocateL1D, "a0", desc="Allocate L1D0 Block") {
if (L1D0cache.isTagPresent(address) == false) {
L1D0cache.allocateVoid(address, new Entry);
}
}
action(a1_allocateL1D, "a1", desc="Allocate L1D1 Block") {
if (L1D1cache.isTagPresent(address) == false) {
L1D1cache.allocateVoid(address, new Entry);
}
}
action(ai_allocateL1I, "ai", desc="Allocate L1I Block") {
if (L1Icache.isTagPresent(address) == false) {
L1Icache.allocateVoid(address, new Entry);
}
}
action(a2_allocateL2, "a2", desc="Allocate L2 Block") {
if (is_invalid(cache_entry)) {
set_cache_entry(L2cache.allocate(address, new Entry));
}
}
action(t_allocateTBE, "t", desc="allocate TBE Entry") {
check_allocate(TBEs);
assert(is_valid(cache_entry));
TBEs.allocate(address);
set_tbe(TBEs.lookup(address));
tbe.DataBlk := cache_entry.DataBlk; // Data only used for WBs
tbe.Dirty := cache_entry.Dirty;
tbe.Shared := false;
}
action(d_deallocateTBE, "d", desc="Deallocate TBE") {
TBEs.deallocate(address);
unset_tbe();
}
action(p_popMandatoryQueue, "pm", desc="Pop Mandatory Queue") {
mandatoryQueue_in.dequeue(clockEdge());
}
action(pr_popResponseQueue, "pr", desc="Pop Response Queue") {
responseToCore_in.dequeue(clockEdge());
}
action(pt_popTriggerQueue, "pt", desc="Pop Trigger Queue") {
triggerQueue_in.dequeue(clockEdge());
}
action(pp_popProbeQueue, "pp", desc="pop probe queue") {
probeNetwork_in.dequeue(clockEdge());
}
action(il0_loadDone, "il0", desc="Cluster 0 i load done") {
Entry entry := getICacheEntry(address);
Entry l2entry := getCacheEntry(address); // Used for functional accesses
assert(is_valid(entry));
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
sequencer.readCallback(address,
l2entry.DataBlk,
true,
testAndClearLocalHit(entry));
}
action(il1_loadDone, "il1", desc="Cluster 1 i load done") {
Entry entry := getICacheEntry(address);
Entry l2entry := getCacheEntry(address); // Used for functional accesses
assert(is_valid(entry));
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
sequencer1.readCallback(address,
l2entry.DataBlk,
true,
testAndClearLocalHit(entry));
}
action(l0_loadDone, "l0", desc="Cluster 0 load done") {
Entry entry := getL1CacheEntry(address, 0);
Entry l2entry := getCacheEntry(address); // Used for functional accesses
assert(is_valid(entry));
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
sequencer.readCallback(address,
l2entry.DataBlk,
true,
testAndClearLocalHit(entry));
}
action(l1_loadDone, "l1", desc="Cluster 1 load done") {
Entry entry := getL1CacheEntry(address, 1);
Entry l2entry := getCacheEntry(address); // Used for functional accesses
assert(is_valid(entry));
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
sequencer1.readCallback(address,
l2entry.DataBlk,
true,
testAndClearLocalHit(entry));
}
action(xl0_loadDone, "xl0", desc="Cluster 0 load done") {
peek(responseToCore_in, ResponseMsg) {
assert((machineIDToMachineType(in_msg.Sender) == MachineType:Directory) ||
(machineIDToMachineType(in_msg.Sender) == MachineType:L3Cache));
Entry l2entry := getCacheEntry(address); // Used for functional accesses
DPRINTF(ProtocolTrace, "CP Load Done 0 -- address %s, data: %s\n",
address, l2entry.DataBlk);
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
assert(is_valid(l2entry));
sequencer.readCallback(address,
l2entry.DataBlk,
false,
machineIDToMachineType(in_msg.Sender),
in_msg.InitialRequestTime,
in_msg.ForwardRequestTime,
in_msg.ProbeRequestStartTime);
}
}
action(xl1_loadDone, "xl1", desc="Cluster 1 load done") {
peek(responseToCore_in, ResponseMsg) {
assert((machineIDToMachineType(in_msg.Sender) == MachineType:Directory) ||
(machineIDToMachineType(in_msg.Sender) == MachineType:L3Cache));
Entry l2entry := getCacheEntry(address); // Used for functional accesses
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
assert(is_valid(l2entry));
sequencer1.readCallback(address,
l2entry.DataBlk,
false,
machineIDToMachineType(in_msg.Sender),
in_msg.InitialRequestTime,
in_msg.ForwardRequestTime,
in_msg.ProbeRequestStartTime);
}
}
action(xi0_loadDone, "xi0", desc="Cluster 0 i-load done") {
peek(responseToCore_in, ResponseMsg) {
assert((machineIDToMachineType(in_msg.Sender) == MachineType:Directory) ||
(machineIDToMachineType(in_msg.Sender) == MachineType:L3Cache));
Entry l2entry := getCacheEntry(address); // Used for functional accesses
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
assert(is_valid(l2entry));
sequencer.readCallback(address,
l2entry.DataBlk,
false,
machineIDToMachineType(in_msg.Sender),
in_msg.InitialRequestTime,
in_msg.ForwardRequestTime,
in_msg.ProbeRequestStartTime);
}
}
action(xi1_loadDone, "xi1", desc="Cluster 1 i-load done") {
peek(responseToCore_in, ResponseMsg) {
assert((machineIDToMachineType(in_msg.Sender) == MachineType:Directory) ||
(machineIDToMachineType(in_msg.Sender) == MachineType:L3Cache));
Entry l2entry := getCacheEntry(address); // Used for functional accesses
// L2 supplies data (functional accesses only look in L2, ok because L1
// writes through to L2)
assert(is_valid(l2entry));
sequencer1.readCallback(address,
l2entry.DataBlk,
false,
machineIDToMachineType(in_msg.Sender),
in_msg.InitialRequestTime,
in_msg.ForwardRequestTime,
in_msg.ProbeRequestStartTime);
}
}
action(s0_storeDone, "s0", desc="Cluster 0 store done") {
Entry entry := getL1CacheEntry(address, 0);
assert(is_valid(entry));
assert(is_valid(cache_entry));
sequencer.writeCallback(address,
cache_entry.DataBlk,
true,
testAndClearLocalHit(entry));
cache_entry.Dirty := true;
entry.DataBlk := cache_entry.DataBlk;
entry.Dirty := true;
DPRINTF(RubySlicc, "%s\n", cache_entry.DataBlk);
}
action(s1_storeDone, "s1", desc="Cluster 1 store done") {
Entry entry := getL1CacheEntry(address, 1);
assert(is_valid(entry));
assert(is_valid(cache_entry));
sequencer1.writeCallback(address,
cache_entry.DataBlk,
true,
testAndClearLocalHit(entry));
cache_entry.Dirty := true;
entry.Dirty := true;
entry.DataBlk := cache_entry.DataBlk;
DPRINTF(RubySlicc, "%s\n", cache_entry.DataBlk);
}
action(xs0_storeDone, "xs0", desc="Cluster 0 store done") {
peek(responseToCore_in, ResponseMsg) {
Entry entry := getL1CacheEntry(address, 0);
assert(is_valid(entry));
assert(is_valid(cache_entry));
assert((machineIDToMachineType(in_msg.Sender) == MachineType:Directory) ||
(machineIDToMachineType(in_msg.Sender) == MachineType:L3Cache));
sequencer.writeCallback(address,
cache_entry.DataBlk,
false,
machineIDToMachineType(in_msg.Sender),
in_msg.InitialRequestTime,
in_msg.ForwardRequestTime,
in_msg.ProbeRequestStartTime);
cache_entry.Dirty := true;
entry.Dirty := true;
entry.DataBlk := cache_entry.DataBlk;
DPRINTF(RubySlicc, "%s\n", cache_entry.DataBlk);
}
}
action(xs1_storeDone, "xs1", desc="Cluster 1 store done") {
peek(responseToCore_in, ResponseMsg) {
Entry entry := getL1CacheEntry(address, 1);
assert(is_valid(entry));
assert(is_valid(cache_entry));
assert((machineIDToMachineType(in_msg.Sender) == MachineType:Directory) ||
(machineIDToMachineType(in_msg.Sender) == MachineType:L3Cache));
sequencer1.writeCallback(address,
cache_entry.DataBlk,
false,
machineIDToMachineType(in_msg.Sender),
in_msg.InitialRequestTime,
in_msg.ForwardRequestTime,
in_msg.ProbeRequestStartTime);
cache_entry.Dirty := true;
entry.Dirty := true;
entry.DataBlk := cache_entry.DataBlk;
DPRINTF(RubySlicc, "%s\n", cache_entry.DataBlk);
}
}
action(forward_eviction_to_cpu0, "fec0", desc="sends eviction information to processor0") {
if (send_evictions) {
DPRINTF(RubySlicc, "Sending invalidation for %s to the CPU\n", address);
sequencer.evictionCallback(address);
}
}
action(forward_eviction_to_cpu1, "fec1", desc="sends eviction information to processor1") {
if (send_evictions) {
DPRINTF(RubySlicc, "Sending invalidation for %s to the CPU\n", address);
sequencer1.evictionCallback(address);
}
}
action(ci_copyL2ToL1, "ci", desc="copy L2 data to L1") {
Entry entry := getICacheEntry(address);
assert(is_valid(entry));
assert(is_valid(cache_entry));
entry.Dirty := cache_entry.Dirty;
entry.DataBlk := cache_entry.DataBlk;
entry.FromL2 := true;
}
action(c0_copyL2ToL1, "c0", desc="copy L2 data to L1") {
Entry entry := getL1CacheEntry(address, 0);
assert(is_valid(entry));
assert(is_valid(cache_entry));
entry.Dirty := cache_entry.Dirty;
entry.DataBlk := cache_entry.DataBlk;
entry.FromL2 := true;
}
action(ss_sendStaleNotification, "ss", desc="stale data; nothing to writeback") {
peek(responseToCore_in, ResponseMsg) {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:StaleNotif;
out_msg.Sender := machineID;
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.MessageSize := MessageSizeType:Response_Control;
DPRINTF(RubySlicc, "%s\n", out_msg);
}
}
}
action(c1_copyL2ToL1, "c1", desc="copy L2 data to L1") {
Entry entry := getL1CacheEntry(address, 1);
assert(is_valid(entry));
assert(is_valid(cache_entry));
entry.Dirty := cache_entry.Dirty;
entry.DataBlk := cache_entry.DataBlk;
entry.FromL2 := true;
}
action(fi_L2ToL1, "fi", desc="L2 to L1 inst fill") {
enqueue(triggerQueue_out, TriggerMsg, l2_hit_latency) {
out_msg.addr := address;
out_msg.Type := TriggerType:L2_to_L1;
out_msg.Dest := CacheId:L1I;
}
}
action(f0_L2ToL1, "f0", desc="L2 to L1 data fill") {
enqueue(triggerQueue_out, TriggerMsg, l2_hit_latency) {
out_msg.addr := address;
out_msg.Type := TriggerType:L2_to_L1;
out_msg.Dest := CacheId:L1D0;
}
}
action(f1_L2ToL1, "f1", desc="L2 to L1 data fill") {
enqueue(triggerQueue_out, TriggerMsg, l2_hit_latency) {
out_msg.addr := address;
out_msg.Type := TriggerType:L2_to_L1;
out_msg.Dest := CacheId:L1D1;
}
}
action(wi_writeIcache, "wi", desc="write data to icache (and l2)") {
peek(responseToCore_in, ResponseMsg) {
Entry entry := getICacheEntry(address);
assert(is_valid(entry));
assert(is_valid(cache_entry));
entry.DataBlk := in_msg.DataBlk;
entry.Dirty := in_msg.Dirty;
cache_entry.DataBlk := in_msg.DataBlk;
cache_entry.Dirty := in_msg.Dirty;
}
}
action(w0_writeDcache, "w0", desc="write data to dcache 0 (and l2)") {
peek(responseToCore_in, ResponseMsg) {
Entry entry := getL1CacheEntry(address, 0);
assert(is_valid(entry));
assert(is_valid(cache_entry));
entry.DataBlk := in_msg.DataBlk;
entry.Dirty := in_msg.Dirty;
cache_entry.DataBlk := in_msg.DataBlk;
cache_entry.Dirty := in_msg.Dirty;
}
}
action(w1_writeDcache, "w1", desc="write data to dcache 1 (and l2)") {
peek(responseToCore_in, ResponseMsg) {
Entry entry := getL1CacheEntry(address, 1);
assert(is_valid(entry));
assert(is_valid(cache_entry));
entry.DataBlk := in_msg.DataBlk;
entry.Dirty := in_msg.Dirty;
cache_entry.DataBlk := in_msg.DataBlk;
cache_entry.Dirty := in_msg.Dirty;
}
}
action(wb_data, "wb", desc="write back data") {
peek(responseToCore_in, ResponseMsg) {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUData;
out_msg.Sender := machineID;
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.DataBlk := tbe.DataBlk;
out_msg.Dirty := tbe.Dirty;
if (tbe.Shared) {
out_msg.NbReqShared := true;
} else {
out_msg.NbReqShared := false;
}
out_msg.State := CoherenceState:Shared; // faux info
out_msg.MessageSize := MessageSizeType:Writeback_Data;
DPRINTF(RubySlicc, "%s\n", out_msg);
}
}
}
action(pi_sendProbeResponseInv, "pi", desc="send probe ack inv, no data") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUPrbResp; // L3 and CPUs respond in same way to probes
out_msg.Sender := machineID;
// will this always be ok? probably not for multisocket
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.Dirty := false;
out_msg.Hit := false;
out_msg.Ntsl := true;
out_msg.State := CoherenceState:NA;
out_msg.MessageSize := MessageSizeType:Response_Control;
out_msg.isValid := isValid(address);
}
}
action(pim_sendProbeResponseInvMs, "pim", desc="send probe ack inv, no data") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUPrbResp; // L3 and CPUs respond in same way to probes
out_msg.Sender := machineID;
// will this always be ok? probably not for multisocket
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.Dirty := false;
out_msg.Ntsl := true;
out_msg.Hit := false;
APPEND_TRANSITION_COMMENT("Setting Ms");
out_msg.State := CoherenceState:NA;
out_msg.MessageSize := MessageSizeType:Response_Control;
out_msg.isValid := isValid(address);
}
}
action(ph_sendProbeResponseHit, "ph", desc="send probe ack PrbShrData, no data") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUPrbResp; // L3 and CPUs respond in same way to probes
out_msg.Sender := machineID;
// will this always be ok? probably not for multisocket
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
assert(addressInCore(address) || is_valid(tbe));
out_msg.Dirty := false; // only true if sending back data i think
out_msg.Hit := true;
out_msg.Ntsl := false;
out_msg.State := CoherenceState:NA;
out_msg.MessageSize := MessageSizeType:Response_Control;
out_msg.isValid := isValid(address);
}
}
action(pb_sendProbeResponseBackprobe, "pb", desc="send probe ack PrbShrData, no data, check for L1 residence") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUPrbResp; // L3 and CPUs respond in same way to probes
out_msg.Sender := machineID;
// will this always be ok? probably not for multisocket
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
if (addressInCore(address)) {
out_msg.Hit := true;
} else {
out_msg.Hit := false;
}
out_msg.Dirty := false; // not sending back data, so def. not dirty
out_msg.Ntsl := false;
out_msg.State := CoherenceState:NA;
out_msg.MessageSize := MessageSizeType:Response_Control;
out_msg.isValid := isValid(address);
}
}
action(pd_sendProbeResponseData, "pd", desc="send probe ack, with data") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
assert(is_valid(cache_entry));
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUPrbResp;
out_msg.Sender := machineID;
// will this always be ok? probably not for multisocket
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.DataBlk := cache_entry.DataBlk;
assert(cache_entry.Dirty);
out_msg.Dirty := true;
out_msg.Hit := true;
out_msg.State := CoherenceState:NA;
out_msg.MessageSize := MessageSizeType:Response_Data;
out_msg.isValid := isValid(address);
}
}
action(pdm_sendProbeResponseDataMs, "pdm", desc="send probe ack, with data") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
assert(is_valid(cache_entry));
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUPrbResp;
out_msg.Sender := machineID;
// will this always be ok? probably not for multisocket
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.DataBlk := cache_entry.DataBlk;
assert(cache_entry.Dirty);
out_msg.Dirty := true;
out_msg.Hit := true;
APPEND_TRANSITION_COMMENT("Setting Ms");
out_msg.State := CoherenceState:NA;
out_msg.MessageSize := MessageSizeType:Response_Data;
out_msg.isValid := isValid(address);
}
}
action(pdt_sendProbeResponseDataFromTBE, "pdt", desc="send probe ack with data") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
assert(is_valid(tbe));
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUPrbResp;
out_msg.Sender := machineID;
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.DataBlk := tbe.DataBlk;
assert(tbe.Dirty);
out_msg.Dirty := true;
out_msg.Hit := true;
out_msg.State := CoherenceState:NA;
out_msg.MessageSize := MessageSizeType:Response_Data;
out_msg.isValid := isValid(address);
}
}
action(ra_sendReplAck, "ra", desc="Send ack to r-buf that line is replaced if needed") {
if (is_invalid(tbe) || tbe.AckNeeded) {
enqueue(requestNetwork_out, CPURequestMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceRequestType:InvAck;
out_msg.Requestor := machineID;
out_msg.Destination.add(getPeer(machineID));
out_msg.MessageSize := MessageSizeType:Request_Control;
}
APPEND_TRANSITION_COMMENT(" Sending ack to r-buf ");
} else {
APPEND_TRANSITION_COMMENT(" NOT Sending ack to r-buf ");
}
}
action(m_markAckNeeded, "m", desc="Mark TBE to send ack when deallocated") {
assert(is_valid(tbe));
tbe.AckNeeded := true;
}
action(mc_cancelWB, "mc", desc="send writeback cancel to L3") {
enqueue(responseNetwork_out, ResponseMsg, issue_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:CPUCancelWB;
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.Sender := machineID;
out_msg.MessageSize := MessageSizeType:Response_Control;
}
}
action(s_setSharedFlip, "s", desc="hit by shared probe, status may be different") {
assert(is_valid(tbe));
tbe.Shared := true;
}
action(uu_sendUnblock, "uu", desc="state changed, unblock") {
enqueue(unblockNetwork_out, UnblockMsg, issue_latency) {
out_msg.addr := address;
out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
out_msg.MessageSize := MessageSizeType:Unblock_Control;
out_msg.wasValid := isValid(address);
DPRINTF(RubySlicc, "%s\n", out_msg);
}
}
action(sdv_sendDoneValid, "sdv", desc="Request finished, send done ack") {
enqueue(unblockNetwork_out, UnblockMsg, 1) {
out_msg.addr := address;
out_msg.Destination.add(getPeer(machineID));
out_msg.DoneAck := true;
out_msg.MessageSize := MessageSizeType:Unblock_Control;
if (is_valid(tbe)) {
out_msg.Dirty := tbe.Dirty;
} else if (is_valid(cache_entry)) {
out_msg.Dirty := cache_entry.Dirty;
} else {
out_msg.Dirty := false;
}
out_msg.validToInvalid := false;
DPRINTF(RubySlicc, "%s\n", out_msg);
}
}
action(sdi_sendDoneInvalid, "sdi", desc="Request finished, send done ack") {
enqueue(unblockNetwork_out, UnblockMsg, 1) {
out_msg.addr := address;
out_msg.Destination.add(getPeer(machineID));
out_msg.DoneAck := true;
out_msg.MessageSize := MessageSizeType:Unblock_Control;
if (is_valid(tbe)) {
out_msg.Dirty := tbe.Dirty;
} else if (is_valid(cache_entry)) {
out_msg.Dirty := cache_entry.Dirty;
} else {
out_msg.Dirty := false;
}
out_msg.validToInvalid := true;
DPRINTF(RubySlicc, "%s\n", out_msg);
}
}
action(l10m_profileMiss, "l10m", desc="l10m miss profile") {
++L1D0cache.demand_misses;
}
action(l11m_profileMiss, "l11m", desc="l11m miss profile") {
++L1D1cache.demand_misses;
}
action(l1im_profileMiss, "l1lm", desc="l1im miss profile") {
++L1Icache.demand_misses;
}
action(l2m_profileMiss, "l2m", desc="l2m miss profile") {
++L2cache.demand_misses;
}
action(yy_recycleProbeQueue, "yy", desc="recycle probe queue") {
probeNetwork_in.recycle(clockEdge(), cyclesToTicks(recycle_latency));
}
action(zz_recycleMandatoryQueue, "\z", desc="recycle mandatory queue") {
mandatoryQueue_in.recycle(clockEdge(), cyclesToTicks(recycle_latency));
}
// END ACTIONS
// BEGIN TRANSITIONS
// transitions from base
transition(I, C0_Load_L1miss, I_E0S) {L1D0TagArrayRead, L2TagArrayRead} {
// track misses, if implemented
// since in I state, L2 miss as well
l2m_profileMiss;
l10m_profileMiss;
a0_allocateL1D;
l1im_profileMiss;
a2_allocateL2;
i1_invCluster;
ii_invIcache;
n_issueRdBlk;
p_popMandatoryQueue;
}
transition(I, C1_Load_L1miss, I_E1S) {L1D1TagArrayRead, L2TagArrayRead} {
// track misses, if implemented
// since in I state, L2 miss as well
l2m_profileMiss;
l11m_profileMiss;
a1_allocateL1D;
a2_allocateL2;
i0_invCluster;
ii_invIcache;
n_issueRdBlk;
p_popMandatoryQueue;
}
transition(I, Ifetch0_L1miss, S0) {L1ITagArrayRead, L2TagArrayRead} {
// track misses, if implemented
// L2 miss as well
l10m_profileMiss;
l2m_profileMiss;
l1im_profileMiss;
ai_allocateL1I;
a2_allocateL2;
ib_invBothClusters;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
transition(I, Ifetch1_L1miss, S1) {L1ITagArrayRead, L2TagArrayRead} {
l11m_profileMiss;
// track misses, if implemented
// L2 miss as well
l2m_profileMiss;
l1im_profileMiss;
ai_allocateL1I;
a2_allocateL2;
ib_invBothClusters;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
transition(I, C0_Store_L1miss, I_M0) {L1D0TagArrayRead,L2TagArrayRead} {
l2m_profileMiss;
l10m_profileMiss;
a0_allocateL1D;
a2_allocateL2;
i1_invCluster;
ii_invIcache;
nM_issueRdBlkM;
p_popMandatoryQueue;
}
transition(I, C1_Store_L1miss, I_M1) {L1D0TagArrayRead, L2TagArrayRead} {
l2m_profileMiss;
l11m_profileMiss;
a1_allocateL1D;
a2_allocateL2;
i0_invCluster;
ii_invIcache;
nM_issueRdBlkM;
p_popMandatoryQueue;
}
transition(S, C0_Load_L1miss, S_F0) {L1D0TagArrayRead, L2TagArrayRead, L2DataArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(S, C1_Load_L1miss, S_F1) {L1D1TagArrayRead, L2TagArrayRead, L2DataArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(S, Ifetch0_L1miss, Si_F0) {L1ITagArrayRead,L2TagArrayRead, L2DataArrayRead} {
l1im_profileMiss;
ai_allocateL1I;
fi_L2ToL1;
p_popMandatoryQueue;
}
transition(S, Ifetch1_L1miss, Si_F1) {L1ITagArrayRead, L2TagArrayRead, L2DataArrayRead} {
l1im_profileMiss;
ai_allocateL1I;
fi_L2ToL1;
p_popMandatoryQueue;
}
transition({S}, {C0_Store_L1hit, C0_Store_L1miss}, S_M0) {L1D0TagArrayRead, L2TagArrayRead}{
l2m_profileMiss;
l10m_profileMiss;
a0_allocateL1D;
i1_invCluster;
ii_invIcache;
nM_issueRdBlkM;
p_popMandatoryQueue;
}
transition({S}, {C1_Store_L1hit, C1_Store_L1miss}, S_M1) {L1D1TagArrayRead,L2TagArrayRead} {
l2m_profileMiss;
l11m_profileMiss;
a1_allocateL1D;
i0_invCluster;
ii_invIcache;
nM_issueRdBlkM;
p_popMandatoryQueue;
}
transition(Es, C0_Load_L1miss, Es_F0) {L1D0TagArrayRead, L2TagArrayRead, L2DataArrayRead} { // can this be folded with S_F?
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(Es, C1_Load_L1miss, Es_F1) {L1D1TagArrayRead, L2TagArrayRead, L2DataArrayRead} { // can this be folded with S_F?
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(Es, Ifetch0_L1miss, S0) {L1ITagArrayRead, L2TagArrayRead} {
l1im_profileMiss;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
ib_invBothClusters;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
transition(Es, Ifetch1_L1miss, S1) {L1ITagArrayRead, L2TagArrayRead} {
l1im_profileMiss;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
ib_invBothClusters;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
// THES SHOULD NOT BE INSTANTANEOUS BUT OH WELL FOR NOW
transition(Es, {C0_Store_L1hit, C0_Store_L1miss}, M0) {L1D0TagArrayWrite,L1D0TagArrayRead, L2TagArrayRead, L1D0DataArrayWrite, L2TagArrayWrite, L2DataArrayWrite} {
a0_allocateL1D;
i1_invCluster;
s0_storeDone; // instantaneous L1/L2 dirty - no writethrough delay
p_popMandatoryQueue;
}
transition(Es, {C1_Store_L1hit, C1_Store_L1miss}, M1) {L1D1TagArrayRead, L1D1TagArrayWrite, L1D1DataArrayWrite, L2TagArrayWrite, L2DataArrayWrite} {
a1_allocateL1D;
i0_invCluster;
s1_storeDone;
p_popMandatoryQueue;
}
transition(E0, C0_Load_L1miss, E0_F) {L1D0TagArrayRead, L2TagArrayRead, L2DataArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(E0, C1_Load_L1miss, E0_Es) {L1D0TagArrayRead, L2TagArrayRead, L2DataArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(E0, Ifetch0_L1miss, S0) {L2TagArrayRead, L1ITagArrayRead} {
l2m_profileMiss; // permissions miss, still issue RdBlkS
l1im_profileMiss;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
i0_invCluster;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
transition(E0, Ifetch1_L1miss, S1) {L2TagArrayRead, L1ITagArrayRead } {
l2m_profileMiss; // permissions miss, still issue RdBlkS
l1im_profileMiss;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
i0_invCluster;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
transition(E0, {C0_Store_L1hit, C0_Store_L1miss}, M0) {L1D0TagArrayRead, L1D0DataArrayWrite, L1D0TagArrayWrite, L2TagArrayRead, L2DataArrayWrite, L2TagArrayWrite} {
a0_allocateL1D;
s0_storeDone;
p_popMandatoryQueue;
}
transition(E0, C1_Store_L1miss, M1) {L1D0TagArrayRead, L1D0TagArrayWrite, L2TagArrayRead, L2TagArrayWrite, L2DataArrayWrite} {
a1_allocateL1D;
l11m_profileMiss;
i0_invCluster;
s1_storeDone;
p_popMandatoryQueue;
}
transition(E1, C1_Load_L1miss, E1_F) {L1D1TagArrayRead, L2TagArrayRead, L2DataArrayRead} {
a1_allocateL1D;
l11m_profileMiss;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(E1, C0_Load_L1miss, E1_Es) {L1D0TagArrayRead, L2TagArrayRead, L2DataArrayRead} {
a0_allocateL1D;
l10m_profileMiss;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(E1, Ifetch1_L1miss, S1) {L2TagArrayRead, L1ITagArrayRead} {
l2m_profileMiss; // permissions miss, still issue RdBlkS
l1im_profileMiss;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
i1_invCluster;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
transition(E1, Ifetch0_L1miss, S0) {L2TagArrayRead,L1ITagArrayRead} {
l2m_profileMiss; // permissions miss, still issue RdBlkS
l1im_profileMiss;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
i1_invCluster;
nS_issueRdBlkS;
p_popMandatoryQueue;
}
transition(E1, {C1_Store_L1hit, C1_Store_L1miss}, M1) {L1D1TagArrayRead, L1D1TagArrayWrite, L2TagArrayRead, L2DataArrayWrite, L2TagArrayWrite} {
a1_allocateL1D;
s1_storeDone;
p_popMandatoryQueue;
}
transition(E1, C0_Store_L1miss, M0) {L1D0TagArrayRead, L1D0TagArrayWrite, L2TagArrayRead, L2TagArrayWrite, L2DataArrayWrite} {
l10m_profileMiss;
a0_allocateL1D;
i1_invCluster;
s0_storeDone;
p_popMandatoryQueue;
}
transition({O}, {C0_Store_L1hit, C0_Store_L1miss}, O_M0) {L1D0TagArrayRead, L2TagArrayRead} {
l2m_profileMiss; // permissions miss, still issue CtoD
l10m_profileMiss;
a0_allocateL1D;
i1_invCluster;
ii_invIcache;
nM_issueRdBlkM;
p_popMandatoryQueue;
}
transition({O}, {C1_Store_L1hit, C1_Store_L1miss}, O_M1) {L1D1TagArrayRead, L2TagArrayRead} {
l2m_profileMiss; // permissions miss, still issue RdBlkS
l11m_profileMiss;
a1_allocateL1D;
i0_invCluster;
ii_invIcache;
nM_issueRdBlkM;
p_popMandatoryQueue;
}
transition(O, C0_Load_L1miss, O_F0) {L2TagArrayRead, L2DataArrayRead, L1D0TagArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(O, C1_Load_L1miss, O_F1) {L2TagArrayRead, L2DataArrayRead, L1D1TagArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(Ms, C0_Load_L1miss, Ms_F0) {L2TagArrayRead, L2DataArrayRead, L1D0TagArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(Ms, C1_Load_L1miss, Ms_F1) {L2TagArrayRead, L2DataArrayRead, L1D1TagArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition({Ms, M0, M1, O}, Ifetch0_L1miss, MO_S0) {L1ITagArrayRead, L2TagArrayRead} {
l2m_profileMiss; // permissions miss
l1im_profileMiss;
ai_allocateL1I;
t_allocateTBE;
ib_invBothClusters;
vd_victim;
// i2_invL2;
p_popMandatoryQueue;
}
transition({Ms, M0, M1, O}, Ifetch1_L1miss, MO_S1) {L1ITagArrayRead L2TagArrayRead } {
l2m_profileMiss; // permissions miss
l10m_profileMiss;
ai_allocateL1I;
t_allocateTBE;
ib_invBothClusters;
vd_victim;
// i2_invL2;
p_popMandatoryQueue;
}
transition(Ms, {C0_Store_L1hit, C0_Store_L1miss}, M0) {L1D0TagArrayRead, L1D0TagArrayWrite, L1D0DataArrayWrite, L2TagArrayRead, L2DataArrayWrite, L2TagArrayWrite} {
a0_allocateL1D;
i1_invCluster;
s0_storeDone;
p_popMandatoryQueue;
}
transition(Ms, {C1_Store_L1hit, C1_Store_L1miss}, M1) {L1D1TagArrayRead, L1D1TagArrayWrite, L1D1DataArrayWrite, L2TagArrayRead, L2DataArrayWrite, L2TagArrayWrite} {
a1_allocateL1D;
i0_invCluster;
s1_storeDone;
p_popMandatoryQueue;
}
transition(M0, C0_Load_L1miss, M0_F) {L1D0TagArrayRead, L2TagArrayRead, L2DataArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(M0, C1_Load_L1miss, M0_Ms) {L2TagArrayRead, L2DataArrayRead,L1D1TagArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(M0, {C0_Store_L1hit, C0_Store_L1miss}) {L1D0TagArrayRead, L1D0DataArrayWrite, L2DataArrayWrite, L2TagArrayRead} {
a0_allocateL1D;
s0_storeDone;
p_popMandatoryQueue;
}
transition(M0, {C1_Store_L1hit, C1_Store_L1miss}, M1) {L1D0TagArrayRead, L1D0TagArrayWrite, L1D0DataArrayWrite, L2DataArrayWrite, L2TagArrayRead, L2TagArrayWrite} {
a1_allocateL1D;
i0_invCluster;
s1_storeDone;
p_popMandatoryQueue;
}
transition(M1, C0_Load_L1miss, M1_Ms) {L2TagArrayRead, L2DataArrayRead, L1D0TagArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(M1, C1_Load_L1miss, M1_F) {L1D1TagArrayRead L2TagArrayRead, L2DataArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(M1, {C0_Store_L1hit, C0_Store_L1miss}, M0) {L1D0TagArrayRead, L1D0TagArrayWrite, L1D0DataArrayWrite, L2TagArrayRead, L2DataArrayWrite, L2TagArrayWrite} {
a0_allocateL1D;
i1_invCluster;
s0_storeDone;
p_popMandatoryQueue;
}
transition(M1, {C1_Store_L1hit, C1_Store_L1miss}) {L1D1TagArrayRead, L1D1DataArrayWrite, L2TagArrayRead, L2DataArrayWrite} {
a1_allocateL1D;
s1_storeDone;
p_popMandatoryQueue;
}
// end transitions from base
// Begin simple hit transitions
transition({S, Es, E0, O, Ms, M0, O_F1, S_F1, Si_F0, Si_F1, Es_F1, E0_Es,
Ms_F1, M0_Ms}, C0_Load_L1hit) {L1D0TagArrayRead, L1D0DataArrayRead} {
// track hits, if implemented
l0_loadDone;
p_popMandatoryQueue;
}
transition({S, Es, E1, O, Ms, M1, O_F0, S_F0, Si_F0, Si_F1, Es_F0, E1_Es,
Ms_F0, M1_Ms}, C1_Load_L1hit) {L1D1TagArrayRead, L1D1DataArrayRead} {
// track hits, if implemented
l1_loadDone;
p_popMandatoryQueue;
}
transition({S, S_C, S_F0, S_F1, S_F}, Ifetch0_L1hit) {L1ITagArrayRead, L1IDataArrayRead} {
// track hits, if implemented
il0_loadDone;
p_popMandatoryQueue;
}
transition({S, S_C, S_F0, S_F1, S_F}, Ifetch1_L1hit) {L1ITagArrayRead, L1IDataArrayWrite} {
// track hits, if implemented
il1_loadDone;
p_popMandatoryQueue;
}
// end simple hit transitions
// Transitions from transient states
// recycles
transition({I_M0, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E0S, I_ES, IF_E0S, IF_ES,
IF0_ES, IF1_ES, S_F0, S_F, O_F0, O_F, S_M0, O_M0, Es_F0, Es_F, E0_F,
E1_Es, Ms_F0, Ms_F, M0_F, M1_Ms}, C0_Load_L1hit) {} {
zz_recycleMandatoryQueue;
}
transition({IF_E1S, F_S0, F_S1, ES_I, MO_I, MO_S0, MO_S1, Si_F0, Si_F1, S_M1,
O_M1, S0, S1, I_C, S0_C, S1_C, S_C}, C0_Load_L1miss) {} {
zz_recycleMandatoryQueue;
}
transition({I_M1, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E1S, I_ES, IF_E1S, IF_ES,
IF0_ES, IF1_ES, S_F1, S_F, O_F1, O_F, S_M1, O_M1, Es_F1, Es_F, E1_F,
E0_Es, Ms_F1, Ms_F, M0_Ms, M1_F}, C1_Load_L1hit) {} {
zz_recycleMandatoryQueue;
}
transition({IF_E0S, F_S0, F_S1, ES_I, MO_I, MO_S0, MO_S1, Si_F0, Si_F1, S_M0,
O_M0, S0, S1, I_C, S0_C, S1_C, S_C}, C1_Load_L1miss) {} {
zz_recycleMandatoryQueue;
}
transition({F_S0, F_S1, MO_S0, MO_S1, Si_F0, Si_F1, S0, S1, S0_C, S1_C}, {Ifetch0_L1hit, Ifetch1_L1hit}) {} {
zz_recycleMandatoryQueue;
}
transition({I_M0, I_M1, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E0S, I_E1S, I_ES,
IF_E0S, IF_E1S, IF_ES, IF0_ES, IF1_ES, ES_I, MO_I, S_F0, S_F1, S_F,
O_F0, O_F1, O_F, S_M0, S_M1, O_M0, O_M1, Es_F0, Es_F1, Es_F, E0_F,
E1_F, E0_Es, E1_Es, Ms_F0, Ms_F1, Ms_F, M0_F, M0_Ms, M1_F, M1_Ms, I_C,
S_C}, {Ifetch0_L1miss, Ifetch1_L1miss}) {} {
zz_recycleMandatoryQueue;
}
transition({I_E1S, IF_E1S, F_S0, F_S1, ES_I, MO_I, MO_S0, MO_S1, S_F1, O_F1,
Si_F0, Si_F1, S_M1, O_M1, S0, S1, Es_F1, E1_F, E0_Es, Ms_F1, M0_Ms,
M1_F, I_C, S0_C, S1_C, S_C}, {C0_Store_L1miss}) {} {
zz_recycleMandatoryQueue;
}
transition({I_E0S, IF_E0S, F_S0, F_S1, ES_I, MO_I, MO_S0, MO_S1 S_F0, O_F0,
Si_F0, Si_F1, S_M0, O_M0, S0, S1, Es_F0, E0_F, E1_Es, Ms_F0, M0_F,
M1_Ms, I_C, S0_C, S1_C, S_C}, {C1_Store_L1miss}) {} {
zz_recycleMandatoryQueue;
}
transition({I_M0, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E0S, I_ES, IF_E0S, IF_ES,
IF0_ES, IF1_ES, S_F0, S_F1, S_F, O_F0, O_F1, O_F, Si_F0, Si_F1, S_M0, O_M0, Es_F0, Es_F1, Es_F, E0_F, E0_Es, E1_Es, Ms_F0, Ms_F1, Ms_F, M0_F, M0_Ms, M1_Ms}, {C0_Store_L1hit}) {} {
zz_recycleMandatoryQueue;
}
transition({I_M1, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E1S, I_ES, IF_E1S, IF_ES,
IF0_ES, IF1_ES, S_F0, S_F1, S_F, O_F0, O_F1, O_F, Si_F0, Si_F1, S_M1,
O_M1, Es_F0, Es_F1, Es_F, E1_F, E0_Es, E1_Es, Ms_F0, Ms_F1, Ms_F,
M0_Ms, M1_F, M1_Ms}, {C1_Store_L1hit}) {} {
zz_recycleMandatoryQueue;
}
transition({I_M0, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E0S, I_ES, IF_E0S, IF_ES,
IF0_ES, IF1_ES, S_F0, S_F, O_F0, O_F, S_M0, O_M0, Es_F0, Es_F, E0_F,
E1_Es, Ms_F0, Ms_F, M0_F, M1_Ms}, L1D0_Repl) {} {
zz_recycleMandatoryQueue;
}
transition({I_M1, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E1S, I_ES, IF_E1S, IF_ES,
IF0_ES, IF1_ES, S_F1, S_F, O_F1, O_F, S_M1, O_M1, Es_F1, Es_F, E1_F,
E0_Es, Ms_F1, Ms_F, M0_Ms, M1_F}, L1D1_Repl) {} {
zz_recycleMandatoryQueue;
}
transition({F_S0, F_S1, MO_S0, MO_S1, Si_F0, Si_F1, S0, S1, S0_C, S1_C}, L1I_Repl) {} {
zz_recycleMandatoryQueue;
}
transition({S_C, S0_C, S1_C, S0, S1, Si_F0, Si_F1, I_M0, I_M1, I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_E0S, I_E1S, I_ES, S_F0, S_F1, S_F, O_F0, O_F1, O_F, S_M0, O_M0, S_M1, O_M1, Es_F0, Es_F1, Es_F, E0_F, E1_F, E0_Es, E1_Es, Ms_F0, Ms_F1, Ms_F, M0_F, M0_Ms, M1_F, M1_Ms, MO_S0, MO_S1, IF_E0S, IF_E1S, IF_ES, IF0_ES, IF1_ES, F_S0, F_S1}, L2_Repl) {} {
zz_recycleMandatoryQueue;
}
transition({IF_E0S, IF_E1S, IF_ES, IF0_ES, IF1_ES, F_S0, F_S1}, {NB_AckS,
PrbInvData, PrbInvDataDemand, PrbInv, PrbShrData, PrbShrDataDemand}) {} {
zz_recycleMandatoryQueue; // these should be resolved soon, but I didn't want to add more states, though technically they could be solved now, and probes really could be solved but i don't think it's really necessary.
}
transition({IF_E0S, IF_E1S, IF_ES, IF0_ES, IF1_ES}, NB_AckE) {} {
zz_recycleMandatoryQueue; // these should be resolved soon, but I didn't want to add more states, though technically they could be solved now, and probes really could be solved but i don't think it's really necessary.
}
transition({E0_Es, E1_F, Es_F1}, C0_Load_L1miss, Es_F) {L2DataArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(S_F1, C0_Load_L1miss, S_F) {L2DataArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(O_F1, C0_Load_L1miss, O_F) {L2DataArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition({Ms_F1, M0_Ms, M1_F}, C0_Load_L1miss, Ms_F) {L2DataArrayRead} {
l10m_profileMiss;
a0_allocateL1D;
f0_L2ToL1;
p_popMandatoryQueue;
}
transition(I_M0, C1_Load_L1miss, I_M0Ms){
l11m_profileMiss;
l2m_profileMiss;
a1_allocateL1D;
p_popMandatoryQueue;
}
transition(I_M1, C0_Load_L1miss, I_M1Ms){
l10m_profileMiss;
l2m_profileMiss;
a0_allocateL1D;
p_popMandatoryQueue;
}
transition(I_M0, C1_Store_L1miss, I_M0M1) {
l11m_profileMiss;
l2m_profileMiss;
a1_allocateL1D;
p_popMandatoryQueue;
}
transition(I_M1, C0_Store_L1miss, I_M1M0) {L1D0TagArrayRead, L1D0TagArrayWrite, L2TagArrayRead, L2TagArrayWrite} {
l2m_profileMiss;
a0_allocateL1D;
p_popMandatoryQueue;
}
transition(I_E0S, C1_Load_L1miss, I_ES) {} {
l2m_profileMiss;
l11m_profileMiss;
a1_allocateL1D;
p_popMandatoryQueue;
}
transition(I_E1S, C0_Load_L1miss, I_ES) {} {
l2m_profileMiss;
l10m_profileMiss;
l2m_profileMiss;
a0_allocateL1D;
p_popMandatoryQueue;
}
transition({E1_Es, E0_F, Es_F0}, C1_Load_L1miss, Es_F) {L2DataArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(S_F0, C1_Load_L1miss, S_F) { L2DataArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition(O_F0, C1_Load_L1miss, O_F) {L2DataArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition({Ms_F0, M1_Ms, M0_F}, C1_Load_L1miss, Ms_F) {L2DataArrayRead} {
l11m_profileMiss;
a1_allocateL1D;
f1_L2ToL1;
p_popMandatoryQueue;
}
transition({S, Es, E0, O, Ms, M0, O_F1, S_F1, Si_F0, Si_F1, Es_F1, E0_Es, Ms_F1, M0_Ms}, L1D0_Repl) {L1D0TagArrayRead} {
i0_invCluster;
}
transition({S, Es, E1, O, Ms, M1, O_F0, S_F0, Si_F0, Si_F1, Es_F0, E1_Es, Ms_F0, M1_Ms}, L1D1_Repl) {L1D1TagArrayRead} {
i1_invCluster;
}
transition({S, S_C, S_F0, S_F1}, L1I_Repl) {L1ITagArrayRead} {
ii_invIcache;
}
transition({S, E0, E1, Es}, L2_Repl, ES_I) {L2TagArrayRead,L1D0TagArrayRead, L1D1TagArrayRead, L1ITagArrayRead} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
t_allocateTBE;
vc_victim;
ib_invBothClusters;
i2_invL2;
ii_invIcache;
}
transition({Ms, M0, M1, O}, L2_Repl, MO_I) {L2TagArrayRead, L2TagArrayWrite, L1D0TagArrayRead, L1D1TagArrayRead} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
t_allocateTBE;
vd_victim;
i2_invL2;
ib_invBothClusters; // nothing will happen for D0 on M1, vice versa
}
transition(S0, NB_AckS, S) {L1D0DataArrayWrite, L1D0TagArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
wi_writeIcache;
xi0_loadDone;
uu_sendUnblock;
sdv_sendDoneValid;
pr_popResponseQueue;
}
transition(S1, NB_AckS, S) {L1D1DataArrayWrite, L1D1TagArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
wi_writeIcache;
xi1_loadDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(S0_C, NB_AckS, S_C) { L1IDataArrayWrite,L2DataArrayWrite} {
// does not need send done since the rdblks was "sinked"
wi_writeIcache;
xi0_loadDone;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(S1_C, NB_AckS, S_C) { L1D1DataArrayWrite,L2DataArrayWrite} {
wi_writeIcache;
xi1_loadDone;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(I_M0, NB_AckM, M0) { L1D0DataArrayWrite, L1D0TagArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
w0_writeDcache;
xs0_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(I_M1, NB_AckM, M1) {L1D1DataArrayWrite, L1D1TagArrayWrite,L2DataArrayWrite, L2TagArrayWrite} {
w1_writeDcache;
xs1_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
// THESE MO->M1 should not be instantaneous but oh well for now.
transition(I_M0M1, NB_AckM, M1) {L1D1DataArrayWrite, L1D1TagArrayWrite,L2DataArrayWrite, L2TagArrayWrite} {
w0_writeDcache;
xs0_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
i0_invCluster;
s1_storeDone;
pr_popResponseQueue;
}
transition(I_M1M0, NB_AckM, M0) {L1D0DataArrayWrite, L1D0TagArrayWrite,L2DataArrayWrite, L2TagArrayWrite} {
w1_writeDcache;
xs1_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
i1_invCluster;
s0_storeDone;
pr_popResponseQueue;
}
// Above shoudl be more like this, which has some latency to xfer to L1
transition(I_M0Ms, NB_AckM, M0_Ms) {L1D0DataArrayWrite,L2DataArrayWrite} {
w0_writeDcache;
xs0_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
f1_L2ToL1;
pr_popResponseQueue;
}
transition(I_M1Ms, NB_AckM, M1_Ms) {L1D1DataArrayWrite,L2DataArrayWrite} {
w1_writeDcache;
xs1_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
f0_L2ToL1;
pr_popResponseQueue;
}
transition(I_E0S, NB_AckE, E0) {L1D0DataArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
w0_writeDcache;
xl0_loadDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(I_E1S, NB_AckE, E1) {L1D1DataArrayWrite, L1D1TagArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
w1_writeDcache;
xl1_loadDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(I_ES, NB_AckE, Es) {L1D1DataArrayWrite, L1D1TagArrayWrite, L1D0DataArrayWrite, L1D0TagArrayWrite, L2DataArrayWrite, L2TagArrayWrite } {
w0_writeDcache;
xl0_loadDone;
w1_writeDcache;
xl1_loadDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(I_E0S, NB_AckS, S) {L1D0DataArrayWrite, L1D0TagArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
w0_writeDcache;
xl0_loadDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(I_E1S, NB_AckS, S) {L1D1TagArrayWrite, L1D1DataArrayWrite, L2TagArrayWrite, L2DataArrayWrite} {
w1_writeDcache;
xl1_loadDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(I_ES, NB_AckS, S) {L1D0TagArrayWrite, L1D0DataArrayWrite, L2TagArrayWrite, L2DataArrayWrite} {
w0_writeDcache;
xl0_loadDone;
w1_writeDcache;
xl1_loadDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(S_F0, L2_to_L1D0, S) {L1D0TagArrayWrite, L1D0DataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(S_F1, L2_to_L1D1, S) {L1D1TagArrayWrite, L1D1DataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(Si_F0, L2_to_L1I, S) {L1ITagArrayWrite, L1IDataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
ci_copyL2ToL1;
il0_loadDone;
pt_popTriggerQueue;
}
transition(Si_F1, L2_to_L1I, S) {L1ITagArrayWrite, L1IDataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
ci_copyL2ToL1;
il1_loadDone;
pt_popTriggerQueue;
}
transition(S_F, L2_to_L1D0, S_F1) { L1D0DataArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(S_F, L2_to_L1D1, S_F0) { L1D1DataArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(O_F0, L2_to_L1D0, O) { L1D0DataArrayWrite, L1D0TagArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(O_F1, L2_to_L1D1, O) {L1D1DataArrayWrite, L1D1TagArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(O_F, L2_to_L1D0, O_F1) { L1D0DataArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(O_F, L2_to_L1D1, O_F0) { L1D1DataArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(M1_F, L2_to_L1D1, M1) {L1D1DataArrayWrite, L1D1TagArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(M0_F, L2_to_L1D0, M0) {L1D0DataArrayWrite, L1D0TagArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(Ms_F0, L2_to_L1D0, Ms) {L1D0DataArrayWrite, L1D0TagArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(Ms_F1, L2_to_L1D1, Ms) {L1D1DataArrayWrite, L1D1TagArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(Ms_F, L2_to_L1D0, Ms_F1) {L1D0DataArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(Ms_F, L2_to_L1D1, Ms_F0) {L1IDataArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(M1_Ms, L2_to_L1D0, Ms) {L1D0TagArrayWrite, L1D0DataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(M0_Ms, L2_to_L1D1, Ms) {L1D1TagArrayWrite, L1D1DataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(Es_F0, L2_to_L1D0, Es) {L1D0TagArrayWrite, L1D0DataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(Es_F1, L2_to_L1D1, Es) {L1D1TagArrayWrite, L1D1DataArrayWrite, L2TagArrayWrite, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(Es_F, L2_to_L1D0, Es_F1) {L2TagArrayRead, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(Es_F, L2_to_L1D1, Es_F0) {L2TagArrayRead, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(E0_F, L2_to_L1D0, E0) {L2TagArrayRead, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(E1_F, L2_to_L1D1, E1) {L2TagArrayRead, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(E1_Es, L2_to_L1D0, Es) {L2TagArrayRead, L2DataArrayRead} {
c0_copyL2ToL1;
l0_loadDone;
pt_popTriggerQueue;
}
transition(E0_Es, L2_to_L1D1, Es) {L2TagArrayRead, L2DataArrayRead} {
c1_copyL2ToL1;
l1_loadDone;
pt_popTriggerQueue;
}
transition(IF_E0S, L2_to_L1D0, I_E0S) {} {
pt_popTriggerQueue;
}
transition(IF_E1S, L2_to_L1D1, I_E1S) {} {
pt_popTriggerQueue;
}
transition(IF_ES, L2_to_L1D0, IF1_ES) {} {
pt_popTriggerQueue;
}
transition(IF_ES, L2_to_L1D1, IF0_ES) {} {
pt_popTriggerQueue;
}
transition(IF0_ES, L2_to_L1D0, I_ES) {} {
pt_popTriggerQueue;
}
transition(IF1_ES, L2_to_L1D1, I_ES) {} {
pt_popTriggerQueue;
}
transition(F_S0, L2_to_L1I, S0) {} {
pt_popTriggerQueue;
}
transition(F_S1, L2_to_L1I, S1) {} {
pt_popTriggerQueue;
}
transition({S_M0, O_M0}, NB_AckM, M0) {L1D0TagArrayWrite, L1D0DataArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
xs0_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition({S_M1, O_M1}, NB_AckM, M1) {L1D1TagArrayWrite, L1D1DataArrayWrite, L2DataArrayWrite, L2TagArrayWrite} {
xs1_storeDone;
sdv_sendDoneValid;
uu_sendUnblock;
pr_popResponseQueue;
}
transition(MO_I, NB_AckWB, I) {L2TagArrayWrite} {
wb_data;
ra_sendReplAck;
sdi_sendDoneInvalid;
d_deallocateTBE;
pr_popResponseQueue;
}
transition(ES_I, NB_AckWB, I) {L2TagArrayWrite} {
wb_data;
ra_sendReplAck;
sdi_sendDoneInvalid;
d_deallocateTBE;
pr_popResponseQueue;
}
transition(MO_S0, NB_AckWB, S0) {L2TagArrayWrite} {
wb_data;
i2_invL2;
a2_allocateL2;
sdv_sendDoneValid;
nS_issueRdBlkS;
d_deallocateTBE; // FOO
pr_popResponseQueue;
}
transition(MO_S1, NB_AckWB, S1) {L2TagArrayWrite} {
wb_data;
i2_invL2;
a2_allocateL2;
sdv_sendDoneValid;
nS_issueRdBlkS;
d_deallocateTBE; // FOO
pr_popResponseQueue;
}
// Writeback cancel "ack"
transition(I_C, NB_AckWB, I) {L2TagArrayWrite} {
ss_sendStaleNotification;
sdi_sendDoneInvalid;
d_deallocateTBE;
pr_popResponseQueue;
}
transition(S0_C, NB_AckWB, S0) {L2TagArrayWrite} {
ss_sendStaleNotification;
sdv_sendDoneValid;
pr_popResponseQueue;
}
transition(S1_C, NB_AckWB, S1) {L2TagArrayWrite} {
ss_sendStaleNotification;
sdv_sendDoneValid;
pr_popResponseQueue;
}
transition(S_C, NB_AckWB, S) {L2TagArrayWrite} {
ss_sendStaleNotification;
sdv_sendDoneValid;
pr_popResponseQueue;
}
// Begin Probe Transitions
transition({Ms, M0, M1, O}, {PrbInvData, PrbInvDataDemand}, I) {L2TagArrayRead, L2TagArrayWrite, L2DataArrayRead} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pd_sendProbeResponseData;
i2_invL2;
ib_invBothClusters;
pp_popProbeQueue;
}
transition({Es, E0, E1, S, I}, {PrbInvData, PrbInvDataDemand}, I) {L2TagArrayRead, L2TagArrayWrite} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
i2_invL2;
ib_invBothClusters;
ii_invIcache; // only relevant for S
pp_popProbeQueue;
}
transition(S_C, {PrbInvData, PrbInvDataDemand}, I_C) {L2TagArrayWrite} {
t_allocateTBE;
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
i2_invL2;
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition(I_C, {PrbInvData, PrbInvDataDemand}, I_C) {} {
pi_sendProbeResponseInv;
ib_invBothClusters;
pp_popProbeQueue;
}
transition({Ms, M0, M1, O, Es, E0, E1, S, I}, PrbInv, I) {L2TagArrayRead, L2TagArrayWrite} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
i2_invL2; // nothing will happen in I
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition(S_C, PrbInv, I_C) {L2TagArrayWrite} {
t_allocateTBE;
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
i2_invL2;
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition(I_C, PrbInv, I_C) {} {
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition({Ms, M0, M1, O}, {PrbShrData, PrbShrDataDemand}, O) {L2TagArrayRead, L2TagArrayWrite, L2DataArrayRead} {
pd_sendProbeResponseData;
pp_popProbeQueue;
}
transition({Es, E0, E1, S}, {PrbShrData, PrbShrDataDemand}, S) {L2TagArrayRead, L2TagArrayWrite} {
ph_sendProbeResponseHit;
pp_popProbeQueue;
}
transition(S_C, {PrbShrData, PrbShrDataDemand}) {} {
ph_sendProbeResponseHit;
pp_popProbeQueue;
}
transition({I, I_C}, {PrbShrData, PrbShrDataDemand}) {L2TagArrayRead} {
pb_sendProbeResponseBackprobe;
pp_popProbeQueue;
}
transition({I_M0, I_E0S}, {PrbInv, PrbInvData, PrbInvDataDemand}) {} {
pi_sendProbeResponseInv;
ib_invBothClusters; // must invalidate current data (only relevant for I_M0)
a0_allocateL1D; // but make sure there is room for incoming data when it arrives
pp_popProbeQueue;
}
transition({I_M1, I_E1S}, {PrbInv, PrbInvData, PrbInvDataDemand}) {} {
pi_sendProbeResponseInv;
ib_invBothClusters; // must invalidate current data (only relevant for I_M1)
a1_allocateL1D; // but make sure there is room for incoming data when it arrives
pp_popProbeQueue;
}
transition({I_M0M1, I_M1M0, I_M0Ms, I_M1Ms, I_ES}, {PrbInv, PrbInvData, PrbInvDataDemand, PrbShrData, PrbShrDataDemand}) {} {
pi_sendProbeResponseInv;
ib_invBothClusters;
a0_allocateL1D;
a1_allocateL1D;
pp_popProbeQueue;
}
transition({I_M0, I_E0S, I_M1, I_E1S}, {PrbShrData, PrbShrDataDemand}) {} {
pb_sendProbeResponseBackprobe;
pp_popProbeQueue;
}
transition(ES_I, {PrbInvData, PrbInvDataDemand}, I_C) {} {
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition(MO_I, {PrbInvData, PrbInvDataDemand}, I_C) {} {
pdt_sendProbeResponseDataFromTBE;
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition(MO_I, PrbInv, I_C) {} {
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition(ES_I, PrbInv, I_C) {} {
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
pp_popProbeQueue;
}
transition(ES_I, {PrbShrData, PrbShrDataDemand}, ES_I) {} {
ph_sendProbeResponseHit;
s_setSharedFlip;
pp_popProbeQueue;
}
transition(MO_I, {PrbShrData, PrbShrDataDemand}, MO_I) {} {
pdt_sendProbeResponseDataFromTBE;
s_setSharedFlip;
pp_popProbeQueue;
}
transition(MO_S0, {PrbInvData, PrbInvDataDemand}, S0_C) {L2TagArrayWrite} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pdt_sendProbeResponseDataFromTBE;
i2_invL2;
a2_allocateL2;
nS_issueRdBlkS;
d_deallocateTBE;
pp_popProbeQueue;
}
transition(MO_S1, {PrbInvData, PrbInvDataDemand}, S1_C) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pdt_sendProbeResponseDataFromTBE;
i2_invL2;
a2_allocateL2;
nS_issueRdBlkS;
d_deallocateTBE;
pp_popProbeQueue;
}
transition(MO_S0, PrbInv, S0_C) {L2TagArrayWrite} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
i2_invL2;
a2_allocateL2;
nS_issueRdBlkS;
d_deallocateTBE;
pp_popProbeQueue;
}
transition(MO_S1, PrbInv, S1_C) {L2TagArrayWrite} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
i2_invL2;
a2_allocateL2;
nS_issueRdBlkS;
d_deallocateTBE;
pp_popProbeQueue;
}
transition({MO_S0, MO_S1}, {PrbShrData, PrbShrDataDemand}) {} {
pdt_sendProbeResponseDataFromTBE;
s_setSharedFlip;
pp_popProbeQueue;
}
transition({S_F0, Es_F0, E0_F, E1_Es}, {PrbInvData, PrbInvDataDemand, PrbInv}, IF_E0S) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
// invalidate everything you've got
ib_invBothClusters;
ii_invIcache;
i2_invL2;
// but make sure you have room for what you need from the fill
a0_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({S_F1, Es_F1, E1_F, E0_Es}, {PrbInvData, PrbInvDataDemand, PrbInv}, IF_E1S) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
// invalidate everything you've got
ib_invBothClusters;
ii_invIcache;
i2_invL2;
// but make sure you have room for what you need from the fill
a1_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({S_F, Es_F}, {PrbInvData, PrbInvDataDemand, PrbInv}, IF_ES) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
// invalidate everything you've got
ib_invBothClusters;
ii_invIcache;
i2_invL2;
// but make sure you have room for what you need from the fill
a0_allocateL1D;
a1_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition(Si_F0, {PrbInvData, PrbInvDataDemand, PrbInv}, F_S0) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
nS_issueRdBlkS;
pp_popProbeQueue;
}
transition(Si_F1, {PrbInvData, PrbInvDataDemand, PrbInv}, F_S1) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
nS_issueRdBlkS;
pp_popProbeQueue;
}
transition({Es_F0, E0_F, E1_Es}, {PrbShrData, PrbShrDataDemand}, S_F0) {} {
ph_sendProbeResponseHit;
pp_popProbeQueue;
}
transition({Es_F1, E1_F, E0_Es}, {PrbShrData, PrbShrDataDemand}, S_F1) {} {
ph_sendProbeResponseHit;
pp_popProbeQueue;
}
transition(Es_F, {PrbShrData, PrbShrDataDemand}, S_F) {} {
ph_sendProbeResponseHit;
pp_popProbeQueue;
}
transition({S_F0, S_F1, S_F, Si_F0, Si_F1}, {PrbShrData, PrbShrDataDemand}) {} {
ph_sendProbeResponseHit;
pp_popProbeQueue;
}
transition(S_M0, {PrbInvData, PrbInvDataDemand}, I_M0) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pim_sendProbeResponseInvMs;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
a0_allocateL1D;
a2_allocateL2;
pp_popProbeQueue;
}
transition(O_M0, {PrbInvData, PrbInvDataDemand}, I_M0) {L2DataArrayRead} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pdm_sendProbeResponseDataMs;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
a0_allocateL1D;
a2_allocateL2;
pp_popProbeQueue;
}
transition({S_M0, O_M0}, {PrbInv}, I_M0) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pim_sendProbeResponseInvMs;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
a0_allocateL1D;
a2_allocateL2;
pp_popProbeQueue;
}
transition(S_M1, {PrbInvData, PrbInvDataDemand}, I_M1) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pim_sendProbeResponseInvMs;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
a1_allocateL1D;
a2_allocateL2;
pp_popProbeQueue;
}
transition(O_M1, {PrbInvData, PrbInvDataDemand}, I_M1) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pdm_sendProbeResponseDataMs;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
a1_allocateL1D;
a2_allocateL2;
pp_popProbeQueue;
}
transition({S_M1, O_M1}, {PrbInv}, I_M1) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pim_sendProbeResponseInvMs;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
a1_allocateL1D;
a2_allocateL2;
pp_popProbeQueue;
}
transition({S0, S0_C}, {PrbInvData, PrbInvDataDemand, PrbInv}) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
pp_popProbeQueue;
}
transition({S1, S1_C}, {PrbInvData, PrbInvDataDemand, PrbInv}) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
ib_invBothClusters;
ii_invIcache;
i2_invL2;
ai_allocateL1I;
a2_allocateL2;
pp_popProbeQueue;
}
transition({S_M0, S_M1}, {PrbShrData, PrbShrDataDemand}) {} {
ph_sendProbeResponseHit;
pp_popProbeQueue;
}
transition({O_M0, O_M1}, {PrbShrData, PrbShrDataDemand}) {L2DataArrayRead} {
pd_sendProbeResponseData;
pp_popProbeQueue;
}
transition({S0, S1, S0_C, S1_C}, {PrbShrData, PrbShrDataDemand}) {} {
pb_sendProbeResponseBackprobe;
pp_popProbeQueue;
}
transition({Ms_F0, M0_F, M1_Ms, O_F0}, {PrbInvData, PrbInvDataDemand}, IF_E0S) {L2DataArrayRead} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pd_sendProbeResponseData;
ib_invBothClusters;
i2_invL2;
a0_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({Ms_F1, M1_F, M0_Ms, O_F1}, {PrbInvData, PrbInvDataDemand}, IF_E1S) {L2DataArrayRead} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pd_sendProbeResponseData;
ib_invBothClusters;
i2_invL2;
a1_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({Ms_F, O_F}, {PrbInvData, PrbInvDataDemand}, IF_ES) {L2DataArrayRead} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pd_sendProbeResponseData;
ib_invBothClusters;
i2_invL2;
a0_allocateL1D;
a1_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({Ms_F0, M0_F, M1_Ms, O_F0}, PrbInv, IF_E0S) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
ib_invBothClusters;
i2_invL2;
a0_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({Ms_F1, M1_F, M0_Ms, O_F1}, PrbInv, IF_E1S) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
ib_invBothClusters;
i2_invL2;
a1_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({Ms_F, O_F}, PrbInv, IF_ES) {} {
forward_eviction_to_cpu0;
forward_eviction_to_cpu1;
pi_sendProbeResponseInv;
ib_invBothClusters;
i2_invL2;
a0_allocateL1D;
a1_allocateL1D;
a2_allocateL2;
n_issueRdBlk;
pp_popProbeQueue;
}
transition({Ms_F0, M0_F, M1_Ms}, {PrbShrData, PrbShrDataDemand}, O_F0) {L2DataArrayRead} {
pd_sendProbeResponseData;
pp_popProbeQueue;
}
transition({Ms_F1, M1_F, M0_Ms}, {PrbShrData, PrbShrDataDemand}, O_F1) {} {
}
transition({Ms_F}, {PrbShrData, PrbShrDataDemand}, O_F) {L2DataArrayRead} {
pd_sendProbeResponseData;
pp_popProbeQueue;
}
transition({O_F0, O_F1, O_F}, {PrbShrData, PrbShrDataDemand}) {L2DataArrayRead} {
pd_sendProbeResponseData;
pp_popProbeQueue;
}
// END TRANSITIONS
}