/* * Copyright (c) 1999-2005 Mark D. Hill and David A. Wood * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer; * redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution; * neither the name of the copyright holders nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * $Id: MSI_MOSI_CMP_directory-L2cache.sm 1.12 05/01/19 15:55:40-06:00 beckmann@s0-28.cs.wisc.edu $ * */ machine(L2Cache, "MOSI Directory L2 Cache CMP") { // L2 BANK QUEUES // From local bank of L2 cache TO the network MessageBuffer DirRequestFromL2Cache, network="To", virtual_network="2", ordered="false"; // this L2 bank -> Memory MessageBuffer L1RequestFromL2Cache, network="To", virtual_network="1", ordered="false"; // this L2 bank -> a local L1 MessageBuffer responseFromL2Cache, network="To", virtual_network="3", ordered="false"; // this L2 bank -> a local L1 || Memory // FROM the network to this local bank of L2 cache MessageBuffer L1RequestToL2Cache, network="From", virtual_network="0", ordered="false"; // a local L1 -> this L2 bank MessageBuffer responseToL2Cache, network="From", virtual_network="3", ordered="false"; // a local L1 || Memory -> this L2 bank MessageBuffer unblockToL2Cache, network="From", virtual_network="4", ordered="false"; // a local L1 || Memory -> this L2 bank // STATES enumeration(State, desc="L2 Cache states", default="L2Cache_State_NP") { // Base states NP, desc="Not present in either cache"; SS, desc="L2 cache entry Shared, also present in one or more L1s"; M, desc="L2 cache entry Modified, not present in any L1s", format="!b"; MT, desc="L2 cache entry Modified in a local L1, assume L2 copy stale", format="!b"; // L2 replacement M_I, desc="L2 cache replacing, have all acks, sent dirty data to memory, waiting for ACK from memory"; MT_I, desc="L2 cache replacing, getting data from exclusive"; MCT_I, desc="L2 cache replacing, clean in L2, getting data or ack from exclusive"; I_I, desc="L2 replacing clean data, need to inv sharers and then drop data"; S_I, desc="L2 replacing dirty data, collecting acks from L1s"; // Transient States for fetching data from memory ISS, desc="L2 idle, got single L1_GETS, issued memory fetch, have not seen response yet"; IS, desc="L2 idle, got L1_GET_INSTR or multiple L1_GETS, issued memory fetch, have not seen response yet"; IM, desc="L2 idle, got L1_GETX, issued memory fetch, have not seen response(s) yet"; // Blocking states SS_MB, desc="Blocked for L1_GETX from SS"; MT_MB, desc="Blocked for L1_GETX from MT"; M_MB, desc="Blocked for L1_GETX from M"; MT_IIB, desc="Blocked for L1_GETS from MT, waiting for unblock and data"; MT_IB, desc="Blocked for L1_GETS from MT, got unblock, waiting for data"; MT_SB, desc="Blocked for L1_GETS from MT, got data, waiting for unblock"; } // EVENTS enumeration(Event, desc="L2 Cache events") { // L2 events // events initiated by the local L1s L1_GET_INSTR, desc="a L1I GET INSTR request for a block maped to us"; L1_GETS, desc="a L1D GETS request for a block maped to us"; L1_GETX, desc="a L1D GETX request for a block maped to us"; L1_UPGRADE, desc="a L1D GETX request for a block maped to us"; L1_PUTX, desc="L1 replacing data"; L1_PUTX_old, desc="L1 replacing data, but no longer sharer"; Fwd_L1_GETX, desc="L1 did not have data, so we supply"; Fwd_L1_GETS, desc="L1 did not have data, so we supply"; Fwd_L1_GET_INSTR, desc="L1 did not have data, so we supply"; // events initiated by this L2 L2_Replacement, desc="L2 Replacement", format="!r"; L2_Replacement_clean, desc="L2 Replacement, but data is clean", format="!r"; // events from memory controller Mem_Data, desc="data from memory", format="!r"; Mem_Ack, desc="ack from memory", format="!r"; // M->S data writeback WB_Data, desc="data from L1"; WB_Data_clean, desc="clean data from L1"; Ack, desc="writeback ack"; Ack_all, desc="writeback ack"; Unblock, desc="Unblock from L1 requestor"; Unblock_Cancel, desc="Unblock from L1 requestor (FOR XACT MEMORY)"; Exclusive_Unblock, desc="Unblock from L1 requestor"; } // TYPES // CacheEntry structure(Entry, desc="...", interface="AbstractCacheEntry") { State CacheState, desc="cache state"; NetDest Sharers, desc="tracks the L1 shares on-chip"; MachineID Exclusive, desc="Exclusive holder of block"; DataBlock DataBlk, desc="data for the block"; bool Dirty, default="false", desc="data is dirty"; } // TBE fields structure(TBE, desc="...") { Address Address, desc="Physical address for this TBE"; State TBEState, desc="Transient state"; DataBlock DataBlk, desc="Buffer for the data block"; bool Dirty, default="false", desc="Data is Dirty"; NetDest L1_GetS_IDs, desc="Set of the internal processors that want the block in shared state"; MachineID L1_GetX_ID, desc="ID of the L1 cache to forward the block to once we get a response"; bool isPrefetch, desc="Set if this was caused by a prefetch"; int pendingAcks, desc="number of pending acks for invalidates during writeback"; } external_type(CacheMemory) { bool cacheAvail(Address); Address cacheProbe(Address); void allocate(Address); void deallocate(Address); Entry lookup(Address); void changePermission(Address, AccessPermission); bool isTagPresent(Address); void setMRU(Address); } external_type(TBETable) { TBE lookup(Address); void allocate(Address); void deallocate(Address); bool isPresent(Address); } TBETable L2_TBEs, template_hack=""; CacheMemory L2cacheMemory, template_hack="", constructor_hack='L2_CACHE_NUM_SETS_BITS,L2_CACHE_ASSOC,MachineType_L2Cache,int_to_string(i)'; // inclusive cache, returns L2 entries only Entry getL2CacheEntry(Address addr), return_by_ref="yes" { return L2cacheMemory[addr]; } void changeL2Permission(Address addr, AccessPermission permission) { if (L2cacheMemory.isTagPresent(addr)) { return L2cacheMemory.changePermission(addr, permission); } } string getCoherenceRequestTypeStr(CoherenceRequestType type) { return CoherenceRequestType_to_string(type); } bool isL2CacheTagPresent(Address addr) { return (L2cacheMemory.isTagPresent(addr)); } bool isOneSharerLeft(Address addr, MachineID requestor) { assert(L2cacheMemory[addr].Sharers.isElement(requestor)); return (L2cacheMemory[addr].Sharers.count() == 1); } bool isSharer(Address addr, MachineID requestor) { if (L2cacheMemory.isTagPresent(addr)) { return L2cacheMemory[addr].Sharers.isElement(requestor); } else { return false; } } void addSharer(Address addr, MachineID requestor) { DEBUG_EXPR(machineID); DEBUG_EXPR(requestor); DEBUG_EXPR(addr); assert(map_L1CacheMachId_to_L2Cache(addr, requestor) == machineID); L2cacheMemory[addr].Sharers.add(requestor); } State getState(Address addr) { if(L2_TBEs.isPresent(addr)) { return L2_TBEs[addr].TBEState; } else if (isL2CacheTagPresent(addr)) { return getL2CacheEntry(addr).CacheState; } return State:NP; } string getStateStr(Address addr) { return L2Cache_State_to_string(getState(addr)); } // when is this called void setState(Address addr, State state) { // MUST CHANGE if (L2_TBEs.isPresent(addr)) { L2_TBEs[addr].TBEState := state; } if (isL2CacheTagPresent(addr)) { getL2CacheEntry(addr).CacheState := state; // Set permission if (state == State:SS ) { changeL2Permission(addr, AccessPermission:Read_Only); } else if (state == State:M) { changeL2Permission(addr, AccessPermission:Read_Write); } else if (state == State:MT) { changeL2Permission(addr, AccessPermission:Stale); } else { changeL2Permission(addr, AccessPermission:Busy); } } } Event L1Cache_request_type_to_event(CoherenceRequestType type, Address addr, MachineID requestor) { if(type == CoherenceRequestType:GETS) { return Event:L1_GETS; } else if(type == CoherenceRequestType:GET_INSTR) { return Event:L1_GET_INSTR; } else if (type == CoherenceRequestType:GETX) { return Event:L1_GETX; } else if (type == CoherenceRequestType:UPGRADE) { if ( isL2CacheTagPresent(addr) && getL2CacheEntry(addr).Sharers.isElement(requestor) ) { return Event:L1_UPGRADE; } else { return Event:L1_GETX; } } else if (type == CoherenceRequestType:PUTX) { if (isSharer(addr, requestor)) { return Event:L1_PUTX; } else { return Event:L1_PUTX_old; } } else { DEBUG_EXPR(addr); DEBUG_EXPR(type); error("Invalid L1 forwarded request type"); } } // ** OUT_PORTS ** out_port(L1RequestIntraChipL2Network_out, RequestMsg, L1RequestFromL2Cache); out_port(DirRequestIntraChipL2Network_out, RequestMsg, DirRequestFromL2Cache); out_port(responseIntraChipL2Network_out, ResponseMsg, responseFromL2Cache); // Response IntraChip L2 Network - response msg to this particular L2 bank in_port(responseIntraChipL2Network_in, ResponseMsg, responseToL2Cache) { if (responseIntraChipL2Network_in.isReady()) { peek(responseIntraChipL2Network_in, ResponseMsg) { // test wether it's from a local L1 or an off chip source assert(in_msg.Destination.isElement(machineID)); if(machineIDToMachineType(in_msg.Sender) == MachineType:L1Cache) { if(in_msg.Type == CoherenceResponseType:DATA) { if (in_msg.Dirty) { trigger(Event:WB_Data, in_msg.Address); } else { trigger(Event:WB_Data_clean, in_msg.Address); } } else if (in_msg.Type == CoherenceResponseType:ACK) { if ((L2_TBEs[in_msg.Address].pendingAcks - in_msg.AckCount) == 0) { trigger(Event:Ack_all, in_msg.Address); } else { trigger(Event:Ack, in_msg.Address); } } else { error("unknown message type"); } } else { // external message if(in_msg.Type == CoherenceResponseType:MEMORY_DATA) { trigger(Event:Mem_Data, in_msg.Address); // L2 now has data and all off-chip acks } else if(in_msg.Type == CoherenceResponseType:MEMORY_ACK) { trigger(Event:Mem_Ack, in_msg.Address); // L2 now has data and all off-chip acks } else { error("unknown message type"); } } } } // if not ready, do nothing } // L1 Request in_port(L1RequestIntraChipL2Network_in, RequestMsg, L1RequestToL2Cache) { if(L1RequestIntraChipL2Network_in.isReady()) { peek(L1RequestIntraChipL2Network_in, RequestMsg) { DEBUG_EXPR(in_msg.Address); DEBUG_EXPR(id); DEBUG_EXPR(getState(in_msg.Address)); DEBUG_EXPR(in_msg.Requestor); DEBUG_EXPR(in_msg.Type); DEBUG_EXPR(in_msg.Destination); assert(machineIDToMachineType(in_msg.Requestor) == MachineType:L1Cache); assert(in_msg.Destination.isElement(machineID)); if (L2cacheMemory.isTagPresent(in_msg.Address)) { // The L2 contains the block, so proceeded with handling the request trigger(L1Cache_request_type_to_event(in_msg.Type, in_msg.Address, in_msg.Requestor), in_msg.Address); } else { if (L2cacheMemory.cacheAvail(in_msg.Address)) { // L2 does't have the line, but we have space for it in the L2 trigger(L1Cache_request_type_to_event(in_msg.Type, in_msg.Address, in_msg.Requestor), in_msg.Address); } else { // No room in the L2, so we need to make room before handling the request if (L2cacheMemory[ L2cacheMemory.cacheProbe(in_msg.Address) ].Dirty ) { trigger(Event:L2_Replacement, L2cacheMemory.cacheProbe(in_msg.Address)); } else { trigger(Event:L2_Replacement_clean, L2cacheMemory.cacheProbe(in_msg.Address)); } } } } } } in_port(L1unblockNetwork_in, ResponseMsg, unblockToL2Cache) { if(L1unblockNetwork_in.isReady()) { peek(L1unblockNetwork_in, ResponseMsg) { assert(in_msg.Destination.isElement(machineID)); if (in_msg.Type == CoherenceResponseType:EXCLUSIVE_UNBLOCK) { trigger(Event:Exclusive_Unblock, in_msg.Address); } else if (in_msg.Type == CoherenceResponseType:UNBLOCK) { trigger(Event:Unblock, in_msg.Address); } else { error("unknown unblock message"); } } } } // ACTIONS action(a_issueFetchToMemory, "a", desc="fetch data from memory") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(DirRequestIntraChipL2Network_out, RequestMsg, latency="L2_REQUEST_LATENCY") { out_msg.Address := address; out_msg.Type := CoherenceRequestType:GETS; out_msg.Requestor := machineID; out_msg.Destination.add(map_Address_to_Directory(address)); out_msg.MessageSize := MessageSizeType:Control; } } } action(b_forwardRequestToExclusive, "b", desc="Forward request to the exclusive L1") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(L1RequestIntraChipL2Network_out, RequestMsg, latency="1") { out_msg.Address := address; out_msg.Type := in_msg.Type; out_msg.Requestor := in_msg.Requestor; out_msg.Destination.add(L2cacheMemory[address].Exclusive); out_msg.MessageSize := MessageSizeType:Request_Control; } } } action(c_exclusiveReplacement, "c", desc="Send data to memory") { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="L2_RESPONSE_LATENCY") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:MEMORY_DATA; out_msg.Sender := machineID; out_msg.Destination.add(map_Address_to_Directory(address)); out_msg.DataBlk := getL2CacheEntry(address).DataBlk; out_msg.Dirty := getL2CacheEntry(address).Dirty; out_msg.MessageSize := MessageSizeType:Response_Data; } } action(ct_exclusiveReplacementFromTBE, "ct", desc="Send data to memory") { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="L2_RESPONSE_LATENCY") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:MEMORY_DATA; out_msg.Sender := machineID; out_msg.Destination.add(map_Address_to_Directory(address)); out_msg.DataBlk := L2_TBEs[address].DataBlk; out_msg.Dirty := L2_TBEs[address].Dirty; out_msg.MessageSize := MessageSizeType:Response_Data; } } action(d_sendDataToRequestor, "d", desc="Send data from cache to reqeustor") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="L2_RESPONSE_LATENCY") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:DATA; out_msg.Sender := machineID; out_msg.Destination.add(in_msg.Requestor); out_msg.DataBlk := getL2CacheEntry(address).DataBlk; out_msg.Dirty := getL2CacheEntry(address).Dirty; out_msg.MessageSize := MessageSizeType:Response_Data; out_msg.AckCount := 0 - getL2CacheEntry(address).Sharers.count(); if (getL2CacheEntry(address).Sharers.isElement(in_msg.Requestor)) { out_msg.AckCount := out_msg.AckCount + 1; } } } } action(dd_sendExclusiveDataToRequestor, "dd", desc="Send data from cache to reqeustor") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="L2_RESPONSE_LATENCY") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:DATA_EXCLUSIVE; out_msg.Sender := machineID; out_msg.Destination.add(in_msg.Requestor); out_msg.DataBlk := getL2CacheEntry(address).DataBlk; out_msg.Dirty := getL2CacheEntry(address).Dirty; out_msg.MessageSize := MessageSizeType:Response_Data; out_msg.AckCount := 0 - getL2CacheEntry(address).Sharers.count(); if (getL2CacheEntry(address).Sharers.isElement(in_msg.Requestor)) { out_msg.AckCount := out_msg.AckCount + 1; } } } } action(ds_sendSharedDataToRequestor, "ds", desc="Send data from cache to reqeustor") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="L2_RESPONSE_LATENCY") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:DATA; out_msg.Sender := machineID; out_msg.Destination.add(in_msg.Requestor); out_msg.DataBlk := getL2CacheEntry(address).DataBlk; out_msg.Dirty := getL2CacheEntry(address).Dirty; out_msg.MessageSize := MessageSizeType:Response_Data; out_msg.AckCount := 0; } } } action(e_sendDataToGetSRequestors, "e", desc="Send data from cache to all GetS IDs") { assert(L2_TBEs[address].L1_GetS_IDs.count() > 0); enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:DATA; out_msg.Sender := machineID; out_msg.Destination := L2_TBEs[address].L1_GetS_IDs; // internal nodes out_msg.DataBlk := getL2CacheEntry(address).DataBlk; out_msg.Dirty := getL2CacheEntry(address).Dirty; out_msg.MessageSize := MessageSizeType:Response_Data; } } action(ex_sendExclusiveDataToGetSRequestors, "ex", desc="Send data from cache to all GetS IDs") { assert(L2_TBEs[address].L1_GetS_IDs.count() == 1); enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:DATA_EXCLUSIVE; out_msg.Sender := machineID; out_msg.Destination := L2_TBEs[address].L1_GetS_IDs; // internal nodes out_msg.DataBlk := getL2CacheEntry(address).DataBlk; out_msg.Dirty := getL2CacheEntry(address).Dirty; out_msg.MessageSize := MessageSizeType:Response_Data; } } action(ee_sendDataToGetXRequestor, "ee", desc="Send data from cache to GetX ID") { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:DATA; out_msg.Sender := machineID; out_msg.Destination.add(L2_TBEs[address].L1_GetX_ID); DEBUG_EXPR(out_msg.Destination); out_msg.DataBlk := getL2CacheEntry(address).DataBlk; out_msg.Dirty := getL2CacheEntry(address).Dirty; DEBUG_EXPR(out_msg.Address); DEBUG_EXPR(out_msg.Destination); DEBUG_EXPR(out_msg.DataBlk); out_msg.MessageSize := MessageSizeType:Response_Data; } } action(f_sendInvToSharers, "f", desc="invalidate sharers for L2 replacement") { enqueue(L1RequestIntraChipL2Network_out, RequestMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceRequestType:INV; out_msg.Requestor := machineID; out_msg.Destination := L2cacheMemory[address].Sharers; out_msg.MessageSize := MessageSizeType:Request_Control; } } action(fw_sendFwdInvToSharers, "fw", desc="invalidate sharers for request") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(L1RequestIntraChipL2Network_out, RequestMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceRequestType:INV; out_msg.Requestor := in_msg.Requestor; out_msg.Destination := L2cacheMemory[address].Sharers; out_msg.MessageSize := MessageSizeType:Request_Control; } } } action(fwm_sendFwdInvToSharersMinusRequestor, "fwm", desc="invalidate sharers for request, requestor is sharer") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(L1RequestIntraChipL2Network_out, RequestMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceRequestType:INV; out_msg.Requestor := in_msg.Requestor; out_msg.Destination := L2cacheMemory[address].Sharers; out_msg.Destination.remove(in_msg.Requestor); out_msg.MessageSize := MessageSizeType:Request_Control; } } } // OTHER ACTIONS action(i_allocateTBE, "i", desc="Allocate TBE for internal/external request(isPrefetch=0, number of invalidates=0)") { check_allocate(L2_TBEs); L2_TBEs.allocate(address); L2_TBEs[address].L1_GetS_IDs.clear(); L2_TBEs[address].DataBlk := getL2CacheEntry(address).DataBlk; L2_TBEs[address].Dirty := getL2CacheEntry(address).Dirty; L2_TBEs[address].pendingAcks := getL2CacheEntry(address).Sharers.count(); } action(s_deallocateTBE, "s", desc="Deallocate external TBE") { L2_TBEs.deallocate(address); } action(jj_popL1RequestQueue, "\j", desc="Pop incoming L1 request queue") { profileMsgDelay(0, L1RequestIntraChipL2Network_in.dequeue_getDelayCycles()); } action(k_popUnblockQueue, "k", desc="Pop incoming unblock queue") { profileMsgDelay(0, L1unblockNetwork_in.dequeue_getDelayCycles()); } action(o_popIncomingResponseQueue, "o", desc="Pop Incoming Response queue") { profileMsgDelay(3, responseIntraChipL2Network_in.dequeue_getDelayCycles()); } action(m_writeDataToCache, "m", desc="Write data from response queue to cache") { peek(responseIntraChipL2Network_in, ResponseMsg) { getL2CacheEntry(address).DataBlk := in_msg.DataBlk; getL2CacheEntry(address).Dirty := in_msg.Dirty; } } action(mr_writeDataToCacheFromRequest, "mr", desc="Write data from response queue to cache") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { getL2CacheEntry(address).DataBlk := in_msg.DataBlk; getL2CacheEntry(address).Dirty := in_msg.Dirty; } } action(q_updateAck, "q", desc="update pending ack count") { peek(responseIntraChipL2Network_in, ResponseMsg) { L2_TBEs[address].pendingAcks := L2_TBEs[address].pendingAcks - in_msg.AckCount; APPEND_TRANSITION_COMMENT(in_msg.AckCount); APPEND_TRANSITION_COMMENT(" p: "); APPEND_TRANSITION_COMMENT(L2_TBEs[address].pendingAcks); } } action(qq_writeDataToTBE, "\qq", desc="Write data from response queue to TBE") { peek(responseIntraChipL2Network_in, ResponseMsg) { L2_TBEs[address].DataBlk := in_msg.DataBlk; L2_TBEs[address].Dirty := in_msg.Dirty; } } action(z_stall, "z", desc="Stall") { } action(ss_recordGetSL1ID, "\s", desc="Record L1 GetS for load response") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { L2_TBEs[address].L1_GetS_IDs.add(in_msg.Requestor); } } action(xx_recordGetXL1ID, "\x", desc="Record L1 GetX for store response") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { L2_TBEs[address].L1_GetX_ID := in_msg.Requestor; } } action(set_setMRU, "\set", desc="set the MRU entry") { L2cacheMemory.setMRU(address); } action(qq_allocateL2CacheBlock, "\q", desc="Set L2 cache tag equal to tag of block B.") { if (L2cacheMemory.isTagPresent(address) == false) { L2cacheMemory.allocate(address); } } action(rr_deallocateL2CacheBlock, "\r", desc="Deallocate L2 cache block. Sets the cache to not present, allowing a replacement in parallel with a fetch.") { L2cacheMemory.deallocate(address); } action(t_sendWBAck, "t", desc="Send writeback ACK") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:WB_ACK; out_msg.Sender := machineID; out_msg.Destination.add(in_msg.Requestor); out_msg.MessageSize := MessageSizeType:Response_Control; } } } action(ts_sendInvAckToUpgrader, "ts", desc="Send ACK to upgrader") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { enqueue(responseIntraChipL2Network_out, ResponseMsg, latency="1") { out_msg.Address := address; out_msg.Type := CoherenceResponseType:ACK; out_msg.Sender := machineID; out_msg.Destination.add(in_msg.Requestor); out_msg.MessageSize := MessageSizeType:Response_Control; // upgrader doesn't get ack from itself, hence the + 1 out_msg.AckCount := 0 - getL2CacheEntry(address).Sharers.count() + 1; } } } action(uu_profileMiss, "\u", desc="Profile the demand miss") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { //profile_L2Cache_miss(convertToGenericType(in_msg.Type), in_msg.AccessMode, MessageSizeTypeToInt(in_msg.MessageSize), in_msg.Prefetch, L1CacheMachIDToProcessorNum(in_msg.Requestor)); } } action(ww_profileMissNoDir, "\w", desc="Profile this transition at the L2 because Dir won't see the request") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { // profile_request(in_msg.L1CacheStateStr, getStateStr(address), "NA", getCoherenceRequestTypeStr(in_msg.Type)); } } action(nn_addSharer, "\n", desc="Add L1 sharer to list") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { addSharer(address, in_msg.Requestor); APPEND_TRANSITION_COMMENT( getL2CacheEntry(address).Sharers ); } } action(nnu_addSharerFromUnblock, "\nu", desc="Add L1 sharer to list") { peek(L1unblockNetwork_in, ResponseMsg) { addSharer(address, in_msg.Sender); } } action(kk_removeRequestSharer, "\k", desc="Remove L1 Request sharer from list") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { L2cacheMemory[address].Sharers.remove(in_msg.Requestor); } } action(ll_clearSharers, "\l", desc="Remove all L1 sharers from list") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { L2cacheMemory[address].Sharers.clear(); } } action(mm_markExclusive, "\m", desc="set the exclusive owner") { peek(L1RequestIntraChipL2Network_in, RequestMsg) { L2cacheMemory[address].Sharers.clear(); L2cacheMemory[address].Exclusive := in_msg.Requestor; addSharer(address, in_msg.Requestor); } } action(mmu_markExclusiveFromUnblock, "\mu", desc="set the exclusive owner") { peek(L1unblockNetwork_in, ResponseMsg) { L2cacheMemory[address].Sharers.clear(); L2cacheMemory[address].Exclusive := in_msg.Sender; addSharer(address, in_msg.Sender); } } action(zz_recycleL1RequestQueue, "zz", desc="recycle L1 request queue") { L1RequestIntraChipL2Network_in.recycle(); } //***************************************************** // TRANSITIONS //***************************************************** //=============================================== // BASE STATE - I // Transitions from I (Idle) transition({NP, IS, ISS, IM, SS, M, M_I, MT_I, MCT_I, I_I, S_I, SS_MB, M_MB, MT_IIB, MT_IB, MT_SB}, L1_PUTX) { jj_popL1RequestQueue; } transition({NP, SS, M, MT, M_I, MT_I, MCT_I, I_I, S_I, IS, ISS, IM, SS_MB, MT_MB, M_MB, MT_IIB, MT_IB, MT_SB}, L1_PUTX_old) { jj_popL1RequestQueue; } transition({IM, IS, ISS, SS_MB, M_MB, MT_MB, MT_IIB, MT_IB, MT_SB}, {L2_Replacement, L2_Replacement_clean}) { zz_recycleL1RequestQueue; } transition({SS_MB, M_MB, MT_MB, MT_IIB, MT_IB, MT_SB}, {L1_GETS, L1_GET_INSTR, L1_GETX, L1_UPGRADE}) { zz_recycleL1RequestQueue; } transition(NP, L1_GETS, ISS) { qq_allocateL2CacheBlock; ll_clearSharers; nn_addSharer; i_allocateTBE; ss_recordGetSL1ID; a_issueFetchToMemory; uu_profileMiss; jj_popL1RequestQueue; } transition(NP, L1_GET_INSTR, IS) { qq_allocateL2CacheBlock; ll_clearSharers; nn_addSharer; i_allocateTBE; ss_recordGetSL1ID; a_issueFetchToMemory; uu_profileMiss; jj_popL1RequestQueue; } transition(NP, L1_GETX, IM) { qq_allocateL2CacheBlock; ll_clearSharers; // nn_addSharer; i_allocateTBE; xx_recordGetXL1ID; a_issueFetchToMemory; uu_profileMiss; jj_popL1RequestQueue; } // transitions from IS/IM transition(ISS, Mem_Data, MT_MB) { m_writeDataToCache; ex_sendExclusiveDataToGetSRequestors; s_deallocateTBE; o_popIncomingResponseQueue; } transition(IS, Mem_Data, SS) { m_writeDataToCache; e_sendDataToGetSRequestors; s_deallocateTBE; o_popIncomingResponseQueue; } transition(IM, Mem_Data, MT_MB) { m_writeDataToCache; ee_sendDataToGetXRequestor; s_deallocateTBE; o_popIncomingResponseQueue; } transition({IS, ISS}, {L1_GETS, L1_GET_INSTR}, IS) { nn_addSharer; ss_recordGetSL1ID; uu_profileMiss; jj_popL1RequestQueue; } transition({IS, ISS}, L1_GETX) { zz_recycleL1RequestQueue; } transition(IM, {L1_GETX, L1_GETS, L1_GET_INSTR}) { zz_recycleL1RequestQueue; } // transitions from SS transition(SS, {L1_GETS, L1_GET_INSTR}) { ds_sendSharedDataToRequestor; nn_addSharer; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(SS, L1_GETX, SS_MB) { d_sendDataToRequestor; // fw_sendFwdInvToSharers; fwm_sendFwdInvToSharersMinusRequestor; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(SS, L1_UPGRADE, SS_MB) { fwm_sendFwdInvToSharersMinusRequestor; ts_sendInvAckToUpgrader; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(SS, L2_Replacement_clean, I_I) { i_allocateTBE; f_sendInvToSharers; rr_deallocateL2CacheBlock; } transition(SS, L2_Replacement, S_I) { i_allocateTBE; f_sendInvToSharers; rr_deallocateL2CacheBlock; } transition(M, L1_GETX, MT_MB) { d_sendDataToRequestor; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(M, L1_GET_INSTR, SS) { d_sendDataToRequestor; nn_addSharer; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(M, L1_GETS, MT_MB) { dd_sendExclusiveDataToRequestor; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(M, L2_Replacement, M_I) { i_allocateTBE; c_exclusiveReplacement; rr_deallocateL2CacheBlock; } transition(M, L2_Replacement_clean, M_I) { rr_deallocateL2CacheBlock; } // transitions from MT transition(MT, L1_GETX, MT_MB) { b_forwardRequestToExclusive; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(MT, {L1_GETS, L1_GET_INSTR}, MT_IIB) { b_forwardRequestToExclusive; uu_profileMiss; set_setMRU; jj_popL1RequestQueue; } transition(MT, L2_Replacement, MT_I) { i_allocateTBE; f_sendInvToSharers; rr_deallocateL2CacheBlock; } transition(MT, L2_Replacement_clean, MCT_I) { i_allocateTBE; f_sendInvToSharers; rr_deallocateL2CacheBlock; } transition(MT, L1_PUTX, M) { ll_clearSharers; mr_writeDataToCacheFromRequest; t_sendWBAck; jj_popL1RequestQueue; } // transitions from blocking states transition(SS_MB, Unblock_Cancel, SS) { k_popUnblockQueue; } transition(MT_MB, Unblock_Cancel, MT) { k_popUnblockQueue; } transition(MT_IB, Unblock_Cancel, MT) { k_popUnblockQueue; } transition(SS_MB, Exclusive_Unblock, MT) { // update actual directory mmu_markExclusiveFromUnblock; k_popUnblockQueue; } transition({M_MB, MT_MB}, Exclusive_Unblock, MT) { // update actual directory mmu_markExclusiveFromUnblock; k_popUnblockQueue; } transition(MT_IIB, Unblock, MT_IB) { nnu_addSharerFromUnblock; k_popUnblockQueue; } transition(MT_IIB, {WB_Data, WB_Data_clean}, MT_SB) { m_writeDataToCache; o_popIncomingResponseQueue; } transition(MT_IB, {WB_Data, WB_Data_clean}, SS) { m_writeDataToCache; o_popIncomingResponseQueue; } transition(MT_SB, Unblock, SS) { nnu_addSharerFromUnblock; k_popUnblockQueue; } // writeback states transition({I_I, S_I, MT_I, MCT_I, M_I}, {L1_GETX, L1_UPGRADE, L1_GETS, L1_GET_INSTR}) { zz_recycleL1RequestQueue; } transition(I_I, Ack) { q_updateAck; o_popIncomingResponseQueue; } transition(I_I, Ack_all, NP) { s_deallocateTBE; o_popIncomingResponseQueue; } transition({MT_I, MCT_I}, WB_Data, M_I) { qq_writeDataToTBE; ct_exclusiveReplacementFromTBE; o_popIncomingResponseQueue; } transition(MCT_I, WB_Data_clean, NP) { s_deallocateTBE; o_popIncomingResponseQueue; } // L1 never changed Dirty data transition(MT_I, Ack_all, M_I) { ct_exclusiveReplacementFromTBE; o_popIncomingResponseQueue; } // clean data that L1 exclusive never wrote transition(MCT_I, Ack_all, NP) { s_deallocateTBE; o_popIncomingResponseQueue; } // drop this because L1 will send data again // the reason we don't accept is that the request virtual network may be completely backed up // transition(MT_I, L1_PUTX) { // jj_popL1RequestQueue; //} // possible race between unblock and immediate replacement transition(MT_MB, L1_PUTX) { zz_recycleL1RequestQueue; } transition(MT_I, WB_Data_clean, NP) { s_deallocateTBE; o_popIncomingResponseQueue; } transition(S_I, Ack) { q_updateAck; o_popIncomingResponseQueue; } transition(S_I, Ack_all, M_I) { ct_exclusiveReplacementFromTBE; o_popIncomingResponseQueue; } transition(M_I, Mem_Ack, NP) { s_deallocateTBE; o_popIncomingResponseQueue; } }