src/mem/protocol/MOESI_AMD_Base-L3cache.sm - public/gem5 - Git at Google

 /*
  * 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:L3Cache, "L3")
  : CacheMemory * L3cache;
    WireBuffer * reqToDir;
    WireBuffer * respToDir;
    WireBuffer * l3UnblockToDir;
    WireBuffer * reqToL3;
    WireBuffer * probeToL3;
    WireBuffer * respToL3;
    Cycles l3_request_latency := 1;
    Cycles l3_response_latency := 35;

   // To the general response network
   MessageBuffer * responseFromL3, network="To", virtual_network="2", ordered="false", vnet_type="response";

   // From the general response network
   MessageBuffer * responseToL3, network="From", virtual_network="2", ordered="false", vnet_type="response";

 {
   // EVENTS
   enumeration(Event, desc="L3 Events") {
     // Requests coming from the Cores
     RdBlk,                  desc="CPU RdBlk event";
     RdBlkM,                 desc="CPU RdBlkM event";
     RdBlkS,                 desc="CPU RdBlkS event";
     CtoD,                   desc="Change to Dirty request";
     WrVicBlk,               desc="L2 Victim (dirty)";
     WrVicBlkShared,               desc="L2 Victim (dirty)";
     ClVicBlk,               desc="L2 Victim (clean)";
     ClVicBlkShared,               desc="L2 Victim (clean)";

     CPUData,                      desc="WB data from CPU";
     CPUDataShared,                desc="WB data from CPU, NBReqShared 1";
     StaleWB,                desc="WB stale; no data";

     L3_Repl,             desc="L3 Replacement";

     // Probes
     PrbInvData,         desc="Invalidating probe, return dirty data";
     PrbInv,             desc="Invalidating probe, no need to return data";
     PrbShrData,         desc="Downgrading probe, return data";

     // Coming from Memory Controller
     WBAck,                     desc="ack from memory";

     CancelWB,                   desc="Cancel WB from L2";
   }

   // STATES
   // Base States:
   state_declaration(State, desc="L3 State", default="L3Cache_State_I") {
     M, AccessPermission:Read_Write, desc="Modified";  // No other cache has copy, memory stale
     O, AccessPermission:Read_Only, desc="Owned";     // Correct most recent copy, others may exist in S
     E, AccessPermission:Read_Write, desc="Exclusive"; // Correct, most recent, and only copy (and == Memory)
     S, AccessPermission:Read_Only, desc="Shared";    // Correct, most recent. If no one in O, then == Memory
     I, AccessPermission:Invalid, desc="Invalid";

     I_M, AccessPermission:Busy, desc="Invalid, received WrVicBlk, sent Ack, waiting for Data";
     I_O, AccessPermission:Busy, desc="Invalid, received WrVicBlk, sent Ack, waiting for Data";
     I_E, AccessPermission:Busy, desc="Invalid, receive ClVicBlk, sent Ack, waiting for Data";
     I_S, AccessPermission:Busy, desc="Invalid, receive ClVicBlk, sent Ack, waiting for Data";
     S_M, AccessPermission:Busy, desc="received WrVicBlk, sent Ack, waiting for Data, then go to M";
     S_O, AccessPermission:Busy, desc="received WrVicBlkShared, sent Ack, waiting for Data, then go to O";
     S_E, AccessPermission:Busy, desc="Shared, received ClVicBlk, sent Ack, waiting for Data, then go to E";
     S_S, AccessPermission:Busy, desc="Shared, received ClVicBlk, sent Ack, waiting for Data, then go to S";
     E_M, AccessPermission:Busy, desc="received WrVicBlk, sent Ack, waiting for Data, then go to O";
     E_O, AccessPermission:Busy, desc="received WrVicBlkShared, sent Ack, waiting for Data, then go to O";
     E_E, AccessPermission:Busy, desc="received WrVicBlk, sent Ack, waiting for Data, then go to O";
     E_S, AccessPermission:Busy, desc="Shared, received WrVicBlk, sent Ack, waiting for Data";
     O_M, AccessPermission:Busy, desc="...";
     O_O, AccessPermission:Busy, desc="...";
     O_E, AccessPermission:Busy, desc="...";
     O_S, AccessPermission:Busy, desc="...";
     M_M, AccessPermission:Busy, desc="...";
     M_O, AccessPermission:Busy, desc="...";
     M_E, AccessPermission:Busy, desc="...";
     M_S, AccessPermission:Busy, desc="...";
     D_I, AccessPermission:Invalid,  desc="drop WB data on the floor when receive";
     MOD_I, AccessPermission:Busy, desc="drop WB data on the floor, waiting for WBAck from Mem";
     MO_I, AccessPermission:Busy, desc="M or O, received L3_Repl, waiting for WBAck from Mem";
     I_I, AccessPermission:Busy, desc="I_MO received L3_Repl";
     I_CD, AccessPermission:Busy, desc="I_I received WBAck, now just waiting for CPUData";
     I_C, AccessPermission:Invalid, desc="sent cancel, just waiting to receive mem wb ack so nothing gets confused";
   }

   enumeration(RequestType, desc="To communicate stats from transitions to recordStats") {
     DataArrayRead,    desc="Read the data array";
     DataArrayWrite,   desc="Write the data array";
     TagArrayRead,     desc="Read the data array";
     TagArrayWrite,    desc="Write the data array";
   }

   // STRUCTURES

   structure(Entry, desc="...", interface="AbstractCacheEntry") {
     State CacheState,           desc="cache state";
     bool Dirty,                 desc="Is the data dirty (diff from memory?)";
     DataBlock DataBlk,          desc="Data for the block";
   }

   structure(TBE, desc="...") {
     State TBEState,     desc="Transient state";
     DataBlock DataBlk,  desc="data for the block";
     bool Dirty,         desc="Is the data dirty?";
     bool Shared,        desc="Victim hit by shared probe";
     MachineID From,     desc="Waiting for writeback from...";
   }

   structure(TBETable, external="yes") {
     TBE lookup(Addr);
     void allocate(Addr);
     void deallocate(Addr);
     bool isPresent(Addr);
   }

   TBETable TBEs, template="<L3Cache_TBE>", constructor="m_number_of_TBEs";

   void set_cache_entry(AbstractCacheEntry b);
   void unset_cache_entry();
   void set_tbe(TBE b);
   void unset_tbe();
   void wakeUpAllBuffers();
   void wakeUpBuffers(Addr a);
   MachineID mapAddressToMachine(Addr addr, MachineType mtype);

   // FUNCTION DEFINITIONS
   Tick clockEdge();
   Tick cyclesToTicks(Cycles c);

   Entry getCacheEntry(Addr addr), return_by_pointer="yes" {
     return static_cast(Entry, "pointer", L3cache.lookup(addr));
   }

   DataBlock getDataBlock(Addr addr), return_by_ref="yes" {
     return getCacheEntry(addr).DataBlk;
   }

   bool presentOrAvail(Addr addr) {
     return L3cache.isTagPresent(addr) || L3cache.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;
     }
   }

   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;
   }

   AccessPermission getAccessPermission(Addr addr) {
     TBE tbe := TBEs.lookup(addr);
     if(is_valid(tbe)) {
       return L3Cache_State_to_permission(tbe.TBEState);
     }

     Entry cache_entry := getCacheEntry(addr);
     if(is_valid(cache_entry)) {
       return L3Cache_State_to_permission(cache_entry.CacheState);
     }

     return AccessPermission:NotPresent;
   }

   void setAccessPermission(Entry cache_entry, Addr addr, State state) {
     if (is_valid(cache_entry)) {
       cache_entry.changePermission(L3Cache_State_to_permission(state));
     }
   }

   void recordRequestType(RequestType request_type, Addr addr) {

   }

   bool checkResourceAvailable(RequestType request_type, Addr addr) {
     return true;
   }


   // OUT PORTS
   out_port(requestNetwork_out, CPURequestMsg, reqToDir);
   out_port(L3Resp_out, ResponseMsg, respToDir);
   out_port(responseNetwork_out, ResponseMsg, responseFromL3);
   out_port(unblockNetwork_out, UnblockMsg, l3UnblockToDir);

   // IN PORTS
   in_port(NBResponse_in, ResponseMsg, respToL3) {
     if (NBResponse_in.isReady(clockEdge())) {
       peek(NBResponse_in, ResponseMsg) {
         Entry cache_entry := getCacheEntry(in_msg.addr);
         TBE tbe := TBEs.lookup(in_msg.addr);
         if (in_msg.Type == CoherenceResponseType:NBSysWBAck) {
           trigger(Event:WBAck, in_msg.addr, cache_entry, tbe);
         } else {
           DPRINTF(RubySlicc, "%s\n", in_msg);
           error("Error on NBResponse Type");
         }
       }
     }
   }

   // Response Network
   in_port(responseNetwork_in, ResponseMsg, responseToL3) {
     if (responseNetwork_in.isReady(clockEdge())) {
       peek(responseNetwork_in, ResponseMsg) {
         Entry cache_entry := getCacheEntry(in_msg.addr);
         TBE tbe := TBEs.lookup(in_msg.addr);
         if (in_msg.Type == CoherenceResponseType:CPUData) {
           if (in_msg.NbReqShared) {
             trigger(Event:CPUDataShared, in_msg.addr, cache_entry, tbe);
           } else {
             trigger(Event:CPUData, in_msg.addr, cache_entry, tbe);
           }
         } else if (in_msg.Type == CoherenceResponseType:StaleNotif) {
             trigger(Event:StaleWB, in_msg.addr, cache_entry, tbe);
         } else {
           DPRINTF(RubySlicc, "%s\n", in_msg);
           error("Error on NBResponse Type");
         }
       }
     }
   }

   // probe network
   in_port(probeNetwork_in, NBProbeRequestMsg, probeToL3) {
     if (probeNetwork_in.isReady(clockEdge())) {
       peek(probeNetwork_in, NBProbeRequestMsg) {
         Entry cache_entry := getCacheEntry(in_msg.addr);
         TBE tbe := TBEs.lookup(in_msg.addr);
         if (in_msg.Type == ProbeRequestType:PrbInv) {
           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.ReturnData) {
             trigger(Event:PrbShrData, in_msg.addr, cache_entry, tbe);
           } else {
             error("Don't think I should get any of these");
           }
         }
       }
     }
   }

   // Request Network
   in_port(requestNetwork_in, CPURequestMsg, reqToL3) {
     if (requestNetwork_in.isReady(clockEdge())) {
       peek(requestNetwork_in, CPURequestMsg) {
         assert(in_msg.Destination.isElement(machineID));
         Entry cache_entry := getCacheEntry(in_msg.addr);
         TBE tbe := TBEs.lookup(in_msg.addr);
         if (in_msg.Type == CoherenceRequestType:RdBlk) {
           trigger(Event:RdBlk, in_msg.addr, cache_entry, tbe);
         } else if (in_msg.Type == CoherenceRequestType:RdBlkS) {
           trigger(Event:RdBlkS, in_msg.addr, cache_entry, tbe);
         } else if (in_msg.Type == CoherenceRequestType:RdBlkM) {
           trigger(Event:RdBlkM, in_msg.addr, cache_entry, tbe);
         } else if (in_msg.Type == CoherenceRequestType:VicClean) {
           if (presentOrAvail(in_msg.addr)) {
             if (in_msg.Shared) {
               trigger(Event:ClVicBlkShared, in_msg.addr, cache_entry, tbe);
             } else {
               trigger(Event:ClVicBlk, in_msg.addr, cache_entry, tbe);
             }
           } else {
             Addr victim :=  L3cache.cacheProbe(in_msg.addr);
             trigger(Event:L3_Repl, victim, getCacheEntry(victim), TBEs.lookup(victim));
           }
         } else if (in_msg.Type == CoherenceRequestType:VicDirty) {
           if (presentOrAvail(in_msg.addr)) {
             if (in_msg.Shared) {
               trigger(Event:WrVicBlkShared, in_msg.addr, cache_entry, tbe);
             } else {
               trigger(Event:WrVicBlk, in_msg.addr, cache_entry, tbe);
             }
           } else {
             Addr victim := L3cache.cacheProbe(in_msg.addr);
             trigger(Event:L3_Repl, victim, getCacheEntry(victim), TBEs.lookup(victim));
           }
         } else if (in_msg.Type == CoherenceRequestType:WrCancel) {
           if (is_valid(tbe) && tbe.From == in_msg.Requestor) {
             trigger(Event:CancelWB, in_msg.addr, cache_entry, tbe);
           } else {
             requestNetwork_in.recycle(clockEdge(), cyclesToTicks(recycle_latency));
           }
         }
       }
     }
   }

   // BEGIN ACTIONS

   action(i_invL3, "i", desc="invalidate L3 cache block") {
     if (is_valid(cache_entry)) {
         L3cache.deallocate(address);
     }
     unset_cache_entry();
   }

   action(rm_sendResponseM, "rm", desc="send Modified response") {
     peek(requestNetwork_in, CPURequestMsg) {
       enqueue(responseNetwork_out, ResponseMsg, l3_response_latency) {
         out_msg.addr := address;
         out_msg.Type := CoherenceResponseType:NBSysResp;
         out_msg.Sender := machineID;
         out_msg.Destination.add(in_msg.Requestor);
         out_msg.DataBlk := cache_entry.DataBlk;
         out_msg.MessageSize := MessageSizeType:Response_Data;
         out_msg.Dirty := cache_entry.Dirty;
         out_msg.State := CoherenceState:Modified;
         DPRINTF(RubySlicc, "%s\n", out_msg);
       }
     }
   }

   action(rs_sendResponseS, "rs", desc="send Shared response") {
     peek(requestNetwork_in, CPURequestMsg) {
       enqueue(responseNetwork_out, ResponseMsg, l3_response_latency) {
         out_msg.addr := address;
         out_msg.Type := CoherenceResponseType:NBSysResp;
         out_msg.Sender := machineID;
         out_msg.Destination.add(in_msg.Requestor);
         out_msg.DataBlk := cache_entry.DataBlk;
         out_msg.MessageSize := MessageSizeType:Response_Data;
         out_msg.Dirty := cache_entry.Dirty;
         out_msg.State := CoherenceState:Shared;
         DPRINTF(RubySlicc, "%s\n", out_msg);
       }
     }
   }


   action(r_requestToMem, "r", desc="Miss in L3, pass on") {
     peek(requestNetwork_in, CPURequestMsg) {
       enqueue(requestNetwork_out, CPURequestMsg, l3_request_latency) {
         out_msg.addr := address;
         out_msg.Type := in_msg.Type;
         out_msg.Requestor := in_msg.Requestor;
         out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
         out_msg.Shared := false; // unneeded for this request
         out_msg.MessageSize := in_msg.MessageSize;
         DPRINTF(RubySlicc, "%s\n", out_msg);
       }
     }
   }

   action(t_allocateTBE, "t", desc="allocate TBE Entry") {
     TBEs.allocate(address);
     set_tbe(TBEs.lookup(address));
     if (is_valid(cache_entry)) {
       tbe.DataBlk := cache_entry.DataBlk; // Data only for WBs
       tbe.Dirty := cache_entry.Dirty;
     }
     tbe.From := machineID;
   }

   action(dt_deallocateTBE, "dt", desc="deallocate TBE Entry") {
     TBEs.deallocate(address);
     unset_tbe();
   }

   action(vd_vicDirty, "vd", desc="Victimize dirty L3 data") {
     enqueue(requestNetwork_out, CPURequestMsg, l3_request_latency) {
       out_msg.addr := address;
       out_msg.Type := CoherenceRequestType:VicDirty;
       out_msg.Requestor := machineID;
       out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
       out_msg.MessageSize := MessageSizeType:Request_Control;
     }
   }

   action(w_sendResponseWBAck, "w", desc="send WB Ack") {
     peek(requestNetwork_in, CPURequestMsg) {
       enqueue(responseNetwork_out, ResponseMsg, l3_response_latency) {
         out_msg.addr := address;
         out_msg.Type := CoherenceResponseType:NBSysWBAck;
         out_msg.Destination.add(in_msg.Requestor);
         out_msg.Sender := machineID;
         out_msg.MessageSize := MessageSizeType:Writeback_Control;
       }
     }
   }

   action(pi_sendProbeResponseInv, "pi", desc="send probe ack inv, no data") {
     enqueue(L3Resp_out, ResponseMsg, l3_request_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;
     }
   }

   action(ph_sendProbeResponseHit, "ph", desc="send probe ack, no data") {
     enqueue(L3Resp_out, ResponseMsg, l3_request_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 := true;
       out_msg.Ntsl := false;
       out_msg.State := CoherenceState:NA;
       out_msg.MessageSize := MessageSizeType:Response_Control;
     }
   }

   action(pm_sendProbeResponseMiss, "pm", desc="send probe ack, no data") {
     enqueue(L3Resp_out, ResponseMsg, l3_request_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 := false;
       out_msg.State := CoherenceState:NA;
       out_msg.MessageSize := MessageSizeType:Response_Control;
     }
   }

   action(pd_sendProbeResponseData, "pd", desc="send probe ack, with data") {
     enqueue(L3Resp_out, ResponseMsg, l3_request_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.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;
     }
   }

   action(pdt_sendProbeResponseDataFromTBE, "pdt", desc="send probe ack with data") {
     enqueue(L3Resp_out, ResponseMsg, l3_request_latency) {
       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.MessageSize := MessageSizeType:Response_Data;
       out_msg.State := CoherenceState:NA;
       DPRINTF(RubySlicc, "%s\n", out_msg);
     }
   }

   action(mc_cancelMemWriteback, "mc", desc="send writeback cancel to memory") {
     enqueue(requestNetwork_out, CPURequestMsg, l3_request_latency) {
       out_msg.addr := address;
       out_msg.Type := CoherenceRequestType:WrCancel;
       out_msg.Requestor := machineID;
       out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
       out_msg.MessageSize := MessageSizeType:Request_Control;
     }
   }

   action(a_allocateBlock, "a", desc="allocate L3 block") {
     if (is_invalid(cache_entry)) {
       set_cache_entry(L3cache.allocate(address, new Entry));
     }
   }

   action(d_writeData, "d", desc="write data to L3") {
     peek(responseNetwork_in, ResponseMsg) {
       if (in_msg.Dirty) {
         cache_entry.Dirty := in_msg.Dirty;
       }
       cache_entry.DataBlk := in_msg.DataBlk;
       DPRINTF(RubySlicc, "Writing to L3: %s\n", in_msg);
     }
   }

   action(rd_copyDataFromRequest, "rd", desc="write data to L3") {
     peek(requestNetwork_in, CPURequestMsg) {
       cache_entry.DataBlk := in_msg.DataBlk;
       cache_entry.Dirty := true;
     }
   }

   action(f_setFrom, "f", desc="set who WB is expected to come from") {
     peek(requestNetwork_in, CPURequestMsg) {
       tbe.From := in_msg.Requestor;
     }
   }

   action(rf_resetFrom, "rf", desc="reset From") {
     tbe.From := machineID;
   }

   action(wb_data, "wb", desc="write back data") {
     enqueue(L3Resp_out, ResponseMsg, l3_request_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(wt_writeDataToTBE, "wt", desc="write WB data to TBE") {
     peek(responseNetwork_in, ResponseMsg) {
       tbe.DataBlk := in_msg.DataBlk;
       tbe.Dirty := in_msg.Dirty;
     }
   }

   action(uu_sendUnblock, "uu", desc="state changed, unblock") {
     enqueue(unblockNetwork_out, UnblockMsg, l3_request_latency) {
       out_msg.addr := address;
       out_msg.Destination.add(mapAddressToMachine(address, MachineType:Directory));
       out_msg.MessageSize := MessageSizeType:Unblock_Control;
       DPRINTF(RubySlicc, "%s\n", out_msg);
     }
   }

   action(ut_updateTag, "ut", desc="update Tag (i.e. set MRU)") {
     L3cache.setMRU(address);
   }

   action(p_popRequestQueue, "p", desc="pop request queue") {
     requestNetwork_in.dequeue(clockEdge());
   }

   action(pr_popResponseQueue, "pr", desc="pop response queue") {
     responseNetwork_in.dequeue(clockEdge());
   }

   action(pn_popNBResponseQueue, "pn", desc="pop NB response queue") {
     NBResponse_in.dequeue(clockEdge());
   }

   action(pp_popProbeQueue, "pp", desc="pop probe queue") {
     probeNetwork_in.dequeue(clockEdge());
   }

   action(zz_recycleRequestQueue, "\z", desc="recycle request queue") {
     requestNetwork_in.recycle(clockEdge(), cyclesToTicks(recycle_latency));
   }


   // END ACTIONS

   // BEGIN TRANSITIONS

   // transitions from base

   transition({I, I_C}, {RdBlk, RdBlkS, RdBlkM, CtoD}) {TagArrayRead} {
     r_requestToMem;
     p_popRequestQueue;
   }

   transition(O, RdBlk ) {TagArrayRead, DataArrayRead} {
     rs_sendResponseS;
     ut_updateTag;
     p_popRequestQueue;
   }
   transition(M, RdBlk, O) {TagArrayRead, DataArrayRead, TagArrayWrite} {
     rs_sendResponseS;
     ut_updateTag;
     p_popRequestQueue;
   }

   transition(S, RdBlk) {TagArrayRead, DataArrayRead} {
     rs_sendResponseS;
     ut_updateTag;
     p_popRequestQueue;
   }
   transition(E, RdBlk, S) {TagArrayRead, DataArrayRead, TagArrayWrite} {
     rs_sendResponseS;
     ut_updateTag;
     p_popRequestQueue;
   }

   transition({M, O}, RdBlkS, O) {TagArrayRead, DataArrayRead, TagArrayWrite} {
     rs_sendResponseS;
     ut_updateTag;
     p_popRequestQueue;
   }

   transition({E, S}, RdBlkS, S) {TagArrayRead, DataArrayRead, TagArrayWrite} {
     rs_sendResponseS;
     ut_updateTag;
     p_popRequestQueue;
   }

   transition(M, RdBlkM, I) {TagArrayRead, TagArrayWrite, DataArrayRead} {
     rm_sendResponseM;
     i_invL3;
     p_popRequestQueue;
   }

   transition({O, S}, {RdBlkM, CtoD}) {TagArrayRead} {
     r_requestToMem;  // can't handle this, just forward
     p_popRequestQueue;
   }

   transition(E, RdBlkM, I) {TagArrayRead, TagArrayWrite, DataArrayRead} {
     rm_sendResponseM;
     i_invL3;
     p_popRequestQueue;
   }

   transition({I}, WrVicBlk, I_M) {TagArrayRead, TagArrayWrite} {
     a_allocateBlock;
     t_allocateTBE;
     f_setFrom;
 //    rd_copyDataFromRequest;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(I_C, {WrVicBlk, WrVicBlkShared, ClVicBlk, ClVicBlkShared}) {} {
     zz_recycleRequestQueue;
   }

   transition({I}, WrVicBlkShared, I_O) {TagArrayRead, TagArrayWrite} {
     a_allocateBlock;
     t_allocateTBE;
     f_setFrom;
 //    rd_copyDataFromRequest;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(S, WrVicBlkShared, S_O) {TagArrayRead, TagArrayWrite} {
 //    rd_copyDataFromRequest;
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(S, WrVicBlk, S_M) {TagArrayRead, TagArrayWrite} { // should be technically not possible, but assume the data comes back with shared bit flipped
 //    rd_copyDataFromRequest;
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(E, WrVicBlk, E_M) {TagArrayRead, TagArrayWrite}  {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(E, WrVicBlkShared, E_O) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(O, WrVicBlk, O_M) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(O, WrVicBlkShared, O_O) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(M, WrVicBlk, M_M) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(M, WrVicBlkShared, M_O) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition({I}, ClVicBlk, I_E) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     a_allocateBlock;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition({I}, ClVicBlkShared, I_S) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     a_allocateBlock;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(S, ClVicBlk, S_E) {TagArrayRead, TagArrayWrite} { // technically impossible, assume data comes back with shared bit flipped
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(S, ClVicBlkShared, S_S) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(E, ClVicBlk, E_E) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(E, ClVicBlkShared, E_S) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(O, ClVicBlk, O_E) {TagArrayRead, TagArrayWrite} { // technically impossible, but assume data comes back with shared bit flipped
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(O, ClVicBlkShared, O_S) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(M, ClVicBlk, M_E) {TagArrayRead, TagArrayWrite}  {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(M, ClVicBlkShared, M_S) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition({MO_I}, {RdBlk, RdBlkS, RdBlkM, CtoD}) {} {
     r_requestToMem;
     p_popRequestQueue;
   }

   transition(MO_I, {WrVicBlkShared, WrVicBlk, ClVicBlk, ClVicBlkShared}, MOD_I) {TagArrayWrite} {
     f_setFrom;
     w_sendResponseWBAck;
     p_popRequestQueue;
   }

   transition(I_M, CPUData, M) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     pr_popResponseQueue;
   }

   transition(I_M, CPUDataShared, O) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     pr_popResponseQueue;
   }

   transition(I_O, {CPUData, CPUDataShared}, O) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     pr_popResponseQueue;
   }

   transition(I_E, CPUData, E) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     pr_popResponseQueue;
   }

   transition(I_E, CPUDataShared, S) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     pr_popResponseQueue;
   }

   transition(I_S, {CPUData, CPUDataShared}, S) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     pr_popResponseQueue;
   }

   transition(S_M, CPUDataShared, O) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     ut_updateTag;  // update tag on writeback hits.
     pr_popResponseQueue;
   }

   transition(S_O, {CPUData, CPUDataShared}, O) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     ut_updateTag;  // update tag on writeback hits.
     pr_popResponseQueue;
   }

   transition(S_E, CPUDataShared, S) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     ut_updateTag;  // update tag on writeback hits.
     pr_popResponseQueue;
   }

   transition(S_S, {CPUData, CPUDataShared}, S) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     ut_updateTag;  // update tag on writeback hits.
     pr_popResponseQueue;
   }

   transition(O_E, CPUDataShared, O) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     ut_updateTag;  // update tag on writeback hits.
     pr_popResponseQueue;
   }

   transition(O_S, {CPUData, CPUDataShared}, O) {DataArrayWrite, TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     d_writeData;
     ut_updateTag;  // update tag on writeback hits.
     pr_popResponseQueue;
   }

   transition({D_I}, {CPUData, CPUDataShared}, I) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     pr_popResponseQueue;
   }

   transition(MOD_I, {CPUData, CPUDataShared}, MO_I) {TagArrayWrite} {
     uu_sendUnblock;
     rf_resetFrom;
     pr_popResponseQueue;
   }

   transition(I_I, {CPUData, CPUDataShared}, MO_I) {TagArrayWrite, DataArrayRead} {
     uu_sendUnblock;
     wt_writeDataToTBE;
     rf_resetFrom;
     pr_popResponseQueue;
   }

   transition(I_CD, {CPUData, CPUDataShared}, I) {DataArrayRead, TagArrayWrite} {
     uu_sendUnblock;
     wt_writeDataToTBE;
     wb_data;
     dt_deallocateTBE;
     pr_popResponseQueue;
   }

   transition({M, O}, L3_Repl, MO_I) {TagArrayRead, TagArrayWrite} {
     t_allocateTBE;
     vd_vicDirty;
     i_invL3;
   }

   transition({E, S,}, L3_Repl, I) {TagArrayRead, TagArrayWrite} {
     i_invL3;
   }

   transition({I_M, I_O, S_M, S_O, E_M, E_O}, L3_Repl) {} {
     zz_recycleRequestQueue;
   }

   transition({O_M, O_O, O_E, O_S, M_M, M_O, M_E, M_S}, L3_Repl) {} {
     zz_recycleRequestQueue;
   }

   transition({I_E, I_S, S_E, S_S, E_E, E_S}, L3_Repl) {} {
     zz_recycleRequestQueue;
   }

   transition({M, O}, PrbInvData, I) {TagArrayRead, TagArrayWrite, DataArrayRead} {
     pd_sendProbeResponseData;
     i_invL3;
     pp_popProbeQueue;
   }

   transition({E, S, I}, PrbInvData, I) {TagArrayRead, TagArrayWrite} {
     pi_sendProbeResponseInv;
     i_invL3;  // nothing will happen in I
     pp_popProbeQueue;
   }

   transition({M, O, E, S, I}, PrbInv, I) {TagArrayRead, TagArrayWrite} {
     pi_sendProbeResponseInv;
     i_invL3; // nothing will happen in I
     pp_popProbeQueue;
   }

   transition({M, O}, PrbShrData, O) {TagArrayRead, DataArrayRead, TagArrayWrite} {
     pd_sendProbeResponseData;
     pp_popProbeQueue;
   }

   transition({E, S}, PrbShrData, S) {TagArrayRead, TagArrayWrite} {
     ph_sendProbeResponseHit;
     pp_popProbeQueue;
   }

   transition(I, PrbShrData) {TagArrayRead} {
     pm_sendProbeResponseMiss;
     pp_popProbeQueue;
   }

   transition(MO_I, PrbInvData, I_C) {TagArrayWrite, DataArrayRead} {
     pdt_sendProbeResponseDataFromTBE;
     mc_cancelMemWriteback;
     pp_popProbeQueue;
   }

   transition(MO_I, PrbInv, I_C) {TagArrayWrite} {
     pi_sendProbeResponseInv;
     mc_cancelMemWriteback;
     pp_popProbeQueue;
   }

   transition(MO_I, PrbShrData) {DataArrayRead} {
     pdt_sendProbeResponseDataFromTBE;
     pp_popProbeQueue;
   }

   transition(I_C, {PrbInvData, PrbInv}) {} {
     pi_sendProbeResponseInv;
     pp_popProbeQueue;
   }

   transition(I_C, PrbShrData) {} {
     pm_sendProbeResponseMiss;
     pp_popProbeQueue;
   }

   transition(I_I, {WBAck}, I_CD) {TagArrayWrite} {
     pn_popNBResponseQueue;
   }

   transition(MOD_I, WBAck, D_I) {DataArrayRead} {
     wb_data;
     pn_popNBResponseQueue;
   }

   transition(MO_I, WBAck, I) {DataArrayRead, TagArrayWrite} {
     wb_data;
     dt_deallocateTBE;
     pn_popNBResponseQueue;
   }

   transition(I_C, {WBAck}, I) {TagArrayWrite} {
     dt_deallocateTBE;
     pn_popNBResponseQueue;
   }

   transition({I_M, I_O, I_E, I_S}, CancelWB, I) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     i_invL3;
     p_popRequestQueue;
   }

   transition({S_S, S_O, S_M, S_E}, CancelWB, S) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     p_popRequestQueue;
   }

   transition({E_M, E_O, E_E, E_S}, CancelWB, E) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     p_popRequestQueue;
   }

   transition({O_M, O_O, O_E, O_S}, CancelWB, O) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     p_popRequestQueue;
   }

   transition({M_M, M_O, M_E, M_S}, CancelWB, M) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     p_popRequestQueue;
   }

   transition(D_I, CancelWB, I) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     p_popRequestQueue;
   }

   transition(MOD_I, CancelWB, MO_I) {TagArrayWrite} {
     uu_sendUnblock;
     rf_resetFrom;
     p_popRequestQueue;
   }

   transition(I_I, CancelWB, I_C) {TagArrayWrite} {
     uu_sendUnblock;
     rf_resetFrom;
     mc_cancelMemWriteback;
     p_popRequestQueue;
   }

   transition(I_CD, CancelWB, I) {TagArrayWrite} {
     uu_sendUnblock;
     dt_deallocateTBE;
     mc_cancelMemWriteback;
     p_popRequestQueue;
   }

 }