blob: 29f862e2ef2a1e0324beca1a0154ca2b36653efc [file] [log] [blame]
/*
* Copyright (c) 2019 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Copyright (c) 1999-2013 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.
*/
machine(MachineType:Directory, "Directory protocol")
: DirectoryMemory * directory;
Cycles directory_latency := 6;
Cycles to_memory_controller_latency := 1;
// Message Queues
MessageBuffer * requestToDir, network="From", virtual_network="1",
vnet_type="request"; // a mod-L2 bank -> this Dir
MessageBuffer * responseToDir, network="From", virtual_network="2",
vnet_type="response"; // a mod-L2 bank -> this Dir
MessageBuffer * forwardFromDir, network="To", virtual_network="1",
vnet_type="forward";
MessageBuffer * responseFromDir, network="To", virtual_network="2",
vnet_type="response"; // Dir -> mod-L2 bank
MessageBuffer * responseFromMemory;
{
// STATES
state_declaration(State, desc="Directory states", default="Directory_State_I") {
// Base states
I, AccessPermission:Read_Write, desc="Invalid";
S, AccessPermission:Read_Only, desc="Shared";
O, AccessPermission:Maybe_Stale, desc="Owner";
M, AccessPermission:Maybe_Stale, desc="Modified";
IS, AccessPermission:Busy, desc="Blocked, was in idle";
SS, AccessPermission:Read_Only, desc="Blocked, was in shared";
OO, AccessPermission:Busy, desc="Blocked, was in owned";
MO, AccessPermission:Busy, desc="Blocked, going to owner or maybe modified";
MM, AccessPermission:Busy, desc="Blocked, going to modified";
MI, AccessPermission:Busy, desc="Blocked on a writeback";
MIS, AccessPermission:Busy, desc="Blocked on a writeback, but don't remove from sharers when received";
OS, AccessPermission:Busy, desc="Blocked on a writeback";
OSS, AccessPermission:Busy, desc="Blocked on a writeback, but don't remove from sharers when received";
XI_M, AccessPermission:Busy, desc="In a stable state, going to I, waiting for the memory controller";
XI_U, AccessPermission:Busy, desc="In a stable state, going to I, waiting for an unblock";
OI_D, AccessPermission:Busy, desc="In O, going to I, waiting for data";
OD, AccessPermission:Busy, desc="In O, waiting for dma ack from L2";
MD, AccessPermission:Busy, desc="In M, waiting for dma ack from L2";
}
// Events
enumeration(Event, desc="Directory events") {
GETX, desc="A GETX arrives";
GETS, desc="A GETS arrives";
PUTX, desc="A PUTX arrives";
PUTO, desc="A PUTO arrives";
PUTO_SHARERS, desc="A PUTO arrives, but don't remove from sharers list";
Unblock, desc="An unblock message arrives";
Last_Unblock, desc="An unblock message arrives, we're not waiting for any additional unblocks";
Exclusive_Unblock, desc="The processor become the exclusive owner (E or M) of the line";
Clean_Writeback, desc="The final message as part of a PutX/PutS, no data";
Dirty_Writeback, desc="The final message as part of a PutX/PutS, contains data";
Memory_Data, desc="Fetched data from memory arrives";
Memory_Ack, desc="Writeback Ack from memory arrives";
DMA_READ, desc="DMA Read";
DMA_WRITE, desc="DMA Write";
DMA_ACK, desc="DMA Ack";
Data, desc="Data to directory";
}
// TYPES
// DirectoryEntry
structure(Entry, desc="...", interface='AbstractCacheEntry', main="false") {
State DirectoryState, desc="Directory state";
NetDest Sharers, desc="Sharers for this block";
NetDest Owner, desc="Owner of this block";
int WaitingUnblocks, desc="Number of acks we're waiting for";
}
structure(TBE, desc="...") {
Addr PhysicalAddress, desc="Physical address for this entry";
int Len, desc="Length of request";
DataBlock DataBlk, desc="DataBlk";
MachineID Requestor, desc="original requestor";
}
structure(TBETable, external = "yes") {
TBE lookup(Addr);
void allocate(Addr);
void deallocate(Addr);
bool isPresent(Addr);
}
// ** OBJECTS **
TBETable TBEs, template="<Directory_TBE>", constructor="m_number_of_TBEs";
Tick clockEdge();
Tick cyclesToTicks(Cycles c);
void set_tbe(TBE b);
void unset_tbe();
Entry getDirectoryEntry(Addr addr), return_by_pointer="yes" {
Entry dir_entry := static_cast(Entry, "pointer", directory[addr]);
if (is_valid(dir_entry)) {
return dir_entry;
}
dir_entry := static_cast(Entry, "pointer",
directory.allocate(addr, new Entry));
return dir_entry;
}
State getState(TBE tbe, Addr addr) {
return getDirectoryEntry(addr).DirectoryState;
}
void setState(TBE tbe, Addr addr, State state) {
if (directory.isPresent(addr)) {
if (state == State:I) {
assert(getDirectoryEntry(addr).Owner.count() == 0);
assert(getDirectoryEntry(addr).Sharers.count() == 0);
}
if (state == State:S) {
assert(getDirectoryEntry(addr).Owner.count() == 0);
}
if (state == State:O) {
assert(getDirectoryEntry(addr).Owner.count() == 1);
assert(getDirectoryEntry(addr).Sharers.isSuperset(getDirectoryEntry(addr).Owner) == false);
}
if (state == State:M) {
assert(getDirectoryEntry(addr).Owner.count() == 1);
assert(getDirectoryEntry(addr).Sharers.count() == 0);
}
if ((state != State:SS) && (state != State:OO)) {
assert(getDirectoryEntry(addr).WaitingUnblocks == 0);
}
if ( (getDirectoryEntry(addr).DirectoryState != State:I) && (state == State:I) ) {
getDirectoryEntry(addr).DirectoryState := state;
// disable coherence checker
// sequencer.checkCoherence(addr);
}
else {
getDirectoryEntry(addr).DirectoryState := state;
}
}
}
AccessPermission getAccessPermission(Addr addr) {
if (directory.isPresent(addr)) {
DPRINTF(RubySlicc, "%s\n", Directory_State_to_permission(getDirectoryEntry(addr).DirectoryState));
return Directory_State_to_permission(getDirectoryEntry(addr).DirectoryState);
}
DPRINTF(RubySlicc, "AccessPermission_NotPresent\n");
return AccessPermission:NotPresent;
}
void setAccessPermission(Addr addr, State state) {
if (directory.isPresent(addr)) {
getDirectoryEntry(addr).changePermission(Directory_State_to_permission(state));
}
}
void functionalRead(Addr addr, Packet *pkt) {
functionalMemoryRead(pkt);
}
int functionalWrite(Addr addr, Packet *pkt) {
int num_functional_writes := 0;
num_functional_writes := num_functional_writes + functionalMemoryWrite(pkt);
return num_functional_writes;
}
// if no sharers, then directory can be considered
// both a sharer and exclusive w.r.t. coherence checking
bool isBlockShared(Addr addr) {
if (directory.isPresent(addr)) {
if (getDirectoryEntry(addr).DirectoryState == State:I) {
return true;
}
}
return false;
}
bool isBlockExclusive(Addr addr) {
if (directory.isPresent(addr)) {
if (getDirectoryEntry(addr).DirectoryState == State:I) {
return true;
}
}
return false;
}
// ** OUT_PORTS **
out_port(forwardNetwork_out, RequestMsg, forwardFromDir);
out_port(responseNetwork_out, ResponseMsg, responseFromDir);
// ** IN_PORTS **
in_port(unblockNetwork_in, ResponseMsg, responseToDir, rank=2) {
if (unblockNetwork_in.isReady(clockEdge())) {
peek(unblockNetwork_in, ResponseMsg) {
if (in_msg.Type == CoherenceResponseType:UNBLOCK) {
if (getDirectoryEntry(in_msg.addr).WaitingUnblocks == 1) {
trigger(Event:Last_Unblock, in_msg.addr,
TBEs[in_msg.addr]);
} else {
trigger(Event:Unblock, in_msg.addr,
TBEs[in_msg.addr]);
}
} else if (in_msg.Type == CoherenceResponseType:UNBLOCK_EXCLUSIVE) {
trigger(Event:Exclusive_Unblock, in_msg.addr,
TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceResponseType:DATA_EXCLUSIVE) {
trigger(Event:Data, in_msg.addr,
TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceResponseType:DMA_ACK) {
trigger(Event:DMA_ACK, in_msg.addr,
TBEs[in_msg.addr]);
} else {
error("Invalid message");
}
}
}
}
in_port(requestQueue_in, RequestMsg, requestToDir, rank=1) {
if (requestQueue_in.isReady(clockEdge())) {
peek(requestQueue_in, RequestMsg) {
if (in_msg.Type == CoherenceRequestType:GETS) {
trigger(Event:GETS, in_msg.addr, TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceRequestType:GETX) {
trigger(Event:GETX, in_msg.addr, TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceRequestType:PUTX) {
trigger(Event:PUTX, in_msg.addr, TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceRequestType:PUTO) {
trigger(Event:PUTO, in_msg.addr, TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceRequestType:PUTO_SHARERS) {
trigger(Event:PUTO_SHARERS, in_msg.addr, TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceRequestType:WRITEBACK_DIRTY_DATA) {
trigger(Event:Dirty_Writeback, in_msg.addr,
TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceRequestType:WRITEBACK_CLEAN_ACK) {
trigger(Event:Clean_Writeback, in_msg.addr,
TBEs[in_msg.addr]);
} else if (in_msg.Type == CoherenceRequestType:DMA_READ) {
trigger(Event:DMA_READ, makeLineAddress(in_msg.addr),
TBEs[makeLineAddress(in_msg.addr)]);
} else if (in_msg.Type == CoherenceRequestType:DMA_WRITE) {
trigger(Event:DMA_WRITE, makeLineAddress(in_msg.addr),
TBEs[makeLineAddress(in_msg.addr)]);
} else {
error("Invalid message");
}
}
}
}
// off-chip memory request/response is done
in_port(memQueue_in, MemoryMsg, responseFromMemory, rank=0) {
if (memQueue_in.isReady(clockEdge())) {
peek(memQueue_in, MemoryMsg) {
if (in_msg.Type == MemoryRequestType:MEMORY_READ) {
trigger(Event:Memory_Data, in_msg.addr, TBEs[in_msg.addr]);
} else if (in_msg.Type == MemoryRequestType:MEMORY_WB) {
trigger(Event:Memory_Ack, in_msg.addr, TBEs[in_msg.addr]);
} else {
DPRINTF(RubySlicc, "%s\n", in_msg.Type);
error("Invalid message");
}
}
}
}
// Actions
action(a_sendWriteBackAck, "a", desc="Send writeback ack to requestor") {
peek(requestQueue_in, RequestMsg) {
enqueue(responseNetwork_out, ResponseMsg, directory_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:WB_ACK;
out_msg.Sender := in_msg.Requestor;
out_msg.SenderMachine := MachineType:Directory;
out_msg.Destination.add(in_msg.Requestor);
out_msg.MessageSize := MessageSizeType:Writeback_Control;
}
}
}
action(b_sendWriteBackNack, "b", desc="Send writeback nack to requestor") {
peek(requestQueue_in, RequestMsg) {
enqueue(responseNetwork_out, ResponseMsg, directory_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceResponseType:WB_NACK;
out_msg.Sender := in_msg.Requestor;
out_msg.SenderMachine := MachineType:Directory;
out_msg.Destination.add(in_msg.Requestor);
out_msg.MessageSize := MessageSizeType:Writeback_Control;
}
}
}
action(c_clearOwner, "c", desc="Clear the owner field") {
getDirectoryEntry(address).Owner.clear();
}
action(c_moveOwnerToSharer, "cc", desc="Move owner to sharers") {
getDirectoryEntry(address).Sharers.addNetDest(getDirectoryEntry(address).Owner);
getDirectoryEntry(address).Owner.clear();
}
action(cc_clearSharers, "\c", desc="Clear the sharers field") {
getDirectoryEntry(address).Sharers.clear();
}
action(d_sendDataMsg, "d", desc="Send data to requestor") {
peek(memQueue_in, MemoryMsg) {
enqueue(responseNetwork_out, ResponseMsg, 1) {
out_msg.addr := address;
out_msg.Sender := machineID;
out_msg.SenderMachine := MachineType:Directory;
out_msg.Destination.add(in_msg.OriginalRequestorMachId);
out_msg.DataBlk := in_msg.DataBlk;
out_msg.Dirty := false; // By definition, the block is now clean
out_msg.Acks := in_msg.Acks;
if (in_msg.ReadX) {
out_msg.Type := CoherenceResponseType:DATA_EXCLUSIVE;
} else {
out_msg.Type := CoherenceResponseType:DATA;
}
out_msg.MessageSize := MessageSizeType:Response_Data;
}
}
}
action(p_fwdDataToDMA, "\d", desc="Send data to requestor") {
peek(requestQueue_in, RequestMsg) {
enqueue(responseNetwork_out, ResponseMsg, 1) {
out_msg.addr := address;
out_msg.Sender := machineID;
out_msg.SenderMachine := MachineType:Directory;
out_msg.Destination.add(in_msg.Requestor);
out_msg.Dirty := false; // By definition, the block is now clean
out_msg.Type := CoherenceResponseType:DATA_EXCLUSIVE;
out_msg.MessageSize := MessageSizeType:Response_Data;
}
}
}
action(e_ownerIsUnblocker, "e", desc="The owner is now the unblocker") {
peek(unblockNetwork_in, ResponseMsg) {
getDirectoryEntry(address).Owner.clear();
getDirectoryEntry(address).Owner.add(in_msg.Sender);
}
}
action(f_forwardRequest, "f", desc="Forward request to owner") {
peek(requestQueue_in, RequestMsg) {
enqueue(forwardNetwork_out, RequestMsg, directory_latency) {
out_msg.addr := address;
out_msg.Type := in_msg.Type;
out_msg.Requestor := in_msg.Requestor;
out_msg.RequestorMachine := machineIDToMachineType(in_msg.Requestor);
out_msg.Destination.addNetDest(getDirectoryEntry(in_msg.addr).Owner);
out_msg.Acks := getDirectoryEntry(address).Sharers.count();
if (getDirectoryEntry(address).Sharers.isElement(in_msg.Requestor)) {
out_msg.Acks := out_msg.Acks - 1;
}
out_msg.MessageSize := MessageSizeType:Forwarded_Control;
}
}
}
action(f_forwardRequestDirIsRequestor, "\f", desc="Forward request to owner") {
peek(requestQueue_in, RequestMsg) {
enqueue(forwardNetwork_out, RequestMsg, directory_latency) {
out_msg.addr := address;
out_msg.Type := in_msg.Type;
out_msg.Requestor := machineID;
out_msg.RequestorMachine := machineIDToMachineType(in_msg.Requestor);
out_msg.Destination.addNetDest(getDirectoryEntry(in_msg.addr).Owner);
out_msg.Acks := getDirectoryEntry(address).Sharers.count();
if (getDirectoryEntry(address).Sharers.isElement(in_msg.Requestor)) {
out_msg.Acks := out_msg.Acks - 1;
}
out_msg.MessageSize := MessageSizeType:Forwarded_Control;
}
}
}
action(g_sendInvalidations, "g", desc="Send invalidations to sharers, not including the requester") {
peek(requestQueue_in, RequestMsg) {
if ((getDirectoryEntry(in_msg.addr).Sharers.count() > 1) ||
((getDirectoryEntry(in_msg.addr).Sharers.count() > 0) &&
(getDirectoryEntry(in_msg.addr).Sharers.isElement(in_msg.Requestor) == false))) {
enqueue(forwardNetwork_out, RequestMsg, directory_latency) {
out_msg.addr := address;
out_msg.Type := CoherenceRequestType:INV;
out_msg.Requestor := in_msg.Requestor;
out_msg.RequestorMachine := machineIDToMachineType(in_msg.Requestor);
// out_msg.Destination := getDirectoryEntry(in_msg.addr).Sharers;
out_msg.Destination.addNetDest(getDirectoryEntry(in_msg.addr).Sharers);
out_msg.Destination.remove(in_msg.Requestor);
out_msg.MessageSize := MessageSizeType:Invalidate_Control;
}
}
}
}
action(i_popIncomingRequestQueue, "i", desc="Pop incoming request queue") {
requestQueue_in.dequeue(clockEdge());
}
action(j_popIncomingUnblockQueue, "j", desc="Pop incoming unblock queue") {
unblockNetwork_in.dequeue(clockEdge());
}
action(m_addUnlockerToSharers, "m", desc="Add the unlocker to the sharer list") {
peek(unblockNetwork_in, ResponseMsg) {
getDirectoryEntry(address).Sharers.add(in_msg.Sender);
}
}
action(n_incrementOutstanding, "n", desc="Increment outstanding requests") {
getDirectoryEntry(address).WaitingUnblocks := getDirectoryEntry(address).WaitingUnblocks + 1;
}
action(o_decrementOutstanding, "o", desc="Decrement outstanding requests") {
getDirectoryEntry(address).WaitingUnblocks := getDirectoryEntry(address).WaitingUnblocks - 1;
assert(getDirectoryEntry(address).WaitingUnblocks >= 0);
}
action(q_popMemQueue, "q", desc="Pop off-chip request queue") {
memQueue_in.dequeue(clockEdge());
}
action(qf_queueMemoryFetchRequest, "qf", desc="Queue off-chip fetch request") {
peek(requestQueue_in, RequestMsg) {
queueMemoryRead(in_msg.Requestor, address, to_memory_controller_latency);
}
}
action(qw_queueMemoryWBFromCacheRequest, "qw", desc="Queue off-chip writeback request") {
peek(requestQueue_in, RequestMsg) {
if (is_valid(tbe)) {
queueMemoryWrite(tbe.Requestor, address, to_memory_controller_latency,
in_msg.DataBlk);
} else {
queueMemoryWrite(in_msg.Requestor, address, to_memory_controller_latency,
in_msg.DataBlk);
}
}
}
action(qw_queueMemoryWBRequestFromMessageAndTBE, "qwmt",
desc="Queue off-chip writeback request") {
peek(unblockNetwork_in, ResponseMsg) {
DataBlock DataBlk := in_msg.DataBlk;
DataBlk.copyPartial(tbe.DataBlk, getOffset(tbe.PhysicalAddress),
tbe.Len);
queueMemoryWrite(tbe.Requestor, address, to_memory_controller_latency,
DataBlk);
}
}
action(qw_queueMemoryWBFromDMARequest, "/qw", desc="Queue off-chip writeback request") {
peek(requestQueue_in, RequestMsg) {
queueMemoryWrite(in_msg.Requestor, address, to_memory_controller_latency,
in_msg.DataBlk);
}
}
action(zz_recycleRequest, "\z", desc="Recycle the request queue") {
requestQueue_in.recycle(clockEdge(), cyclesToTicks(recycle_latency));
}
action(a_sendDMAAck, "\a", desc="Send DMA Ack that write completed, along with Inv Ack count") {
peek(requestQueue_in, RequestMsg) {
enqueue(responseNetwork_out, ResponseMsg, 1) {
out_msg.addr := address;
out_msg.Sender := machineID;
out_msg.SenderMachine := MachineType:Directory;
out_msg.Destination.add(in_msg.Requestor);
out_msg.DataBlk := in_msg.DataBlk;
out_msg.Acks := getDirectoryEntry(address).Sharers.count(); // for dma requests
out_msg.Type := CoherenceResponseType:DMA_ACK;
out_msg.MessageSize := MessageSizeType:Writeback_Control;
}
}
}
action(a_sendDMAAck2, "\aa", desc="Send DMA Ack that write completed, along with Inv Ack count") {
peek(unblockNetwork_in, ResponseMsg) {
enqueue(responseNetwork_out, ResponseMsg, 1) {
out_msg.addr := address;
out_msg.Sender := machineID;
out_msg.SenderMachine := MachineType:Directory;
if (is_valid(tbe)) {
out_msg.Destination.add(tbe.Requestor);
}
out_msg.DataBlk := in_msg.DataBlk;
out_msg.Acks := getDirectoryEntry(address).Sharers.count(); // for dma requests
out_msg.Type := CoherenceResponseType:DMA_ACK;
out_msg.MessageSize := MessageSizeType:Writeback_Control;
}
}
}
action(v_allocateTBE, "v", desc="Allocate TBE entry") {
peek (requestQueue_in, RequestMsg) {
TBEs.allocate(address);
set_tbe(TBEs[address]);
tbe.PhysicalAddress := in_msg.addr;
tbe.Len := in_msg.Len;
tbe.DataBlk := in_msg.DataBlk;
tbe.Requestor := in_msg.Requestor;
}
}
action(w_deallocateTBE, "w", desc="Deallocate TBE entry") {
TBEs.deallocate(address);
unset_tbe();
}
// TRANSITIONS
transition(I, GETX, MM) {
qf_queueMemoryFetchRequest;
i_popIncomingRequestQueue;
}
transition(I, DMA_READ, XI_M) {
qf_queueMemoryFetchRequest;
i_popIncomingRequestQueue;
}
transition(I, DMA_WRITE, XI_U) {
qw_queueMemoryWBFromDMARequest;
a_sendDMAAck; // ack count may be zero
i_popIncomingRequestQueue;
}
transition(XI_M, Memory_Data, I) {
d_sendDataMsg; // ack count may be zero
q_popMemQueue;
}
transition(XI_U, Exclusive_Unblock, I) {
cc_clearSharers;
c_clearOwner;
j_popIncomingUnblockQueue;
}
transition(S, GETX, MM) {
qf_queueMemoryFetchRequest;
g_sendInvalidations;
i_popIncomingRequestQueue;
}
transition(S, DMA_READ) {
//qf_queueMemoryFetchRequest;
p_fwdDataToDMA;
//g_sendInvalidations; // the DMA will collect the invalidations then send an Unblock Exclusive
i_popIncomingRequestQueue;
}
transition(S, DMA_WRITE, XI_U) {
qw_queueMemoryWBFromDMARequest;
a_sendDMAAck; // ack count may be zero
g_sendInvalidations; // the DMA will collect invalidations
i_popIncomingRequestQueue;
}
transition(I, GETS, IS) {
qf_queueMemoryFetchRequest;
i_popIncomingRequestQueue;
}
transition({S, SS}, GETS, SS) {
qf_queueMemoryFetchRequest;
n_incrementOutstanding;
i_popIncomingRequestQueue;
}
transition({I, S}, PUTO) {
b_sendWriteBackNack;
i_popIncomingRequestQueue;
}
transition({I, S, O}, PUTX) {
b_sendWriteBackNack;
i_popIncomingRequestQueue;
}
transition(O, GETX, MM) {
f_forwardRequest;
g_sendInvalidations;
i_popIncomingRequestQueue;
}
transition(O, DMA_READ, OD) {
f_forwardRequest; // this will cause the data to go to DMA directly
//g_sendInvalidations; // this will cause acks to be sent to the DMA
i_popIncomingRequestQueue;
}
transition(OD, DMA_ACK, O) {
j_popIncomingUnblockQueue;
}
transition({O,M}, DMA_WRITE, OI_D) {
f_forwardRequestDirIsRequestor; // need the modified data before we can proceed
g_sendInvalidations; // these go to the DMA Controller
v_allocateTBE;
i_popIncomingRequestQueue;
}
transition(OI_D, Data, XI_U) {
qw_queueMemoryWBRequestFromMessageAndTBE;
a_sendDMAAck2; // ack count may be zero
w_deallocateTBE;
j_popIncomingUnblockQueue;
}
transition({O, OO}, GETS, OO) {
f_forwardRequest;
n_incrementOutstanding;
i_popIncomingRequestQueue;
}
transition(M, GETX, MM) {
f_forwardRequest;
i_popIncomingRequestQueue;
}
// no exclusive unblock will show up to the directory
transition(M, DMA_READ, MD) {
f_forwardRequest; // this will cause the data to go to DMA directly
i_popIncomingRequestQueue;
}
transition(MD, DMA_ACK, M) {
j_popIncomingUnblockQueue;
}
transition(M, GETS, MO) {
f_forwardRequest;
i_popIncomingRequestQueue;
}
transition(M, PUTX, MI) {
a_sendWriteBackAck;
i_popIncomingRequestQueue;
}
// happens if M->O transition happens on-chip
transition(M, PUTO, MI) {
a_sendWriteBackAck;
i_popIncomingRequestQueue;
}
transition(M, PUTO_SHARERS, MIS) {
a_sendWriteBackAck;
i_popIncomingRequestQueue;
}
transition(O, PUTO, OS) {
a_sendWriteBackAck;
i_popIncomingRequestQueue;
}
transition(O, PUTO_SHARERS, OSS) {
a_sendWriteBackAck;
i_popIncomingRequestQueue;
}
transition({MM, MO, MI, MIS, OS, OSS, XI_M, XI_U, OI_D, OD, MD}, {GETS, GETX, PUTO, PUTO_SHARERS, PUTX, DMA_READ, DMA_WRITE}) {
zz_recycleRequest;
}
transition({MM, MO}, Exclusive_Unblock, M) {
cc_clearSharers;
e_ownerIsUnblocker;
j_popIncomingUnblockQueue;
}
transition(MO, Unblock, O) {
m_addUnlockerToSharers;
j_popIncomingUnblockQueue;
}
transition({IS, SS, OO}, {GETX, PUTO, PUTO_SHARERS, PUTX, DMA_READ, DMA_WRITE}) {
zz_recycleRequest;
}
transition(IS, GETS) {
zz_recycleRequest;
}
transition(IS, Unblock, S) {
m_addUnlockerToSharers;
j_popIncomingUnblockQueue;
}
transition(IS, Exclusive_Unblock, M) {
cc_clearSharers;
e_ownerIsUnblocker;
j_popIncomingUnblockQueue;
}
transition(SS, Unblock) {
m_addUnlockerToSharers;
o_decrementOutstanding;
j_popIncomingUnblockQueue;
}
transition(SS, Last_Unblock, S) {
m_addUnlockerToSharers;
o_decrementOutstanding;
j_popIncomingUnblockQueue;
}
transition(OO, Unblock) {
m_addUnlockerToSharers;
o_decrementOutstanding;
j_popIncomingUnblockQueue;
}
transition(OO, Last_Unblock, O) {
m_addUnlockerToSharers;
o_decrementOutstanding;
j_popIncomingUnblockQueue;
}
transition(MI, Dirty_Writeback, I) {
c_clearOwner;
cc_clearSharers;
qw_queueMemoryWBFromCacheRequest;
i_popIncomingRequestQueue;
}
transition(MIS, Dirty_Writeback, S) {
c_moveOwnerToSharer;
qw_queueMemoryWBFromCacheRequest;
i_popIncomingRequestQueue;
}
transition(MIS, Clean_Writeback, S) {
c_moveOwnerToSharer;
i_popIncomingRequestQueue;
}
transition(OS, Dirty_Writeback, S) {
c_clearOwner;
qw_queueMemoryWBFromCacheRequest;
i_popIncomingRequestQueue;
}
transition(OSS, Dirty_Writeback, S) {
c_moveOwnerToSharer;
qw_queueMemoryWBFromCacheRequest;
i_popIncomingRequestQueue;
}
transition(OSS, Clean_Writeback, S) {
c_moveOwnerToSharer;
i_popIncomingRequestQueue;
}
transition(MI, Clean_Writeback, I) {
c_clearOwner;
cc_clearSharers;
i_popIncomingRequestQueue;
}
transition(OS, Clean_Writeback, S) {
c_clearOwner;
i_popIncomingRequestQueue;
}
transition({MI, MIS}, Unblock, M) {
j_popIncomingUnblockQueue;
}
transition({OS, OSS}, Unblock, O) {
j_popIncomingUnblockQueue;
}
transition({I, S, O, M, IS, SS, OO, MO, MM, MI, MIS, OS, OSS}, Memory_Data) {
d_sendDataMsg;
q_popMemQueue;
}
transition({I, S, O, M, IS, SS, OO, MO, MM, MI, MIS, OS, OSS, XI_U, XI_M}, Memory_Ack) {
//a_sendAck;
q_popMemQueue;
}
}