public bool is_row_hit(Req req)
{
MemCtrl mctrl = get_mctrl(req);
Bank bank = mctrl.chan.ranks[req.addr.rid].banks[req.addr.bid];
return bank.curr_rowid == (long)req.addr.rowid;
}
public bool is_row_hit(Req req)
{
Dbg.Assert(mctrl.cid == req.addr.cid);
Bank bank = mctrl.chan.ranks[req.addr.rid].banks[req.addr.bid];
return bank.curr_rowid == (long)req.addr.rowid;
}
public override Req better_req(Req req1, Req req2)
{
bool marked1 = req1.marked;
bool marked2 = req2.marked;
if (marked1 ^ marked2) {
if (marked1) return req1;
else return req2;
}
int rank1 = rank[req1.pid];
int rank2 = rank[req2.pid];
if (rank1 != rank2) {
if (rank1 > rank2) return req1;
else return req2;
}
bool hit1 = is_row_hit(req1);
bool hit2 = is_row_hit(req2);
if (hit1 ^ hit2) {
if (hit1) return req1;
else return req2;
}
if (req1.ts_arrival <= req2.ts_arrival) return req1;
else return req2;
}
public override Req better_req(Req req1, Req req2)
{
if (mark[req1.pid] != 1 ^ mark[req2.pid] != 1) {
if (mark[req1.pid] != 1)
{
return req1;
}
else
{
return req2;
}
}
bool hit1 = is_row_hit(req1);
bool hit2 = is_row_hit(req2);
if (hit1 ^ hit2) {
if (hit1) return req1;
else return req2;
}
if (req1.ts_arrival <= req2.ts_arrival) return req1;
else return req2;
}
public override void dequeue_req(Req req)
{
if (!req.marked)
return;
Dbg.Assert(marked_load > 0);
marked_load--;
}
//constructor
public Cmd(TypeEnum type, MemAddr addr, int pid, Req req, List<Cmd> cmd_q)
{
valid = true;
this.pid = pid;
this.addr = addr;
this.type = type;
this.req = req;
this.cmd_q = cmd_q;
}
public override Req better_req(Req req1, Req req2)
{
bool hit1 = is_row_hit(req1);
bool hit2 = is_row_hit(req2);
if (hit1 ^ hit2) {
if (hit1) return req1;
else return req2;
}
if (req1.ts_arrival <= req2.ts_arrival) return req1;
else return req2;
}
public override void issue_req(Req req)
{
if (req != null) {
uint bid = meta_mctrl.get_bid(req);
if (is_row_hit(req)) {
streak[bid] += 1;
}
else {
streak[bid] = 1;
}
}
}
public virtual void count_streaks(Req req)
{
if (pid_last_req != req.pid)
{
if (!proc_done[pid_last_req])
{
if (last_streak_length < 16) streak_length[pid_last_req, last_streak_length] ++;
else streak_length[pid_last_req, 16] ++;
}
last_streak_length = 1;
pid_last_req = req.pid;
}
else last_streak_length ++;
}
public void get_req(ref int cpu_inst_cnt, out Req rd_req, out Req wb_req)
{
try
{
ulong rd_addr = binary_reader.ReadUInt64();
cpu_inst_cnt = binary_reader.ReadInt32();
ReqType req_type, proc_req_type;
req_type = ReqType.RD;
if (rd_addr >> 63 != 1) proc_req_type = ReqType.RD;
else proc_req_type = ReqType.WR;
rd_addr = rd_addr | (((ulong)pid) << 56);
rd_req = RequestPool.depool();
rd_req.set(pid, req_type, proc_req_type, rd_addr);
wb_req = null;
}
catch (EndOfStreamException)
{
gzip_reader = new GZipInputStream(File.OpenRead(trace_fname));
binary_reader = new BinaryReader (gzip_reader);
ulong rd_addr = binary_reader.ReadUInt64();
cpu_inst_cnt = binary_reader.ReadInt32();
ReqType req_type, proc_req_type;
req_type = ReqType.RD;
if (rd_addr >> 63 != 1) proc_req_type = ReqType.RD;
else proc_req_type = ReqType.WR;
rd_addr = rd_addr | (((ulong)pid) << 56);
rd_req = RequestPool.depool();
rd_req.set(pid, req_type, proc_req_type, rd_addr);
wb_req = null;
}
}
public override Req better_req(Req req1, Req req2)
{
bool hit1 = is_row_hit(req1);
bool hit2 = is_row_hit(req2);
uint bid1 = meta_mctrl.get_bid(req1);
uint bid2 = meta_mctrl.get_bid(req2);
bool capped1 = streak[bid1] >= Config.sched.row_hit_cap;
bool capped2 = streak[bid2] >= Config.sched.row_hit_cap;
hit1 = hit1 && (!capped1);
hit2 = hit2 && (!capped2);
if (hit1 ^ hit2) {
if (hit1) return req1;
else return req2;
}
if (req1.ts_arrival <= req2.ts_arrival) return req1;
else return req2;
}
public uint get_bid(Req req)
{
uint cid = req.addr.cid;
uint rid = req.addr.rid;
uint bid = req.addr.bid;
uint global_bid = 0;
if (is_omniscient && cid > 0) {
global_bid += (cid - 1) * mctrls[0].rmax * mctrls[0].bmax;
}
if(rid > 0){
global_bid += (rid - 1) * mctrls[0].bmax;
}
global_bid += bid;
return global_bid;
}
public bool issue_wb_req(Req wb_req)
{
bool mctrl_ok = insert_mctrl(wb_req);
return(mctrl_ok);
}
public void process_request(int pid, ulong block_addr, ulong input_pc)
{
if (!pc_present(input_pc))
{
StrideEntry new_stride_entry = new StrideEntry();
new_stride_entry.block_addr = block_addr;
new_stride_entry.trained = false;
new_stride_entry.stride = 0;
new_stride_entry.train_hits = 0;
insert_entry(input_pc, new_stride_entry);
return;
}
int hit_position = entry_position(input_pc);
int current_stride = (int)(block_addr - stride_entries[hit_position].block_addr);
if (current_stride != stride_entries[hit_position].stride)
{
stride_entries[hit_position].stride = current_stride;
stride_entries[hit_position].trained = false;
stride_entries[hit_position].train_hits = 0;
}
stride_entries[hit_position].block_addr = block_addr;
if (!stride_entries[hit_position].trained)
{
stride_entries[hit_position].train_hits++;
stride_entries[hit_position].prefetch_block_addr = block_addr;
}
if (stride_entries[hit_position].train_hits >= num_trains)
{
stride_entries[hit_position].trained = true;
}
if (stride_entries[hit_position].stride == 0)
{
return;
}
if (stride_entries[hit_position].trained == true)
{
ulong max_block_address = stride_entries[hit_position].block_addr + (ulong)((distance + 1) * stride_entries[hit_position].stride);
int max_prefetches = (int)(((int)max_block_address - (int)stride_entries[hit_position].prefetch_block_addr) / stride_entries[hit_position].stride);
int num_prefetches = (max_prefetches > degree) ? degree : max_prefetches;
for (int i = 0; i < num_prefetches; i++)
{
stride_entries[hit_position].prefetch_block_addr += (ulong)stride_entries[hit_position].stride;
Req new_prefetch = create_new_prefetch_req(pid, stride_entries[hit_position].prefetch_block_addr);
bool mctrl_ok = insert_mctrl(new_prefetch);
if (!mctrl_ok)
{
RequestPool.enpool(new_prefetch);
}
else
{
Stat.procs[new_prefetch.pid].num_prefetches.Collect();
};
}
}
return;
}
public void dequeue_req(Req req)
{
sched.dequeue_req(req);
wbsched.issue_req(req);
}
public void __enqueue_req(Req req, List<Req> q)
{
//timestamp
req.ts_arrival = cycles;
//add to queue
q.Add(req);
if (req.type == ReqType.WR) {
Dbg.Assert(mctrl_writeq.Count < mctrl_writeq.Capacity);
mctrl_writeq.Add(req);
}
//sched
meta_mctrl.enqueue_req(req); //does nothing for now
//stats
if (req.type == ReqType.RD) {
rload++;
rload_per_proc[req.pid]++;
rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]++;
}
else {
wload++;
wload_per_proc[req.pid]++;
wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]++;
}
}
//scheduler-specific overridden method public abstract Req better_req(Req req1, Req req2);
public static void enpool(Req req)
{
req.reset();
req_pool.AddLast(req);
}
public void enqueue_req(Req req)
{
//check if writeback hit
List<Req> q = get_q(req);
MemAddr addr = req.addr;
if (req.type == ReqType.RD) {
List<Req> wq = writeqs[addr.rid, addr.bid];
int idx = wq.FindIndex(delegate(Req w) { return w.block_addr == req.block_addr; });
if (idx != -1) {
//writeback hit
Sim.xbar.enqueue(req);
Stat.procs[req.pid].wb_hit.Collect();
return;
}
}
//writeback dumpster
if (req.type == ReqType.WR && Config.mctrl.wb_dump) {
req.addr.rowid = 0;
}
//enqueue proper
Dbg.Assert(q.Count < q.Capacity);
__enqueue_req(req, q);
}
new public void __dequeue_req(Req req)
{
req.ts_departure = cycles;
Dbg.Assert(req.ts_departure - req.ts_arrival > 0);
if ((!req.migrated_request) && (Config.proc.cache_insertion_policy == "PFA"))
{
RowStat.UpdateMLP(RowStat.DramDict, req);
Measurement.mem_num_dec(req);
// Measurement.DramServiceTimeUpdate (req);
// Measurement.DramCoreReqNumDec (req);
}
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.DramCoreReqNumDec(req);
}
/* if (Config.proc.cache_insertion_policy == "RBLAMLP" || Config.proc.cache_insertion_policy == "PFA")
* Measurement.DramSetCorePrevRowid (req);
*/
//sched
meta_mctrl.dequeue_req(req);
//load stat management
if (!req.migrated_request)
{
if (req.type == ReqType.RD)
{
rload--;
rload_per_proc[req.pid]--;
rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]--;
Dbg.Assert(rload >= 0);
Dbg.Assert(rload_per_proc[req.pid] >= 0);
Dbg.Assert(rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid] >= 0);
}
else
{
wload--;
wload_per_proc[req.pid]--;
wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]--;
Dbg.Assert(wload >= 0);
Dbg.Assert(wload_per_proc[req.pid] >= 0);
Dbg.Assert(wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid] >= 0);
// RequestPool.CacheWrite--;
}
}
else
{
if (req.type == ReqType.RD)
{
rload--;
}
else
{
wload--;
}
}
/* //dequeue proper
* if (req.type == ReqType.RD) {
* //traverse crossbar
* //Sim.xbar.enqueue(req);
*
* Callback cb = req.cache_callback;
* cb(req);
*
*
* }
* else {
* bool removeok = mctrl_writeq.Remove(req);
* Dbg.Assert(removeok);
* req.latency = (int)(req.ts_departure - req.ts_arrival);
*
* Callback cb = req.cache_callback;
* cb(req);
*
*
* RequestPool.enpool(req);
* }*/
//yang:
//dequeue proper
if (req.type == ReqType.RD)
{
Callback cb = req.cache_callback;
cb(req);
}
else
{
bool removeok = mctrl_writeq.Remove(req);
Dbg.Assert(removeok);
req.latency = (int)(req.ts_departure - req.ts_arrival);
Callback cb = req.cache_callback;
cb(req);
/* Callback cb1 = req.callback;
* if (cb1!=null)
* {
* Console.WriteLine("Position3");
* RequestPool.CacheWrite--;
* }*/
}
}
new public void __enqueue_req(Req req, List <Req> q)
{
//timestamp
// req.ts_arrival = cycles;
/* // do any analysis
* if (Config.collect_reuse == true) {
* if (Sim.reuse[req.pid].ContainsKey(req.block_addr))
* Sim.reuse[req.pid][req.block_addr] = Sim.reuse[req.pid][req.block_addr] + 1;
* else
* Sim.reuse[req.pid].Add(req.block_addr, 1);
* }
*
*/
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.DramCoreReqNumInc(req);
}
// check if cache hit
bool cache_serviced = false;
/*
* // TODO: add support for DRAM caching
* // don't allow cache writeback requests to be re-cached
* if (Config.proc.cache && Sim.caches[Sim.get_cache(req.pid)].is_cached(req) && !req.cache_wb) {
* Sim.caches[Sim.get_cache(req.pid)].promote(req);
* //stats
* if (req.type == ReqType.RD) {
* Stat.procs[req.pid].cache_read.Collect();
* Stat.procs[req.pid].cache_hit_rate_read.Collect(1);
* Sim.caches[Sim.get_cache(req.pid)].service(req);
* cache_serviced = true;
* }
* else {
* switch (Config.proc.cache_write_policy) {
* case "WriteThrough":
* // displace entry
* Sim.caches[Sim.get_cache(req.pid)].displace(req);
* break;
* case "WriteBack":
* Stat.procs[req.pid].cache_write.Collect();
* Stat.procs[req.pid].cache_hit_rate_write.Collect(1);
* Sim.caches[Sim.get_cache(req.pid)].service(req);
* cache_serviced = true;
* break;
* }
* }
* }
*/
if (!cache_serviced)
{
/* if (Sim.in_hot_region(req))
* Sim.thread_criticality[req.pid]++;
*
* //add to queue
*/
if (!req.migrated_request)
{
Sim.Dram_req_num = Sim.Dram_req_num + 1;
}
q.Add(req);
if (req.type == ReqType.WR)
{
Dbg.Assert(mctrl_writeq.Count < mctrl_writeq.Capacity);
mctrl_writeq.Add(req);
}
//sched
meta_mctrl.enqueue_req(req); //does nothing for now
//stats
if (!req.migrated_request)
{
if (req.type == ReqType.RD)
{
rload++;
rload_per_proc[req.pid]++;
rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]++;
Stat.procs[req.pid].cache_hit_rate_read.Collect(0);
}
else
{
wload++;
wload_per_proc[req.pid]++;
wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]++;
Stat.procs[req.pid].cache_hit_rate_write.Collect(0);
}
}
else
{
if (req.type == ReqType.RD)
{
rload++;
}
else
{
wload++;
}
}
}
}
new public void tick()
{
//must be the very first thing that's done
cycles++;
meta_mctrl.tick(cid);
wbthrottle.tick();
mwbmode.tick(cid);
//load stats
for (int p = 0; p < Config.N; p++)
{
//read load
if (rload_per_proc[p] > 0)
{
Stat.mctrls2[cid].rbinaryloadtick_per_proc[p].Collect();
}
Stat.mctrls2[cid].rloadtick_per_proc[p].Collect(rload_per_proc[p]);
//write load
if (wload_per_proc[p] > 0)
{
Stat.mctrls2[cid].wbinaryloadtick_per_proc[p].Collect();
}
Stat.mctrls2[cid].wloadtick_per_proc[p].Collect(wload_per_proc[p]);
}
//busy/idle stats
if (rload > 0)
{
read_loaded_time++;
if (read_unloaded_time > 0)
{
//Stat.mctrls2[cid].read_unloaded_time.Collect(read_unloaded_time);
}
read_unloaded_time = 0;
}
else
{
read_unloaded_time++;
if (read_loaded_time > 0)
{
//Stat.mctrls2[cid].read_loaded_time.Collect(read_loaded_time);
}
read_loaded_time = 0;
}
/*** writeback mode ***/
update_wb_mode();
/*
* if (wb_mode && cid == 0) {
* Console.WriteLine("==={0}==============================================", cycles);
* Console.WriteLine("Reads to Drain: {0}", reads_to_drain);
* Console.WriteLine("Writes Serviced: {0}", ((DecoupledWBFullServeN) mwbmode).serve_cnt[0]);
* uint r = 0;
* for (uint b = 0; b < bmax; b++) {
* Console.Write("{0}\t", b);
* foreach (Cmd cmd in cmdqs[r, b]) {
* Console.Write("{0} {1}\t", cmd.type.ToString(), can_schedule_cmd(cmd));
* }
* Console.WriteLine();
* }
* }
*/
/*** clock factor ***/
if (cycles % Config.mem.clock_factor != 0)
{
return;
}
if ((Config.proc.cache_insertion_policy == "PFA") && (cycles % (6 * Config.mem.clock_factor) == 0))
{
int indexi, indexj;
for (indexi = 0; indexi < rmax; indexi++)
{
for (indexj = 0; indexj < bmax; indexj++)
{
Measurement.read_MLP_cal(ref readqs[indexi, indexj]);
Measurement.write_MLP_cal(ref writeqs[indexi, indexj]);
Measurement.MLP_cal(ref inflightqs[indexi, indexj]);
}
}
}
/*** serve completed request ***/
if (bus_q.Count > 0 && bus_q[0].ts <= cycles)
{
MemAddr addr = bus_q[0].addr;
bus_q.RemoveAt(0);
List <Req> inflight_q = inflightqs[addr.rid, addr.bid];
Dbg.Assert(inflight_q.Count > 0);
Dbg.Assert(addr == inflight_q[0].addr);
Req req = inflight_q[0];
inflight_q.RemoveAt(0);
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.DramBankPidDeUpdate(req);
}
dequeue_req(req);
}
Cmd best_cmd = find_best_cmd();
Req best_req = find_best_req();
//nothing to issue
if (best_cmd == null && best_req == null)
{
if (Config.proc.cache_insertion_policy == "PFA")
{
CheckBusConflict();
}
return;
}
//arbitrate between command and request
bool is_issue_req = false;
if (best_req != null && best_cmd == null)
{
is_issue_req = true;
}
else if (best_req == null && best_cmd != null)
{
is_issue_req = false;
}
else
{
if (best_req == __better_req(best_cmd.req, best_req))
{
is_issue_req = true;
}
else
{
is_issue_req = false;
}
}
//issue command or request
if (is_issue_req)
{
if (!best_req.migrated_request)
{
if (Config.proc.cache_insertion_policy == "RBLA")
{
RowStat.UpdateDict(RowStat.DramDict, best_req, this);
}
else if (Config.proc.cache_insertion_policy == "PFA")
{
RowStat.UpdateDict(RowStat.DramDict, best_req, this);
// Measurement.DramBankPidEnUpdate(best_req);
}
// if (Config.proc.cache_insertion_policy == "PFA")
// Measurement.DramBankPidEnUpdate(best_req);
}
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.DramBankPidEnUpdate(best_req);
}
issue_req(best_req);
}
else
{
issue_cmd(best_cmd);
}
if (Config.proc.cache_insertion_policy == "PFA")
{
CheckBusConflict();
}
}
private void issue_req(Req req)
{
//remove request from waiting queue
List <Req> q = get_q(req);
Dbg.Assert(q.Contains(req));
q.Remove(req);
//add to inflight queue
MemAddr addr = req.addr;
List <Req> inflight_q = inflightqs[addr.rid, addr.bid];
Dbg.Assert(inflight_q.Count < inflight_q.Capacity);
inflight_q.Add(req);
//add to command queue
List <Cmd> cmd_q = cmdqs[addr.rid, addr.bid];
Dbg.Assert(cmd_q.Count == 0);
List <Cmd> new_cmd_q = decode_req(req);
Dbg.Assert(new_cmd_q.Count > 0);
cmd_q.AddRange(new_cmd_q);
Cmd cmd = cmd_q[0];
//meta_mctrl
meta_mctrl.issue_req(req);
Dbg.Assert(cmd.req.addr.rowid == req.addr.rowid);
//stats
BankStat bstat = Stat.banks2[addr.cid, addr.rid, addr.bid];
bstat.access.Collect();
if (cmd.type == Cmd.TypeEnum.PRECHARGE || cmd.type == Cmd.TypeEnum.ACTIVATE)
{
//bank stat
bstat.row_miss.Collect();
bstat.row_miss_perproc[req.pid].Collect();
//proc stat
if (cmd.req.type == ReqType.RD)
{
Stat.procs[req.pid].row_hit_rate_read.Collect(0);
Stat.procs[req.pid].row_miss_read.Collect();
}
else
{
Stat.procs[req.pid].row_hit_rate_write.Collect(0);
Stat.procs[req.pid].row_miss_write.Collect();
}
req.hit = 2;
// Power Measurement:
Sim.DRAM_power_statistics(req.pid, req.migrated_request, req.type, false);
//
if (Config.proc.cache_insertion_policy == "PFA")
{
// if ((!req.migrated_request) && (req.type == ReqType.RD))
Measurement.DramMissSetRowBufferChange(req);
}
}
else
{
//bank stat
bstat.row_hit.Collect();
bstat.row_hit_perproc[req.pid].Collect();
//proc stat
if (cmd.req.type == ReqType.RD)
{
Stat.procs[req.pid].row_hit_rate_read.Collect(1);
Stat.procs[req.pid].row_hit_read.Collect();
}
else
{
Stat.procs[req.pid].row_hit_rate_write.Collect(1);
Stat.procs[req.pid].row_hit_write.Collect();
}
req.hit = 1;
// Power Measurement:
Sim.DRAM_power_statistics(req.pid, req.migrated_request, req.type, true);
//
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.DramHitSetRowBufferChange(req);
}
}
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.DramSetCorePrevRowid(req);
}
//issue command
issue_cmd(cmd);
if (cmd.addr != req.addr)
{
Console.Write("big error!");
}
}
public void enqueue(Req req)
{
reqs.Add(req);
}
public virtual void service_counter(Req req)
{
return;
}
public override void dequeue_req(Req req)
{
}
public override void issue_req(Req req)
{
if (req == null) return;
count_streaks(req);
uint bid;
if (Config.sched.channel_level)
{
if (req.pid == last_req_pid && oldest_streak_global < Config.sched.row_hit_cap) {
oldest_streak_global += 1;
}
else if (req.pid == last_req_pid && oldest_streak_global == Config.sched.row_hit_cap)
{
mark[req.pid] = 1;
oldest_streak_global = 1;
}
else {
oldest_streak_global = 1;
}
last_req_pid = req.pid;
}
else
{
bid = meta_mctrl.get_bid(req);
if (meta_mctrl.is_req_to_cur_proc(req) && oldest_streak[bid] < Config.sched.row_hit_cap) {
oldest_streak[bid] += 1;
}
else if (meta_mctrl.is_req_to_cur_proc(req) && oldest_streak[bid] == Config.sched.row_hit_cap)
{
mark[req.pid] = 1;
oldest_streak[bid] = 1;
// Console.Write(" OLDEST: Marking processor " + req.pid + "\n");
}
else {
oldest_streak[bid] = 1;
}
}
}
public override void issue_req(Req req)
{
}
public List<Req> get_q(Req req)
{
List<Req>[,] rw_qs = (req.type == ReqType.RD ? readqs : writeqs);
List<Req> q = rw_qs[req.addr.rid, req.addr.bid];
return q;
}
public void __enqueue_req(Req req, List <Req> q)
{
//timestamp
req.ts_arrival = cycles;
/* // do any analysis
* if (Config.collect_reuse == true) {
* if (Sim.reuse[req.pid].ContainsKey(req.block_addr))
* Sim.reuse[req.pid][req.block_addr] = Sim.reuse[req.pid][req.block_addr] + 1;
* else
* Sim.reuse[req.pid].Add(req.block_addr, 1);
* }
*/
// check if cache hit
bool cache_serviced = false;
// don't allow cache writeback requests to be re-cached
if (Config.proc.cache && Sim.caches[Sim.get_cache(req.pid)].is_cached(req) && (!req.migrated_request))
{
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.mem_num_inc(req);
}
Sim.caches[Sim.get_cache(req.pid)].promote(req);
//stats
if (req.type == ReqType.RD)
{
Stat.procs[req.pid].cache_read.Collect();
Stat.procs[req.pid].cache_hit_rate_read.Collect(1);
Sim.caches[Sim.get_cache(req.pid)].service(req);
cache_serviced = true;
}
else
{
switch (Config.proc.cache_write_policy)
{
case "WriteThrough":
// displace entry
Sim.caches[Sim.get_cache(req.pid)].displace(req);
break;
case "WriteBack":
Stat.procs[req.pid].cache_write.Collect();
Stat.procs[req.pid].cache_hit_rate_write.Collect(1);
Sim.caches[Sim.get_cache(req.pid)].service(req);
cache_serviced = true;
break;
}
}
}
if (!cache_serviced)
{
if (!req.migrated_request)
{
Sim.NVM_req_num = Sim.NVM_req_num + 1;
}
if ((!req.migrated_request) && (Config.proc.cache_insertion_policy == "PFA"))
{
Measurement.mem_num_inc(req);
}
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.NVMCoreReqNumInc(req);
}
q.Add(req);
if (req.type == ReqType.WR)
{
Dbg.Assert(mctrl_writeq.Count < mctrl_writeq.Capacity);
mctrl_writeq.Add(req);
}
//sched
meta_mctrl.enqueue_req(req); //does nothing for now
//stats
if (!req.cache_wb)
{
if (req.type == ReqType.RD)
{
rload++;
rload_per_proc[req.pid]++;
rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]++;
Stat.procs[req.pid].cache_hit_rate_read.Collect(0);
}
else
{
wload++;
wload_per_proc[req.pid]++;
wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]++;
Stat.procs[req.pid].cache_hit_rate_write.Collect(0);
}
}
else
{
if (req.type == ReqType.RD)
{
rload++;
}
else
{
wload++;
}
}
}
}
private void issue_req(Req req)
{
//remove request from waiting queue
List<Req> q = get_q(req);
Dbg.Assert(q.Contains(req));
q.Remove(req);
req.queueing_latency = (int) (cycles - req.ts_arrival);
total_queueing_latency[req.pid] += (ulong)req.queueing_latency;
if (Sim.highest_rank_proc == req.pid) Sim.procs[req.pid].queueing_latency += (ulong)req.queueing_latency;
Stat.mctrls[cid].queueing_latency_per_proc[req.pid].Collect(req.queueing_latency);
//add to inflight queue
MemAddr addr = req.addr;
List<Req> inflight_q = inflightqs[addr.rid, addr.bid];
Dbg.Assert(inflight_q.Count < inflight_q.Capacity);
inflight_q.Add(req);
//add to command queue
List<Cmd> cmd_q = cmdqs[addr.rid, addr.bid];
Dbg.Assert(cmd_q.Count == 0);
List<Cmd> new_cmd_q = decode_req(req);
Dbg.Assert(new_cmd_q.Count > 0);
cmd_q.AddRange(new_cmd_q);
Cmd cmd = cmd_q[0];
//meta_mctrl
meta_mctrl.issue_req(req);
req.ts_issue = cycles;
//stats
BankStat bstat = Stat.banks[addr.cid, addr.rid, addr.bid];
bstat.access.Collect();
if (cmd.type == Cmd.TypeEnum.PRECHARGE || cmd.type == Cmd.TypeEnum.ACTIVATE) {
//bank stat
bstat.row_miss.Collect();
bstat.row_miss_perproc[req.pid].Collect();
//proc stat
if (cmd.req.type == ReqType.RD) {
Stat.procs[req.pid].row_hit_rate_read.Collect(0);
Stat.procs[req.pid].row_miss_read.Collect();
}
else {
Stat.procs[req.pid].row_hit_rate_write.Collect(0);
Stat.procs[req.pid].row_miss_write.Collect();
}
}
else {
//bank stat
bstat.row_hit.Collect();
bstat.row_hit_perproc[req.pid].Collect();
//proc stat
if (cmd.req.type == ReqType.RD) {
Stat.procs[req.pid].row_hit_rate_read.Collect(1);
Stat.procs[req.pid].row_hit_read.Collect();
}
else {
Stat.procs[req.pid].row_hit_rate_write.Collect(1);
Stat.procs[req.pid].row_hit_write.Collect();
}
}
//issue command
issue_cmd(cmd);
}
public bool is_req_to_cur_proc(Req req)
{
MemCtrl mctrl = get_mctrl(req);
Bank bank = mctrl.chan.ranks[req.addr.rid].banks[req.addr.bid];
Req curr_req = get_curr_req(bank);
if (curr_req != null) return curr_req.pid == (long)req.pid;
else return false;
}
public void tick()
{
/*** Preamble ***/
cycles++;
Stat.procs[pid].cycle.Collect();
ulong inst_cnt = Stat.procs[pid].ipc.Count;
if (inst_cnt != 0 && inst_cnt % 1000000 == 0)
{
ulong quantum = inst_cnt / 1000000;
if (quantum > curr_quantum)
{
curr_quantum = quantum;
ulong read_req = Stat.procs[pid].read_req.Count;
Stat.procs[pid].read_quantum.EndQuantum(read_req - prev_read_req);
prev_read_req = read_req;
ulong write_req = Stat.procs[pid].write_req.Count;
Stat.procs[pid].write_quantum.EndQuantum(write_req - prev_write_req);
prev_write_req = write_req;
}
}
/*** Throttle ***/
if (throttle_fraction > 0)
{
if (rand.NextDouble() < throttle_fraction)
{
return;
}
}
/*** Retire ***/
int retired = inst_wnd.retire(Config.proc.ipc);
Stat.procs[pid].ipc.Collect(retired);
if (retired < 0.5 * Config.proc.ipc)
{
Measurement.core_stall_cycles[pid] += 1;
}
/*** Issue writeback request ***/
if (Config.proc.wb && wb_q.Count > 0)
{
bool wb_ok = issue_wb_req(wb_q[0]);
// Console.WriteLine("Issue Write {0}",wb_ok);
if (wb_ok)
{
wb_q.RemoveAt(0);
}
//writeback stall
bool stalled_wb = wb_q.Count > Config.proc.wb_q_max;
if (stalled_wb)
{
return;
}
}
/*** Reissue previous read request ***/
bool issued_rd_req = false;
if (mshr_retry || mctrl_retry)
{
Dbg.Assert(curr_rd_req != null && curr_cpu_inst_cnt == 0);
//mshr/mctrl stall
bool reissue_ok = reissue_rd_req();
// Console.Write("Reissue read {0}",reissue_ok);
if (!reissue_ok)
{
return;
}
//reissue success
Dbg.Assert(!mshr_retry && !mctrl_retry);
issued_rd_req = true;
curr_rd_req = get_req();
}
/*** Issue instructions ***/
Dbg.Assert(curr_rd_req != null);
issue_insts(issued_rd_req);
}
private void send_req(Req req)
{
Sim.procs[req.pid].inflight_mem_requests++;
req.callback = new Callback(Sim.procs[req.pid].recv_req);
Sim.mctrls[req.addr.cid].enqueue_req(req);
}
public void issue_req(Req req)
{
sched.issue_req(req);
wbsched.issue_req(req);
}
public List <Req> get_inflight_q(Req req)
{
List <Req> q = inflightqs[req.addr.rid, req.addr.bid];
return(q);
}
public Req better_wb_req(Req req1, Req req2)
{
return wbsched.better_req(req1, req2);
}
public void tick()
{
//must be the very first thing that's done
cycles++;
meta_mctrl.tick(cid);
wbthrottle.tick();
mwbmode.tick(cid);
//load stats
for (int p = 0; p < Config.N; p++)
{
//read load
if (rload_per_proc[p] > 0)
{
Stat.mctrls[cid].rbinaryloadtick_per_proc[p].Collect();
}
Stat.mctrls[cid].rloadtick_per_proc[p].Collect(rload_per_proc[p]);
//write load
if (wload_per_proc[p] > 0)
{
Stat.mctrls[cid].wbinaryloadtick_per_proc[p].Collect();
}
Stat.mctrls[cid].wloadtick_per_proc[p].Collect(wload_per_proc[p]);
}
//busy/idle stats
if (rload > 0)
{
read_loaded_time++;
if (read_unloaded_time > 0)
{
//Stat.mctrls[cid].read_unloaded_time.Collect(read_unloaded_time);
}
read_unloaded_time = 0;
}
else
{
read_unloaded_time++;
if (read_loaded_time > 0)
{
//Stat.mctrls[cid].read_loaded_time.Collect(read_loaded_time);
}
read_loaded_time = 0;
}
/*** writeback mode ***/
update_wb_mode();
/*
* if (wb_mode && cid == 0) {
* Console.WriteLine("==={0}==============================================", cycles);
* Console.WriteLine("Reads to Drain: {0}", reads_to_drain);
* Console.WriteLine("Writes Serviced: {0}", ((DecoupledWBFullServeN) mwbmode).serve_cnt[0]);
* uint r = 0;
* for (uint b = 0; b < bmax; b++) {
* Console.Write("{0}\t", b);
* foreach (Cmd cmd in cmdqs[r, b]) {
* Console.Write("{0} {1}\t", cmd.type.ToString(), can_schedule_cmd(cmd));
* }
* Console.WriteLine();
* }
* }
*/
/*** clock factor ***/
if (cycles % Config.mem.clock_factor != 0)
{
return;
}
/*** serve completed request ***/
if (bus_q.Count > 0 && bus_q[0].ts <= cycles)
{
MemAddr addr = bus_q[0].addr;
bus_q.RemoveAt(0);
List <Req> inflight_q = inflightqs[addr.rid, addr.bid];
Dbg.Assert(inflight_q.Count > 0);
Dbg.Assert(addr == inflight_q[0].addr);
Req req = inflight_q[0];
inflight_q.RemoveAt(0);
dequeue_req(req);
}
Cmd best_cmd = find_best_cmd();
Req best_req = find_best_req();
//nothing to issue
if (best_cmd == null && best_req == null)
{
return;
}
//arbitrate between command and request
bool is_issue_req = false;
if (best_req != null && best_cmd == null)
{
is_issue_req = true;
}
else if (best_req == null && best_cmd != null)
{
is_issue_req = false;
}
else
{
if (best_req == __better_req(best_cmd.req, best_req))
{
is_issue_req = true;
}
else
{
is_issue_req = false;
}
}
//issue command or request
if (is_issue_req)
{
// Console.Write(" Cycles " + meta_mctrl.get_cycles() + "\n");
issue_req(best_req);
meta_mctrl.prev_req_pid = best_req.pid;
}
else
{
issue_cmd(best_cmd);
meta_mctrl.prev_req_pid = best_cmd.req.pid;
}
}
public void enqueue_req(Req req)
{
sched.enqueue_req(req);
wbsched.issue_req(req);
}
public void update_wb_mode()
{
bool prev_wb_mode = wb_mode;
wb_mode = mwbmode.is_wb_mode(cid);
if (wb_mode)
{
Stat.mctrls[cid].wbmode_fraction.Collect();
}
if (prev_wb_mode == false && wb_mode == true)
{
//stats
ts_start_wbmode = cycles;
if (ts_end_wbmode != -1)
{
Stat.mctrls[cid].wbmode_distance.Collect((int)(ts_start_wbmode - ts_end_wbmode));
}
/*
* if (cid == 0) {
* Console.WriteLine("=====Start: {0,8}======================================", cycles);
* Console.Write("\t");
* for (uint b = 0; b < bmax; b++) {
* Console.Write("{0,4}", readqs[0, b].Count);
* }
* Console.WriteLine();
*
* Console.Write("\t");
* for (uint b = 0; b < bmax; b++) {
* Console.Write("{0,4}", writeqs[0, b].Count);
* }
* Console.WriteLine();
* }
*/
//stats: longest write transaction
int longest_transaction = 0;
for (uint r = 0; r < rmax; r++)
{
for (uint b = 0; b < bmax; b++)
{
List <Req> q = writeqs[r, b];
Dictionary <ulong, int> dict = new Dictionary <ulong, int>();
foreach (Req req in q)
{
if (!dict.ContainsKey(req.addr.rowid))
{
dict.Add(req.addr.rowid, 0);
}
dict[req.addr.rowid] += 1;
}
foreach (int transaction in dict.Values)
{
if (transaction > longest_transaction)
{
longest_transaction = transaction;
}
}
}
}
Stat.mctrls[cid].wbmode_longest_transaction.Collect(longest_transaction);
/*
* if (cid == 0)
* Console.WriteLine("Longest Transaction: {0}", longest_transaction);
*/
//flush/drain reads
reads_to_drain = 0;
for (uint r = 0; r < rmax; r++)
{
for (uint b = 0; b < bmax; b++)
{
List <Cmd> cmdq = cmdqs[r, b];
if (cmdq.Count == 0)
{
continue;
}
//only column command
if (cmdq.Count == 1)
{
//increment the number of reads to drain during the first part of the writeback mode
Dbg.Assert(cmdq[0].type == Cmd.TypeEnum.READ || cmdq[0].type == Cmd.TypeEnum.WRITE);
if (cmdq[0].type == Cmd.TypeEnum.READ)
{
reads_to_drain++;
cmdq[0].is_drain = true;
}
continue;
}
//activate+column command
Dbg.Assert(cmdq.Count == 2);
Dbg.Assert(cmdq[0].type == Cmd.TypeEnum.ACTIVATE);
Dbg.Assert(cmdq[1].type == Cmd.TypeEnum.READ || cmdq[1].type == Cmd.TypeEnum.WRITE);
//write requests don't matter
if (cmdq[1].type == Cmd.TypeEnum.WRITE)
{
continue;
}
//don't flush read request
if (Config.mctrl.read_bypass)
{
if (writeqs[r, b].Count == 0)
{
continue;
}
}
//flush read request
Req req = cmdq[1].req;
List <Req> inflightq = get_inflight_q(req);
Req last_req = inflightq[inflightq.Count - 1];
Dbg.Assert(last_req.block_addr == req.block_addr);
inflightq.RemoveAt(inflightq.Count - 1);
List <Req> q = get_q(req);
Dbg.Assert(q.Count < q.Capacity);
q.Add(req);
//flush read command
cmdq.RemoveRange(0, 2);
}
}
}
else if (prev_wb_mode == true && wb_mode == false)
{
//stats
ts_end_wbmode = cycles;
Stat.mctrls[cid].wbmode_length.Collect((int)(ts_end_wbmode - ts_start_wbmode));
/*
* if (cid == 0) {
* Console.WriteLine("Length: {0}", cycles-ts_start_wbmode);
* Console.WriteLine("Rds: {0}", rds_per_wb_mode);
* Console.WriteLine("Wrs: {0}", wbs_per_wb_mode);
* Console.WriteLine("=====End: {0,8}======================================", cycles);
* }
*/
Stat.mctrls[cid].rds_per_wb_mode.Collect(rds_per_wb_mode);
Stat.mctrls[cid].wbs_per_wb_mode.Collect(wbs_per_wb_mode);
rds_per_wb_mode = 0;
wbs_per_wb_mode = 0;
//flush/drain writes
writes_to_drain = 0;
foreach (List <Cmd> cmdq in cmdqs)
{
if (cmdq.Count == 0)
{
continue;
}
//only column command
if (cmdq.Count == 1)
{
//increment the number of reads to drain during the first part of the writeback mode
Dbg.Assert(cmdq[0].type == Cmd.TypeEnum.READ || cmdq[0].type == Cmd.TypeEnum.WRITE);
if (cmdq[0].type == Cmd.TypeEnum.WRITE)
{
writes_to_drain++;
cmdq[0].is_drain = true;
}
continue;
}
//activate+column command
Dbg.Assert(cmdq.Count == 2);
Dbg.Assert(cmdq[0].type == Cmd.TypeEnum.ACTIVATE);
Dbg.Assert(cmdq[1].type == Cmd.TypeEnum.READ || cmdq[1].type == Cmd.TypeEnum.WRITE);
if (cmdq[1].type == Cmd.TypeEnum.READ)
{
continue;
}
//flush read request
Req req = cmdq[1].req;
List <Req> inflightq = get_inflight_q(req);
Req last_req = inflightq[inflightq.Count - 1];
Dbg.Assert(last_req.block_addr == req.block_addr);
inflightq.RemoveAt(inflightq.Count - 1);
List <Req> q = get_q(req);
Dbg.Assert(q.Count < q.Capacity);
q.Add(req);
//flush read command
cmdq.RemoveRange(0, 2);
}
}
}
public void issue_insts(bool issued_rd_req)
{
//issue instructions
for (int i = 0; i < Config.proc.ipc; i++)
{
if (inst_wnd.is_full())
{
if (i == 0)
{
Stat.procs[pid].stall_inst_wnd.Collect();
// Measurement.core_stall_cycles[pid] += 1;
}
return;
}
//cpu instructions
if (curr_cpu_inst_cnt > 0)
{
curr_cpu_inst_cnt--;
inst_wnd.add(0, false, true);
continue;
}
//only one memory instruction can be issued per cycle
if (issued_rd_req)
{
return;
}
//memory instruction (only AFTER checking for one memory instruction per cycle)
inst_wnd.add(curr_rd_req.block_addr, true, false);
//check if true miss
bool false_miss = inst_wnd.is_duplicate(curr_rd_req.block_addr);
if (false_miss)
{
Dbg.Assert(curr_rd_req.wb_req == null);
RequestPool.enpool(curr_rd_req);
curr_rd_req = get_req();
continue;
}
//try mshr
bool mshr_ok = insert_mshr(curr_rd_req);
if (!mshr_ok)
{
mshr_retry = true;
return;
}
//try memory controller
bool mctrl_ok = insert_mctrl(curr_rd_req);
if (!mctrl_ok)
{
mctrl_retry = true;
return;
}
//issued memory request
issued_rd_req = true;
//get new read request
curr_rd_req = get_req();
}
}
private Req __find_best_req(int r, int b)
{
//no need to search for request, already outstanding commands
if (cmdqs[r, b].Count > 0)
{
return(null);
}
/*** find best request ***/
List <Req> rq = readqs[r, b];
List <Req> wq = writeqs[r, b];
if (rq.Count == 0 && wq.Count == 0)
{
return(null);
}
Req best_req = null;
Cmd cmd = null;
//find best writeback request
if (wb_mode)
{
best_req = meta_mctrl.find_best_wb_req(wq);
if (best_req != null)
{
//check if best writeback request is schedulable
cmd = decode_req(best_req)[0];
if (!can_schedule_cmd(cmd))
{
return(null);
}
return(best_req);
}
//writeq is empty: should we let reads bypass?
if (!Config.mctrl.read_bypass)
{
return(null);
}
}
//find best read request
best_req = meta_mctrl.find_best_rd_req(rq);
/*** row-hit bypass ***/
if (Config.mctrl.row_hit_bypass)
{
Req hit_req = rh_finder.find_best_req(rq);
if (!meta_mctrl.is_row_hit(best_req) && hit_req != null)
{
Bank bank = chan.ranks[r].banks[b];
Dbg.Assert(bank.ts_act != -1);
long ts_pre = bank.ts_act + timing.tRAS;
long speculative_ts_pre = cycles + timing.tRTP;
if (speculative_ts_pre <= ts_pre)
{
best_req = hit_req;
}
}
}
if (best_req == null)
{
return(null);
}
//check if best request is schedulable
cmd = decode_req(best_req)[0];
if (!can_schedule_cmd(cmd))
{
return(null);
}
return(best_req);
}
public void dequeue_req(Req req)
{
__dequeue_req(req);
}
private void issue_req(Req req)
{
//remove request from waiting queue
List <Req> q = get_q(req);
Dbg.Assert(q.Contains(req));
q.Remove(req);
req.queueing_latency = (int)(cycles - req.ts_arrival);
total_queueing_latency[req.pid] += (ulong)req.queueing_latency;
//add to inflight queue
MemAddr addr = req.addr;
List <Req> inflight_q = inflightqs[addr.rid, addr.bid];
Dbg.Assert(inflight_q.Count < inflight_q.Capacity);
inflight_q.Add(req);
//add to command queue
List <Cmd> cmd_q = cmdqs[addr.rid, addr.bid];
Dbg.Assert(cmd_q.Count == 0);
List <Cmd> new_cmd_q = decode_req(req);
Dbg.Assert(new_cmd_q.Count > 0);
cmd_q.AddRange(new_cmd_q);
Cmd cmd = cmd_q[0];
//meta_mctrl
meta_mctrl.issue_req(req);
req.ts_issue = cycles;
//stats
BankStat bstat = Stat.banks[addr.cid, addr.rid, addr.bid];
bstat.access.Collect();
if (cmd.type == Cmd.TypeEnum.PRECHARGE || cmd.type == Cmd.TypeEnum.ACTIVATE)
{
//bank stat
bstat.row_miss.Collect();
bstat.row_miss_perproc[req.pid].Collect();
//proc stat
if (cmd.req.type == ReqType.RD)
{
Stat.procs[req.pid].row_hit_rate_read.Collect(0);
Stat.procs[req.pid].row_miss_read.Collect();
}
else
{
Stat.procs[req.pid].row_hit_rate_write.Collect(0);
Stat.procs[req.pid].row_miss_write.Collect();
}
}
else
{
//bank stat
bstat.row_hit.Collect();
bstat.row_hit_perproc[req.pid].Collect();
//proc stat
if (cmd.req.type == ReqType.RD)
{
Stat.procs[req.pid].row_hit_rate_read.Collect(1);
Stat.procs[req.pid].row_hit_read.Collect();
}
else
{
Stat.procs[req.pid].row_hit_rate_write.Collect(1);
Stat.procs[req.pid].row_hit_write.Collect();
}
}
//issue command
issue_cmd(cmd);
}
protected bool is_row_hit(Req req)
{
return(meta_mctrl.is_row_hit(req));
}
public static void DramSetCorePrevRowid(Req req)
{
core_prev_rowid[req.pid, NVM_bank_num + (req.addr.cid * Config.mem2.rank_max + req.addr.rid) * Dram_BANK_MAX + req.addr.bid] = req.addr.rowid;
}
public void dequeue_req(Req req)
{
__dequeue_req(req);
}
public static void NVMSetCorePrevRowid(Req req)
{
core_prev_rowid[req.pid, (req.addr.cid * Config.mem.rank_max + req.addr.rid) * NVM_BANK_MAX + req.addr.bid] = req.addr.rowid;
}
public List<Req> get_inflight_q(Req req)
{
List<Req> q = inflightqs[req.addr.rid, req.addr.bid];
return q;
}
public abstract void enqueue_req(Req req);
public void __dequeue_req(Req req)
{
req.ts_departure = cycles;
Dbg.Assert(req.ts_departure - req.ts_arrival > 0);
//sched
meta_mctrl.dequeue_req(req);
//load stat management
if (req.type == ReqType.RD) {
rload--;
rload_per_proc[req.pid]--;
rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]--;
Dbg.Assert(rload >= 0);
Dbg.Assert(rload_per_proc[req.pid] >= 0);
Dbg.Assert(rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid] >= 0);
}
else {
wload--;
wload_per_proc[req.pid]--;
wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]--;
Dbg.Assert(wload >= 0);
Dbg.Assert(wload_per_proc[req.pid] >= 0);
Dbg.Assert(wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid] >= 0);
}
meta_mctrl.sched.service_counter(req);
//dequeue proper
if (req.type == ReqType.RD) {
//traverse crossbar
Sim.xbar.enqueue(req);
}
else {
bool removeok = mctrl_writeq.Remove(req);
Dbg.Assert(removeok);
req.latency = (int)(req.ts_departure - req.ts_arrival);
Callback cb = req.callback;
cb(req);
}
}
public static void NVMResetRowBufferChange(Req req)
{
core_prev_rowid[req.pid, (req.addr.cid * Config.mem.rank_max + req.addr.rid) * NVM_BANK_MAX + req.addr.bid] = 0;
}
private List<Cmd> decode_req(Req req)
{
MemAddr addr = req.addr;
List<Cmd> cmd_q = cmdqs[addr.rid, addr.bid];
int pid = req.pid;
Bank b = chan.ranks[addr.rid].banks[addr.bid];
List<Cmd> decode_cmd_q = new List<Cmd>(CMDQ_MAX);
if (b.curr_rowid == -1) {
//row-closed
req.row_hit = false;
decode_cmd_q.Add(new Cmd(Cmd.TypeEnum.ACTIVATE, addr, pid, req, cmd_q));
}
else if (b.curr_rowid != (long)addr.rowid) {
//row-conflict
req.row_hit = false;
decode_cmd_q.Add(new Cmd(Cmd.TypeEnum.PRECHARGE, addr, pid, req, cmd_q));
decode_cmd_q.Add(new Cmd(Cmd.TypeEnum.ACTIVATE, addr, pid, req, cmd_q));
}
Cmd.TypeEnum RW = (req.type == ReqType.WR ? Cmd.TypeEnum.WRITE : Cmd.TypeEnum.READ);
decode_cmd_q.Add(new Cmd(RW, addr, pid, req, cmd_q));
return decode_cmd_q;
}
public static void DramBankPidDeUpdate(Req req)
{
bank_req_pid[NVM_bank_num + (req.addr.cid * Config.mem2.rank_max + req.addr.rid) * Dram_BANK_MAX + req.addr.bid] = Config.N;
}
private Req __better_req(Req req1, Req req2)
{
bool is_wr1 = req1.type == ReqType.WR;
bool is_wr2 = req2.type == ReqType.WR;
if (is_wr1 && is_wr2) {
return meta_mctrl.better_wb_req(req1, req2);
}
if (is_wr1 ^ is_wr2) {
if (is_wr1) return req1;
else return req2;
}
//two reads
return meta_mctrl.better_req(req1, req2);
}
public static void NVMBankPidDeUpdate(Req req)
{
bank_req_pid[(req.addr.cid * Config.mem.rank_max + req.addr.rid) * NVM_BANK_MAX + req.addr.bid] = Config.N;
}
public override void dequeue_req(Req req) { }
public MemCtrl get_mctrl(Req req)
{
if (!is_omniscient) {
Dbg.Assert(mctrl.cid == req.addr.cid);
return mctrl;
}
return mctrls[req.addr.cid];
}
public static void DramResetRowBufferChange(Req req)
{
core_prev_rowid[req.pid, NVM_bank_num + (req.addr.cid * Config.mem2.rank_max + req.addr.rid) * Dram_BANK_MAX + req.addr.bid] = 0;
}
public void __dequeue_req(Req req)
{
req.ts_departure = cycles;
Dbg.Assert(req.ts_departure - req.ts_arrival > 0);
if (!req.migrated_request)
{
if (Config.proc.cache_insertion_policy == "PFA")
{
RowStat.UpdateMLP(RowStat.NVMDict, req);
Measurement.mem_num_dec(req);
// Measurement.NVMServiceTimeUpdate (req);
// Measurement.NVMCoreReqNumDec (req);
Row_Migration_Policies.target = true;
Row_Migration_Policies.target_req = req;
}
else if (Config.proc.cache_insertion_policy == "RBLA")
{
Row_Migration_Policies.target = true;
Row_Migration_Policies.target_req = req;
}
}
if (Config.proc.cache_insertion_policy == "PFA")
{
Measurement.NVMCoreReqNumDec(req);
}
/* if (Config.proc.cache_insertion_policy == "PFA")
* {
* Measurement.NVMSetCorePrevRowid (req);
* }
*/
//sched
meta_mctrl.dequeue_req(req);
//load stat management
if (!req.cache_wb)
{
if (req.type == ReqType.RD)
{
rload--;
rload_per_proc[req.pid]--;
rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]--;
Dbg.Assert(rload >= 0);
Dbg.Assert(rload_per_proc[req.pid] >= 0);
Dbg.Assert(rload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid] >= 0);
}
else
{
wload--;
wload_per_proc[req.pid]--;
wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid]--;
Dbg.Assert(wload >= 0);
Dbg.Assert(wload_per_proc[req.pid] >= 0);
Dbg.Assert(wload_per_procrankbank[req.pid, req.addr.rid, req.addr.bid] >= 0);
}
}
else
{
if (req.type == ReqType.RD)
{
rload--;
}
else
{
wload--;
}
}
/* //dequeue proper
* if (req.type == ReqType.RD) {
* //traverse crossbar
* Sim.xbar.enqueue(req);
*
* //cache
* Sim.caches[Sim.get_cache(req.pid)].meta_insert(req);
* }
* else {
* bool removeok = mctrl_writeq.Remove(req);
* Dbg.Assert(removeok);
* req.latency = (int)(req.ts_departure - req.ts_arrival);
*
* Callback cb = req.callback;
* cb(req);
*
* if (!req.cache_wb) {
* //cache
* switch (Config.proc.cache_write_policy) {
* case "WriteThrough":
* // do nothing
* break;
* case "WriteBack":
* Sim.caches[Sim.get_cache(req.pid)].meta_insert(req);
* break;
* }
* }
* else
* RequestPool.enpool(req);
* }
*/
if (req.type == ReqType.RD)
{
if (!Sim.caches[Sim.get_cache(req.pid)].is_cached(req))
{
Sim.caches[Sim.get_cache(req.pid)].meta_insert(req);
}
// if (req.callback != null)
Sim.xbar.enqueue(req);
// else
// RequestPool.enpool(req);
}
else
{
bool removeok = mctrl_writeq.Remove(req);
Dbg.Assert(removeok);
req.latency = (int)(req.ts_departure - req.ts_arrival);
Callback cb = req.callback;
if (!req.cache_wb)
{
switch (Config.proc.cache_write_policy)
{
case "WriteThrough":
break;
case "WriteBack":
if (!Sim.caches[Sim.get_cache(req.pid)].is_cached(req))
{
Sim.caches[Sim.get_cache(req.pid)].meta_insert(req);
}
break;
}
if (cb != null)
{
cb(req);
}
// else
// RequestPool.enpool(req);
}
else
{
RequestPool.enpool(req);
}
}
}
