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/*
* Copyright (c) 2011-2015 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.
*
* Author: John Kalamatianos, Anthony Gutierrez
*/
#ifndef __COMPUTE_UNIT_HH__
#define __COMPUTE_UNIT_HH__
#include <deque>
#include <map>
#include <unordered_map>
#include <vector>
#include "base/callback.hh"
#include "base/statistics.hh"
#include "base/types.hh"
#include "enums/PrefetchType.hh"
#include "gpu-compute/exec_stage.hh"
#include "gpu-compute/fetch_stage.hh"
#include "gpu-compute/global_memory_pipeline.hh"
#include "gpu-compute/local_memory_pipeline.hh"
#include "gpu-compute/qstruct.hh"
#include "gpu-compute/schedule_stage.hh"
#include "gpu-compute/scoreboard_check_stage.hh"
#include "mem/mem_object.hh"
#include "mem/port.hh"
static const int MAX_REGS_FOR_NON_VEC_MEM_INST = 1;
static const int MAX_WIDTH_FOR_MEM_INST = 32;
class NDRange;
class Shader;
class VectorRegisterFile;
struct ComputeUnitParams;
enum EXEC_POLICY
{
OLDEST = 0,
RR
};
// List of execution units
enum EXEC_UNIT
{
SIMD0 = 0,
SIMD1,
SIMD2,
SIMD3,
GLBMEM_PIPE,
LDSMEM_PIPE,
NUM_UNITS
};
enum TLB_CACHE
{
TLB_MISS_CACHE_MISS = 0,
TLB_MISS_CACHE_HIT,
TLB_HIT_CACHE_MISS,
TLB_HIT_CACHE_HIT
};
class ComputeUnit : public MemObject
{
public:
FetchStage fetchStage;
ScoreboardCheckStage scoreboardCheckStage;
ScheduleStage scheduleStage;
ExecStage execStage;
GlobalMemPipeline globalMemoryPipe;
LocalMemPipeline localMemoryPipe;
// Buffers used to communicate between various pipeline stages
// List of waves which are ready to be scheduled.
// Each execution resource has a ready list. readyList is
// used to communicate between scoreboardCheck stage and
// schedule stage
// TODO: make enum to index readyList
std::vector<std::vector<Wavefront*>> readyList;
// Stores the status of waves. A READY implies the
// wave is ready to be scheduled this cycle and
// is already present in the readyList. waveStatusList is
// used to communicate between scoreboardCheck stage and
// schedule stage
// TODO: convert std::pair to a class to increase readability
std::vector<std::vector<std::pair<Wavefront*, WAVE_STATUS>>> waveStatusList;
// List of waves which will be dispatched to
// each execution resource. A FILLED implies
// dispatch list is non-empty and
// execution unit has something to execute
// this cycle. Currently, the dispatch list of
// an execution resource can hold only one wave because
// an execution resource can execute only one wave in a cycle.
// dispatchList is used to communicate between schedule
// and exec stage
// TODO: convert std::pair to a class to increase readability
std::vector<std::pair<Wavefront*, DISPATCH_STATUS>> dispatchList;
int rrNextMemID; // used by RR WF exec policy to cycle through WF's
int rrNextALUWp;
typedef ComputeUnitParams Params;
std::vector<std::vector<Wavefront*>> wfList;
int cu_id;
// array of vector register files, one per SIMD
std::vector<VectorRegisterFile*> vrf;
// Number of vector ALU units (SIMDs) in CU
int numSIMDs;
// number of pipe stages for bypassing data to next dependent single
// precision vector instruction inside the vector ALU pipeline
int spBypassPipeLength;
// number of pipe stages for bypassing data to next dependent double
// precision vector instruction inside the vector ALU pipeline
int dpBypassPipeLength;
// number of cycles per issue period
int issuePeriod;
// Number of global and local memory execution resources in CU
int numGlbMemUnits;
int numLocMemUnits;
// tracks the last cycle a vector instruction was executed on a SIMD
std::vector<uint64_t> lastExecCycle;
// true if we allow a separate TLB per lane
bool perLaneTLB;
// if 0, TLB prefetching is off.
int prefetchDepth;
// if fixed-stride prefetching, this is the stride.
int prefetchStride;
std::vector<Addr> lastVaddrCU;
std::vector<std::vector<Addr>> lastVaddrSimd;
std::vector<std::vector<std::vector<Addr>>> lastVaddrWF;
Enums::PrefetchType prefetchType;
EXEC_POLICY exec_policy;
bool xact_cas_mode;
bool debugSegFault;
bool functionalTLB;
bool localMemBarrier;
/*
* for Counting page accesses
*
* cuExitCallback inherits from Callback. When you register a callback
* function as an exit callback, it will get added to an exit callback
* queue, such that on simulation exit, all callbacks in the callback
* queue will have their process() function called.
*/
bool countPages;
Shader *shader;
uint32_t barrier_id;
// vector of Vector ALU (MACC) pipelines
std::vector<WaitClass> aluPipe;
// minimum issue period per SIMD unit (in cycles)
std::vector<WaitClass> wfWait;
// Resource control for Vector Register File->Global Memory pipe buses
std::vector<WaitClass> vrfToGlobalMemPipeBus;
// Resource control for Vector Register File->Local Memory pipe buses
std::vector<WaitClass> vrfToLocalMemPipeBus;
int nextGlbMemBus;
int nextLocMemBus;
// Resource control for global memory to VRF data/address bus
WaitClass glbMemToVrfBus;
// Resource control for local memory to VRF data/address bus
WaitClass locMemToVrfBus;
uint32_t vrfToCoalescerBusWidth; // VRF->Coalescer data bus width in bytes
uint32_t coalescerToVrfBusWidth; // Coalescer->VRF data bus width in bytes
uint32_t numCyclesPerStoreTransfer; // number of cycles per vector store
uint32_t numCyclesPerLoadTransfer; // number of cycles per vector load
Tick req_tick_latency;
Tick resp_tick_latency;
// number of vector registers being reserved for each SIMD unit
std::vector<int> vectorRegsReserved;
// number of vector registers per SIMD unit
uint32_t numVecRegsPerSimd;
// Support for scheduling VGPR status update events
std::vector<std::pair<uint32_t, uint32_t> > regIdxVec;
std::vector<uint64_t> timestampVec;
std::vector<uint8_t> statusVec;
void
registerEvent(uint32_t simdId,
uint32_t regIdx,
uint32_t operandSize,
uint64_t when,
uint8_t newStatus) {
regIdxVec.push_back(std::make_pair(simdId, regIdx));
timestampVec.push_back(when);
statusVec.push_back(newStatus);
if (operandSize > 4) {
regIdxVec.push_back(std::make_pair(simdId,
((regIdx + 1) %
numVecRegsPerSimd)));
timestampVec.push_back(when);
statusVec.push_back(newStatus);
}
}
void updateEvents();
// this hash map will keep track of page divergence
// per memory instruction per wavefront. The hash map
// is cleared in GPUDynInst::updateStats() in gpu_dyn_inst.cc.
std::map<Addr, int> pagesTouched;
ComputeUnit(const Params *p);
~ComputeUnit();
int spBypassLength() { return spBypassPipeLength; };
int dpBypassLength() { return dpBypassPipeLength; };
int storeBusLength() { return numCyclesPerStoreTransfer; };
int loadBusLength() { return numCyclesPerLoadTransfer; };
int wfSize() const { return wavefrontSize; };
void resizeRegFiles(int num_cregs, int num_sregs, int num_dregs);
void exec();
void initiateFetch(Wavefront *wavefront);
void fetch(PacketPtr pkt, Wavefront *wavefront);
void FillKernelState(Wavefront *w, NDRange *ndr);
void StartWF(Wavefront *w, int trueWgSize[], int trueWgSizeTotal,
int cnt, LdsChunk *ldsChunk, NDRange *ndr);
void StartWorkgroup(NDRange *ndr);
int ReadyWorkgroup(NDRange *ndr);
bool isVecAlu(int unitId) { return unitId >= SIMD0 && unitId <= SIMD3; }
bool isGlbMem(int unitId) { return unitId == GLBMEM_PIPE; }
bool isShrMem(int unitId) { return unitId == LDSMEM_PIPE; }
int GlbMemUnitId() { return GLBMEM_PIPE; }
int ShrMemUnitId() { return LDSMEM_PIPE; }
int nextGlbRdBus() { return (++nextGlbMemBus) % numGlbMemUnits; }
int nextLocRdBus() { return (++nextLocMemBus) % numLocMemUnits; }
/* This function cycles through all the wavefronts in all the phases to see
* if all of the wavefronts which should be associated with one barrier
* (denoted with _barrier_id), are all at the same barrier in the program
* (denoted by bcnt). When the number at the barrier matches bslots, then
* return true.
*/
int AllAtBarrier(uint32_t _barrier_id, uint32_t bcnt, uint32_t bslots);
bool cedeSIMD(int simdId, int wfSlotId);
template<typename c0, typename c1> void doSmReturn(GPUDynInstPtr gpuDynInst);
virtual void init();
void sendRequest(GPUDynInstPtr gpuDynInst, int index, PacketPtr pkt);
void sendSyncRequest(GPUDynInstPtr gpuDynInst, int index, PacketPtr pkt);
void injectGlobalMemFence(GPUDynInstPtr gpuDynInst,
bool kernelLaunch=true,
RequestPtr req=nullptr);
void handleMemPacket(PacketPtr pkt, int memport_index);
bool processTimingPacket(PacketPtr pkt);
void processFetchReturn(PacketPtr pkt);
void updatePageDivergenceDist(Addr addr);
MasterID masterId() { return _masterId; }
bool isDone() const;
bool isSimdDone(uint32_t) const;
protected:
MasterID _masterId;
LdsState &lds;
public:
// the following stats compute the avg. TLB accesslatency per
// uncoalesced request (only for data)
Stats::Scalar tlbRequests;
Stats::Scalar tlbCycles;
Stats::Formula tlbLatency;
// hitsPerTLBLevel[x] are the hits in Level x TLB. x = 0 is the page table.
Stats::Vector hitsPerTLBLevel;
Stats::Scalar ldsBankAccesses;
Stats::Distribution ldsBankConflictDist;
// over all memory instructions executed over all wavefronts
// how many touched 0-4 pages, 4-8, ..., 60-64 pages
Stats::Distribution pageDivergenceDist;
Stats::Scalar dynamicGMemInstrCnt;
Stats::Scalar dynamicLMemInstrCnt;
Stats::Scalar wgBlockedDueLdsAllocation;
// Number of instructions executed, i.e. if 64 (or 32 or 7) lanes are active
// when the instruction is committed, this number is still incremented by 1
Stats::Scalar numInstrExecuted;
// Number of cycles among successive instruction executions across all
// wavefronts of the same CU
Stats::Distribution execRateDist;
// number of individual vector operations executed
Stats::Scalar numVecOpsExecuted;
// Total cycles that something is running on the GPU
Stats::Scalar totalCycles;
Stats::Formula vpc; // vector ops per cycle
Stats::Formula ipc; // vector instructions per cycle
Stats::Distribution controlFlowDivergenceDist;
Stats::Distribution activeLanesPerGMemInstrDist;
Stats::Distribution activeLanesPerLMemInstrDist;
// number of vector ALU instructions received
Stats::Formula numALUInstsExecuted;
// number of times a WG can not start due to lack of free VGPRs in SIMDs
Stats::Scalar numTimesWgBlockedDueVgprAlloc;
Stats::Scalar numCASOps;
Stats::Scalar numFailedCASOps;
Stats::Scalar completedWfs;
// flag per vector SIMD unit that is set when there is at least one
// WV that has a vector ALU instruction as the oldest in its
// Instruction Buffer: Defined in the Scoreboard stage, consumed
// by the Execute stage.
std::vector<bool> vectorAluInstAvail;
// number of available (oldest) LDS instructions that could have
// been issued to the LDS at a specific issue slot
int shrMemInstAvail;
// number of available Global memory instructions that could have
// been issued to TCP at a specific issue slot
int glbMemInstAvail;
void
regStats();
LdsState &
getLds() const
{
return lds;
}
int32_t
getRefCounter(const uint32_t dispatchId, const uint32_t wgId) const;
bool
sendToLds(GPUDynInstPtr gpuDynInst) __attribute__((warn_unused_result));
typedef std::unordered_map<Addr, std::pair<int, int>> pageDataStruct;
pageDataStruct pageAccesses;
class CUExitCallback : public Callback
{
private:
ComputeUnit *computeUnit;
public:
virtual ~CUExitCallback() { }
CUExitCallback(ComputeUnit *_cu)
{
computeUnit = _cu;
}
virtual void
process();
};
CUExitCallback *cuExitCallback;
/** Data access Port **/
class DataPort : public MasterPort
{
public:
DataPort(const std::string &_name, ComputeUnit *_cu, PortID _index)
: MasterPort(_name, _cu), computeUnit(_cu),
index(_index) { }
bool snoopRangeSent;
struct SenderState : public Packet::SenderState
{
GPUDynInstPtr _gpuDynInst;
int port_index;
Packet::SenderState *saved;
SenderState(GPUDynInstPtr gpuDynInst, PortID _port_index,
Packet::SenderState *sender_state=nullptr)
: _gpuDynInst(gpuDynInst),
port_index(_port_index),
saved(sender_state) { }
};
class MemReqEvent : public Event
{
private:
DataPort *dataPort;
PacketPtr pkt;
public:
MemReqEvent(DataPort *_data_port, PacketPtr _pkt)
: Event(), dataPort(_data_port), pkt(_pkt)
{
setFlags(Event::AutoDelete);
}
void process();
const char *description() const;
};
class MemRespEvent : public Event
{
private:
DataPort *dataPort;
PacketPtr pkt;
public:
MemRespEvent(DataPort *_data_port, PacketPtr _pkt)
: Event(), dataPort(_data_port), pkt(_pkt)
{
setFlags(Event::AutoDelete);
}
void process();
const char *description() const;
};
std::deque<std::pair<PacketPtr, GPUDynInstPtr>> retries;
protected:
ComputeUnit *computeUnit;
int index;
virtual bool recvTimingResp(PacketPtr pkt);
virtual Tick recvAtomic(PacketPtr pkt) { return 0; }
virtual void recvFunctional(PacketPtr pkt) { }
virtual void recvRangeChange() { }
virtual void recvReqRetry();
virtual void
getDeviceAddressRanges(AddrRangeList &resp, bool &snoop)
{
resp.clear();
snoop = true;
}
};
// Instruction cache access port
class SQCPort : public MasterPort
{
public:
SQCPort(const std::string &_name, ComputeUnit *_cu, PortID _index)
: MasterPort(_name, _cu), computeUnit(_cu),
index(_index) { }
bool snoopRangeSent;
struct SenderState : public Packet::SenderState
{
Wavefront *wavefront;
Packet::SenderState *saved;
SenderState(Wavefront *_wavefront, Packet::SenderState
*sender_state=nullptr)
: wavefront(_wavefront), saved(sender_state) { }
};
std::deque<std::pair<PacketPtr, Wavefront*>> retries;
protected:
ComputeUnit *computeUnit;
int index;
virtual bool recvTimingResp(PacketPtr pkt);
virtual Tick recvAtomic(PacketPtr pkt) { return 0; }
virtual void recvFunctional(PacketPtr pkt) { }
virtual void recvRangeChange() { }
virtual void recvReqRetry();
virtual void
getDeviceAddressRanges(AddrRangeList &resp, bool &snoop)
{
resp.clear();
snoop = true;
}
};
/** Data TLB port **/
class DTLBPort : public MasterPort
{
public:
DTLBPort(const std::string &_name, ComputeUnit *_cu, PortID _index)
: MasterPort(_name, _cu), computeUnit(_cu),
index(_index), stalled(false)
{ }
bool isStalled() { return stalled; }
void stallPort() { stalled = true; }
void unstallPort() { stalled = false; }
/**
* here we queue all the translation requests that were
* not successfully sent.
*/
std::deque<PacketPtr> retries;
/** SenderState is information carried along with the packet
* throughout the TLB hierarchy
*/
struct SenderState: public Packet::SenderState
{
// the memInst that this is associated with
GPUDynInstPtr _gpuDynInst;
// the lane in the memInst this is associated with, so we send
// the memory request down the right port
int portIndex;
// constructor used for packets involved in timing accesses
SenderState(GPUDynInstPtr gpuDynInst, PortID port_index)
: _gpuDynInst(gpuDynInst), portIndex(port_index) { }
};
protected:
ComputeUnit *computeUnit;
int index;
bool stalled;
virtual bool recvTimingResp(PacketPtr pkt);
virtual Tick recvAtomic(PacketPtr pkt) { return 0; }
virtual void recvFunctional(PacketPtr pkt) { }
virtual void recvRangeChange() { }
virtual void recvReqRetry();
};
class ITLBPort : public MasterPort
{
public:
ITLBPort(const std::string &_name, ComputeUnit *_cu)
: MasterPort(_name, _cu), computeUnit(_cu), stalled(false) { }
bool isStalled() { return stalled; }
void stallPort() { stalled = true; }
void unstallPort() { stalled = false; }
/**
* here we queue all the translation requests that were
* not successfully sent.
*/
std::deque<PacketPtr> retries;
/** SenderState is information carried along with the packet
* throughout the TLB hierarchy
*/
struct SenderState: public Packet::SenderState
{
// The wavefront associated with this request
Wavefront *wavefront;
SenderState(Wavefront *_wavefront) : wavefront(_wavefront) { }
};
protected:
ComputeUnit *computeUnit;
bool stalled;
virtual bool recvTimingResp(PacketPtr pkt);
virtual Tick recvAtomic(PacketPtr pkt) { return 0; }
virtual void recvFunctional(PacketPtr pkt) { }
virtual void recvRangeChange() { }
virtual void recvReqRetry();
};
/**
* the port intended to communicate between the CU and its LDS
*/
class LDSPort : public MasterPort
{
public:
LDSPort(const std::string &_name, ComputeUnit *_cu, PortID _id)
: MasterPort(_name, _cu, _id), computeUnit(_cu)
{
}
bool isStalled() const { return stalled; }
void stallPort() { stalled = true; }
void unstallPort() { stalled = false; }
/**
* here we queue all the requests that were
* not successfully sent.
*/
std::queue<PacketPtr> retries;
/**
* SenderState is information carried along with the packet, esp. the
* GPUDynInstPtr
*/
class SenderState: public Packet::SenderState
{
protected:
// The actual read/write/atomic request that goes with this command
GPUDynInstPtr _gpuDynInst = nullptr;
public:
SenderState(GPUDynInstPtr gpuDynInst):
_gpuDynInst(gpuDynInst)
{
}
GPUDynInstPtr
getMemInst() const
{
return _gpuDynInst;
}
};
virtual bool
sendTimingReq(PacketPtr pkt);
protected:
bool stalled = false; ///< whether or not it is stalled
ComputeUnit *computeUnit;
virtual bool
recvTimingResp(PacketPtr pkt);
virtual Tick
recvAtomic(PacketPtr pkt) { return 0; }
virtual void
recvFunctional(PacketPtr pkt)
{
}
virtual void
recvRangeChange()
{
}
virtual void
recvReqRetry();
};
/** The port to access the Local Data Store
* Can be connected to a LDS object
*/
LDSPort *ldsPort = nullptr;
LDSPort *
getLdsPort() const
{
return ldsPort;
}
/** The memory port for SIMD data accesses.
* Can be connected to PhysMem for Ruby for timing simulations
*/
std::vector<DataPort*> memPort;
// port to the TLB hierarchy (i.e., the L1 TLB)
std::vector<DTLBPort*> tlbPort;
// port to the SQC (i.e. the I-cache)
SQCPort *sqcPort;
// port to the SQC TLB (there's a separate TLB for each I-cache)
ITLBPort *sqcTLBPort;
virtual BaseMasterPort&
getMasterPort(const std::string &if_name, PortID idx)
{
if (if_name == "memory_port") {
memPort[idx] = new DataPort(csprintf("%s-port%d", name(), idx),
this, idx);
return *memPort[idx];
} else if (if_name == "translation_port") {
tlbPort[idx] = new DTLBPort(csprintf("%s-port%d", name(), idx),
this, idx);
return *tlbPort[idx];
} else if (if_name == "sqc_port") {
sqcPort = new SQCPort(csprintf("%s-port%d", name(), idx),
this, idx);
return *sqcPort;
} else if (if_name == "sqc_tlb_port") {
sqcTLBPort = new ITLBPort(csprintf("%s-port", name()), this);
return *sqcTLBPort;
} else if (if_name == "ldsPort") {
if (ldsPort) {
fatal("an LDS port was already allocated");
}
ldsPort = new LDSPort(csprintf("%s-port", name()), this, idx);
return *ldsPort;
} else {
panic("incorrect port name");
}
}
// xact_cas_load()
class waveIdentifier
{
public:
waveIdentifier() { }
waveIdentifier(int _simdId, int _wfSlotId)
: simdId(_simdId), wfSlotId(_wfSlotId) { }
int simdId;
int wfSlotId;
};
class waveQueue
{
public:
std::list<waveIdentifier> waveIDQueue;
};
std::map<unsigned, waveQueue> xactCasLoadMap;
uint64_t getAndIncSeqNum() { return globalSeqNum++; }
private:
uint64_t globalSeqNum;
int wavefrontSize;
};
#endif // __COMPUTE_UNIT_HH__
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