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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: Lisa Hsu
*/
#ifndef __WAVEFRONT_HH__
#define __WAVEFRONT_HH__
#include <cassert>
#include <deque>
#include <memory>
#include <stack>
#include <vector>
#include "base/misc.hh"
#include "base/types.hh"
#include "gpu-compute/condition_register_state.hh"
#include "gpu-compute/lds_state.hh"
#include "gpu-compute/misc.hh"
#include "params/Wavefront.hh"
#include "sim/sim_object.hh"
static const int MAX_NUM_INSTS_PER_WF = 12;
/*
* Arguments for the hsail opcode call, are user defined and variable length.
* The hardware/finalizer can support arguments in hardware or use memory to
* pass arguments. For now, let's assume that an unlimited number of arguments
* are supported in hardware (the compiler inlines functions whenver it can
* anyways, so unless someone is interested in the implications of linking/
* library functions, I think this is a reasonable assumption given the typical
* size of an OpenCL kernel).
*
* Note that call args are different than kernel arguments:
* * All work-items in a kernel refer the same set of kernel arguments
* * Each work-item has it's on set of call args. So a call argument at
* address 0x4 is different for work-item 0 and work-item 1.
*
* Ok, the table below shows an example of how we organize the call arguments in
* the CallArgMem class.
*
* int foo(int arg1, double arg2)
* ___________________________________________________
* | 0: return.0 | 4: return.1 | ... | 252: return.63 |
* |---------------------------------------------------|
* | 256: arg1.0 | 260: arg1.1 | ... | 508: arg1.63 |
* |---------------------------------------------------|
* | 512: arg2.0 | 520: arg2.1 | ... | 1016: arg2.63 |
* ___________________________________________________
*/
class CallArgMem
{
public:
// pointer to buffer for storing function arguments
uint8_t *mem;
int wfSize;
// size of function args
int funcArgsSizePerItem;
template<typename CType>
int
getLaneOffset(int lane, int addr)
{
return addr * wfSize + sizeof(CType) * lane;
}
CallArgMem(int func_args_size_per_item, int wf_size)
: wfSize(wf_size), funcArgsSizePerItem(func_args_size_per_item)
{
mem = (uint8_t*)malloc(funcArgsSizePerItem * wfSize);
}
~CallArgMem()
{
free(mem);
}
template<typename CType>
uint8_t*
getLaneAddr(int lane, int addr)
{
return mem + getLaneOffset<CType>(lane, addr);
}
template<typename CType>
void
setLaneAddr(int lane, int addr, CType val)
{
*((CType*)(mem + getLaneOffset<CType>(lane, addr))) = val;
}
};
/**
* A reconvergence stack entry conveys the necessary state to implement
* control flow divergence.
*/
class ReconvergenceStackEntry {
public:
ReconvergenceStackEntry(uint32_t new_pc, uint32_t new_rpc,
VectorMask new_mask) : pc(new_pc), rpc(new_rpc),
execMask(new_mask) {
}
/**
* PC of current instruction.
*/
uint32_t pc;
/**
* PC of the immediate post-dominator instruction, i.e., the value of
* @a pc for the first instruction that will be executed by the wavefront
* when a reconvergence point is reached.
*/
uint32_t rpc;
/**
* Execution mask.
*/
VectorMask execMask;
};
class Wavefront : public SimObject
{
public:
enum itype_e {I_ALU,I_GLOBAL,I_SHARED,I_FLAT,I_PRIVATE};
enum status_e {S_STOPPED,S_RETURNING,S_RUNNING};
// Base pointer for array of instruction pointers
uint64_t base_ptr;
uint32_t old_barrier_cnt;
uint32_t barrier_cnt;
uint32_t barrier_id;
uint32_t barrier_slots;
status_e status;
// HW slot id where the WF is mapped to inside a SIMD unit
int wfSlotId;
int kern_id;
// SIMD unit where the WV has been scheduled
int simdId;
// pointer to parent CU
ComputeUnit *computeUnit;
std::deque<GPUDynInstPtr> instructionBuffer;
bool pendingFetch;
bool dropFetch;
// Condition Register State (for HSAIL simulations only)
class ConditionRegisterState *condRegState;
// number of single precision VGPRs required by WF
uint32_t maxSpVgprs;
// number of double precision VGPRs required by WF
uint32_t maxDpVgprs;
// map virtual to physical vector register
uint32_t remap(uint32_t vgprIndex, uint32_t size, uint8_t mode=0);
void resizeRegFiles(int num_cregs, int num_sregs, int num_dregs);
bool isGmInstruction(GPUDynInstPtr ii);
bool isLmInstruction(GPUDynInstPtr ii);
bool isOldestInstGMem();
bool isOldestInstLMem();
bool isOldestInstPrivMem();
bool isOldestInstFlatMem();
bool isOldestInstALU();
bool isOldestInstBarrier();
// used for passing spill address to DDInstGPU
std::vector<Addr> last_addr;
std::vector<uint32_t> workitemid[3];
std::vector<uint32_t> workitemFlatId;
uint32_t workgroupid[3];
uint32_t workgroupsz[3];
uint32_t gridsz[3];
uint32_t wg_id;
uint32_t wg_sz;
uint32_t dynwaveid;
uint32_t maxdynwaveid;
uint32_t dispatchid;
// outstanding global+local memory requests
uint32_t outstanding_reqs;
// memory requests between scoreboard
// and execute stage not yet executed
uint32_t mem_reqs_in_pipe;
// outstanding global memory write requests
uint32_t outstanding_reqs_wr_gm;
// outstanding local memory write requests
uint32_t outstanding_reqs_wr_lm;
// outstanding global memory read requests
uint32_t outstanding_reqs_rd_gm;
// outstanding local memory read requests
uint32_t outstanding_reqs_rd_lm;
uint32_t rd_lm_reqs_in_pipe;
uint32_t rd_gm_reqs_in_pipe;
uint32_t wr_lm_reqs_in_pipe;
uint32_t wr_gm_reqs_in_pipe;
int mem_trace_busy;
uint64_t last_trace;
// number of vector registers reserved by WF
int reservedVectorRegs;
// Index into the Vector Register File's namespace where the WF's registers
// will live while the WF is executed
uint32_t startVgprIndex;
// Old value of destination gpr (for trace)
std::vector<uint32_t> old_vgpr;
// Id of destination gpr (for trace)
uint32_t old_vgpr_id;
// Tick count of last old_vgpr copy
uint64_t old_vgpr_tcnt;
// Old value of destination gpr (for trace)
std::vector<uint64_t> old_dgpr;
// Id of destination gpr (for trace)
uint32_t old_dgpr_id;
// Tick count of last old_vgpr copy
uint64_t old_dgpr_tcnt;
// Execution mask at wavefront start
VectorMask init_mask;
// number of barriers this WF has joined
std::vector<int> bar_cnt;
int max_bar_cnt;
// Flag to stall a wave on barrier
bool stalledAtBarrier;
// a pointer to the fraction of the LDS allocated
// to this workgroup (thus this wavefront)
LdsChunk *ldsChunk;
// A pointer to the spill area
Addr spillBase;
// The size of the spill area
uint32_t spillSizePerItem;
// The vector width of the spill area
uint32_t spillWidth;
// A pointer to the private memory area
Addr privBase;
// The size of the private memory area
uint32_t privSizePerItem;
// A pointer ot the read-only memory area
Addr roBase;
// size of the read-only memory area
uint32_t roSize;
// pointer to buffer for storing kernel arguments
uint8_t *kernelArgs;
// unique WF id over all WFs executed across all CUs
uint64_t wfDynId;
// number of times instruction issue for this wavefront is blocked
// due to VRF port availability
Stats::Scalar numTimesBlockedDueVrfPortAvail;
// number of times an instruction of a WF is blocked from being issued
// due to WAR and WAW dependencies
Stats::Scalar numTimesBlockedDueWAXDependencies;
// number of times an instruction of a WF is blocked from being issued
// due to WAR and WAW dependencies
Stats::Scalar numTimesBlockedDueRAWDependencies;
// distribution of executed instructions based on their register
// operands; this is used to highlight the load on the VRF
Stats::Distribution srcRegOpDist;
Stats::Distribution dstRegOpDist;
// Functions to operate on call argument memory
// argument memory for hsail call instruction
CallArgMem *callArgMem;
void
initCallArgMem(int func_args_size_per_item, int wf_size)
{
callArgMem = new CallArgMem(func_args_size_per_item, wf_size);
}
template<typename CType>
CType
readCallArgMem(int lane, int addr)
{
return *((CType*)(callArgMem->getLaneAddr<CType>(lane, addr)));
}
template<typename CType>
void
writeCallArgMem(int lane, int addr, CType val)
{
callArgMem->setLaneAddr<CType>(lane, addr, val);
}
typedef WavefrontParams Params;
Wavefront(const Params *p);
~Wavefront();
virtual void init();
void
setParent(ComputeUnit *cu)
{
computeUnit = cu;
}
void start(uint64_t _wfDynId, uint64_t _base_ptr);
void exec();
void updateResources();
int ready(itype_e type);
bool instructionBufferHasBranch();
void regStats();
VectorMask get_pred() { return execMask() & init_mask; }
bool waitingAtBarrier(int lane);
void pushToReconvergenceStack(uint32_t pc, uint32_t rpc,
const VectorMask& exec_mask);
void popFromReconvergenceStack();
uint32_t pc() const;
uint32_t rpc() const;
VectorMask execMask() const;
bool execMask(int lane) const;
void pc(uint32_t new_pc);
void discardFetch();
private:
/**
* Stack containing Control Flow Graph nodes (i.e., kernel instructions)
* to be visited by the wavefront, and the associated execution masks. The
* reconvergence stack grows every time the wavefront reaches a divergence
* point (branch instruction), and shrinks every time the wavefront
* reaches a reconvergence point (immediate post-dominator instruction).
*/
std::stack<std::unique_ptr<ReconvergenceStackEntry>> reconvergenceStack;
};
#endif // __WAVEFRONT_HH__
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