compute_unit.cc revision 11695:0a65922d564d
1/*
2 * Copyright (c) 2011-2015 Advanced Micro Devices, Inc.
3 * All rights reserved.
4 *
5 * For use for simulation and test purposes only
6 *
7 * Redistribution and use in source and binary forms, with or without
8 * modification, are permitted provided that the following conditions are met:
9 *
10 * 1. Redistributions of source code must retain the above copyright notice,
11 * this list of conditions and the following disclaimer.
12 *
13 * 2. Redistributions in binary form must reproduce the above copyright notice,
14 * this list of conditions and the following disclaimer in the documentation
15 * and/or other materials provided with the distribution.
16 *
17 * 3. Neither the name of the copyright holder nor the names of its contributors
18 * may be used to endorse or promote products derived from this software
19 * without specific prior written permission.
20 *
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
22 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
23 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
24 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
25 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
26 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
27 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
28 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
29 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
30 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
31 * POSSIBILITY OF SUCH DAMAGE.
32 *
33 * Author: John Kalamatianos, Anthony Gutierrez
34 */
35#include "gpu-compute/compute_unit.hh"
36
37#include <limits>
38
39#include "base/output.hh"
40#include "debug/GPUDisp.hh"
41#include "debug/GPUExec.hh"
42#include "debug/GPUFetch.hh"
43#include "debug/GPUMem.hh"
44#include "debug/GPUPort.hh"
45#include "debug/GPUPrefetch.hh"
46#include "debug/GPUSync.hh"
47#include "debug/GPUTLB.hh"
48#include "gpu-compute/dispatcher.hh"
49#include "gpu-compute/gpu_dyn_inst.hh"
50#include "gpu-compute/gpu_static_inst.hh"
51#include "gpu-compute/ndrange.hh"
52#include "gpu-compute/shader.hh"
53#include "gpu-compute/simple_pool_manager.hh"
54#include "gpu-compute/vector_register_file.hh"
55#include "gpu-compute/wavefront.hh"
56#include "mem/page_table.hh"
57#include "sim/process.hh"
58
59ComputeUnit::ComputeUnit(const Params *p) : MemObject(p), fetchStage(p),
60    scoreboardCheckStage(p), scheduleStage(p), execStage(p),
61    globalMemoryPipe(p), localMemoryPipe(p), rrNextMemID(0), rrNextALUWp(0),
62    cu_id(p->cu_id), vrf(p->vector_register_file), numSIMDs(p->num_SIMDs),
63    spBypassPipeLength(p->spbypass_pipe_length),
64    dpBypassPipeLength(p->dpbypass_pipe_length),
65    issuePeriod(p->issue_period),
66    numGlbMemUnits(p->num_global_mem_pipes),
67    numLocMemUnits(p->num_shared_mem_pipes),
68    perLaneTLB(p->perLaneTLB), prefetchDepth(p->prefetch_depth),
69    prefetchStride(p->prefetch_stride), prefetchType(p->prefetch_prev_type),
70    xact_cas_mode(p->xactCasMode), debugSegFault(p->debugSegFault),
71    functionalTLB(p->functionalTLB), localMemBarrier(p->localMemBarrier),
72    countPages(p->countPages), barrier_id(0),
73    vrfToCoalescerBusWidth(p->vrf_to_coalescer_bus_width),
74    coalescerToVrfBusWidth(p->coalescer_to_vrf_bus_width),
75    req_tick_latency(p->mem_req_latency * p->clk_domain->clockPeriod()),
76    resp_tick_latency(p->mem_resp_latency * p->clk_domain->clockPeriod()),
77    _masterId(p->system->getMasterId(name() + ".ComputeUnit")),
78    lds(*p->localDataStore), globalSeqNum(0),  wavefrontSize(p->wfSize),
79    kernelLaunchInst(new KernelLaunchStaticInst())
80{
81    /**
82     * This check is necessary because std::bitset only provides conversion
83     * to unsigned long or unsigned long long via to_ulong() or to_ullong().
84     * there are * a few places in the code where to_ullong() is used, however
85     * if VSZ is larger than a value the host can support then bitset will
86     * throw a runtime exception. we should remove all use of to_long() or
87     * to_ullong() so we can have VSZ greater than 64b, however until that is
88     * done this assert is required.
89     */
90    fatal_if(p->wfSize > std::numeric_limits<unsigned long long>::digits ||
91             p->wfSize <= 0,
92             "WF size is larger than the host can support");
93    fatal_if(!isPowerOf2(wavefrontSize),
94             "Wavefront size should be a power of 2");
95    // calculate how many cycles a vector load or store will need to transfer
96    // its data over the corresponding buses
97    numCyclesPerStoreTransfer =
98        (uint32_t)ceil((double)(wfSize() * sizeof(uint32_t)) /
99                (double)vrfToCoalescerBusWidth);
100
101    numCyclesPerLoadTransfer = (wfSize() * sizeof(uint32_t))
102                               / coalescerToVrfBusWidth;
103
104    lastVaddrWF.resize(numSIMDs);
105    wfList.resize(numSIMDs);
106
107    for (int j = 0; j < numSIMDs; ++j) {
108        lastVaddrWF[j].resize(p->n_wf);
109
110        for (int i = 0; i < p->n_wf; ++i) {
111            lastVaddrWF[j][i].resize(wfSize());
112
113            wfList[j].push_back(p->wavefronts[j * p->n_wf + i]);
114            wfList[j][i]->setParent(this);
115
116            for (int k = 0; k < wfSize(); ++k) {
117                lastVaddrWF[j][i][k] = 0;
118            }
119        }
120    }
121
122    lastVaddrSimd.resize(numSIMDs);
123
124    for (int i = 0; i < numSIMDs; ++i) {
125        lastVaddrSimd[i].resize(wfSize(), 0);
126    }
127
128    lastVaddrCU.resize(wfSize());
129
130    lds.setParent(this);
131
132    if (p->execPolicy == "OLDEST-FIRST") {
133        exec_policy = EXEC_POLICY::OLDEST;
134    } else if (p->execPolicy == "ROUND-ROBIN") {
135        exec_policy = EXEC_POLICY::RR;
136    } else {
137        fatal("Invalid WF execution policy (CU)\n");
138    }
139
140    memPort.resize(wfSize());
141
142    // resize the tlbPort vectorArray
143    int tlbPort_width = perLaneTLB ? wfSize() : 1;
144    tlbPort.resize(tlbPort_width);
145
146    cuExitCallback = new CUExitCallback(this);
147    registerExitCallback(cuExitCallback);
148
149    xactCasLoadMap.clear();
150    lastExecCycle.resize(numSIMDs, 0);
151
152    for (int i = 0; i < vrf.size(); ++i) {
153        vrf[i]->setParent(this);
154    }
155
156    numVecRegsPerSimd = vrf[0]->numRegs();
157}
158
159ComputeUnit::~ComputeUnit()
160{
161    // Delete wavefront slots
162    for (int j = 0; j < numSIMDs; ++j) {
163        for (int i = 0; i < shader->n_wf; ++i) {
164            delete wfList[j][i];
165        }
166        lastVaddrSimd[j].clear();
167    }
168    lastVaddrCU.clear();
169    readyList.clear();
170    waveStatusList.clear();
171    dispatchList.clear();
172    vectorAluInstAvail.clear();
173    delete cuExitCallback;
174    delete ldsPort;
175}
176
177void
178ComputeUnit::fillKernelState(Wavefront *w, NDRange *ndr)
179{
180    w->resizeRegFiles(ndr->q.cRegCount, ndr->q.sRegCount, ndr->q.dRegCount);
181
182    w->workGroupSz[0] = ndr->q.wgSize[0];
183    w->workGroupSz[1] = ndr->q.wgSize[1];
184    w->workGroupSz[2] = ndr->q.wgSize[2];
185    w->wgSz = w->workGroupSz[0] * w->workGroupSz[1] * w->workGroupSz[2];
186    w->gridSz[0] = ndr->q.gdSize[0];
187    w->gridSz[1] = ndr->q.gdSize[1];
188    w->gridSz[2] = ndr->q.gdSize[2];
189    w->kernelArgs = ndr->q.args;
190    w->privSizePerItem = ndr->q.privMemPerItem;
191    w->spillSizePerItem = ndr->q.spillMemPerItem;
192    w->roBase = ndr->q.roMemStart;
193    w->roSize = ndr->q.roMemTotal;
194    w->computeActualWgSz(ndr);
195}
196
197void
198ComputeUnit::updateEvents() {
199
200    if (!timestampVec.empty()) {
201        uint32_t vecSize = timestampVec.size();
202        uint32_t i = 0;
203        while (i < vecSize) {
204            if (timestampVec[i] <= shader->tick_cnt) {
205                std::pair<uint32_t, uint32_t> regInfo = regIdxVec[i];
206                vrf[regInfo.first]->markReg(regInfo.second, sizeof(uint32_t),
207                                            statusVec[i]);
208                timestampVec.erase(timestampVec.begin() + i);
209                regIdxVec.erase(regIdxVec.begin() + i);
210                statusVec.erase(statusVec.begin() + i);
211                --vecSize;
212                --i;
213            }
214            ++i;
215        }
216    }
217
218    for (int i = 0; i< numSIMDs; ++i) {
219        vrf[i]->updateEvents();
220    }
221}
222
223
224void
225ComputeUnit::startWavefront(Wavefront *w, int waveId, LdsChunk *ldsChunk,
226                            NDRange *ndr)
227{
228    static int _n_wave = 0;
229
230    VectorMask init_mask;
231    init_mask.reset();
232
233    for (int k = 0; k < wfSize(); ++k) {
234        if (k + waveId * wfSize() < w->actualWgSzTotal)
235            init_mask[k] = 1;
236    }
237
238    w->kernId = ndr->dispatchId;
239    w->wfId = waveId;
240    w->initMask = init_mask.to_ullong();
241
242    for (int k = 0; k < wfSize(); ++k) {
243        w->workItemId[0][k] = (k + waveId * wfSize()) % w->actualWgSz[0];
244        w->workItemId[1][k] = ((k + waveId * wfSize()) / w->actualWgSz[0]) %
245                             w->actualWgSz[1];
246        w->workItemId[2][k] = (k + waveId * wfSize()) /
247                              (w->actualWgSz[0] * w->actualWgSz[1]);
248
249        w->workItemFlatId[k] = w->workItemId[2][k] * w->actualWgSz[0] *
250            w->actualWgSz[1] + w->workItemId[1][k] * w->actualWgSz[0] +
251            w->workItemId[0][k];
252    }
253
254    w->barrierSlots = divCeil(w->actualWgSzTotal, wfSize());
255
256    w->barCnt.resize(wfSize(), 0);
257
258    w->maxBarCnt = 0;
259    w->oldBarrierCnt = 0;
260    w->barrierCnt = 0;
261
262    w->privBase = ndr->q.privMemStart;
263    ndr->q.privMemStart += ndr->q.privMemPerItem * wfSize();
264
265    w->spillBase = ndr->q.spillMemStart;
266    ndr->q.spillMemStart += ndr->q.spillMemPerItem * wfSize();
267
268    w->pushToReconvergenceStack(0, UINT32_MAX, init_mask.to_ulong());
269
270    // WG state
271    w->wgId = ndr->globalWgId;
272    w->dispatchId = ndr->dispatchId;
273    w->workGroupId[0] = w->wgId % ndr->numWg[0];
274    w->workGroupId[1] = (w->wgId / ndr->numWg[0]) % ndr->numWg[1];
275    w->workGroupId[2] = w->wgId / (ndr->numWg[0] * ndr->numWg[1]);
276
277    w->barrierId = barrier_id;
278    w->stalledAtBarrier = false;
279
280    // set the wavefront context to have a pointer to this section of the LDS
281    w->ldsChunk = ldsChunk;
282
283    int32_t refCount M5_VAR_USED =
284                    lds.increaseRefCounter(w->dispatchId, w->wgId);
285    DPRINTF(GPUDisp, "CU%d: increase ref ctr wg[%d] to [%d]\n",
286                    cu_id, w->wgId, refCount);
287
288    w->instructionBuffer.clear();
289
290    if (w->pendingFetch)
291        w->dropFetch = true;
292
293    // is this the last wavefront in the workgroup
294    // if set the spillWidth to be the remaining work-items
295    // so that the vector access is correct
296    if ((waveId + 1) * wfSize() >= w->actualWgSzTotal) {
297        w->spillWidth = w->actualWgSzTotal - (waveId * wfSize());
298    } else {
299        w->spillWidth = wfSize();
300    }
301
302    DPRINTF(GPUDisp, "Scheduling wfDynId/barrier_id %d/%d on CU%d: "
303            "WF[%d][%d]\n", _n_wave, barrier_id, cu_id, w->simdId, w->wfSlotId);
304
305    w->start(++_n_wave, ndr->q.code_ptr);
306}
307
308void
309ComputeUnit::StartWorkgroup(NDRange *ndr)
310{
311    // reserve the LDS capacity allocated to the work group
312    // disambiguated by the dispatch ID and workgroup ID, which should be
313    // globally unique
314    LdsChunk *ldsChunk = lds.reserveSpace(ndr->dispatchId, ndr->globalWgId,
315                                          ndr->q.ldsSize);
316
317    // Send L1 cache acquire
318    // isKernel + isAcquire = Kernel Begin
319    if (shader->impl_kern_boundary_sync) {
320        GPUDynInstPtr gpuDynInst =
321            std::make_shared<GPUDynInst>(this, nullptr, kernelLaunchInst,
322                                         getAndIncSeqNum());
323
324        gpuDynInst->useContinuation = false;
325        injectGlobalMemFence(gpuDynInst, true);
326    }
327
328    // calculate the number of 32-bit vector registers required by wavefront
329    int vregDemand = ndr->q.sRegCount + (2 * ndr->q.dRegCount);
330    int wave_id = 0;
331
332    // Assign WFs by spreading them across SIMDs, 1 WF per SIMD at a time
333    for (int m = 0; m < shader->n_wf * numSIMDs; ++m) {
334        Wavefront *w = wfList[m % numSIMDs][m / numSIMDs];
335        // Check if this wavefront slot is available:
336        // It must be stopped and not waiting
337        // for a release to complete S_RETURNING
338        if (w->status == Wavefront::S_STOPPED) {
339            fillKernelState(w, ndr);
340            // if we have scheduled all work items then stop
341            // scheduling wavefronts
342            if (wave_id * wfSize() >= w->actualWgSzTotal)
343                break;
344
345            // reserve vector registers for the scheduled wavefront
346            assert(vectorRegsReserved[m % numSIMDs] <= numVecRegsPerSimd);
347            uint32_t normSize = 0;
348
349            w->startVgprIndex = vrf[m % numSIMDs]->manager->
350                                    allocateRegion(vregDemand, &normSize);
351
352            w->reservedVectorRegs = normSize;
353            vectorRegsReserved[m % numSIMDs] += w->reservedVectorRegs;
354
355            startWavefront(w, wave_id, ldsChunk, ndr);
356            ++wave_id;
357        }
358    }
359    ++barrier_id;
360}
361
362int
363ComputeUnit::ReadyWorkgroup(NDRange *ndr)
364{
365    // Get true size of workgroup (after clamping to grid size)
366    int trueWgSize[3];
367    int trueWgSizeTotal = 1;
368
369    for (int d = 0; d < 3; ++d) {
370        trueWgSize[d] = std::min(ndr->q.wgSize[d], ndr->q.gdSize[d] -
371                                 ndr->wgId[d] * ndr->q.wgSize[d]);
372
373        trueWgSizeTotal *= trueWgSize[d];
374        DPRINTF(GPUDisp, "trueWgSize[%d] =  %d\n", d, trueWgSize[d]);
375    }
376
377    DPRINTF(GPUDisp, "trueWgSizeTotal =  %d\n", trueWgSizeTotal);
378
379    // calculate the number of 32-bit vector registers required by each
380    // work item of the work group
381    int vregDemandPerWI = ndr->q.sRegCount + (2 * ndr->q.dRegCount);
382    bool vregAvail = true;
383    int numWfs = (trueWgSizeTotal + wfSize() - 1) / wfSize();
384    int freeWfSlots = 0;
385    // check if the total number of VGPRs required by all WFs of the WG
386    // fit in the VRFs of all SIMD units
387    assert((numWfs * vregDemandPerWI) <= (numSIMDs * numVecRegsPerSimd));
388    int numMappedWfs = 0;
389    std::vector<int> numWfsPerSimd;
390    numWfsPerSimd.resize(numSIMDs, 0);
391    // find how many free WF slots we have across all SIMDs
392    for (int j = 0; j < shader->n_wf; ++j) {
393        for (int i = 0; i < numSIMDs; ++i) {
394            if (wfList[i][j]->status == Wavefront::S_STOPPED) {
395                // count the number of free WF slots
396                ++freeWfSlots;
397                if (numMappedWfs < numWfs) {
398                    // count the WFs to be assigned per SIMD
399                    numWfsPerSimd[i]++;
400                }
401                numMappedWfs++;
402            }
403        }
404    }
405
406    // if there are enough free WF slots then find if there are enough
407    // free VGPRs per SIMD based on the WF->SIMD mapping
408    if (freeWfSlots >= numWfs) {
409        for (int j = 0; j < numSIMDs; ++j) {
410            // find if there are enough free VGPR regions in the SIMD's VRF
411            // to accommodate the WFs of the new WG that would be mapped to
412            // this SIMD unit
413            vregAvail = vrf[j]->manager->canAllocate(numWfsPerSimd[j],
414                                                     vregDemandPerWI);
415
416            // stop searching if there is at least one SIMD
417            // whose VRF does not have enough free VGPR pools.
418            // This is because a WG is scheduled only if ALL
419            // of its WFs can be scheduled
420            if (!vregAvail)
421                break;
422        }
423    }
424
425    DPRINTF(GPUDisp, "Free WF slots =  %d, VGPR Availability = %d\n",
426            freeWfSlots, vregAvail);
427
428    if (!vregAvail) {
429        ++numTimesWgBlockedDueVgprAlloc;
430    }
431
432    // Return true if enough WF slots to submit workgroup and if there are
433    // enough VGPRs to schedule all WFs to their SIMD units
434    if (!lds.canReserve(ndr->q.ldsSize)) {
435        wgBlockedDueLdsAllocation++;
436    }
437
438    // Return true if (a) there are enough free WF slots to submit
439    // workgrounp and (b) if there are enough VGPRs to schedule all WFs to their
440    // SIMD units and (c) if there is enough space in LDS
441    return freeWfSlots >= numWfs && vregAvail && lds.canReserve(ndr->q.ldsSize);
442}
443
444int
445ComputeUnit::AllAtBarrier(uint32_t _barrier_id, uint32_t bcnt, uint32_t bslots)
446{
447    DPRINTF(GPUSync, "CU%d: Checking for All At Barrier\n", cu_id);
448    int ccnt = 0;
449
450    for (int i_simd = 0; i_simd < numSIMDs; ++i_simd) {
451        for (int i_wf = 0; i_wf < shader->n_wf; ++i_wf) {
452            Wavefront *w = wfList[i_simd][i_wf];
453
454            if (w->status == Wavefront::S_RUNNING) {
455                DPRINTF(GPUSync, "Checking WF[%d][%d]\n", i_simd, i_wf);
456
457                DPRINTF(GPUSync, "wf->barrier_id = %d, _barrier_id = %d\n",
458                        w->barrierId, _barrier_id);
459
460                DPRINTF(GPUSync, "wf->barrier_cnt %d, bcnt = %d\n",
461                        w->barrierCnt, bcnt);
462            }
463
464            if (w->status == Wavefront::S_RUNNING &&
465                w->barrierId == _barrier_id && w->barrierCnt == bcnt &&
466                !w->outstandingReqs) {
467                ++ccnt;
468
469                DPRINTF(GPUSync, "WF[%d][%d] at barrier, increment ccnt to "
470                        "%d\n", i_simd, i_wf, ccnt);
471            }
472        }
473    }
474
475    DPRINTF(GPUSync, "CU%d: returning allAtBarrier ccnt = %d, bslots = %d\n",
476            cu_id, ccnt, bslots);
477
478    return ccnt == bslots;
479}
480
481//  Check if the current wavefront is blocked on additional resources.
482bool
483ComputeUnit::cedeSIMD(int simdId, int wfSlotId)
484{
485    bool cede = false;
486
487    // If --xact-cas-mode option is enabled in run.py, then xact_cas_ld
488    // magic instructions will impact the scheduling of wavefronts
489    if (xact_cas_mode) {
490        /*
491         * When a wavefront calls xact_cas_ld, it adds itself to a per address
492         * queue. All per address queues are managed by the xactCasLoadMap.
493         *
494         * A wavefront is not blocked if: it is not in ANY per address queue or
495         * if it is at the head of a per address queue.
496         */
497        for (auto itMap : xactCasLoadMap) {
498            std::list<waveIdentifier> curWaveIDQueue = itMap.second.waveIDQueue;
499
500            if (!curWaveIDQueue.empty()) {
501                for (auto it : curWaveIDQueue) {
502                    waveIdentifier cur_wave = it;
503
504                    if (cur_wave.simdId == simdId &&
505                        cur_wave.wfSlotId == wfSlotId) {
506                        // 2 possibilities
507                        // 1: this WF has a green light
508                        // 2: another WF has a green light
509                        waveIdentifier owner_wave = curWaveIDQueue.front();
510
511                        if (owner_wave.simdId != cur_wave.simdId ||
512                            owner_wave.wfSlotId != cur_wave.wfSlotId) {
513                            // possibility 2
514                            cede = true;
515                            break;
516                        } else {
517                            // possibility 1
518                            break;
519                        }
520                    }
521                }
522            }
523        }
524    }
525
526    return cede;
527}
528
529// Execute one clock worth of work on the ComputeUnit.
530void
531ComputeUnit::exec()
532{
533    updateEvents();
534    // Execute pipeline stages in reverse order to simulate
535    // the pipeline latency
536    globalMemoryPipe.exec();
537    localMemoryPipe.exec();
538    execStage.exec();
539    scheduleStage.exec();
540    scoreboardCheckStage.exec();
541    fetchStage.exec();
542
543    totalCycles++;
544}
545
546void
547ComputeUnit::init()
548{
549    // Initialize CU Bus models
550    glbMemToVrfBus.init(&shader->tick_cnt, shader->ticks(1));
551    locMemToVrfBus.init(&shader->tick_cnt, shader->ticks(1));
552    nextGlbMemBus = 0;
553    nextLocMemBus = 0;
554    fatal_if(numGlbMemUnits > 1,
555             "No support for multiple Global Memory Pipelines exists!!!");
556    vrfToGlobalMemPipeBus.resize(numGlbMemUnits);
557    for (int j = 0; j < numGlbMemUnits; ++j) {
558        vrfToGlobalMemPipeBus[j] = WaitClass();
559        vrfToGlobalMemPipeBus[j].init(&shader->tick_cnt, shader->ticks(1));
560    }
561
562    fatal_if(numLocMemUnits > 1,
563             "No support for multiple Local Memory Pipelines exists!!!");
564    vrfToLocalMemPipeBus.resize(numLocMemUnits);
565    for (int j = 0; j < numLocMemUnits; ++j) {
566        vrfToLocalMemPipeBus[j] = WaitClass();
567        vrfToLocalMemPipeBus[j].init(&shader->tick_cnt, shader->ticks(1));
568    }
569    vectorRegsReserved.resize(numSIMDs, 0);
570    aluPipe.resize(numSIMDs);
571    wfWait.resize(numSIMDs + numLocMemUnits + numGlbMemUnits);
572
573    for (int i = 0; i < numSIMDs + numLocMemUnits + numGlbMemUnits; ++i) {
574        wfWait[i] = WaitClass();
575        wfWait[i].init(&shader->tick_cnt, shader->ticks(1));
576    }
577
578    for (int i = 0; i < numSIMDs; ++i) {
579        aluPipe[i] = WaitClass();
580        aluPipe[i].init(&shader->tick_cnt, shader->ticks(1));
581    }
582
583    // Setup space for call args
584    for (int j = 0; j < numSIMDs; ++j) {
585        for (int i = 0; i < shader->n_wf; ++i) {
586            wfList[j][i]->initCallArgMem(shader->funcargs_size, wavefrontSize);
587        }
588    }
589
590    // Initializing pipeline resources
591    readyList.resize(numSIMDs + numGlbMemUnits + numLocMemUnits);
592    waveStatusList.resize(numSIMDs);
593
594    for (int j = 0; j < numSIMDs; ++j) {
595        for (int i = 0; i < shader->n_wf; ++i) {
596            waveStatusList[j].push_back(
597                std::make_pair(wfList[j][i], BLOCKED));
598        }
599    }
600
601    for (int j = 0; j < (numSIMDs + numGlbMemUnits + numLocMemUnits); ++j) {
602        dispatchList.push_back(std::make_pair((Wavefront*)nullptr, EMPTY));
603    }
604
605    fetchStage.init(this);
606    scoreboardCheckStage.init(this);
607    scheduleStage.init(this);
608    execStage.init(this);
609    globalMemoryPipe.init(this);
610    localMemoryPipe.init(this);
611    // initialize state for statistics calculation
612    vectorAluInstAvail.resize(numSIMDs, false);
613    shrMemInstAvail = 0;
614    glbMemInstAvail = 0;
615}
616
617bool
618ComputeUnit::DataPort::recvTimingResp(PacketPtr pkt)
619{
620    // Ruby has completed the memory op. Schedule the mem_resp_event at the
621    // appropriate cycle to process the timing memory response
622    // This delay represents the pipeline delay
623    SenderState *sender_state = safe_cast<SenderState*>(pkt->senderState);
624    int index = sender_state->port_index;
625    GPUDynInstPtr gpuDynInst = sender_state->_gpuDynInst;
626
627    // Is the packet returned a Kernel End or Barrier
628    if (pkt->req->isKernel() && pkt->req->isRelease()) {
629        Wavefront *w =
630            computeUnit->wfList[gpuDynInst->simdId][gpuDynInst->wfSlotId];
631
632        // Check if we are waiting on Kernel End Release
633        if (w->status == Wavefront::S_RETURNING) {
634            DPRINTF(GPUDisp, "CU%d: WF[%d][%d][wv=%d]: WG id completed %d\n",
635                    computeUnit->cu_id, w->simdId, w->wfSlotId,
636                    w->wfDynId, w->kernId);
637
638            computeUnit->shader->dispatcher->notifyWgCompl(w);
639            w->status = Wavefront::S_STOPPED;
640        } else {
641            w->outstandingReqs--;
642        }
643
644        DPRINTF(GPUSync, "CU%d: WF[%d][%d]: barrier_cnt = %d\n",
645                computeUnit->cu_id, gpuDynInst->simdId,
646                gpuDynInst->wfSlotId, w->barrierCnt);
647
648        if (gpuDynInst->useContinuation) {
649            assert(!gpuDynInst->isNoScope());
650            gpuDynInst->execContinuation(gpuDynInst->staticInstruction(),
651                                           gpuDynInst);
652        }
653
654        delete pkt->senderState;
655        delete pkt->req;
656        delete pkt;
657        return true;
658    } else if (pkt->req->isKernel() && pkt->req->isAcquire()) {
659        if (gpuDynInst->useContinuation) {
660            assert(!gpuDynInst->isNoScope());
661            gpuDynInst->execContinuation(gpuDynInst->staticInstruction(),
662                                           gpuDynInst);
663        }
664
665        delete pkt->senderState;
666        delete pkt->req;
667        delete pkt;
668        return true;
669    }
670
671    ComputeUnit::DataPort::MemRespEvent *mem_resp_event =
672        new ComputeUnit::DataPort::MemRespEvent(computeUnit->memPort[index],
673                                                pkt);
674
675    DPRINTF(GPUPort, "CU%d: WF[%d][%d]: index %d, addr %#x received!\n",
676            computeUnit->cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId,
677            index, pkt->req->getPaddr());
678
679    computeUnit->schedule(mem_resp_event,
680                          curTick() + computeUnit->resp_tick_latency);
681    return true;
682}
683
684void
685ComputeUnit::DataPort::recvReqRetry()
686{
687    int len = retries.size();
688
689    assert(len > 0);
690
691    for (int i = 0; i < len; ++i) {
692        PacketPtr pkt = retries.front().first;
693        GPUDynInstPtr gpuDynInst M5_VAR_USED = retries.front().second;
694        DPRINTF(GPUMem, "CU%d: WF[%d][%d]: retry mem inst addr %#x\n",
695                computeUnit->cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId,
696                pkt->req->getPaddr());
697
698        /** Currently Ruby can return false due to conflicts for the particular
699         *  cache block or address.  Thus other requests should be allowed to
700         *  pass and the data port should expect multiple retries. */
701        if (!sendTimingReq(pkt)) {
702            DPRINTF(GPUMem, "failed again!\n");
703            break;
704        } else {
705            DPRINTF(GPUMem, "successful!\n");
706            retries.pop_front();
707        }
708    }
709}
710
711bool
712ComputeUnit::SQCPort::recvTimingResp(PacketPtr pkt)
713{
714    computeUnit->fetchStage.processFetchReturn(pkt);
715
716    return true;
717}
718
719void
720ComputeUnit::SQCPort::recvReqRetry()
721{
722    int len = retries.size();
723
724    assert(len > 0);
725
726    for (int i = 0; i < len; ++i) {
727        PacketPtr pkt = retries.front().first;
728        Wavefront *wavefront M5_VAR_USED = retries.front().second;
729        DPRINTF(GPUFetch, "CU%d: WF[%d][%d]: retrying FETCH addr %#x\n",
730                computeUnit->cu_id, wavefront->simdId, wavefront->wfSlotId,
731                pkt->req->getPaddr());
732        if (!sendTimingReq(pkt)) {
733            DPRINTF(GPUFetch, "failed again!\n");
734            break;
735        } else {
736            DPRINTF(GPUFetch, "successful!\n");
737            retries.pop_front();
738        }
739    }
740}
741
742void
743ComputeUnit::sendRequest(GPUDynInstPtr gpuDynInst, int index, PacketPtr pkt)
744{
745    // There must be a way around this check to do the globalMemStart...
746    Addr tmp_vaddr = pkt->req->getVaddr();
747
748    updatePageDivergenceDist(tmp_vaddr);
749
750    pkt->req->setVirt(pkt->req->getAsid(), tmp_vaddr, pkt->req->getSize(),
751                      pkt->req->getFlags(), pkt->req->masterId(),
752                      pkt->req->getPC());
753
754    // figure out the type of the request to set read/write
755    BaseTLB::Mode TLB_mode;
756    assert(pkt->isRead() || pkt->isWrite());
757
758    // Check write before read for atomic operations
759    // since atomic operations should use BaseTLB::Write
760    if (pkt->isWrite()){
761        TLB_mode = BaseTLB::Write;
762    } else if (pkt->isRead()) {
763        TLB_mode = BaseTLB::Read;
764    } else {
765        fatal("pkt is not a read nor a write\n");
766    }
767
768    tlbCycles -= curTick();
769    ++tlbRequests;
770
771    int tlbPort_index = perLaneTLB ? index : 0;
772
773    if (shader->timingSim) {
774        if (debugSegFault) {
775            Process *p = shader->gpuTc->getProcessPtr();
776            Addr vaddr = pkt->req->getVaddr();
777            unsigned size = pkt->getSize();
778
779            if ((vaddr + size - 1) % 64 < vaddr % 64) {
780                panic("CU%d: WF[%d][%d]: Access to addr %#x is unaligned!\n",
781                      cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId, vaddr);
782            }
783
784            Addr paddr;
785
786            if (!p->pTable->translate(vaddr, paddr)) {
787                if (!p->fixupStackFault(vaddr)) {
788                    panic("CU%d: WF[%d][%d]: Fault on addr %#x!\n",
789                          cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId,
790                          vaddr);
791                }
792            }
793        }
794
795        // This is the SenderState needed upon return
796        pkt->senderState = new DTLBPort::SenderState(gpuDynInst, index);
797
798        // This is the senderState needed by the TLB hierarchy to function
799        TheISA::GpuTLB::TranslationState *translation_state =
800          new TheISA::GpuTLB::TranslationState(TLB_mode, shader->gpuTc, false,
801                                               pkt->senderState);
802
803        pkt->senderState = translation_state;
804
805        if (functionalTLB) {
806            tlbPort[tlbPort_index]->sendFunctional(pkt);
807
808            // update the hitLevel distribution
809            int hit_level = translation_state->hitLevel;
810            assert(hit_level != -1);
811            hitsPerTLBLevel[hit_level]++;
812
813            // New SenderState for the memory access
814            X86ISA::GpuTLB::TranslationState *sender_state =
815                safe_cast<X86ISA::GpuTLB::TranslationState*>(pkt->senderState);
816
817            delete sender_state->tlbEntry;
818            delete sender_state->saved;
819            delete sender_state;
820
821            assert(pkt->req->hasPaddr());
822            assert(pkt->req->hasSize());
823
824            uint8_t *tmpData = pkt->getPtr<uint8_t>();
825
826            // this is necessary because the GPU TLB receives packets instead
827            // of requests. when the translation is complete, all relevent
828            // fields in the request will be populated, but not in the packet.
829            // here we create the new packet so we can set the size, addr,
830            // and proper flags.
831            PacketPtr oldPkt = pkt;
832            pkt = new Packet(oldPkt->req, oldPkt->cmd);
833            delete oldPkt;
834            pkt->dataStatic(tmpData);
835
836
837            // New SenderState for the memory access
838            pkt->senderState = new ComputeUnit::DataPort::SenderState(gpuDynInst,
839                                                             index, nullptr);
840
841            gpuDynInst->memStatusVector[pkt->getAddr()].push_back(index);
842            gpuDynInst->tlbHitLevel[index] = hit_level;
843
844
845            // translation is done. Schedule the mem_req_event at the
846            // appropriate cycle to send the timing memory request to ruby
847            ComputeUnit::DataPort::MemReqEvent *mem_req_event =
848                new ComputeUnit::DataPort::MemReqEvent(memPort[index], pkt);
849
850            DPRINTF(GPUPort, "CU%d: WF[%d][%d]: index %d, addr %#x data "
851                    "scheduled\n", cu_id, gpuDynInst->simdId,
852                    gpuDynInst->wfSlotId, index, pkt->req->getPaddr());
853
854            schedule(mem_req_event, curTick() + req_tick_latency);
855        } else if (tlbPort[tlbPort_index]->isStalled()) {
856            assert(tlbPort[tlbPort_index]->retries.size() > 0);
857
858            DPRINTF(GPUTLB, "CU%d: WF[%d][%d]: Translation for addr %#x "
859                    "failed!\n", cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId,
860                    tmp_vaddr);
861
862            tlbPort[tlbPort_index]->retries.push_back(pkt);
863        } else if (!tlbPort[tlbPort_index]->sendTimingReq(pkt)) {
864            // Stall the data port;
865            // No more packet will be issued till
866            // ruby indicates resources are freed by
867            // a recvReqRetry() call back on this port.
868            tlbPort[tlbPort_index]->stallPort();
869
870            DPRINTF(GPUTLB, "CU%d: WF[%d][%d]: Translation for addr %#x "
871                    "failed!\n", cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId,
872                    tmp_vaddr);
873
874            tlbPort[tlbPort_index]->retries.push_back(pkt);
875        } else {
876           DPRINTF(GPUTLB,
877                   "CU%d: WF[%d][%d]: Translation for addr %#x sent!\n",
878                   cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId, tmp_vaddr);
879        }
880    } else {
881        if (pkt->cmd == MemCmd::MemFenceReq) {
882            gpuDynInst->statusBitVector = VectorMask(0);
883        } else {
884            gpuDynInst->statusBitVector &= (~(1ll << index));
885        }
886
887        // New SenderState for the memory access
888        delete pkt->senderState;
889
890        // Because it's atomic operation, only need TLB translation state
891        pkt->senderState = new TheISA::GpuTLB::TranslationState(TLB_mode,
892                                                                shader->gpuTc);
893
894        tlbPort[tlbPort_index]->sendFunctional(pkt);
895
896        // the addr of the packet is not modified, so we need to create a new
897        // packet, or otherwise the memory access will have the old virtual
898        // address sent in the translation packet, instead of the physical
899        // address returned by the translation.
900        PacketPtr new_pkt = new Packet(pkt->req, pkt->cmd);
901        new_pkt->dataStatic(pkt->getPtr<uint8_t>());
902
903        // Translation is done. It is safe to send the packet to memory.
904        memPort[0]->sendFunctional(new_pkt);
905
906        DPRINTF(GPUMem, "CU%d: WF[%d][%d]: index %d: addr %#x\n", cu_id,
907                gpuDynInst->simdId, gpuDynInst->wfSlotId, index,
908                new_pkt->req->getPaddr());
909
910        // safe_cast the senderState
911        TheISA::GpuTLB::TranslationState *sender_state =
912             safe_cast<TheISA::GpuTLB::TranslationState*>(pkt->senderState);
913
914        delete sender_state->tlbEntry;
915        delete new_pkt;
916        delete pkt->senderState;
917        delete pkt->req;
918        delete pkt;
919    }
920}
921
922void
923ComputeUnit::sendSyncRequest(GPUDynInstPtr gpuDynInst, int index, PacketPtr pkt)
924{
925    ComputeUnit::DataPort::MemReqEvent *mem_req_event =
926        new ComputeUnit::DataPort::MemReqEvent(memPort[index], pkt);
927
928
929    // New SenderState for the memory access
930    pkt->senderState = new ComputeUnit::DataPort::SenderState(gpuDynInst, index,
931                                                              nullptr);
932
933    DPRINTF(GPUPort, "CU%d: WF[%d][%d]: index %d, addr %#x sync scheduled\n",
934            cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId, index,
935            pkt->req->getPaddr());
936
937    schedule(mem_req_event, curTick() + req_tick_latency);
938}
939
940void
941ComputeUnit::injectGlobalMemFence(GPUDynInstPtr gpuDynInst, bool kernelLaunch,
942                                  Request* req)
943{
944    assert(gpuDynInst->isGlobalSeg());
945
946    if (!req) {
947        req = new Request(0, 0, 0, 0, masterId(), 0, gpuDynInst->wfDynId);
948    }
949    req->setPaddr(0);
950    if (kernelLaunch) {
951        req->setFlags(Request::KERNEL);
952    }
953
954    // for non-kernel MemFence operations, memorder flags are set depending
955    // on which type of request is currently being sent, so this
956    // should be set by the caller (e.g. if an inst has acq-rel
957    // semantics, it will send one acquire req an one release req)
958    gpuDynInst->setRequestFlags(req, kernelLaunch);
959
960    // a mem fence must correspond to an acquire/release request
961    assert(req->isAcquire() || req->isRelease());
962
963    // create packet
964    PacketPtr pkt = new Packet(req, MemCmd::MemFenceReq);
965
966    // set packet's sender state
967    pkt->senderState =
968        new ComputeUnit::DataPort::SenderState(gpuDynInst, 0, nullptr);
969
970    // send the packet
971    sendSyncRequest(gpuDynInst, 0, pkt);
972}
973
974const char*
975ComputeUnit::DataPort::MemRespEvent::description() const
976{
977    return "ComputeUnit memory response event";
978}
979
980void
981ComputeUnit::DataPort::MemRespEvent::process()
982{
983    DataPort::SenderState *sender_state =
984        safe_cast<DataPort::SenderState*>(pkt->senderState);
985
986    GPUDynInstPtr gpuDynInst = sender_state->_gpuDynInst;
987    ComputeUnit *compute_unit = dataPort->computeUnit;
988
989    assert(gpuDynInst);
990
991    DPRINTF(GPUPort, "CU%d: WF[%d][%d]: Response for addr %#x, index %d\n",
992            compute_unit->cu_id, gpuDynInst->simdId, gpuDynInst->wfSlotId,
993            pkt->req->getPaddr(), dataPort->index);
994
995    Addr paddr = pkt->req->getPaddr();
996
997    if (pkt->cmd != MemCmd::MemFenceResp) {
998        int index = gpuDynInst->memStatusVector[paddr].back();
999
1000        DPRINTF(GPUMem, "Response for addr %#x, index %d\n",
1001                pkt->req->getPaddr(), index);
1002
1003        gpuDynInst->memStatusVector[paddr].pop_back();
1004        gpuDynInst->pAddr = pkt->req->getPaddr();
1005
1006        if (pkt->isRead() || pkt->isWrite()) {
1007
1008            if (gpuDynInst->n_reg <= MAX_REGS_FOR_NON_VEC_MEM_INST) {
1009                gpuDynInst->statusBitVector &= (~(1ULL << index));
1010            } else {
1011                assert(gpuDynInst->statusVector[index] > 0);
1012                gpuDynInst->statusVector[index]--;
1013
1014                if (!gpuDynInst->statusVector[index])
1015                    gpuDynInst->statusBitVector &= (~(1ULL << index));
1016            }
1017
1018            DPRINTF(GPUMem, "bitvector is now %#x\n",
1019                    gpuDynInst->statusBitVector);
1020
1021            if (gpuDynInst->statusBitVector == VectorMask(0)) {
1022                auto iter = gpuDynInst->memStatusVector.begin();
1023                auto end = gpuDynInst->memStatusVector.end();
1024
1025                while (iter != end) {
1026                    assert(iter->second.empty());
1027                    ++iter;
1028                }
1029
1030                gpuDynInst->memStatusVector.clear();
1031
1032                if (gpuDynInst->n_reg > MAX_REGS_FOR_NON_VEC_MEM_INST)
1033                    gpuDynInst->statusVector.clear();
1034
1035                if (gpuDynInst->isLoad() || gpuDynInst->isAtomic()) {
1036                    assert(compute_unit->globalMemoryPipe.isGMLdRespFIFOWrRdy());
1037
1038                    compute_unit->globalMemoryPipe.getGMLdRespFIFO()
1039                        .push(gpuDynInst);
1040                } else {
1041                    assert(compute_unit->globalMemoryPipe.isGMStRespFIFOWrRdy());
1042
1043                    compute_unit->globalMemoryPipe.getGMStRespFIFO()
1044                        .push(gpuDynInst);
1045                }
1046
1047                DPRINTF(GPUMem, "CU%d: WF[%d][%d]: packet totally complete\n",
1048                        compute_unit->cu_id, gpuDynInst->simdId,
1049                        gpuDynInst->wfSlotId);
1050
1051                // after clearing the status vectors,
1052                // see if there is a continuation to perform
1053                // the continuation may generate more work for
1054                // this memory request
1055                if (gpuDynInst->useContinuation) {
1056                    assert(!gpuDynInst->isNoScope());
1057                    gpuDynInst->execContinuation(gpuDynInst->staticInstruction(),
1058                                                 gpuDynInst);
1059                }
1060            }
1061        }
1062    } else {
1063        gpuDynInst->statusBitVector = VectorMask(0);
1064
1065        if (gpuDynInst->useContinuation) {
1066            assert(!gpuDynInst->isNoScope());
1067            gpuDynInst->execContinuation(gpuDynInst->staticInstruction(),
1068                                         gpuDynInst);
1069        }
1070    }
1071
1072    delete pkt->senderState;
1073    delete pkt->req;
1074    delete pkt;
1075}
1076
1077ComputeUnit*
1078ComputeUnitParams::create()
1079{
1080    return new ComputeUnit(this);
1081}
1082
1083bool
1084ComputeUnit::DTLBPort::recvTimingResp(PacketPtr pkt)
1085{
1086    Addr line = pkt->req->getPaddr();
1087
1088    DPRINTF(GPUTLB, "CU%d: DTLBPort received %#x->%#x\n", computeUnit->cu_id,
1089            pkt->req->getVaddr(), line);
1090
1091    assert(pkt->senderState);
1092    computeUnit->tlbCycles += curTick();
1093
1094    // pop off the TLB translation state
1095    TheISA::GpuTLB::TranslationState *translation_state =
1096               safe_cast<TheISA::GpuTLB::TranslationState*>(pkt->senderState);
1097
1098    // no PageFaults are permitted for data accesses
1099    if (!translation_state->tlbEntry->valid) {
1100        DTLBPort::SenderState *sender_state =
1101            safe_cast<DTLBPort::SenderState*>(translation_state->saved);
1102
1103        Wavefront *w M5_VAR_USED =
1104            computeUnit->wfList[sender_state->_gpuDynInst->simdId]
1105            [sender_state->_gpuDynInst->wfSlotId];
1106
1107        DPRINTFN("Wave %d couldn't tranlate vaddr %#x\n", w->wfDynId,
1108                 pkt->req->getVaddr());
1109    }
1110
1111    assert(translation_state->tlbEntry->valid);
1112
1113    // update the hitLevel distribution
1114    int hit_level = translation_state->hitLevel;
1115    computeUnit->hitsPerTLBLevel[hit_level]++;
1116
1117    delete translation_state->tlbEntry;
1118    assert(!translation_state->ports.size());
1119    pkt->senderState = translation_state->saved;
1120
1121    // for prefetch pkt
1122    BaseTLB::Mode TLB_mode = translation_state->tlbMode;
1123
1124    delete translation_state;
1125
1126    // use the original sender state to know how to close this transaction
1127    DTLBPort::SenderState *sender_state =
1128        safe_cast<DTLBPort::SenderState*>(pkt->senderState);
1129
1130    GPUDynInstPtr gpuDynInst = sender_state->_gpuDynInst;
1131    int mp_index = sender_state->portIndex;
1132    Addr vaddr = pkt->req->getVaddr();
1133    gpuDynInst->memStatusVector[line].push_back(mp_index);
1134    gpuDynInst->tlbHitLevel[mp_index] = hit_level;
1135
1136    MemCmd requestCmd;
1137
1138    if (pkt->cmd == MemCmd::ReadResp) {
1139        requestCmd = MemCmd::ReadReq;
1140    } else if (pkt->cmd == MemCmd::WriteResp) {
1141        requestCmd = MemCmd::WriteReq;
1142    } else if (pkt->cmd == MemCmd::SwapResp) {
1143        requestCmd = MemCmd::SwapReq;
1144    } else {
1145        panic("unsupported response to request conversion %s\n",
1146              pkt->cmd.toString());
1147    }
1148
1149    if (computeUnit->prefetchDepth) {
1150        int simdId = gpuDynInst->simdId;
1151        int wfSlotId = gpuDynInst->wfSlotId;
1152        Addr last = 0;
1153
1154        switch(computeUnit->prefetchType) {
1155        case Enums::PF_CU:
1156            last = computeUnit->lastVaddrCU[mp_index];
1157            break;
1158        case Enums::PF_PHASE:
1159            last = computeUnit->lastVaddrSimd[simdId][mp_index];
1160            break;
1161        case Enums::PF_WF:
1162            last = computeUnit->lastVaddrWF[simdId][wfSlotId][mp_index];
1163        default:
1164            break;
1165        }
1166
1167        DPRINTF(GPUPrefetch, "CU[%d][%d][%d][%d]: %#x was last\n",
1168                computeUnit->cu_id, simdId, wfSlotId, mp_index, last);
1169
1170        int stride = last ? (roundDown(vaddr, TheISA::PageBytes) -
1171                     roundDown(last, TheISA::PageBytes)) >> TheISA::PageShift
1172                     : 0;
1173
1174        DPRINTF(GPUPrefetch, "Stride is %d\n", stride);
1175
1176        computeUnit->lastVaddrCU[mp_index] = vaddr;
1177        computeUnit->lastVaddrSimd[simdId][mp_index] = vaddr;
1178        computeUnit->lastVaddrWF[simdId][wfSlotId][mp_index] = vaddr;
1179
1180        stride = (computeUnit->prefetchType == Enums::PF_STRIDE) ?
1181            computeUnit->prefetchStride: stride;
1182
1183        DPRINTF(GPUPrefetch, "%#x to: CU[%d][%d][%d][%d]\n", vaddr,
1184                computeUnit->cu_id, simdId, wfSlotId, mp_index);
1185
1186        DPRINTF(GPUPrefetch, "Prefetching from %#x:", vaddr);
1187
1188        // Prefetch Next few pages atomically
1189        for (int pf = 1; pf <= computeUnit->prefetchDepth; ++pf) {
1190            DPRINTF(GPUPrefetch, "%d * %d: %#x\n", pf, stride,
1191                    vaddr+stride*pf*TheISA::PageBytes);
1192
1193            if (!stride)
1194                break;
1195
1196            Request *prefetch_req = new Request(0, vaddr + stride * pf *
1197                                                TheISA::PageBytes,
1198                                                sizeof(uint8_t), 0,
1199                                                computeUnit->masterId(),
1200                                                0, 0, 0);
1201
1202            PacketPtr prefetch_pkt = new Packet(prefetch_req, requestCmd);
1203            uint8_t foo = 0;
1204            prefetch_pkt->dataStatic(&foo);
1205
1206            // Because it's atomic operation, only need TLB translation state
1207            prefetch_pkt->senderState =
1208                new TheISA::GpuTLB::TranslationState(TLB_mode,
1209                                                     computeUnit->shader->gpuTc,
1210                                                     true);
1211
1212            // Currently prefetches are zero-latency, hence the sendFunctional
1213            sendFunctional(prefetch_pkt);
1214
1215            /* safe_cast the senderState */
1216            TheISA::GpuTLB::TranslationState *tlb_state =
1217                 safe_cast<TheISA::GpuTLB::TranslationState*>(
1218                         prefetch_pkt->senderState);
1219
1220
1221            delete tlb_state->tlbEntry;
1222            delete tlb_state;
1223            delete prefetch_pkt->req;
1224            delete prefetch_pkt;
1225        }
1226    }
1227
1228    // First we must convert the response cmd back to a request cmd so that
1229    // the request can be sent through the cu's master port
1230    PacketPtr new_pkt = new Packet(pkt->req, requestCmd);
1231    new_pkt->dataStatic(pkt->getPtr<uint8_t>());
1232    delete pkt->senderState;
1233    delete pkt;
1234
1235    // New SenderState for the memory access
1236    new_pkt->senderState =
1237            new ComputeUnit::DataPort::SenderState(gpuDynInst, mp_index,
1238                                                   nullptr);
1239
1240    // translation is done. Schedule the mem_req_event at the appropriate
1241    // cycle to send the timing memory request to ruby
1242    ComputeUnit::DataPort::MemReqEvent *mem_req_event =
1243        new ComputeUnit::DataPort::MemReqEvent(computeUnit->memPort[mp_index],
1244                                               new_pkt);
1245
1246    DPRINTF(GPUPort, "CU%d: WF[%d][%d]: index %d, addr %#x data scheduled\n",
1247            computeUnit->cu_id, gpuDynInst->simdId,
1248            gpuDynInst->wfSlotId, mp_index, new_pkt->req->getPaddr());
1249
1250    computeUnit->schedule(mem_req_event, curTick() +
1251                          computeUnit->req_tick_latency);
1252
1253    return true;
1254}
1255
1256const char*
1257ComputeUnit::DataPort::MemReqEvent::description() const
1258{
1259    return "ComputeUnit memory request event";
1260}
1261
1262void
1263ComputeUnit::DataPort::MemReqEvent::process()
1264{
1265    SenderState *sender_state = safe_cast<SenderState*>(pkt->senderState);
1266    GPUDynInstPtr gpuDynInst = sender_state->_gpuDynInst;
1267    ComputeUnit *compute_unit M5_VAR_USED = dataPort->computeUnit;
1268
1269    if (!(dataPort->sendTimingReq(pkt))) {
1270        dataPort->retries.push_back(std::make_pair(pkt, gpuDynInst));
1271
1272        DPRINTF(GPUPort,
1273                "CU%d: WF[%d][%d]: index %d, addr %#x data req failed!\n",
1274                compute_unit->cu_id, gpuDynInst->simdId,
1275                gpuDynInst->wfSlotId, dataPort->index,
1276                pkt->req->getPaddr());
1277    } else {
1278        DPRINTF(GPUPort,
1279                "CU%d: WF[%d][%d]: index %d, addr %#x data req sent!\n",
1280                compute_unit->cu_id, gpuDynInst->simdId,
1281                gpuDynInst->wfSlotId, dataPort->index,
1282                pkt->req->getPaddr());
1283    }
1284}
1285
1286/*
1287 * The initial translation request could have been rejected,
1288 * if <retries> queue is not Retry sending the translation
1289 * request. sendRetry() is called from the peer port whenever
1290 * a translation completes.
1291 */
1292void
1293ComputeUnit::DTLBPort::recvReqRetry()
1294{
1295    int len = retries.size();
1296
1297    DPRINTF(GPUTLB, "CU%d: DTLB recvReqRetry - %d pending requests\n",
1298            computeUnit->cu_id, len);
1299
1300    assert(len > 0);
1301    assert(isStalled());
1302    // recvReqRetry is an indication that the resource on which this
1303    // port was stalling on is freed. So, remove the stall first
1304    unstallPort();
1305
1306    for (int i = 0; i < len; ++i) {
1307        PacketPtr pkt = retries.front();
1308        Addr vaddr M5_VAR_USED = pkt->req->getVaddr();
1309        DPRINTF(GPUTLB, "CU%d: retrying D-translaton for address%#x", vaddr);
1310
1311        if (!sendTimingReq(pkt)) {
1312            // Stall port
1313            stallPort();
1314            DPRINTF(GPUTLB, ": failed again\n");
1315            break;
1316        } else {
1317            DPRINTF(GPUTLB, ": successful\n");
1318            retries.pop_front();
1319        }
1320    }
1321}
1322
1323bool
1324ComputeUnit::ITLBPort::recvTimingResp(PacketPtr pkt)
1325{
1326    Addr line M5_VAR_USED = pkt->req->getPaddr();
1327    DPRINTF(GPUTLB, "CU%d: ITLBPort received %#x->%#x\n",
1328            computeUnit->cu_id, pkt->req->getVaddr(), line);
1329
1330    assert(pkt->senderState);
1331
1332    // pop off the TLB translation state
1333    TheISA::GpuTLB::TranslationState *translation_state =
1334                 safe_cast<TheISA::GpuTLB::TranslationState*>(pkt->senderState);
1335
1336    bool success = translation_state->tlbEntry->valid;
1337    delete translation_state->tlbEntry;
1338    assert(!translation_state->ports.size());
1339    pkt->senderState = translation_state->saved;
1340    delete translation_state;
1341
1342    // use the original sender state to know how to close this transaction
1343    ITLBPort::SenderState *sender_state =
1344        safe_cast<ITLBPort::SenderState*>(pkt->senderState);
1345
1346    // get the wavefront associated with this translation request
1347    Wavefront *wavefront = sender_state->wavefront;
1348    delete pkt->senderState;
1349
1350    if (success) {
1351        // pkt is reused in fetch(), don't delete it here.  However, we must
1352        // reset the command to be a request so that it can be sent through
1353        // the cu's master port
1354        assert(pkt->cmd == MemCmd::ReadResp);
1355        pkt->cmd = MemCmd::ReadReq;
1356
1357        computeUnit->fetchStage.fetch(pkt, wavefront);
1358    } else {
1359        if (wavefront->dropFetch) {
1360            assert(wavefront->instructionBuffer.empty());
1361            wavefront->dropFetch = false;
1362        }
1363
1364        wavefront->pendingFetch = 0;
1365    }
1366
1367    return true;
1368}
1369
1370/*
1371 * The initial translation request could have been rejected, if
1372 * <retries> queue is not empty. Retry sending the translation
1373 * request. sendRetry() is called from the peer port whenever
1374 * a translation completes.
1375 */
1376void
1377ComputeUnit::ITLBPort::recvReqRetry()
1378{
1379
1380    int len = retries.size();
1381    DPRINTF(GPUTLB, "CU%d: ITLB recvReqRetry - %d pending requests\n", len);
1382
1383    assert(len > 0);
1384    assert(isStalled());
1385
1386    // recvReqRetry is an indication that the resource on which this
1387    // port was stalling on is freed. So, remove the stall first
1388    unstallPort();
1389
1390    for (int i = 0; i < len; ++i) {
1391        PacketPtr pkt = retries.front();
1392        Addr vaddr M5_VAR_USED = pkt->req->getVaddr();
1393        DPRINTF(GPUTLB, "CU%d: retrying I-translaton for address%#x", vaddr);
1394
1395        if (!sendTimingReq(pkt)) {
1396            stallPort(); // Stall port
1397            DPRINTF(GPUTLB, ": failed again\n");
1398            break;
1399        } else {
1400            DPRINTF(GPUTLB, ": successful\n");
1401            retries.pop_front();
1402        }
1403    }
1404}
1405
1406void
1407ComputeUnit::regStats()
1408{
1409    MemObject::regStats();
1410
1411    vALUInsts
1412        .name(name() + ".valu_insts")
1413        .desc("Number of vector ALU insts issued.")
1414        ;
1415    vALUInstsPerWF
1416        .name(name() + ".valu_insts_per_wf")
1417        .desc("The avg. number of vector ALU insts issued per-wavefront.")
1418        ;
1419    sALUInsts
1420        .name(name() + ".salu_insts")
1421        .desc("Number of scalar ALU insts issued.")
1422        ;
1423    sALUInstsPerWF
1424        .name(name() + ".salu_insts_per_wf")
1425        .desc("The avg. number of scalar ALU insts issued per-wavefront.")
1426        ;
1427    instCyclesVALU
1428        .name(name() + ".inst_cycles_valu")
1429        .desc("Number of cycles needed to execute VALU insts.")
1430        ;
1431    instCyclesSALU
1432        .name(name() + ".inst_cycles_salu")
1433        .desc("Number of cycles needed to execute SALU insts.")
1434        ;
1435    threadCyclesVALU
1436        .name(name() + ".thread_cycles_valu")
1437        .desc("Number of thread cycles used to execute vector ALU ops. "
1438              "Similar to instCyclesVALU but multiplied by the number of "
1439              "active threads.")
1440        ;
1441    vALUUtilization
1442        .name(name() + ".valu_utilization")
1443        .desc("Percentage of active vector ALU threads in a wave.")
1444        ;
1445    ldsNoFlatInsts
1446        .name(name() + ".lds_no_flat_insts")
1447        .desc("Number of LDS insts issued, not including FLAT "
1448              "accesses that resolve to LDS.")
1449        ;
1450    ldsNoFlatInstsPerWF
1451        .name(name() + ".lds_no_flat_insts_per_wf")
1452        .desc("The avg. number of LDS insts (not including FLAT "
1453              "accesses that resolve to LDS) per-wavefront.")
1454        ;
1455    flatVMemInsts
1456        .name(name() + ".flat_vmem_insts")
1457        .desc("The number of FLAT insts that resolve to vmem issued.")
1458        ;
1459    flatVMemInstsPerWF
1460        .name(name() + ".flat_vmem_insts_per_wf")
1461        .desc("The average number of FLAT insts that resolve to vmem "
1462              "issued per-wavefront.")
1463        ;
1464    flatLDSInsts
1465        .name(name() + ".flat_lds_insts")
1466        .desc("The number of FLAT insts that resolve to LDS issued.")
1467        ;
1468    flatLDSInstsPerWF
1469        .name(name() + ".flat_lds_insts_per_wf")
1470        .desc("The average number of FLAT insts that resolve to LDS "
1471              "issued per-wavefront.")
1472        ;
1473    vectorMemWrites
1474        .name(name() + ".vector_mem_writes")
1475        .desc("Number of vector mem write insts (excluding FLAT insts).")
1476        ;
1477    vectorMemWritesPerWF
1478        .name(name() + ".vector_mem_writes_per_wf")
1479        .desc("The average number of vector mem write insts "
1480              "(excluding FLAT insts) per-wavefront.")
1481        ;
1482    vectorMemReads
1483        .name(name() + ".vector_mem_reads")
1484        .desc("Number of vector mem read insts (excluding FLAT insts).")
1485        ;
1486    vectorMemReadsPerWF
1487        .name(name() + ".vector_mem_reads_per_wf")
1488        .desc("The avg. number of vector mem read insts (excluding "
1489              "FLAT insts) per-wavefront.")
1490        ;
1491    scalarMemWrites
1492        .name(name() + ".scalar_mem_writes")
1493        .desc("Number of scalar mem write insts.")
1494        ;
1495    scalarMemWritesPerWF
1496        .name(name() + ".scalar_mem_writes_per_wf")
1497        .desc("The average number of scalar mem write insts per-wavefront.")
1498        ;
1499    scalarMemReads
1500        .name(name() + ".scalar_mem_reads")
1501        .desc("Number of scalar mem read insts.")
1502        ;
1503    scalarMemReadsPerWF
1504        .name(name() + ".scalar_mem_reads_per_wf")
1505        .desc("The average number of scalar mem read insts per-wavefront.")
1506        ;
1507
1508    vALUInstsPerWF = vALUInsts / completedWfs;
1509    sALUInstsPerWF = sALUInsts / completedWfs;
1510    vALUUtilization = (threadCyclesVALU / (64 * instCyclesVALU)) * 100;
1511    ldsNoFlatInstsPerWF = ldsNoFlatInsts / completedWfs;
1512    flatVMemInstsPerWF = flatVMemInsts / completedWfs;
1513    flatLDSInstsPerWF = flatLDSInsts / completedWfs;
1514    vectorMemWritesPerWF = vectorMemWrites / completedWfs;
1515    vectorMemReadsPerWF = vectorMemReads / completedWfs;
1516    scalarMemWritesPerWF = scalarMemWrites / completedWfs;
1517    scalarMemReadsPerWF = scalarMemReads / completedWfs;
1518
1519    tlbCycles
1520        .name(name() + ".tlb_cycles")
1521        .desc("total number of cycles for all uncoalesced requests")
1522        ;
1523
1524    tlbRequests
1525        .name(name() + ".tlb_requests")
1526        .desc("number of uncoalesced requests")
1527        ;
1528
1529    tlbLatency
1530        .name(name() + ".avg_translation_latency")
1531        .desc("Avg. translation latency for data translations")
1532        ;
1533
1534    tlbLatency = tlbCycles / tlbRequests;
1535
1536    hitsPerTLBLevel
1537       .init(4)
1538       .name(name() + ".TLB_hits_distribution")
1539       .desc("TLB hits distribution (0 for page table, x for Lx-TLB")
1540       ;
1541
1542    // fixed number of TLB levels
1543    for (int i = 0; i < 4; ++i) {
1544        if (!i)
1545            hitsPerTLBLevel.subname(i,"page_table");
1546        else
1547            hitsPerTLBLevel.subname(i, csprintf("L%d_TLB",i));
1548    }
1549
1550    execRateDist
1551        .init(0, 10, 2)
1552        .name(name() + ".inst_exec_rate")
1553        .desc("Instruction Execution Rate: Number of executed vector "
1554              "instructions per cycle")
1555        ;
1556
1557    ldsBankConflictDist
1558       .init(0, wfSize(), 2)
1559       .name(name() + ".lds_bank_conflicts")
1560       .desc("Number of bank conflicts per LDS memory packet")
1561       ;
1562
1563    ldsBankAccesses
1564        .name(name() + ".lds_bank_access_cnt")
1565        .desc("Total number of LDS bank accesses")
1566        ;
1567
1568    pageDivergenceDist
1569        // A wavefront can touch up to N pages per memory instruction where
1570        // N is equal to the wavefront size
1571        // The number of pages per bin can be configured (here it's 4).
1572       .init(1, wfSize(), 4)
1573       .name(name() + ".page_divergence_dist")
1574       .desc("pages touched per wf (over all mem. instr.)")
1575       ;
1576
1577    controlFlowDivergenceDist
1578        .init(1, wfSize(), 4)
1579        .name(name() + ".warp_execution_dist")
1580        .desc("number of lanes active per instruction (oval all instructions)")
1581        ;
1582
1583    activeLanesPerGMemInstrDist
1584        .init(1, wfSize(), 4)
1585        .name(name() + ".gmem_lanes_execution_dist")
1586        .desc("number of active lanes per global memory instruction")
1587        ;
1588
1589    activeLanesPerLMemInstrDist
1590        .init(1, wfSize(), 4)
1591        .name(name() + ".lmem_lanes_execution_dist")
1592        .desc("number of active lanes per local memory instruction")
1593        ;
1594
1595    numInstrExecuted
1596        .name(name() + ".num_instr_executed")
1597        .desc("number of instructions executed")
1598        ;
1599
1600    numVecOpsExecuted
1601        .name(name() + ".num_vec_ops_executed")
1602        .desc("number of vec ops executed (e.g. WF size/inst)")
1603        ;
1604
1605    totalCycles
1606        .name(name() + ".num_total_cycles")
1607        .desc("number of cycles the CU ran for")
1608        ;
1609
1610    ipc
1611        .name(name() + ".ipc")
1612        .desc("Instructions per cycle (this CU only)")
1613        ;
1614
1615    vpc
1616        .name(name() + ".vpc")
1617        .desc("Vector Operations per cycle (this CU only)")
1618        ;
1619
1620    numALUInstsExecuted
1621        .name(name() + ".num_alu_insts_executed")
1622        .desc("Number of dynamic non-GM memory insts executed")
1623        ;
1624
1625    wgBlockedDueLdsAllocation
1626        .name(name() + ".wg_blocked_due_lds_alloc")
1627        .desc("Workgroup blocked due to LDS capacity")
1628        ;
1629
1630    ipc = numInstrExecuted / totalCycles;
1631    vpc = numVecOpsExecuted / totalCycles;
1632
1633    numTimesWgBlockedDueVgprAlloc
1634        .name(name() + ".times_wg_blocked_due_vgpr_alloc")
1635        .desc("Number of times WGs are blocked due to VGPR allocation per SIMD")
1636        ;
1637
1638    dynamicGMemInstrCnt
1639        .name(name() + ".global_mem_instr_cnt")
1640        .desc("dynamic global memory instructions count")
1641        ;
1642
1643    dynamicLMemInstrCnt
1644        .name(name() + ".local_mem_instr_cnt")
1645        .desc("dynamic local memory intruction count")
1646        ;
1647
1648    numALUInstsExecuted = numInstrExecuted - dynamicGMemInstrCnt -
1649        dynamicLMemInstrCnt;
1650
1651    completedWfs
1652        .name(name() + ".num_completed_wfs")
1653        .desc("number of completed wavefronts")
1654        ;
1655
1656    numCASOps
1657        .name(name() + ".num_CAS_ops")
1658        .desc("number of compare and swap operations")
1659        ;
1660
1661    numFailedCASOps
1662        .name(name() + ".num_failed_CAS_ops")
1663        .desc("number of compare and swap operations that failed")
1664        ;
1665
1666    // register stats of pipeline stages
1667    fetchStage.regStats();
1668    scoreboardCheckStage.regStats();
1669    scheduleStage.regStats();
1670    execStage.regStats();
1671
1672    // register stats of memory pipeline
1673    globalMemoryPipe.regStats();
1674    localMemoryPipe.regStats();
1675}
1676
1677void
1678ComputeUnit::updateInstStats(GPUDynInstPtr gpuDynInst)
1679{
1680    if (gpuDynInst->isScalar()) {
1681        if (gpuDynInst->isALU() && !gpuDynInst->isWaitcnt()) {
1682            sALUInsts++;
1683            instCyclesSALU++;
1684        } else if (gpuDynInst->isLoad()) {
1685            scalarMemReads++;
1686        } else if (gpuDynInst->isStore()) {
1687            scalarMemWrites++;
1688        }
1689    } else {
1690        if (gpuDynInst->isALU()) {
1691            vALUInsts++;
1692            instCyclesVALU++;
1693            threadCyclesVALU += gpuDynInst->wavefront()->execMask().count();
1694        } else if (gpuDynInst->isFlat()) {
1695            if (gpuDynInst->isLocalMem()) {
1696                flatLDSInsts++;
1697            } else {
1698                flatVMemInsts++;
1699            }
1700        } else if (gpuDynInst->isLocalMem()) {
1701            ldsNoFlatInsts++;
1702        } else if (gpuDynInst->isLoad()) {
1703            vectorMemReads++;
1704        } else if (gpuDynInst->isStore()) {
1705            vectorMemWrites++;
1706        }
1707    }
1708}
1709
1710void
1711ComputeUnit::updatePageDivergenceDist(Addr addr)
1712{
1713    Addr virt_page_addr = roundDown(addr, TheISA::PageBytes);
1714
1715    if (!pagesTouched.count(virt_page_addr))
1716        pagesTouched[virt_page_addr] = 1;
1717    else
1718        pagesTouched[virt_page_addr]++;
1719}
1720
1721void
1722ComputeUnit::CUExitCallback::process()
1723{
1724    if (computeUnit->countPages) {
1725        std::ostream *page_stat_file =
1726            simout.create(computeUnit->name().c_str())->stream();
1727
1728        *page_stat_file << "page, wavefront accesses, workitem accesses" <<
1729            std::endl;
1730
1731        for (auto iter : computeUnit->pageAccesses) {
1732            *page_stat_file << std::hex << iter.first << ",";
1733            *page_stat_file << std::dec << iter.second.first << ",";
1734            *page_stat_file << std::dec << iter.second.second << std::endl;
1735        }
1736    }
1737 }
1738
1739bool
1740ComputeUnit::isDone() const
1741{
1742    for (int i = 0; i < numSIMDs; ++i) {
1743        if (!isSimdDone(i)) {
1744            return false;
1745        }
1746    }
1747
1748    bool glbMemBusRdy = true;
1749    for (int j = 0; j < numGlbMemUnits; ++j) {
1750        glbMemBusRdy &= vrfToGlobalMemPipeBus[j].rdy();
1751    }
1752    bool locMemBusRdy = true;
1753    for (int j = 0; j < numLocMemUnits; ++j) {
1754        locMemBusRdy &= vrfToLocalMemPipeBus[j].rdy();
1755    }
1756
1757    if (!globalMemoryPipe.isGMLdRespFIFOWrRdy() ||
1758        !globalMemoryPipe.isGMStRespFIFOWrRdy() ||
1759        !globalMemoryPipe.isGMReqFIFOWrRdy() || !localMemoryPipe.isLMReqFIFOWrRdy()
1760        || !localMemoryPipe.isLMRespFIFOWrRdy() || !locMemToVrfBus.rdy() ||
1761        !glbMemToVrfBus.rdy() || !locMemBusRdy || !glbMemBusRdy) {
1762        return false;
1763    }
1764
1765    return true;
1766}
1767
1768int32_t
1769ComputeUnit::getRefCounter(const uint32_t dispatchId, const uint32_t wgId) const
1770{
1771    return lds.getRefCounter(dispatchId, wgId);
1772}
1773
1774bool
1775ComputeUnit::isSimdDone(uint32_t simdId) const
1776{
1777    assert(simdId < numSIMDs);
1778
1779    for (int i=0; i < numGlbMemUnits; ++i) {
1780        if (!vrfToGlobalMemPipeBus[i].rdy())
1781            return false;
1782    }
1783    for (int i=0; i < numLocMemUnits; ++i) {
1784        if (!vrfToLocalMemPipeBus[i].rdy())
1785            return false;
1786    }
1787    if (!aluPipe[simdId].rdy()) {
1788        return false;
1789    }
1790
1791    for (int i_wf = 0; i_wf < shader->n_wf; ++i_wf){
1792        if (wfList[simdId][i_wf]->status != Wavefront::S_STOPPED) {
1793            return false;
1794        }
1795    }
1796
1797    return true;
1798}
1799
1800/**
1801 * send a general request to the LDS
1802 * make sure to look at the return value here as your request might be
1803 * NACK'd and returning false means that you have to have some backup plan
1804 */
1805bool
1806ComputeUnit::sendToLds(GPUDynInstPtr gpuDynInst)
1807{
1808    // this is just a request to carry the GPUDynInstPtr
1809    // back and forth
1810    Request *newRequest = new Request();
1811    newRequest->setPaddr(0x0);
1812
1813    // ReadReq is not evaluted by the LDS but the Packet ctor requires this
1814    PacketPtr newPacket = new Packet(newRequest, MemCmd::ReadReq);
1815
1816    // This is the SenderState needed upon return
1817    newPacket->senderState = new LDSPort::SenderState(gpuDynInst);
1818
1819    return ldsPort->sendTimingReq(newPacket);
1820}
1821
1822/**
1823 * get the result of packets sent to the LDS when they return
1824 */
1825bool
1826ComputeUnit::LDSPort::recvTimingResp(PacketPtr packet)
1827{
1828    const ComputeUnit::LDSPort::SenderState *senderState =
1829        dynamic_cast<ComputeUnit::LDSPort::SenderState *>(packet->senderState);
1830
1831    fatal_if(!senderState, "did not get the right sort of sender state");
1832
1833    GPUDynInstPtr gpuDynInst = senderState->getMemInst();
1834
1835    delete packet->senderState;
1836    delete packet->req;
1837    delete packet;
1838
1839    computeUnit->localMemoryPipe.getLMRespFIFO().push(gpuDynInst);
1840    return true;
1841}
1842
1843/**
1844 * attempt to send this packet, either the port is already stalled, the request
1845 * is nack'd and must stall or the request goes through
1846 * when a request cannot be sent, add it to the retries queue
1847 */
1848bool
1849ComputeUnit::LDSPort::sendTimingReq(PacketPtr pkt)
1850{
1851    ComputeUnit::LDSPort::SenderState *sender_state =
1852            dynamic_cast<ComputeUnit::LDSPort::SenderState*>(pkt->senderState);
1853    fatal_if(!sender_state, "packet without a valid sender state");
1854
1855    GPUDynInstPtr gpuDynInst M5_VAR_USED = sender_state->getMemInst();
1856
1857    if (isStalled()) {
1858        fatal_if(retries.empty(), "must have retries waiting to be stalled");
1859
1860        retries.push(pkt);
1861
1862        DPRINTF(GPUPort, "CU%d: WF[%d][%d]: LDS send failed!\n",
1863                        computeUnit->cu_id, gpuDynInst->simdId,
1864                        gpuDynInst->wfSlotId);
1865        return false;
1866    } else if (!MasterPort::sendTimingReq(pkt)) {
1867        // need to stall the LDS port until a recvReqRetry() is received
1868        // this indicates that there is more space
1869        stallPort();
1870        retries.push(pkt);
1871
1872        DPRINTF(GPUPort, "CU%d: WF[%d][%d]: addr %#x lds req failed!\n",
1873                computeUnit->cu_id, gpuDynInst->simdId,
1874                gpuDynInst->wfSlotId, pkt->req->getPaddr());
1875        return false;
1876    } else {
1877        DPRINTF(GPUPort, "CU%d: WF[%d][%d]: addr %#x lds req sent!\n",
1878                computeUnit->cu_id, gpuDynInst->simdId,
1879                gpuDynInst->wfSlotId, pkt->req->getPaddr());
1880        return true;
1881    }
1882}
1883
1884/**
1885 * the bus is telling the port that there is now space so retrying stalled
1886 * requests should work now
1887 * this allows the port to have a request be nack'd and then have the receiver
1888 * say when there is space, rather than simply retrying the send every cycle
1889 */
1890void
1891ComputeUnit::LDSPort::recvReqRetry()
1892{
1893    auto queueSize = retries.size();
1894
1895    DPRINTF(GPUPort, "CU%d: LDSPort recvReqRetry - %d pending requests\n",
1896            computeUnit->cu_id, queueSize);
1897
1898    fatal_if(queueSize < 1,
1899             "why was there a recvReqRetry() with no pending reqs?");
1900    fatal_if(!isStalled(),
1901             "recvReqRetry() happened when the port was not stalled");
1902
1903    unstallPort();
1904
1905    while (!retries.empty()) {
1906        PacketPtr packet = retries.front();
1907
1908        DPRINTF(GPUPort, "CU%d: retrying LDS send\n", computeUnit->cu_id);
1909
1910        if (!MasterPort::sendTimingReq(packet)) {
1911            // Stall port
1912            stallPort();
1913            DPRINTF(GPUPort, ": LDS send failed again\n");
1914            break;
1915        } else {
1916            DPRINTF(GPUTLB, ": LDS send successful\n");
1917            retries.pop();
1918        }
1919    }
1920}
1921