Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Ben Skeggs | 3041 | 99.38% | 36 | 92.31% |
Alexandre Courbot | 10 | 0.33% | 1 | 2.56% |
Dave Airlie | 5 | 0.16% | 1 | 2.56% |
Alistair Popple | 4 | 0.13% | 1 | 2.56% |
Total | 3060 | 39 |
/* * Copyright 2023 Red Hat Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ #include "gf100.h" #include <core/memory.h> #include <subdev/gsp.h> #include <subdev/mmu/vmm.h> #include <engine/fifo/priv.h> #include <nvif/if900d.h> #include <nvhw/drf.h> #include <nvrm/nvtypes.h> #include <nvrm/535.113.01/common/sdk/nvidia/inc/alloc/alloc_channel.h> #include <nvrm/535.113.01/common/sdk/nvidia/inc/ctrl/ctrl0080/ctrl0080fifo.h> #include <nvrm/535.113.01/common/sdk/nvidia/inc/ctrl/ctrl2080/ctrl2080gpu.h> #include <nvrm/535.113.01/common/sdk/nvidia/inc/ctrl/ctrl2080/ctrl2080internal.h> #include <nvrm/535.113.01/nvidia/generated/g_kernel_channel_nvoc.h> #define r535_gr(p) container_of((p), struct r535_gr, base) #define R515_GR_MAX_CTXBUFS 9 struct r535_gr { struct nvkm_gr base; struct { u16 bufferId; u32 size; u8 page; u8 align; bool global; bool init; bool ro; } ctxbuf[R515_GR_MAX_CTXBUFS]; int ctxbuf_nr; struct nvkm_memory *ctxbuf_mem[R515_GR_MAX_CTXBUFS]; }; struct r535_gr_chan { struct nvkm_object object; struct r535_gr *gr; struct nvkm_vmm *vmm; struct nvkm_chan *chan; struct nvkm_memory *mem[R515_GR_MAX_CTXBUFS]; struct nvkm_vma *vma[R515_GR_MAX_CTXBUFS]; }; struct r535_gr_obj { struct nvkm_object object; struct nvkm_gsp_object rm; }; static void * r535_gr_obj_dtor(struct nvkm_object *object) { struct r535_gr_obj *obj = container_of(object, typeof(*obj), object); nvkm_gsp_rm_free(&obj->rm); return obj; } static const struct nvkm_object_func r535_gr_obj = { .dtor = r535_gr_obj_dtor, }; static int r535_gr_obj_ctor(const struct nvkm_oclass *oclass, void *argv, u32 argc, struct nvkm_object **pobject) { struct r535_gr_chan *chan = container_of(oclass->parent, typeof(*chan), object); struct r535_gr_obj *obj; if (!(obj = kzalloc(sizeof(*obj), GFP_KERNEL))) return -ENOMEM; nvkm_object_ctor(&r535_gr_obj, oclass, &obj->object); *pobject = &obj->object; return nvkm_gsp_rm_alloc(&chan->chan->rm.object, oclass->handle, oclass->base.oclass, 0, &obj->rm); } static void * r535_gr_chan_dtor(struct nvkm_object *object) { struct r535_gr_chan *grc = container_of(object, typeof(*grc), object); struct r535_gr *gr = grc->gr; for (int i = 0; i < gr->ctxbuf_nr; i++) { nvkm_vmm_put(grc->vmm, &grc->vma[i]); nvkm_memory_unref(&grc->mem[i]); } nvkm_vmm_unref(&grc->vmm); return grc; } static const struct nvkm_object_func r535_gr_chan = { .dtor = r535_gr_chan_dtor, }; static int r535_gr_promote_ctx(struct r535_gr *gr, bool golden, struct nvkm_vmm *vmm, struct nvkm_memory **pmem, struct nvkm_vma **pvma, struct nvkm_gsp_object *chan) { struct nvkm_subdev *subdev = &gr->base.engine.subdev; struct nvkm_device *device = subdev->device; NV2080_CTRL_GPU_PROMOTE_CTX_PARAMS *ctrl; ctrl = nvkm_gsp_rm_ctrl_get(&vmm->rm.device.subdevice, NV2080_CTRL_CMD_GPU_PROMOTE_CTX, sizeof(*ctrl)); if (WARN_ON(IS_ERR(ctrl))) return PTR_ERR(ctrl); ctrl->engineType = 1; ctrl->hChanClient = vmm->rm.client.object.handle; ctrl->hObject = chan->handle; for (int i = 0; i < gr->ctxbuf_nr; i++) { NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ENTRY *entry = &ctrl->promoteEntry[ctrl->entryCount]; const bool alloc = golden || !gr->ctxbuf[i].global; int ret; entry->bufferId = gr->ctxbuf[i].bufferId; entry->bInitialize = gr->ctxbuf[i].init && alloc; if (alloc) { ret = nvkm_memory_new(device, gr->ctxbuf[i].init ? NVKM_MEM_TARGET_INST : NVKM_MEM_TARGET_INST_SR_LOST, gr->ctxbuf[i].size, 1 << gr->ctxbuf[i].page, gr->ctxbuf[i].init, &pmem[i]); if (WARN_ON(ret)) return ret; if (gr->ctxbuf[i].bufferId == NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID_PRIV_ACCESS_MAP) entry->bNonmapped = 1; } else { if (gr->ctxbuf[i].bufferId == NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID_UNRESTRICTED_PRIV_ACCESS_MAP) continue; pmem[i] = nvkm_memory_ref(gr->ctxbuf_mem[i]); } if (!entry->bNonmapped) { struct gf100_vmm_map_v0 args = { .priv = 1, .ro = gr->ctxbuf[i].ro, }; mutex_lock(&vmm->mutex.vmm); ret = nvkm_vmm_get_locked(vmm, false, true, false, 0, gr->ctxbuf[i].align, nvkm_memory_size(pmem[i]), &pvma[i]); mutex_unlock(&vmm->mutex.vmm); if (ret) return ret; ret = nvkm_memory_map(pmem[i], 0, vmm, pvma[i], &args, sizeof(args)); if (ret) return ret; entry->gpuVirtAddr = pvma[i]->addr; } if (entry->bInitialize) { entry->gpuPhysAddr = nvkm_memory_addr(pmem[i]); entry->size = gr->ctxbuf[i].size; entry->physAttr = 4; } nvkm_debug(subdev, "promote %02d: pa %016llx/%08x sz %016llx va %016llx init:%d nm:%d\n", entry->bufferId, entry->gpuPhysAddr, entry->physAttr, entry->size, entry->gpuVirtAddr, entry->bInitialize, entry->bNonmapped); ctrl->entryCount++; } return nvkm_gsp_rm_ctrl_wr(&vmm->rm.device.subdevice, ctrl); } static int r535_gr_chan_new(struct nvkm_gr *base, struct nvkm_chan *chan, const struct nvkm_oclass *oclass, struct nvkm_object **pobject) { struct r535_gr *gr = r535_gr(base); struct r535_gr_chan *grc; int ret; if (!(grc = kzalloc(sizeof(*grc), GFP_KERNEL))) return -ENOMEM; nvkm_object_ctor(&r535_gr_chan, oclass, &grc->object); grc->gr = gr; grc->vmm = nvkm_vmm_ref(chan->vmm); grc->chan = chan; *pobject = &grc->object; ret = r535_gr_promote_ctx(gr, false, grc->vmm, grc->mem, grc->vma, &chan->rm.object); if (ret) return ret; return 0; } static u64 r535_gr_units(struct nvkm_gr *gr) { struct nvkm_gsp *gsp = gr->engine.subdev.device->gsp; return (gsp->gr.tpcs << 8) | gsp->gr.gpcs; } static int r535_gr_oneinit(struct nvkm_gr *base) { NV2080_CTRL_INTERNAL_STATIC_GR_GET_CONTEXT_BUFFERS_INFO_PARAMS *info; struct r535_gr *gr = container_of(base, typeof(*gr), base); struct nvkm_subdev *subdev = &gr->base.engine.subdev; struct nvkm_device *device = subdev->device; struct nvkm_gsp *gsp = device->gsp; struct nvkm_mmu *mmu = device->mmu; struct { struct nvkm_memory *inst; struct nvkm_vmm *vmm; struct nvkm_gsp_object chan; struct nvkm_vma *vma[R515_GR_MAX_CTXBUFS]; } golden = {}; int ret; /* Allocate a channel to use for golden context init. */ ret = nvkm_memory_new(device, NVKM_MEM_TARGET_INST, 0x12000, 0, true, &golden.inst); if (ret) goto done; ret = nvkm_vmm_new(device, 0x1000, 0, NULL, 0, NULL, "grGoldenVmm", &golden.vmm); if (ret) goto done; ret = mmu->func->promote_vmm(golden.vmm); if (ret) goto done; { NV_CHANNELGPFIFO_ALLOCATION_PARAMETERS *args; args = nvkm_gsp_rm_alloc_get(&golden.vmm->rm.device.object, 0xf1f00000, device->fifo->func->chan.user.oclass, sizeof(*args), &golden.chan); if (IS_ERR(args)) { ret = PTR_ERR(args); goto done; } args->gpFifoOffset = 0; args->gpFifoEntries = 0x1000 / 8; args->flags = NVDEF(NVOS04, FLAGS, CHANNEL_TYPE, PHYSICAL) | NVDEF(NVOS04, FLAGS, VPR, FALSE) | NVDEF(NVOS04, FLAGS, CHANNEL_SKIP_MAP_REFCOUNTING, FALSE) | NVVAL(NVOS04, FLAGS, GROUP_CHANNEL_RUNQUEUE, 0) | NVDEF(NVOS04, FLAGS, PRIVILEGED_CHANNEL, TRUE) | NVDEF(NVOS04, FLAGS, DELAY_CHANNEL_SCHEDULING, FALSE) | NVDEF(NVOS04, FLAGS, CHANNEL_DENY_PHYSICAL_MODE_CE, FALSE) | NVVAL(NVOS04, FLAGS, CHANNEL_USERD_INDEX_VALUE, 0) | NVDEF(NVOS04, FLAGS, CHANNEL_USERD_INDEX_FIXED, FALSE) | NVVAL(NVOS04, FLAGS, CHANNEL_USERD_INDEX_PAGE_VALUE, 0) | NVDEF(NVOS04, FLAGS, CHANNEL_USERD_INDEX_PAGE_FIXED, TRUE) | NVDEF(NVOS04, FLAGS, CHANNEL_DENY_AUTH_LEVEL_PRIV, FALSE) | NVDEF(NVOS04, FLAGS, CHANNEL_SKIP_SCRUBBER, FALSE) | NVDEF(NVOS04, FLAGS, CHANNEL_CLIENT_MAP_FIFO, FALSE) | NVDEF(NVOS04, FLAGS, SET_EVICT_LAST_CE_PREFETCH_CHANNEL, FALSE) | NVDEF(NVOS04, FLAGS, CHANNEL_VGPU_PLUGIN_CONTEXT, FALSE) | NVDEF(NVOS04, FLAGS, CHANNEL_PBDMA_ACQUIRE_TIMEOUT, FALSE) | NVDEF(NVOS04, FLAGS, GROUP_CHANNEL_THREAD, DEFAULT) | NVDEF(NVOS04, FLAGS, MAP_CHANNEL, FALSE) | NVDEF(NVOS04, FLAGS, SKIP_CTXBUFFER_ALLOC, FALSE); args->hVASpace = golden.vmm->rm.object.handle; args->engineType = 1; args->instanceMem.base = nvkm_memory_addr(golden.inst); args->instanceMem.size = 0x1000; args->instanceMem.addressSpace = 2; args->instanceMem.cacheAttrib = 1; args->ramfcMem.base = nvkm_memory_addr(golden.inst); args->ramfcMem.size = 0x200; args->ramfcMem.addressSpace = 2; args->ramfcMem.cacheAttrib = 1; args->userdMem.base = nvkm_memory_addr(golden.inst) + 0x1000; args->userdMem.size = 0x200; args->userdMem.addressSpace = 2; args->userdMem.cacheAttrib = 1; args->mthdbufMem.base = nvkm_memory_addr(golden.inst) + 0x2000; args->mthdbufMem.size = 0x5000; args->mthdbufMem.addressSpace = 2; args->mthdbufMem.cacheAttrib = 1; args->internalFlags = NVDEF(NV_KERNELCHANNEL, ALLOC_INTERNALFLAGS, PRIVILEGE, ADMIN) | NVDEF(NV_KERNELCHANNEL, ALLOC_INTERNALFLAGS, ERROR_NOTIFIER_TYPE, NONE) | NVDEF(NV_KERNELCHANNEL, ALLOC_INTERNALFLAGS, ECC_ERROR_NOTIFIER_TYPE, NONE); ret = nvkm_gsp_rm_alloc_wr(&golden.chan, args); if (ret) goto done; } /* Fetch context buffer info from RM and allocate each of them here to use * during golden context init (or later as a global context buffer). * * Also build the information that'll be used to create channel contexts. */ info = nvkm_gsp_rm_ctrl_rd(&gsp->internal.device.subdevice, NV2080_CTRL_CMD_INTERNAL_STATIC_KGR_GET_CONTEXT_BUFFERS_INFO, sizeof(*info)); if (WARN_ON(IS_ERR(info))) { ret = PTR_ERR(info); goto done; } for (int i = 0; i < ARRAY_SIZE(info->engineContextBuffersInfo[0].engine); i++) { static const struct { u32 id0; /* NV0080_CTRL_FIFO_GET_ENGINE_CONTEXT_PROPERTIES_ENGINE_ID */ u32 id1; /* NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID */ bool global; bool init; bool ro; } map[] = { #define _A(n,N,G,I,R) { .id0 = NV0080_CTRL_FIFO_GET_ENGINE_CONTEXT_PROPERTIES_ENGINE_ID_##n, \ .id1 = NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID_##N, \ .global = (G), .init = (I), .ro = (R) } #define _B(N,G,I,R) _A(GRAPHICS_##N, N, (G), (I), (R)) /* global init ro */ _A( GRAPHICS, MAIN, false, true, false), _B( PATCH, false, true, false), _A( GRAPHICS_BUNDLE_CB, BUFFER_BUNDLE_CB, true, false, false), _B( PAGEPOOL, true, false, false), _B( ATTRIBUTE_CB, true, false, false), _B( RTV_CB_GLOBAL, true, false, false), _B( FECS_EVENT, true, true, false), _B( PRIV_ACCESS_MAP, true, true, true), #undef _B #undef _A }; u32 size = info->engineContextBuffersInfo[0].engine[i].size; u8 align, page; int id; for (id = 0; id < ARRAY_SIZE(map); id++) { if (map[id].id0 == i) break; } nvkm_debug(subdev, "%02x: size:0x%08x %s\n", i, size, (id < ARRAY_SIZE(map)) ? "*" : ""); if (id >= ARRAY_SIZE(map)) continue; if (map[id].id1 == NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID_MAIN) size = ALIGN(size, 0x1000) + 64 * 0x1000; /* per-subctx headers */ if (size >= 1 << 21) page = 21; else if (size >= 1 << 16) page = 16; else page = 12; if (map[id].id1 == NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID_ATTRIBUTE_CB) align = order_base_2(size); else align = page; if (WARN_ON(gr->ctxbuf_nr == ARRAY_SIZE(gr->ctxbuf))) continue; gr->ctxbuf[gr->ctxbuf_nr].bufferId = map[id].id1; gr->ctxbuf[gr->ctxbuf_nr].size = size; gr->ctxbuf[gr->ctxbuf_nr].page = page; gr->ctxbuf[gr->ctxbuf_nr].align = align; gr->ctxbuf[gr->ctxbuf_nr].global = map[id].global; gr->ctxbuf[gr->ctxbuf_nr].init = map[id].init; gr->ctxbuf[gr->ctxbuf_nr].ro = map[id].ro; gr->ctxbuf_nr++; if (map[id].id1 == NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID_PRIV_ACCESS_MAP) { if (WARN_ON(gr->ctxbuf_nr == ARRAY_SIZE(gr->ctxbuf))) continue; gr->ctxbuf[gr->ctxbuf_nr] = gr->ctxbuf[gr->ctxbuf_nr - 1]; gr->ctxbuf[gr->ctxbuf_nr].bufferId = NV2080_CTRL_GPU_PROMOTE_CTX_BUFFER_ID_UNRESTRICTED_PRIV_ACCESS_MAP; gr->ctxbuf_nr++; } } nvkm_gsp_rm_ctrl_done(&gsp->internal.device.subdevice, info); /* Promote golden context to RM. */ ret = r535_gr_promote_ctx(gr, true, golden.vmm, gr->ctxbuf_mem, golden.vma, &golden.chan); if (ret) goto done; /* Allocate 3D class on channel to trigger golden context init in RM. */ { int i; for (i = 0; gr->base.func->sclass[i].ctor; i++) { if ((gr->base.func->sclass[i].oclass & 0xff) == 0x97) { struct nvkm_gsp_object threed; ret = nvkm_gsp_rm_alloc(&golden.chan, 0x97000000, gr->base.func->sclass[i].oclass, 0, &threed); if (ret) goto done; nvkm_gsp_rm_free(&threed); break; } } if (WARN_ON(!gr->base.func->sclass[i].ctor)) { ret = -EINVAL; goto done; } } done: nvkm_gsp_rm_free(&golden.chan); for (int i = gr->ctxbuf_nr - 1; i >= 0; i--) nvkm_vmm_put(golden.vmm, &golden.vma[i]); nvkm_vmm_unref(&golden.vmm); nvkm_memory_unref(&golden.inst); return ret; } static void * r535_gr_dtor(struct nvkm_gr *base) { struct r535_gr *gr = r535_gr(base); while (gr->ctxbuf_nr) nvkm_memory_unref(&gr->ctxbuf_mem[--gr->ctxbuf_nr]); kfree(gr->base.func); return gr; } int r535_gr_new(const struct gf100_gr_func *hw, struct nvkm_device *device, enum nvkm_subdev_type type, int inst, struct nvkm_gr **pgr) { struct nvkm_gr_func *rm; struct r535_gr *gr; int nclass; for (nclass = 0; hw->sclass[nclass].oclass; nclass++); if (!(rm = kzalloc(sizeof(*rm) + (nclass + 1) * sizeof(rm->sclass[0]), GFP_KERNEL))) return -ENOMEM; rm->dtor = r535_gr_dtor; rm->oneinit = r535_gr_oneinit; rm->units = r535_gr_units; rm->chan_new = r535_gr_chan_new; for (int i = 0; i < nclass; i++) { rm->sclass[i].minver = hw->sclass[i].minver; rm->sclass[i].maxver = hw->sclass[i].maxver; rm->sclass[i].oclass = hw->sclass[i].oclass; rm->sclass[i].ctor = r535_gr_obj_ctor; } if (!(gr = kzalloc(sizeof(*gr), GFP_KERNEL))) { kfree(rm); return -ENOMEM; } *pgr = &gr->base; return nvkm_gr_ctor(rm, device, type, inst, true, &gr->base); }
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