Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Matthew Brost | 2943 | 78.23% | 2 | 5.88% |
Badal Nilawar | 297 | 7.89% | 2 | 5.88% |
Rodrigo Vivi | 229 | 6.09% | 2 | 5.88% |
Vinay Belgaumkar | 99 | 2.63% | 1 | 2.94% |
Matt Roper | 70 | 1.86% | 6 | 17.65% |
Lucas De Marchi | 45 | 1.20% | 12 | 35.29% |
Francois Dugast | 33 | 0.88% | 3 | 8.82% |
Niranjana Vishwanathapura | 27 | 0.72% | 2 | 5.88% |
Daniele Ceraolo Spurio | 14 | 0.37% | 2 | 5.88% |
John Harrison | 4 | 0.11% | 1 | 2.94% |
Michał Winiarski | 1 | 0.03% | 1 | 2.94% |
Total | 3762 | 34 |
// SPDX-License-Identifier: MIT /* * Copyright © 2022 Intel Corporation */ #include "xe_guc_ads.h" #include <drm/drm_managed.h> #include <generated/xe_wa_oob.h> #include "abi/guc_actions_abi.h" #include "regs/xe_engine_regs.h" #include "regs/xe_gt_regs.h" #include "regs/xe_guc_regs.h" #include "xe_bo.h" #include "xe_gt.h" #include "xe_gt_ccs_mode.h" #include "xe_gt_printk.h" #include "xe_guc.h" #include "xe_guc_ct.h" #include "xe_hw_engine.h" #include "xe_lrc.h" #include "xe_map.h" #include "xe_mmio.h" #include "xe_platform_types.h" #include "xe_wa.h" /* Slack of a few additional entries per engine */ #define ADS_REGSET_EXTRA_MAX 8 static struct xe_guc * ads_to_guc(struct xe_guc_ads *ads) { return container_of(ads, struct xe_guc, ads); } static struct xe_gt * ads_to_gt(struct xe_guc_ads *ads) { return container_of(ads, struct xe_gt, uc.guc.ads); } static struct xe_device * ads_to_xe(struct xe_guc_ads *ads) { return gt_to_xe(ads_to_gt(ads)); } static struct iosys_map * ads_to_map(struct xe_guc_ads *ads) { return &ads->bo->vmap; } /* UM Queue parameters: */ #define GUC_UM_QUEUE_SIZE (SZ_64K) #define GUC_PAGE_RES_TIMEOUT_US (-1) /* * The Additional Data Struct (ADS) has pointers for different buffers used by * the GuC. One single gem object contains the ADS struct itself (guc_ads) and * all the extra buffers indirectly linked via the ADS struct's entries. * * Layout of the ADS blob allocated for the GuC: * * +---------------------------------------+ <== base * | guc_ads | * +---------------------------------------+ * | guc_policies | * +---------------------------------------+ * | guc_gt_system_info | * +---------------------------------------+ * | guc_engine_usage | * +---------------------------------------+ * | guc_um_init_params | * +---------------------------------------+ <== static * | guc_mmio_reg[countA] (engine 0.0) | * | guc_mmio_reg[countB] (engine 0.1) | * | guc_mmio_reg[countC] (engine 1.0) | * | ... | * +---------------------------------------+ <== dynamic * | padding | * +---------------------------------------+ <== 4K aligned * | golden contexts | * +---------------------------------------+ * | padding | * +---------------------------------------+ <== 4K aligned * | w/a KLVs | * +---------------------------------------+ * | padding | * +---------------------------------------+ <== 4K aligned * | capture lists | * +---------------------------------------+ * | padding | * +---------------------------------------+ <== 4K aligned * | UM queues | * +---------------------------------------+ * | padding | * +---------------------------------------+ <== 4K aligned * | private data | * +---------------------------------------+ * | padding | * +---------------------------------------+ <== 4K aligned */ struct __guc_ads_blob { struct guc_ads ads; struct guc_policies policies; struct guc_gt_system_info system_info; struct guc_engine_usage engine_usage; struct guc_um_init_params um_init_params; /* From here on, location is dynamic! Refer to above diagram. */ struct guc_mmio_reg regset[]; } __packed; #define ads_blob_read(ads_, field_) \ xe_map_rd_field(ads_to_xe(ads_), ads_to_map(ads_), 0, \ struct __guc_ads_blob, field_) #define ads_blob_write(ads_, field_, val_) \ xe_map_wr_field(ads_to_xe(ads_), ads_to_map(ads_), 0, \ struct __guc_ads_blob, field_, val_) #define info_map_write(xe_, map_, field_, val_) \ xe_map_wr_field(xe_, map_, 0, struct guc_gt_system_info, field_, val_) #define info_map_read(xe_, map_, field_) \ xe_map_rd_field(xe_, map_, 0, struct guc_gt_system_info, field_) static size_t guc_ads_regset_size(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); xe_assert(xe, ads->regset_size); return ads->regset_size; } static size_t guc_ads_golden_lrc_size(struct xe_guc_ads *ads) { return PAGE_ALIGN(ads->golden_lrc_size); } static u32 guc_ads_waklv_size(struct xe_guc_ads *ads) { return PAGE_ALIGN(ads->ads_waklv_size); } static size_t guc_ads_capture_size(struct xe_guc_ads *ads) { /* FIXME: Allocate a proper capture list */ return PAGE_ALIGN(PAGE_SIZE); } static size_t guc_ads_um_queues_size(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); if (!xe->info.has_usm) return 0; return GUC_UM_QUEUE_SIZE * GUC_UM_HW_QUEUE_MAX; } static size_t guc_ads_private_data_size(struct xe_guc_ads *ads) { return PAGE_ALIGN(ads_to_guc(ads)->fw.private_data_size); } static size_t guc_ads_regset_offset(struct xe_guc_ads *ads) { return offsetof(struct __guc_ads_blob, regset); } static size_t guc_ads_golden_lrc_offset(struct xe_guc_ads *ads) { size_t offset; offset = guc_ads_regset_offset(ads) + guc_ads_regset_size(ads); return PAGE_ALIGN(offset); } static size_t guc_ads_waklv_offset(struct xe_guc_ads *ads) { u32 offset; offset = guc_ads_golden_lrc_offset(ads) + guc_ads_golden_lrc_size(ads); return PAGE_ALIGN(offset); } static size_t guc_ads_capture_offset(struct xe_guc_ads *ads) { size_t offset; offset = guc_ads_waklv_offset(ads) + guc_ads_waklv_size(ads); return PAGE_ALIGN(offset); } static size_t guc_ads_um_queues_offset(struct xe_guc_ads *ads) { u32 offset; offset = guc_ads_capture_offset(ads) + guc_ads_capture_size(ads); return PAGE_ALIGN(offset); } static size_t guc_ads_private_data_offset(struct xe_guc_ads *ads) { size_t offset; offset = guc_ads_um_queues_offset(ads) + guc_ads_um_queues_size(ads); return PAGE_ALIGN(offset); } static size_t guc_ads_size(struct xe_guc_ads *ads) { return guc_ads_private_data_offset(ads) + guc_ads_private_data_size(ads); } static bool needs_wa_1607983814(struct xe_device *xe) { return GRAPHICS_VERx100(xe) < 1250; } static size_t calculate_regset_size(struct xe_gt *gt) { struct xe_reg_sr_entry *sr_entry; unsigned long sr_idx; struct xe_hw_engine *hwe; enum xe_hw_engine_id id; unsigned int count = 0; for_each_hw_engine(hwe, gt, id) xa_for_each(&hwe->reg_sr.xa, sr_idx, sr_entry) count++; count += ADS_REGSET_EXTRA_MAX * XE_NUM_HW_ENGINES; if (needs_wa_1607983814(gt_to_xe(gt))) count += LNCFCMOCS_REG_COUNT; return count * sizeof(struct guc_mmio_reg); } static u32 engine_enable_mask(struct xe_gt *gt, enum xe_engine_class class) { struct xe_hw_engine *hwe; enum xe_hw_engine_id id; u32 mask = 0; for_each_hw_engine(hwe, gt, id) if (hwe->class == class) mask |= BIT(hwe->instance); return mask; } static size_t calculate_golden_lrc_size(struct xe_guc_ads *ads) { struct xe_gt *gt = ads_to_gt(ads); size_t total_size = 0, alloc_size, real_size; int class; for (class = 0; class < XE_ENGINE_CLASS_MAX; ++class) { if (!engine_enable_mask(gt, class)) continue; real_size = xe_gt_lrc_size(gt, class); alloc_size = PAGE_ALIGN(real_size); total_size += alloc_size; } return total_size; } static void guc_waklv_enable_one_word(struct xe_guc_ads *ads, enum xe_guc_klv_ids klv_id, u32 value, u32 *offset, u32 *remain) { u32 size; u32 klv_entry[] = { /* 16:16 key/length */ FIELD_PREP(GUC_KLV_0_KEY, klv_id) | FIELD_PREP(GUC_KLV_0_LEN, 1), value, /* 1 dword data */ }; size = sizeof(klv_entry); if (*remain < size) { drm_warn(&ads_to_xe(ads)->drm, "w/a klv buffer too small to add klv id %d\n", klv_id); } else { xe_map_memcpy_to(ads_to_xe(ads), ads_to_map(ads), *offset, klv_entry, size); *offset += size; *remain -= size; } } static void guc_waklv_enable_simple(struct xe_guc_ads *ads, enum xe_guc_klv_ids klv_id, u32 *offset, u32 *remain) { u32 klv_entry[] = { /* 16:16 key/length */ FIELD_PREP(GUC_KLV_0_KEY, klv_id) | FIELD_PREP(GUC_KLV_0_LEN, 0), /* 0 dwords data */ }; u32 size; size = sizeof(klv_entry); if (xe_gt_WARN(ads_to_gt(ads), *remain < size, "w/a klv buffer too small to add klv id %d\n", klv_id)) return; xe_map_memcpy_to(ads_to_xe(ads), ads_to_map(ads), *offset, klv_entry, size); *offset += size; *remain -= size; } static void guc_waklv_init(struct xe_guc_ads *ads) { struct xe_gt *gt = ads_to_gt(ads); u64 addr_ggtt; u32 offset, remain, size; offset = guc_ads_waklv_offset(ads); remain = guc_ads_waklv_size(ads); if (XE_WA(gt, 14019882105)) guc_waklv_enable_simple(ads, GUC_WORKAROUND_KLV_BLOCK_INTERRUPTS_WHEN_MGSR_BLOCKED, &offset, &remain); if (XE_WA(gt, 18024947630)) guc_waklv_enable_simple(ads, GUC_WORKAROUND_KLV_ID_GAM_PFQ_SHADOW_TAIL_POLLING, &offset, &remain); if (XE_WA(gt, 16022287689)) guc_waklv_enable_simple(ads, GUC_WORKAROUND_KLV_ID_DISABLE_MTP_DURING_ASYNC_COMPUTE, &offset, &remain); /* * On RC6 exit, GuC will write register 0xB04 with the default value provided. As of now, * the default value for this register is determined to be 0xC40. This could change in the * future, so GuC depends on KMD to send it the correct value. */ if (XE_WA(gt, 13011645652)) guc_waklv_enable_one_word(ads, GUC_WA_KLV_NP_RD_WRITE_TO_CLEAR_RCSM_AT_CGP_LATE_RESTORE, 0xC40, &offset, &remain); size = guc_ads_waklv_size(ads) - remain; if (!size) return; offset = guc_ads_waklv_offset(ads); addr_ggtt = xe_bo_ggtt_addr(ads->bo) + offset; ads_blob_write(ads, ads.wa_klv_addr_lo, lower_32_bits(addr_ggtt)); ads_blob_write(ads, ads.wa_klv_addr_hi, upper_32_bits(addr_ggtt)); ads_blob_write(ads, ads.wa_klv_size, size); } static int calculate_waklv_size(struct xe_guc_ads *ads) { /* * A single page is both the minimum size possible and * is sufficiently large enough for all current platforms. */ return SZ_4K; } #define MAX_GOLDEN_LRC_SIZE (SZ_4K * 64) int xe_guc_ads_init(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); struct xe_gt *gt = ads_to_gt(ads); struct xe_tile *tile = gt_to_tile(gt); struct xe_bo *bo; ads->golden_lrc_size = calculate_golden_lrc_size(ads); ads->regset_size = calculate_regset_size(gt); ads->ads_waklv_size = calculate_waklv_size(ads); bo = xe_managed_bo_create_pin_map(xe, tile, guc_ads_size(ads) + MAX_GOLDEN_LRC_SIZE, XE_BO_FLAG_SYSTEM | XE_BO_FLAG_GGTT | XE_BO_FLAG_GGTT_INVALIDATE); if (IS_ERR(bo)) return PTR_ERR(bo); ads->bo = bo; return 0; } /** * xe_guc_ads_init_post_hwconfig - initialize ADS post hwconfig load * @ads: Additional data structures object * * Recalcuate golden_lrc_size & regset_size as the number hardware engines may * have changed after the hwconfig was loaded. Also verify the new sizes fit in * the already allocated ADS buffer object. * * Return: 0 on success, negative error code on error. */ int xe_guc_ads_init_post_hwconfig(struct xe_guc_ads *ads) { struct xe_gt *gt = ads_to_gt(ads); u32 prev_regset_size = ads->regset_size; xe_gt_assert(gt, ads->bo); ads->golden_lrc_size = calculate_golden_lrc_size(ads); ads->regset_size = calculate_regset_size(gt); xe_gt_assert(gt, ads->golden_lrc_size + (ads->regset_size - prev_regset_size) <= MAX_GOLDEN_LRC_SIZE); return 0; } static void guc_policies_init(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); u32 global_flags = 0; ads_blob_write(ads, policies.dpc_promote_time, GLOBAL_POLICY_DEFAULT_DPC_PROMOTE_TIME_US); ads_blob_write(ads, policies.max_num_work_items, GLOBAL_POLICY_MAX_NUM_WI); if (xe->wedged.mode == 2) global_flags |= GLOBAL_POLICY_DISABLE_ENGINE_RESET; ads_blob_write(ads, policies.global_flags, global_flags); ads_blob_write(ads, policies.is_valid, 1); } static void fill_engine_enable_masks(struct xe_gt *gt, struct iosys_map *info_map) { struct xe_device *xe = gt_to_xe(gt); info_map_write(xe, info_map, engine_enabled_masks[GUC_RENDER_CLASS], engine_enable_mask(gt, XE_ENGINE_CLASS_RENDER)); info_map_write(xe, info_map, engine_enabled_masks[GUC_BLITTER_CLASS], engine_enable_mask(gt, XE_ENGINE_CLASS_COPY)); info_map_write(xe, info_map, engine_enabled_masks[GUC_VIDEO_CLASS], engine_enable_mask(gt, XE_ENGINE_CLASS_VIDEO_DECODE)); info_map_write(xe, info_map, engine_enabled_masks[GUC_VIDEOENHANCE_CLASS], engine_enable_mask(gt, XE_ENGINE_CLASS_VIDEO_ENHANCE)); info_map_write(xe, info_map, engine_enabled_masks[GUC_COMPUTE_CLASS], engine_enable_mask(gt, XE_ENGINE_CLASS_COMPUTE)); info_map_write(xe, info_map, engine_enabled_masks[GUC_GSC_OTHER_CLASS], engine_enable_mask(gt, XE_ENGINE_CLASS_OTHER)); } static void guc_prep_golden_lrc_null(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); struct iosys_map info_map = IOSYS_MAP_INIT_OFFSET(ads_to_map(ads), offsetof(struct __guc_ads_blob, system_info)); u8 guc_class; for (guc_class = 0; guc_class <= GUC_MAX_ENGINE_CLASSES; ++guc_class) { if (!info_map_read(xe, &info_map, engine_enabled_masks[guc_class])) continue; ads_blob_write(ads, ads.eng_state_size[guc_class], guc_ads_golden_lrc_size(ads) - xe_lrc_skip_size(xe)); ads_blob_write(ads, ads.golden_context_lrca[guc_class], xe_bo_ggtt_addr(ads->bo) + guc_ads_golden_lrc_offset(ads)); } } static void guc_mapping_table_init_invalid(struct xe_gt *gt, struct iosys_map *info_map) { struct xe_device *xe = gt_to_xe(gt); unsigned int i, j; /* Table must be set to invalid values for entries not used */ for (i = 0; i < GUC_MAX_ENGINE_CLASSES; ++i) for (j = 0; j < GUC_MAX_INSTANCES_PER_CLASS; ++j) info_map_write(xe, info_map, mapping_table[i][j], GUC_MAX_INSTANCES_PER_CLASS); } static void guc_mapping_table_init(struct xe_gt *gt, struct iosys_map *info_map) { struct xe_device *xe = gt_to_xe(gt); struct xe_hw_engine *hwe; enum xe_hw_engine_id id; guc_mapping_table_init_invalid(gt, info_map); for_each_hw_engine(hwe, gt, id) { u8 guc_class; guc_class = xe_engine_class_to_guc_class(hwe->class); info_map_write(xe, info_map, mapping_table[guc_class][hwe->logical_instance], hwe->instance); } } static void guc_capture_list_init(struct xe_guc_ads *ads) { int i, j; u32 addr = xe_bo_ggtt_addr(ads->bo) + guc_ads_capture_offset(ads); /* FIXME: Populate a proper capture list */ for (i = 0; i < GUC_CAPTURE_LIST_INDEX_MAX; i++) { for (j = 0; j < GUC_MAX_ENGINE_CLASSES; j++) { ads_blob_write(ads, ads.capture_instance[i][j], addr); ads_blob_write(ads, ads.capture_class[i][j], addr); } ads_blob_write(ads, ads.capture_global[i], addr); } } static void guc_mmio_regset_write_one(struct xe_guc_ads *ads, struct iosys_map *regset_map, struct xe_reg reg, unsigned int n_entry) { struct guc_mmio_reg entry = { .offset = reg.addr, .flags = reg.masked ? GUC_REGSET_MASKED : 0, }; xe_map_memcpy_to(ads_to_xe(ads), regset_map, n_entry * sizeof(entry), &entry, sizeof(entry)); } static unsigned int guc_mmio_regset_write(struct xe_guc_ads *ads, struct iosys_map *regset_map, struct xe_hw_engine *hwe) { struct xe_device *xe = ads_to_xe(ads); struct xe_hw_engine *hwe_rcs_reset_domain = xe_gt_any_hw_engine_by_reset_domain(hwe->gt, XE_ENGINE_CLASS_RENDER); struct xe_reg_sr_entry *entry; unsigned long idx; unsigned int count = 0; const struct { struct xe_reg reg; bool skip; } *e, extra_regs[] = { { .reg = RING_MODE(hwe->mmio_base), }, { .reg = RING_HWS_PGA(hwe->mmio_base), }, { .reg = RING_IMR(hwe->mmio_base), }, { .reg = RCU_MODE, .skip = hwe != hwe_rcs_reset_domain }, { .reg = CCS_MODE, .skip = hwe != hwe_rcs_reset_domain || !xe_gt_ccs_mode_enabled(hwe->gt) }, }; u32 i; BUILD_BUG_ON(ARRAY_SIZE(extra_regs) > ADS_REGSET_EXTRA_MAX); xa_for_each(&hwe->reg_sr.xa, idx, entry) guc_mmio_regset_write_one(ads, regset_map, entry->reg, count++); for (e = extra_regs; e < extra_regs + ARRAY_SIZE(extra_regs); e++) { if (e->skip) continue; guc_mmio_regset_write_one(ads, regset_map, e->reg, count++); } /* Wa_1607983814 */ if (needs_wa_1607983814(xe) && hwe->class == XE_ENGINE_CLASS_RENDER) { for (i = 0; i < LNCFCMOCS_REG_COUNT; i++) { guc_mmio_regset_write_one(ads, regset_map, XELP_LNCFCMOCS(i), count++); } } return count; } static void guc_mmio_reg_state_init(struct xe_guc_ads *ads) { size_t regset_offset = guc_ads_regset_offset(ads); struct xe_gt *gt = ads_to_gt(ads); struct xe_hw_engine *hwe; enum xe_hw_engine_id id; u32 addr = xe_bo_ggtt_addr(ads->bo) + regset_offset; struct iosys_map regset_map = IOSYS_MAP_INIT_OFFSET(ads_to_map(ads), regset_offset); unsigned int regset_used = 0; for_each_hw_engine(hwe, gt, id) { unsigned int count; u8 gc; /* * 1. Write all MMIO entries for this exec queue to the table. No * need to worry about fused-off engines and when there are * entries in the regset: the reg_state_list has been zero'ed * by xe_guc_ads_populate() */ count = guc_mmio_regset_write(ads, ®set_map, hwe); if (!count) continue; /* * 2. Record in the header (ads.reg_state_list) the address * location and number of entries */ gc = xe_engine_class_to_guc_class(hwe->class); ads_blob_write(ads, ads.reg_state_list[gc][hwe->instance].address, addr); ads_blob_write(ads, ads.reg_state_list[gc][hwe->instance].count, count); addr += count * sizeof(struct guc_mmio_reg); iosys_map_incr(®set_map, count * sizeof(struct guc_mmio_reg)); regset_used += count * sizeof(struct guc_mmio_reg); } xe_gt_assert(gt, regset_used <= ads->regset_size); } static void guc_um_init_params(struct xe_guc_ads *ads) { u32 um_queue_offset = guc_ads_um_queues_offset(ads); u64 base_dpa; u32 base_ggtt; int i; base_ggtt = xe_bo_ggtt_addr(ads->bo) + um_queue_offset; base_dpa = xe_bo_main_addr(ads->bo, PAGE_SIZE) + um_queue_offset; for (i = 0; i < GUC_UM_HW_QUEUE_MAX; ++i) { ads_blob_write(ads, um_init_params.queue_params[i].base_dpa, base_dpa + (i * GUC_UM_QUEUE_SIZE)); ads_blob_write(ads, um_init_params.queue_params[i].base_ggtt_address, base_ggtt + (i * GUC_UM_QUEUE_SIZE)); ads_blob_write(ads, um_init_params.queue_params[i].size_in_bytes, GUC_UM_QUEUE_SIZE); } ads_blob_write(ads, um_init_params.page_response_timeout_in_us, GUC_PAGE_RES_TIMEOUT_US); } static void guc_doorbell_init(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); struct xe_gt *gt = ads_to_gt(ads); if (GRAPHICS_VER(xe) >= 12 && !IS_DGFX(xe)) { u32 distdbreg = xe_mmio_read32(gt, DIST_DBS_POPULATED); ads_blob_write(ads, system_info.generic_gt_sysinfo[GUC_GENERIC_GT_SYSINFO_DOORBELL_COUNT_PER_SQIDI], REG_FIELD_GET(DOORBELLS_PER_SQIDI_MASK, distdbreg) + 1); } } /** * xe_guc_ads_populate_minimal - populate minimal ADS * @ads: Additional data structures object * * This function populates a minimal ADS that does not support submissions but * enough so the GuC can load and the hwconfig table can be read. */ void xe_guc_ads_populate_minimal(struct xe_guc_ads *ads) { struct xe_gt *gt = ads_to_gt(ads); struct iosys_map info_map = IOSYS_MAP_INIT_OFFSET(ads_to_map(ads), offsetof(struct __guc_ads_blob, system_info)); u32 base = xe_bo_ggtt_addr(ads->bo); xe_gt_assert(gt, ads->bo); xe_map_memset(ads_to_xe(ads), ads_to_map(ads), 0, 0, ads->bo->size); guc_policies_init(ads); guc_prep_golden_lrc_null(ads); guc_mapping_table_init_invalid(gt, &info_map); guc_doorbell_init(ads); ads_blob_write(ads, ads.scheduler_policies, base + offsetof(struct __guc_ads_blob, policies)); ads_blob_write(ads, ads.gt_system_info, base + offsetof(struct __guc_ads_blob, system_info)); ads_blob_write(ads, ads.private_data, base + guc_ads_private_data_offset(ads)); } void xe_guc_ads_populate(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); struct xe_gt *gt = ads_to_gt(ads); struct iosys_map info_map = IOSYS_MAP_INIT_OFFSET(ads_to_map(ads), offsetof(struct __guc_ads_blob, system_info)); u32 base = xe_bo_ggtt_addr(ads->bo); xe_gt_assert(gt, ads->bo); xe_map_memset(ads_to_xe(ads), ads_to_map(ads), 0, 0, ads->bo->size); guc_policies_init(ads); fill_engine_enable_masks(gt, &info_map); guc_mmio_reg_state_init(ads); guc_prep_golden_lrc_null(ads); guc_mapping_table_init(gt, &info_map); guc_capture_list_init(ads); guc_doorbell_init(ads); guc_waklv_init(ads); if (xe->info.has_usm) { guc_um_init_params(ads); ads_blob_write(ads, ads.um_init_data, base + offsetof(struct __guc_ads_blob, um_init_params)); } ads_blob_write(ads, ads.scheduler_policies, base + offsetof(struct __guc_ads_blob, policies)); ads_blob_write(ads, ads.gt_system_info, base + offsetof(struct __guc_ads_blob, system_info)); ads_blob_write(ads, ads.private_data, base + guc_ads_private_data_offset(ads)); } static void guc_populate_golden_lrc(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); struct xe_gt *gt = ads_to_gt(ads); struct iosys_map info_map = IOSYS_MAP_INIT_OFFSET(ads_to_map(ads), offsetof(struct __guc_ads_blob, system_info)); size_t total_size = 0, alloc_size, real_size; u32 addr_ggtt, offset; int class; offset = guc_ads_golden_lrc_offset(ads); addr_ggtt = xe_bo_ggtt_addr(ads->bo) + offset; for (class = 0; class < XE_ENGINE_CLASS_MAX; ++class) { u8 guc_class; guc_class = xe_engine_class_to_guc_class(class); if (!info_map_read(xe, &info_map, engine_enabled_masks[guc_class])) continue; xe_gt_assert(gt, gt->default_lrc[class]); real_size = xe_gt_lrc_size(gt, class); alloc_size = PAGE_ALIGN(real_size); total_size += alloc_size; /* * This interface is slightly confusing. We need to pass the * base address of the full golden context and the size of just * the engine state, which is the section of the context image * that starts after the execlists LRC registers. This is * required to allow the GuC to restore just the engine state * when a watchdog reset occurs. * We calculate the engine state size by removing the size of * what comes before it in the context image (which is identical * on all engines). */ ads_blob_write(ads, ads.eng_state_size[guc_class], real_size - xe_lrc_skip_size(xe)); ads_blob_write(ads, ads.golden_context_lrca[guc_class], addr_ggtt); xe_map_memcpy_to(xe, ads_to_map(ads), offset, gt->default_lrc[class], real_size); addr_ggtt += alloc_size; offset += alloc_size; } xe_gt_assert(gt, total_size == ads->golden_lrc_size); } void xe_guc_ads_populate_post_load(struct xe_guc_ads *ads) { guc_populate_golden_lrc(ads); } static int guc_ads_action_update_policies(struct xe_guc_ads *ads, u32 policy_offset) { struct xe_guc_ct *ct = &ads_to_guc(ads)->ct; u32 action[] = { XE_GUC_ACTION_GLOBAL_SCHED_POLICY_CHANGE, policy_offset }; return xe_guc_ct_send(ct, action, ARRAY_SIZE(action), 0, 0); } /** * xe_guc_ads_scheduler_policy_toggle_reset - Toggle reset policy * @ads: Additional data structures object * * This function update the GuC's engine reset policy based on wedged.mode. * * Return: 0 on success, and negative error code otherwise. */ int xe_guc_ads_scheduler_policy_toggle_reset(struct xe_guc_ads *ads) { struct xe_device *xe = ads_to_xe(ads); struct xe_gt *gt = ads_to_gt(ads); struct xe_tile *tile = gt_to_tile(gt); struct guc_policies *policies; struct xe_bo *bo; int ret = 0; policies = kmalloc(sizeof(*policies), GFP_KERNEL); if (!policies) return -ENOMEM; policies->dpc_promote_time = ads_blob_read(ads, policies.dpc_promote_time); policies->max_num_work_items = ads_blob_read(ads, policies.max_num_work_items); policies->is_valid = 1; if (xe->wedged.mode == 2) policies->global_flags |= GLOBAL_POLICY_DISABLE_ENGINE_RESET; else policies->global_flags &= ~GLOBAL_POLICY_DISABLE_ENGINE_RESET; bo = xe_managed_bo_create_from_data(xe, tile, policies, sizeof(struct guc_policies), XE_BO_FLAG_VRAM_IF_DGFX(tile) | XE_BO_FLAG_GGTT); if (IS_ERR(bo)) { ret = PTR_ERR(bo); goto out; } ret = guc_ads_action_update_policies(ads, xe_bo_ggtt_addr(bo)); out: kfree(policies); return ret; }
Information contained on this website is for historical information purposes only and does not indicate or represent copyright ownership.
Created with Cregit http://github.com/cregit/cregit
Version 2.0-RC1