| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Matthew Brost | 3915 | 43.78% | 9 | 13.85% |
| Matt Roper | 2447 | 27.36% | 15 | 23.08% |
| Niranjana Vishwanathapura | 721 | 8.06% | 5 | 7.69% |
| Umesh Nerlige Ramappa | 625 | 6.99% | 4 | 6.15% |
| Maarten Lankhorst | 494 | 5.52% | 3 | 4.62% |
| Michal Wajdeczko | 253 | 2.83% | 2 | 3.08% |
| Lucas De Marchi | 116 | 1.30% | 6 | 9.23% |
| Thomas Hellstrom | 89 | 1.00% | 2 | 3.08% |
| Ilia Levi | 88 | 0.98% | 3 | 4.62% |
| Daniele Ceraolo Spurio | 55 | 0.62% | 2 | 3.08% |
| Rodrigo Vivi | 34 | 0.38% | 1 | 1.54% |
| Matthew Auld | 25 | 0.28% | 3 | 4.62% |
| Tejas Upadhyay | 24 | 0.27% | 1 | 1.54% |
| Francois Dugast | 17 | 0.19% | 3 | 4.62% |
| Gustavo Sousa | 16 | 0.18% | 1 | 1.54% |
| Ashutosh Dixit | 11 | 0.12% | 1 | 1.54% |
| Brian Welty | 6 | 0.07% | 1 | 1.54% |
| Himal Prasad Ghimiray | 3 | 0.03% | 1 | 1.54% |
| Michał Winiarski | 3 | 0.03% | 1 | 1.54% |
| Dawei Li | 1 | 0.01% | 1 | 1.54% |
| Total | 8943 | 65 |
// SPDX-License-Identifier: MIT /* * Copyright © 2021 Intel Corporation */ #include "xe_lrc.h" #include <generated/xe_wa_oob.h> #include <linux/ascii85.h> #include "instructions/xe_mi_commands.h" #include "instructions/xe_gfxpipe_commands.h" #include "instructions/xe_gfx_state_commands.h" #include "regs/xe_engine_regs.h" #include "regs/xe_lrc_layout.h" #include "xe_bb.h" #include "xe_bo.h" #include "xe_device.h" #include "xe_drm_client.h" #include "xe_exec_queue_types.h" #include "xe_gt.h" #include "xe_gt_printk.h" #include "xe_hw_fence.h" #include "xe_map.h" #include "xe_memirq.h" #include "xe_mmio.h" #include "xe_sriov.h" #include "xe_trace_lrc.h" #include "xe_vm.h" #include "xe_wa.h" #define LRC_VALID BIT_ULL(0) #define LRC_PRIVILEGE BIT_ULL(8) #define LRC_ADDRESSING_MODE GENMASK_ULL(4, 3) #define LRC_LEGACY_64B_CONTEXT 3 #define LRC_ENGINE_CLASS GENMASK_ULL(63, 61) #define LRC_ENGINE_INSTANCE GENMASK_ULL(53, 48) #define LRC_PPHWSP_SIZE SZ_4K #define LRC_INDIRECT_RING_STATE_SIZE SZ_4K #define LRC_WA_BB_SIZE SZ_4K static struct xe_device * lrc_to_xe(struct xe_lrc *lrc) { return gt_to_xe(lrc->fence_ctx.gt); } size_t xe_gt_lrc_size(struct xe_gt *gt, enum xe_engine_class class) { struct xe_device *xe = gt_to_xe(gt); size_t size; /* Per-process HW status page (PPHWSP) */ size = LRC_PPHWSP_SIZE; /* Engine context image */ switch (class) { case XE_ENGINE_CLASS_RENDER: if (GRAPHICS_VER(xe) >= 20) size += 3 * SZ_4K; else size += 13 * SZ_4K; break; case XE_ENGINE_CLASS_COMPUTE: if (GRAPHICS_VER(xe) >= 20) size += 2 * SZ_4K; else size += 13 * SZ_4K; break; default: WARN(1, "Unknown engine class: %d", class); fallthrough; case XE_ENGINE_CLASS_COPY: case XE_ENGINE_CLASS_VIDEO_DECODE: case XE_ENGINE_CLASS_VIDEO_ENHANCE: case XE_ENGINE_CLASS_OTHER: size += 1 * SZ_4K; } /* Add indirect ring state page */ if (xe_gt_has_indirect_ring_state(gt)) size += LRC_INDIRECT_RING_STATE_SIZE; return size; } /* * The per-platform tables are u8-encoded in @data. Decode @data and set the * addresses' offset and commands in @regs. The following encoding is used * for each byte. There are 2 steps: decoding commands and decoding addresses. * * Commands: * [7]: create NOPs - number of NOPs are set in lower bits * [6]: When creating MI_LOAD_REGISTER_IMM command, allow to set * MI_LRI_FORCE_POSTED * [5:0]: Number of NOPs or registers to set values to in case of * MI_LOAD_REGISTER_IMM * * Addresses: these are decoded after a MI_LOAD_REGISTER_IMM command by "count" * number of registers. They are set by using the REG/REG16 macros: the former * is used for offsets smaller than 0x200 while the latter is for values bigger * than that. Those macros already set all the bits documented below correctly: * * [7]: When a register offset needs more than 6 bits, use additional bytes, to * follow, for the lower bits * [6:0]: Register offset, without considering the engine base. * * This function only tweaks the commands and register offsets. Values are not * filled out. */ static void set_offsets(u32 *regs, const u8 *data, const struct xe_hw_engine *hwe) #define NOP(x) (BIT(7) | (x)) #define LRI(count, flags) ((flags) << 6 | (count) | \ BUILD_BUG_ON_ZERO(count >= BIT(6))) #define POSTED BIT(0) #define REG(x) (((x) >> 2) | BUILD_BUG_ON_ZERO(x >= 0x200)) #define REG16(x) \ (((x) >> 9) | BIT(7) | BUILD_BUG_ON_ZERO(x >= 0x10000)), \ (((x) >> 2) & 0x7f) { const u32 base = hwe->mmio_base; while (*data) { u8 count, flags; if (*data & BIT(7)) { /* skip */ count = *data++ & ~BIT(7); regs += count; continue; } count = *data & 0x3f; flags = *data >> 6; data++; *regs = MI_LOAD_REGISTER_IMM | MI_LRI_NUM_REGS(count); if (flags & POSTED) *regs |= MI_LRI_FORCE_POSTED; *regs |= MI_LRI_LRM_CS_MMIO; regs++; xe_gt_assert(hwe->gt, count); do { u32 offset = 0; u8 v; do { v = *data++; offset <<= 7; offset |= v & ~BIT(7); } while (v & BIT(7)); regs[0] = base + (offset << 2); regs += 2; } while (--count); } *regs = MI_BATCH_BUFFER_END | BIT(0); } static const u8 gen12_xcs_offsets[] = { NOP(1), LRI(13, POSTED), REG16(0x244), REG(0x034), REG(0x030), REG(0x038), REG(0x03c), REG(0x168), REG(0x140), REG(0x110), REG(0x1c0), REG(0x1c4), REG(0x1c8), REG(0x180), REG16(0x2b4), NOP(5), LRI(9, POSTED), REG16(0x3a8), REG16(0x28c), REG16(0x288), REG16(0x284), REG16(0x280), REG16(0x27c), REG16(0x278), REG16(0x274), REG16(0x270), 0 }; static const u8 dg2_xcs_offsets[] = { NOP(1), LRI(15, POSTED), REG16(0x244), REG(0x034), REG(0x030), REG(0x038), REG(0x03c), REG(0x168), REG(0x140), REG(0x110), REG(0x1c0), REG(0x1c4), REG(0x1c8), REG(0x180), REG16(0x2b4), REG(0x120), REG(0x124), NOP(1), LRI(9, POSTED), REG16(0x3a8), REG16(0x28c), REG16(0x288), REG16(0x284), REG16(0x280), REG16(0x27c), REG16(0x278), REG16(0x274), REG16(0x270), 0 }; static const u8 gen12_rcs_offsets[] = { NOP(1), LRI(13, POSTED), REG16(0x244), REG(0x034), REG(0x030), REG(0x038), REG(0x03c), REG(0x168), REG(0x140), REG(0x110), REG(0x1c0), REG(0x1c4), REG(0x1c8), REG(0x180), REG16(0x2b4), NOP(5), LRI(9, POSTED), REG16(0x3a8), REG16(0x28c), REG16(0x288), REG16(0x284), REG16(0x280), REG16(0x27c), REG16(0x278), REG16(0x274), REG16(0x270), LRI(3, POSTED), REG(0x1b0), REG16(0x5a8), REG16(0x5ac), NOP(6), LRI(1, 0), REG(0x0c8), NOP(3 + 9 + 1), LRI(51, POSTED), REG16(0x588), REG16(0x588), REG16(0x588), REG16(0x588), REG16(0x588), REG16(0x588), REG(0x028), REG(0x09c), REG(0x0c0), REG(0x178), REG(0x17c), REG16(0x358), REG(0x170), REG(0x150), REG(0x154), REG(0x158), REG16(0x41c), REG16(0x600), REG16(0x604), REG16(0x608), REG16(0x60c), REG16(0x610), REG16(0x614), REG16(0x618), REG16(0x61c), REG16(0x620), REG16(0x624), REG16(0x628), REG16(0x62c), REG16(0x630), REG16(0x634), REG16(0x638), REG16(0x63c), REG16(0x640), REG16(0x644), REG16(0x648), REG16(0x64c), REG16(0x650), REG16(0x654), REG16(0x658), REG16(0x65c), REG16(0x660), REG16(0x664), REG16(0x668), REG16(0x66c), REG16(0x670), REG16(0x674), REG16(0x678), REG16(0x67c), REG(0x068), REG(0x084), NOP(1), 0 }; static const u8 xehp_rcs_offsets[] = { NOP(1), LRI(13, POSTED), REG16(0x244), REG(0x034), REG(0x030), REG(0x038), REG(0x03c), REG(0x168), REG(0x140), REG(0x110), REG(0x1c0), REG(0x1c4), REG(0x1c8), REG(0x180), REG16(0x2b4), NOP(5), LRI(9, POSTED), REG16(0x3a8), REG16(0x28c), REG16(0x288), REG16(0x284), REG16(0x280), REG16(0x27c), REG16(0x278), REG16(0x274), REG16(0x270), LRI(3, POSTED), REG(0x1b0), REG16(0x5a8), REG16(0x5ac), NOP(6), LRI(1, 0), REG(0x0c8), 0 }; static const u8 dg2_rcs_offsets[] = { NOP(1), LRI(15, POSTED), REG16(0x244), REG(0x034), REG(0x030), REG(0x038), REG(0x03c), REG(0x168), REG(0x140), REG(0x110), REG(0x1c0), REG(0x1c4), REG(0x1c8), REG(0x180), REG16(0x2b4), REG(0x120), REG(0x124), NOP(1), LRI(9, POSTED), REG16(0x3a8), REG16(0x28c), REG16(0x288), REG16(0x284), REG16(0x280), REG16(0x27c), REG16(0x278), REG16(0x274), REG16(0x270), LRI(3, POSTED), REG(0x1b0), REG16(0x5a8), REG16(0x5ac), NOP(6), LRI(1, 0), REG(0x0c8), 0 }; static const u8 mtl_rcs_offsets[] = { NOP(1), LRI(15, POSTED), REG16(0x244), REG(0x034), REG(0x030), REG(0x038), REG(0x03c), REG(0x168), REG(0x140), REG(0x110), REG(0x1c0), REG(0x1c4), REG(0x1c8), REG(0x180), REG16(0x2b4), REG(0x120), REG(0x124), NOP(1), LRI(9, POSTED), REG16(0x3a8), REG16(0x28c), REG16(0x288), REG16(0x284), REG16(0x280), REG16(0x27c), REG16(0x278), REG16(0x274), REG16(0x270), NOP(2), LRI(2, POSTED), REG16(0x5a8), REG16(0x5ac), NOP(6), LRI(1, 0), REG(0x0c8), 0 }; #define XE2_CTX_COMMON \ NOP(1), /* [0x00] */ \ LRI(15, POSTED), /* [0x01] */ \ REG16(0x244), /* [0x02] CTXT_SR_CTL */ \ REG(0x034), /* [0x04] RING_BUFFER_HEAD */ \ REG(0x030), /* [0x06] RING_BUFFER_TAIL */ \ REG(0x038), /* [0x08] RING_BUFFER_START */ \ REG(0x03c), /* [0x0a] RING_BUFFER_CONTROL */ \ REG(0x168), /* [0x0c] BB_ADDR_UDW */ \ REG(0x140), /* [0x0e] BB_ADDR */ \ REG(0x110), /* [0x10] BB_STATE */ \ REG(0x1c0), /* [0x12] BB_PER_CTX_PTR */ \ REG(0x1c4), /* [0x14] RCS_INDIRECT_CTX */ \ REG(0x1c8), /* [0x16] RCS_INDIRECT_CTX_OFFSET */ \ REG(0x180), /* [0x18] CCID */ \ REG16(0x2b4), /* [0x1a] SEMAPHORE_TOKEN */ \ REG(0x120), /* [0x1c] PRT_BB_STATE */ \ REG(0x124), /* [0x1e] PRT_BB_STATE_UDW */ \ \ NOP(1), /* [0x20] */ \ LRI(9, POSTED), /* [0x21] */ \ REG16(0x3a8), /* [0x22] CTX_TIMESTAMP */ \ REG16(0x3ac), /* [0x24] CTX_TIMESTAMP_UDW */ \ REG(0x108), /* [0x26] INDIRECT_RING_STATE */ \ REG16(0x284), /* [0x28] dummy reg */ \ REG16(0x280), /* [0x2a] CS_ACC_CTR_THOLD */ \ REG16(0x27c), /* [0x2c] CS_CTX_SYS_PASID */ \ REG16(0x278), /* [0x2e] CS_CTX_ASID */ \ REG16(0x274), /* [0x30] PTBP_UDW */ \ REG16(0x270) /* [0x32] PTBP_LDW */ static const u8 xe2_rcs_offsets[] = { XE2_CTX_COMMON, NOP(2), /* [0x34] */ LRI(2, POSTED), /* [0x36] */ REG16(0x5a8), /* [0x37] CONTEXT_SCHEDULING_ATTRIBUTES */ REG16(0x5ac), /* [0x39] PREEMPTION_STATUS */ NOP(6), /* [0x41] */ LRI(1, 0), /* [0x47] */ REG(0x0c8), /* [0x48] R_PWR_CLK_STATE */ 0 }; static const u8 xe2_bcs_offsets[] = { XE2_CTX_COMMON, NOP(4 + 8 + 1), /* [0x34] */ LRI(2, POSTED), /* [0x41] */ REG16(0x200), /* [0x42] BCS_SWCTRL */ REG16(0x204), /* [0x44] BLIT_CCTL */ 0 }; static const u8 xe2_xcs_offsets[] = { XE2_CTX_COMMON, 0 }; static const u8 xe2_indirect_ring_state_offsets[] = { NOP(1), /* [0x00] */ LRI(5, POSTED), /* [0x01] */ REG(0x034), /* [0x02] RING_BUFFER_HEAD */ REG(0x030), /* [0x04] RING_BUFFER_TAIL */ REG(0x038), /* [0x06] RING_BUFFER_START */ REG(0x048), /* [0x08] RING_BUFFER_START_UDW */ REG(0x03c), /* [0x0a] RING_BUFFER_CONTROL */ NOP(5), /* [0x0c] */ LRI(9, POSTED), /* [0x11] */ REG(0x168), /* [0x12] BB_ADDR_UDW */ REG(0x140), /* [0x14] BB_ADDR */ REG(0x110), /* [0x16] BB_STATE */ REG16(0x588), /* [0x18] BB_STACK_WRITE_PORT */ REG16(0x588), /* [0x20] BB_STACK_WRITE_PORT */ REG16(0x588), /* [0x22] BB_STACK_WRITE_PORT */ REG16(0x588), /* [0x24] BB_STACK_WRITE_PORT */ REG16(0x588), /* [0x26] BB_STACK_WRITE_PORT */ REG16(0x588), /* [0x28] BB_STACK_WRITE_PORT */ NOP(12), /* [0x00] */ 0 }; #undef REG16 #undef REG #undef LRI #undef NOP static const u8 *reg_offsets(struct xe_device *xe, enum xe_engine_class class) { if (class == XE_ENGINE_CLASS_RENDER) { if (GRAPHICS_VER(xe) >= 20) return xe2_rcs_offsets; else if (GRAPHICS_VERx100(xe) >= 1270) return mtl_rcs_offsets; else if (GRAPHICS_VERx100(xe) >= 1255) return dg2_rcs_offsets; else if (GRAPHICS_VERx100(xe) >= 1250) return xehp_rcs_offsets; else return gen12_rcs_offsets; } else if (class == XE_ENGINE_CLASS_COPY) { if (GRAPHICS_VER(xe) >= 20) return xe2_bcs_offsets; else return gen12_xcs_offsets; } else { if (GRAPHICS_VER(xe) >= 20) return xe2_xcs_offsets; else if (GRAPHICS_VERx100(xe) >= 1255) return dg2_xcs_offsets; else return gen12_xcs_offsets; } } static void set_context_control(u32 *regs, struct xe_hw_engine *hwe) { regs[CTX_CONTEXT_CONTROL] = _MASKED_BIT_ENABLE(CTX_CTRL_INHIBIT_SYN_CTX_SWITCH | CTX_CTRL_ENGINE_CTX_RESTORE_INHIBIT); if (xe_gt_has_indirect_ring_state(hwe->gt)) regs[CTX_CONTEXT_CONTROL] |= _MASKED_BIT_ENABLE(CTX_CTRL_INDIRECT_RING_STATE_ENABLE); /* TODO: Timestamp */ } static void set_memory_based_intr(u32 *regs, struct xe_hw_engine *hwe) { struct xe_memirq *memirq = >_to_tile(hwe->gt)->memirq; struct xe_device *xe = gt_to_xe(hwe->gt); u8 num_regs; if (!xe_device_uses_memirq(xe)) return; regs[CTX_LRM_INT_MASK_ENABLE] = MI_LOAD_REGISTER_MEM | MI_LRI_LRM_CS_MMIO | MI_LRM_USE_GGTT; regs[CTX_INT_MASK_ENABLE_REG] = RING_IMR(0).addr; regs[CTX_INT_MASK_ENABLE_PTR] = xe_memirq_enable_ptr(memirq); num_regs = xe_device_has_msix(xe) ? 3 : 2; regs[CTX_LRI_INT_REPORT_PTR] = MI_LOAD_REGISTER_IMM | MI_LRI_NUM_REGS(num_regs) | MI_LRI_LRM_CS_MMIO | MI_LRI_FORCE_POSTED; regs[CTX_INT_STATUS_REPORT_REG] = RING_INT_STATUS_RPT_PTR(0).addr; regs[CTX_INT_STATUS_REPORT_PTR] = xe_memirq_status_ptr(memirq, hwe); regs[CTX_INT_SRC_REPORT_REG] = RING_INT_SRC_RPT_PTR(0).addr; regs[CTX_INT_SRC_REPORT_PTR] = xe_memirq_source_ptr(memirq, hwe); if (xe_device_has_msix(xe)) { regs[CTX_CS_INT_VEC_REG] = CS_INT_VEC(0).addr; /* CTX_CS_INT_VEC_DATA will be set in xe_lrc_init */ } } static int lrc_ring_mi_mode(struct xe_hw_engine *hwe) { struct xe_device *xe = gt_to_xe(hwe->gt); if (GRAPHICS_VERx100(xe) >= 1250) return 0x70; else return 0x60; } static void reset_stop_ring(u32 *regs, struct xe_hw_engine *hwe) { int x; x = lrc_ring_mi_mode(hwe); regs[x + 1] &= ~STOP_RING; regs[x + 1] |= STOP_RING << 16; } static inline bool xe_lrc_has_indirect_ring_state(struct xe_lrc *lrc) { return lrc->flags & XE_LRC_FLAG_INDIRECT_RING_STATE; } static inline u32 __xe_lrc_ring_offset(struct xe_lrc *lrc) { return 0; } u32 xe_lrc_pphwsp_offset(struct xe_lrc *lrc) { return lrc->ring.size; } /* Make the magic macros work */ #define __xe_lrc_pphwsp_offset xe_lrc_pphwsp_offset #define __xe_lrc_regs_offset xe_lrc_regs_offset #define LRC_SEQNO_PPHWSP_OFFSET 512 #define LRC_START_SEQNO_PPHWSP_OFFSET (LRC_SEQNO_PPHWSP_OFFSET + 8) #define LRC_CTX_JOB_TIMESTAMP_OFFSET (LRC_START_SEQNO_PPHWSP_OFFSET + 8) #define LRC_PARALLEL_PPHWSP_OFFSET 2048 #define LRC_ENGINE_ID_PPHWSP_OFFSET 2096 u32 xe_lrc_regs_offset(struct xe_lrc *lrc) { return xe_lrc_pphwsp_offset(lrc) + LRC_PPHWSP_SIZE; } static size_t lrc_reg_size(struct xe_device *xe) { if (GRAPHICS_VERx100(xe) >= 1250) return 96 * sizeof(u32); else return 80 * sizeof(u32); } size_t xe_lrc_skip_size(struct xe_device *xe) { return LRC_PPHWSP_SIZE + lrc_reg_size(xe); } static inline u32 __xe_lrc_seqno_offset(struct xe_lrc *lrc) { /* The seqno is stored in the driver-defined portion of PPHWSP */ return xe_lrc_pphwsp_offset(lrc) + LRC_SEQNO_PPHWSP_OFFSET; } static inline u32 __xe_lrc_start_seqno_offset(struct xe_lrc *lrc) { /* The start seqno is stored in the driver-defined portion of PPHWSP */ return xe_lrc_pphwsp_offset(lrc) + LRC_START_SEQNO_PPHWSP_OFFSET; } static u32 __xe_lrc_ctx_job_timestamp_offset(struct xe_lrc *lrc) { /* This is stored in the driver-defined portion of PPHWSP */ return xe_lrc_pphwsp_offset(lrc) + LRC_CTX_JOB_TIMESTAMP_OFFSET; } static inline u32 __xe_lrc_parallel_offset(struct xe_lrc *lrc) { /* The parallel is stored in the driver-defined portion of PPHWSP */ return xe_lrc_pphwsp_offset(lrc) + LRC_PARALLEL_PPHWSP_OFFSET; } static inline u32 __xe_lrc_engine_id_offset(struct xe_lrc *lrc) { return xe_lrc_pphwsp_offset(lrc) + LRC_ENGINE_ID_PPHWSP_OFFSET; } static u32 __xe_lrc_ctx_timestamp_offset(struct xe_lrc *lrc) { return __xe_lrc_regs_offset(lrc) + CTX_TIMESTAMP * sizeof(u32); } static u32 __xe_lrc_ctx_timestamp_udw_offset(struct xe_lrc *lrc) { return __xe_lrc_regs_offset(lrc) + CTX_TIMESTAMP_UDW * sizeof(u32); } static inline u32 __xe_lrc_indirect_ring_offset(struct xe_lrc *lrc) { /* Indirect ring state page is at the very end of LRC */ return lrc->size - LRC_INDIRECT_RING_STATE_SIZE; } #define DECL_MAP_ADDR_HELPERS(elem) \ static inline struct iosys_map __xe_lrc_##elem##_map(struct xe_lrc *lrc) \ { \ struct iosys_map map = lrc->bo->vmap; \ \ xe_assert(lrc_to_xe(lrc), !iosys_map_is_null(&map)); \ iosys_map_incr(&map, __xe_lrc_##elem##_offset(lrc)); \ return map; \ } \ static inline u32 __maybe_unused __xe_lrc_##elem##_ggtt_addr(struct xe_lrc *lrc) \ { \ return xe_bo_ggtt_addr(lrc->bo) + __xe_lrc_##elem##_offset(lrc); \ } \ DECL_MAP_ADDR_HELPERS(ring) DECL_MAP_ADDR_HELPERS(pphwsp) DECL_MAP_ADDR_HELPERS(seqno) DECL_MAP_ADDR_HELPERS(regs) DECL_MAP_ADDR_HELPERS(start_seqno) DECL_MAP_ADDR_HELPERS(ctx_job_timestamp) DECL_MAP_ADDR_HELPERS(ctx_timestamp) DECL_MAP_ADDR_HELPERS(ctx_timestamp_udw) DECL_MAP_ADDR_HELPERS(parallel) DECL_MAP_ADDR_HELPERS(indirect_ring) DECL_MAP_ADDR_HELPERS(engine_id) #undef DECL_MAP_ADDR_HELPERS /** * xe_lrc_ctx_timestamp_ggtt_addr() - Get ctx timestamp GGTT address * @lrc: Pointer to the lrc. * * Returns: ctx timestamp GGTT address */ u32 xe_lrc_ctx_timestamp_ggtt_addr(struct xe_lrc *lrc) { return __xe_lrc_ctx_timestamp_ggtt_addr(lrc); } /** * xe_lrc_ctx_timestamp_udw_ggtt_addr() - Get ctx timestamp udw GGTT address * @lrc: Pointer to the lrc. * * Returns: ctx timestamp udw GGTT address */ u32 xe_lrc_ctx_timestamp_udw_ggtt_addr(struct xe_lrc *lrc) { return __xe_lrc_ctx_timestamp_udw_ggtt_addr(lrc); } /** * xe_lrc_ctx_timestamp() - Read ctx timestamp value * @lrc: Pointer to the lrc. * * Returns: ctx timestamp value */ u64 xe_lrc_ctx_timestamp(struct xe_lrc *lrc) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map map; u32 ldw, udw = 0; map = __xe_lrc_ctx_timestamp_map(lrc); ldw = xe_map_read32(xe, &map); if (xe->info.has_64bit_timestamp) { map = __xe_lrc_ctx_timestamp_udw_map(lrc); udw = xe_map_read32(xe, &map); } return (u64)udw << 32 | ldw; } /** * xe_lrc_ctx_job_timestamp_ggtt_addr() - Get ctx job timestamp GGTT address * @lrc: Pointer to the lrc. * * Returns: ctx timestamp job GGTT address */ u32 xe_lrc_ctx_job_timestamp_ggtt_addr(struct xe_lrc *lrc) { return __xe_lrc_ctx_job_timestamp_ggtt_addr(lrc); } /** * xe_lrc_ctx_job_timestamp() - Read ctx job timestamp value * @lrc: Pointer to the lrc. * * Returns: ctx timestamp job value */ u32 xe_lrc_ctx_job_timestamp(struct xe_lrc *lrc) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map map; map = __xe_lrc_ctx_job_timestamp_map(lrc); return xe_map_read32(xe, &map); } u32 xe_lrc_ggtt_addr(struct xe_lrc *lrc) { return __xe_lrc_pphwsp_ggtt_addr(lrc); } u32 xe_lrc_indirect_ring_ggtt_addr(struct xe_lrc *lrc) { if (!xe_lrc_has_indirect_ring_state(lrc)) return 0; return __xe_lrc_indirect_ring_ggtt_addr(lrc); } static u32 xe_lrc_read_indirect_ctx_reg(struct xe_lrc *lrc, int reg_nr) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map map; map = __xe_lrc_indirect_ring_map(lrc); iosys_map_incr(&map, reg_nr * sizeof(u32)); return xe_map_read32(xe, &map); } static void xe_lrc_write_indirect_ctx_reg(struct xe_lrc *lrc, int reg_nr, u32 val) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map map; map = __xe_lrc_indirect_ring_map(lrc); iosys_map_incr(&map, reg_nr * sizeof(u32)); xe_map_write32(xe, &map, val); } u32 xe_lrc_read_ctx_reg(struct xe_lrc *lrc, int reg_nr) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map map; map = __xe_lrc_regs_map(lrc); iosys_map_incr(&map, reg_nr * sizeof(u32)); return xe_map_read32(xe, &map); } void xe_lrc_write_ctx_reg(struct xe_lrc *lrc, int reg_nr, u32 val) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map map; map = __xe_lrc_regs_map(lrc); iosys_map_incr(&map, reg_nr * sizeof(u32)); xe_map_write32(xe, &map, val); } static void *empty_lrc_data(struct xe_hw_engine *hwe) { struct xe_gt *gt = hwe->gt; void *data; u32 *regs; data = kzalloc(xe_gt_lrc_size(gt, hwe->class), GFP_KERNEL); if (!data) return NULL; /* 1st page: Per-Process of HW status Page */ regs = data + LRC_PPHWSP_SIZE; set_offsets(regs, reg_offsets(gt_to_xe(gt), hwe->class), hwe); set_context_control(regs, hwe); set_memory_based_intr(regs, hwe); reset_stop_ring(regs, hwe); if (xe_gt_has_indirect_ring_state(gt)) { regs = data + xe_gt_lrc_size(gt, hwe->class) - LRC_INDIRECT_RING_STATE_SIZE; set_offsets(regs, xe2_indirect_ring_state_offsets, hwe); } return data; } static void xe_lrc_set_ppgtt(struct xe_lrc *lrc, struct xe_vm *vm) { u64 desc = xe_vm_pdp4_descriptor(vm, gt_to_tile(lrc->gt)); xe_lrc_write_ctx_reg(lrc, CTX_PDP0_UDW, upper_32_bits(desc)); xe_lrc_write_ctx_reg(lrc, CTX_PDP0_LDW, lower_32_bits(desc)); } static void xe_lrc_finish(struct xe_lrc *lrc) { xe_hw_fence_ctx_finish(&lrc->fence_ctx); xe_bo_unpin_map_no_vm(lrc->bo); } static size_t wa_bb_offset(struct xe_lrc *lrc) { return lrc->bo->size - LRC_WA_BB_SIZE; } /* * xe_lrc_setup_utilization() - Setup wa bb to assist in calculating active * context run ticks. * @lrc: Pointer to the lrc. * * Context Timestamp (CTX_TIMESTAMP) in the LRC accumulates the run ticks of the * context, but only gets updated when the context switches out. In order to * check how long a context has been active before it switches out, two things * are required: * * (1) Determine if the context is running: * To do so, we program the WA BB to set an initial value for CTX_TIMESTAMP in * the LRC. The value chosen is 1 since 0 is the initial value when the LRC is * initialized. During a query, we just check for this value to determine if the * context is active. If the context switched out, it would overwrite this * location with the actual CTX_TIMESTAMP MMIO value. Note that WA BB runs as * the last part of context restore, so reusing this LRC location will not * clobber anything. * * (2) Calculate the time that the context has been active for: * The CTX_TIMESTAMP ticks only when the context is active. If a context is * active, we just use the CTX_TIMESTAMP MMIO as the new value of utilization. * While doing so, we need to read the CTX_TIMESTAMP MMIO for the specific * engine instance. Since we do not know which instance the context is running * on until it is scheduled, we also read the ENGINE_ID MMIO in the WA BB and * store it in the PPHSWP. */ #define CONTEXT_ACTIVE 1ULL static int xe_lrc_setup_utilization(struct xe_lrc *lrc) { const size_t max_size = LRC_WA_BB_SIZE; u32 *cmd, *buf = NULL; if (lrc->bo->vmap.is_iomem) { buf = kmalloc(max_size, GFP_KERNEL); if (!buf) return -ENOMEM; cmd = buf; } else { cmd = lrc->bo->vmap.vaddr + wa_bb_offset(lrc); } *cmd++ = MI_STORE_REGISTER_MEM | MI_SRM_USE_GGTT | MI_SRM_ADD_CS_OFFSET; *cmd++ = ENGINE_ID(0).addr; *cmd++ = __xe_lrc_engine_id_ggtt_addr(lrc); *cmd++ = 0; *cmd++ = MI_STORE_DATA_IMM | MI_SDI_GGTT | MI_SDI_NUM_DW(1); *cmd++ = __xe_lrc_ctx_timestamp_ggtt_addr(lrc); *cmd++ = 0; *cmd++ = lower_32_bits(CONTEXT_ACTIVE); if (lrc_to_xe(lrc)->info.has_64bit_timestamp) { *cmd++ = MI_STORE_DATA_IMM | MI_SDI_GGTT | MI_SDI_NUM_DW(1); *cmd++ = __xe_lrc_ctx_timestamp_udw_ggtt_addr(lrc); *cmd++ = 0; *cmd++ = upper_32_bits(CONTEXT_ACTIVE); } *cmd++ = MI_BATCH_BUFFER_END; if (buf) { xe_map_memcpy_to(gt_to_xe(lrc->gt), &lrc->bo->vmap, wa_bb_offset(lrc), buf, (cmd - buf) * sizeof(*cmd)); kfree(buf); } xe_lrc_write_ctx_reg(lrc, CTX_BB_PER_CTX_PTR, xe_bo_ggtt_addr(lrc->bo) + wa_bb_offset(lrc) + 1); return 0; } #define PVC_CTX_ASID (0x2e + 1) #define PVC_CTX_ACC_CTR_THOLD (0x2a + 1) static int xe_lrc_init(struct xe_lrc *lrc, struct xe_hw_engine *hwe, struct xe_vm *vm, u32 ring_size, u16 msix_vec, u32 init_flags) { struct xe_gt *gt = hwe->gt; struct xe_tile *tile = gt_to_tile(gt); struct xe_device *xe = gt_to_xe(gt); struct iosys_map map; void *init_data = NULL; u32 arb_enable; u32 lrc_size; u32 bo_flags; int err; kref_init(&lrc->refcount); lrc->gt = gt; lrc->flags = 0; lrc_size = ring_size + xe_gt_lrc_size(gt, hwe->class); if (xe_gt_has_indirect_ring_state(gt)) lrc->flags |= XE_LRC_FLAG_INDIRECT_RING_STATE; bo_flags = XE_BO_FLAG_VRAM_IF_DGFX(tile) | XE_BO_FLAG_GGTT | XE_BO_FLAG_GGTT_INVALIDATE; if (vm && vm->xef) /* userspace */ bo_flags |= XE_BO_FLAG_PINNED_LATE_RESTORE; /* * FIXME: Perma-pinning LRC as we don't yet support moving GGTT address * via VM bind calls. */ lrc->bo = xe_bo_create_pin_map(xe, tile, NULL, lrc_size + LRC_WA_BB_SIZE, ttm_bo_type_kernel, bo_flags); if (IS_ERR(lrc->bo)) return PTR_ERR(lrc->bo); lrc->size = lrc_size; lrc->ring.size = ring_size; lrc->ring.tail = 0; xe_hw_fence_ctx_init(&lrc->fence_ctx, hwe->gt, hwe->fence_irq, hwe->name); if (!gt->default_lrc[hwe->class]) { init_data = empty_lrc_data(hwe); if (!init_data) { err = -ENOMEM; goto err_lrc_finish; } } /* * Init Per-Process of HW status Page, LRC / context state to known * values */ map = __xe_lrc_pphwsp_map(lrc); if (!init_data) { xe_map_memset(xe, &map, 0, 0, LRC_PPHWSP_SIZE); /* PPHWSP */ xe_map_memcpy_to(xe, &map, LRC_PPHWSP_SIZE, gt->default_lrc[hwe->class] + LRC_PPHWSP_SIZE, xe_gt_lrc_size(gt, hwe->class) - LRC_PPHWSP_SIZE); } else { xe_map_memcpy_to(xe, &map, 0, init_data, xe_gt_lrc_size(gt, hwe->class)); kfree(init_data); } if (vm) { xe_lrc_set_ppgtt(lrc, vm); if (vm->xef) xe_drm_client_add_bo(vm->xef->client, lrc->bo); } if (xe_device_has_msix(xe)) { xe_lrc_write_ctx_reg(lrc, CTX_INT_STATUS_REPORT_PTR, xe_memirq_status_ptr(&tile->memirq, hwe)); xe_lrc_write_ctx_reg(lrc, CTX_INT_SRC_REPORT_PTR, xe_memirq_source_ptr(&tile->memirq, hwe)); xe_lrc_write_ctx_reg(lrc, CTX_CS_INT_VEC_DATA, msix_vec << 16 | msix_vec); } if (xe_gt_has_indirect_ring_state(gt)) { xe_lrc_write_ctx_reg(lrc, CTX_INDIRECT_RING_STATE, __xe_lrc_indirect_ring_ggtt_addr(lrc)); xe_lrc_write_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_START, __xe_lrc_ring_ggtt_addr(lrc)); xe_lrc_write_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_START_UDW, 0); xe_lrc_write_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_HEAD, 0); xe_lrc_write_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_TAIL, lrc->ring.tail); xe_lrc_write_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_CTL, RING_CTL_SIZE(lrc->ring.size) | RING_VALID); } else { xe_lrc_write_ctx_reg(lrc, CTX_RING_START, __xe_lrc_ring_ggtt_addr(lrc)); xe_lrc_write_ctx_reg(lrc, CTX_RING_HEAD, 0); xe_lrc_write_ctx_reg(lrc, CTX_RING_TAIL, lrc->ring.tail); xe_lrc_write_ctx_reg(lrc, CTX_RING_CTL, RING_CTL_SIZE(lrc->ring.size) | RING_VALID); } if (init_flags & XE_LRC_CREATE_RUNALONE) xe_lrc_write_ctx_reg(lrc, CTX_CONTEXT_CONTROL, xe_lrc_read_ctx_reg(lrc, CTX_CONTEXT_CONTROL) | _MASKED_BIT_ENABLE(CTX_CTRL_RUN_ALONE)); if (init_flags & XE_LRC_CREATE_PXP) xe_lrc_write_ctx_reg(lrc, CTX_CONTEXT_CONTROL, xe_lrc_read_ctx_reg(lrc, CTX_CONTEXT_CONTROL) | _MASKED_BIT_ENABLE(CTX_CTRL_PXP_ENABLE)); lrc->ctx_timestamp = 0; xe_lrc_write_ctx_reg(lrc, CTX_TIMESTAMP, 0); if (lrc_to_xe(lrc)->info.has_64bit_timestamp) xe_lrc_write_ctx_reg(lrc, CTX_TIMESTAMP_UDW, 0); if (xe->info.has_asid && vm) xe_lrc_write_ctx_reg(lrc, PVC_CTX_ASID, vm->usm.asid); lrc->desc = LRC_VALID; lrc->desc |= FIELD_PREP(LRC_ADDRESSING_MODE, LRC_LEGACY_64B_CONTEXT); /* TODO: Priority */ /* While this appears to have something about privileged batches or * some such, it really just means PPGTT mode. */ if (vm) lrc->desc |= LRC_PRIVILEGE; if (GRAPHICS_VERx100(xe) < 1250) { lrc->desc |= FIELD_PREP(LRC_ENGINE_INSTANCE, hwe->instance); lrc->desc |= FIELD_PREP(LRC_ENGINE_CLASS, hwe->class); } arb_enable = MI_ARB_ON_OFF | MI_ARB_ENABLE; xe_lrc_write_ring(lrc, &arb_enable, sizeof(arb_enable)); map = __xe_lrc_seqno_map(lrc); xe_map_write32(lrc_to_xe(lrc), &map, lrc->fence_ctx.next_seqno - 1); map = __xe_lrc_start_seqno_map(lrc); xe_map_write32(lrc_to_xe(lrc), &map, lrc->fence_ctx.next_seqno - 1); err = xe_lrc_setup_utilization(lrc); if (err) goto err_lrc_finish; return 0; err_lrc_finish: xe_lrc_finish(lrc); return err; } /** * xe_lrc_create - Create a LRC * @hwe: Hardware Engine * @vm: The VM (address space) * @ring_size: LRC ring size * @msix_vec: MSI-X interrupt vector (for platforms that support it) * @flags: LRC initialization flags * * Allocate and initialize the Logical Ring Context (LRC). * * Return pointer to created LRC upon success and an error pointer * upon failure. */ struct xe_lrc *xe_lrc_create(struct xe_hw_engine *hwe, struct xe_vm *vm, u32 ring_size, u16 msix_vec, u32 flags) { struct xe_lrc *lrc; int err; lrc = kzalloc(sizeof(*lrc), GFP_KERNEL); if (!lrc) return ERR_PTR(-ENOMEM); err = xe_lrc_init(lrc, hwe, vm, ring_size, msix_vec, flags); if (err) { kfree(lrc); return ERR_PTR(err); } return lrc; } /** * xe_lrc_destroy - Destroy the LRC * @ref: reference to LRC * * Called when ref == 0, release resources held by the Logical Ring Context * (LRC) and free the LRC memory. */ void xe_lrc_destroy(struct kref *ref) { struct xe_lrc *lrc = container_of(ref, struct xe_lrc, refcount); xe_lrc_finish(lrc); kfree(lrc); } void xe_lrc_set_ring_tail(struct xe_lrc *lrc, u32 tail) { if (xe_lrc_has_indirect_ring_state(lrc)) xe_lrc_write_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_TAIL, tail); else xe_lrc_write_ctx_reg(lrc, CTX_RING_TAIL, tail); } u32 xe_lrc_ring_tail(struct xe_lrc *lrc) { if (xe_lrc_has_indirect_ring_state(lrc)) return xe_lrc_read_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_TAIL) & TAIL_ADDR; else return xe_lrc_read_ctx_reg(lrc, CTX_RING_TAIL) & TAIL_ADDR; } static u32 xe_lrc_ring_start(struct xe_lrc *lrc) { if (xe_lrc_has_indirect_ring_state(lrc)) return xe_lrc_read_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_START); else return xe_lrc_read_ctx_reg(lrc, CTX_RING_START); } void xe_lrc_set_ring_head(struct xe_lrc *lrc, u32 head) { if (xe_lrc_has_indirect_ring_state(lrc)) xe_lrc_write_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_HEAD, head); else xe_lrc_write_ctx_reg(lrc, CTX_RING_HEAD, head); } u32 xe_lrc_ring_head(struct xe_lrc *lrc) { if (xe_lrc_has_indirect_ring_state(lrc)) return xe_lrc_read_indirect_ctx_reg(lrc, INDIRECT_CTX_RING_HEAD) & HEAD_ADDR; else return xe_lrc_read_ctx_reg(lrc, CTX_RING_HEAD) & HEAD_ADDR; } u32 xe_lrc_ring_space(struct xe_lrc *lrc) { const u32 head = xe_lrc_ring_head(lrc); const u32 tail = lrc->ring.tail; const u32 size = lrc->ring.size; return ((head - tail - 1) & (size - 1)) + 1; } static void __xe_lrc_write_ring(struct xe_lrc *lrc, struct iosys_map ring, const void *data, size_t size) { struct xe_device *xe = lrc_to_xe(lrc); iosys_map_incr(&ring, lrc->ring.tail); xe_map_memcpy_to(xe, &ring, 0, data, size); lrc->ring.tail = (lrc->ring.tail + size) & (lrc->ring.size - 1); } void xe_lrc_write_ring(struct xe_lrc *lrc, const void *data, size_t size) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map ring; u32 rhs; size_t aligned_size; xe_assert(xe, IS_ALIGNED(size, 4)); aligned_size = ALIGN(size, 8); ring = __xe_lrc_ring_map(lrc); xe_assert(xe, lrc->ring.tail < lrc->ring.size); rhs = lrc->ring.size - lrc->ring.tail; if (size > rhs) { __xe_lrc_write_ring(lrc, ring, data, rhs); __xe_lrc_write_ring(lrc, ring, data + rhs, size - rhs); } else { __xe_lrc_write_ring(lrc, ring, data, size); } if (aligned_size > size) { u32 noop = MI_NOOP; __xe_lrc_write_ring(lrc, ring, &noop, sizeof(noop)); } } u64 xe_lrc_descriptor(struct xe_lrc *lrc) { return lrc->desc | xe_lrc_ggtt_addr(lrc); } u32 xe_lrc_seqno_ggtt_addr(struct xe_lrc *lrc) { return __xe_lrc_seqno_ggtt_addr(lrc); } /** * xe_lrc_alloc_seqno_fence() - Allocate an lrc seqno fence. * * Allocate but don't initialize an lrc seqno fence. * * Return: Pointer to the allocated fence or * negative error pointer on error. */ struct dma_fence *xe_lrc_alloc_seqno_fence(void) { return xe_hw_fence_alloc(); } /** * xe_lrc_free_seqno_fence() - Free an lrc seqno fence. * @fence: Pointer to the fence to free. * * Frees an lrc seqno fence that hasn't yet been * initialized. */ void xe_lrc_free_seqno_fence(struct dma_fence *fence) { xe_hw_fence_free(fence); } /** * xe_lrc_init_seqno_fence() - Initialize an lrc seqno fence. * @lrc: Pointer to the lrc. * @fence: Pointer to the fence to initialize. * * Initializes a pre-allocated lrc seqno fence. * After initialization, the fence is subject to normal * dma-fence refcounting. */ void xe_lrc_init_seqno_fence(struct xe_lrc *lrc, struct dma_fence *fence) { xe_hw_fence_init(fence, &lrc->fence_ctx, __xe_lrc_seqno_map(lrc)); } s32 xe_lrc_seqno(struct xe_lrc *lrc) { struct iosys_map map = __xe_lrc_seqno_map(lrc); return xe_map_read32(lrc_to_xe(lrc), &map); } s32 xe_lrc_start_seqno(struct xe_lrc *lrc) { struct iosys_map map = __xe_lrc_start_seqno_map(lrc); return xe_map_read32(lrc_to_xe(lrc), &map); } u32 xe_lrc_start_seqno_ggtt_addr(struct xe_lrc *lrc) { return __xe_lrc_start_seqno_ggtt_addr(lrc); } u32 xe_lrc_parallel_ggtt_addr(struct xe_lrc *lrc) { return __xe_lrc_parallel_ggtt_addr(lrc); } struct iosys_map xe_lrc_parallel_map(struct xe_lrc *lrc) { return __xe_lrc_parallel_map(lrc); } /** * xe_lrc_engine_id() - Read engine id value * @lrc: Pointer to the lrc. * * Returns: context id value */ static u32 xe_lrc_engine_id(struct xe_lrc *lrc) { struct xe_device *xe = lrc_to_xe(lrc); struct iosys_map map; map = __xe_lrc_engine_id_map(lrc); return xe_map_read32(xe, &map); } static int instr_dw(u32 cmd_header) { /* GFXPIPE "SINGLE_DW" opcodes are a single dword */ if ((cmd_header & (XE_INSTR_CMD_TYPE | GFXPIPE_PIPELINE)) == GFXPIPE_SINGLE_DW_CMD(0, 0)) return 1; /* 3DSTATE_SO_DECL_LIST has a 9-bit dword length rather than 8 */ if ((cmd_header & GFXPIPE_MATCH_MASK) == CMD_3DSTATE_SO_DECL_LIST) return REG_FIELD_GET(CMD_3DSTATE_SO_DECL_LIST_DW_LEN, cmd_header) + 2; /* Most instructions have the # of dwords (minus 2) in 7:0 */ return REG_FIELD_GET(XE_INSTR_LEN_MASK, cmd_header) + 2; } static int dump_mi_command(struct drm_printer *p, struct xe_gt *gt, u32 *dw, int remaining_dw) { u32 inst_header = *dw; u32 numdw = instr_dw(inst_header); u32 opcode = REG_FIELD_GET(MI_OPCODE, inst_header); int num_noop; /* First check for commands that don't have/use a '# DW' field */ switch (inst_header & MI_OPCODE) { case MI_NOOP: num_noop = 1; while (num_noop < remaining_dw && (*(++dw) & REG_GENMASK(31, 23)) == MI_NOOP) num_noop++; drm_printf(p, "[%#010x] MI_NOOP (%d dwords)\n", inst_header, num_noop); return num_noop; case MI_TOPOLOGY_FILTER: drm_printf(p, "[%#010x] MI_TOPOLOGY_FILTER\n", inst_header); return 1; case MI_BATCH_BUFFER_END: drm_printf(p, "[%#010x] MI_BATCH_BUFFER_END\n", inst_header); /* Return 'remaining_dw' to consume the rest of the LRC */ return remaining_dw; } /* * Any remaining commands include a # of dwords. We should make sure * it doesn't exceed the remaining size of the LRC. */ if (xe_gt_WARN_ON(gt, numdw > remaining_dw)) numdw = remaining_dw; switch (inst_header & MI_OPCODE) { case MI_LOAD_REGISTER_IMM: drm_printf(p, "[%#010x] MI_LOAD_REGISTER_IMM: %d regs\n", inst_header, (numdw - 1) / 2); for (int i = 1; i < numdw; i += 2) drm_printf(p, " - %#6x = %#010x\n", dw[i], dw[i + 1]); return numdw; case MI_LOAD_REGISTER_MEM & MI_OPCODE: drm_printf(p, "[%#010x] MI_LOAD_REGISTER_MEM: %s%s\n", inst_header, dw[0] & MI_LRI_LRM_CS_MMIO ? "CS_MMIO " : "", dw[0] & MI_LRM_USE_GGTT ? "USE_GGTT " : ""); if (numdw == 4) drm_printf(p, " - %#6x = %#010llx\n", dw[1], ((u64)(dw[3]) << 32 | (u64)(dw[2]))); else drm_printf(p, " - %*ph (%s)\n", (int)sizeof(u32) * (numdw - 1), dw + 1, numdw < 4 ? "truncated" : "malformed"); return numdw; case MI_FORCE_WAKEUP: drm_printf(p, "[%#010x] MI_FORCE_WAKEUP\n", inst_header); return numdw; default: drm_printf(p, "[%#010x] unknown MI opcode %#x, likely %d dwords\n", inst_header, opcode, numdw); return numdw; } } static int dump_gfxpipe_command(struct drm_printer *p, struct xe_gt *gt, u32 *dw, int remaining_dw) { u32 numdw = instr_dw(*dw); u32 pipeline = REG_FIELD_GET(GFXPIPE_PIPELINE, *dw); u32 opcode = REG_FIELD_GET(GFXPIPE_OPCODE, *dw); u32 subopcode = REG_FIELD_GET(GFXPIPE_SUBOPCODE, *dw); /* * Make sure we haven't mis-parsed a number of dwords that exceeds the * remaining size of the LRC. */ if (xe_gt_WARN_ON(gt, numdw > remaining_dw)) numdw = remaining_dw; switch (*dw & GFXPIPE_MATCH_MASK) { #define MATCH(cmd) \ case cmd: \ drm_printf(p, "[%#010x] " #cmd " (%d dwords)\n", *dw, numdw); \ return numdw #define MATCH3D(cmd) \ case CMD_##cmd: \ drm_printf(p, "[%#010x] " #cmd " (%d dwords)\n", *dw, numdw); \ return numdw MATCH(STATE_BASE_ADDRESS); MATCH(STATE_SIP); MATCH(GPGPU_CSR_BASE_ADDRESS); MATCH(STATE_COMPUTE_MODE); MATCH3D(3DSTATE_BTD); MATCH(STATE_SYSTEM_MEM_FENCE_ADDRESS); MATCH(STATE_CONTEXT_DATA_BASE_ADDRESS); MATCH3D(3DSTATE_VF_STATISTICS); MATCH(PIPELINE_SELECT); MATCH3D(3DSTATE_DRAWING_RECTANGLE_FAST); MATCH3D(3DSTATE_CLEAR_PARAMS); MATCH3D(3DSTATE_DEPTH_BUFFER); MATCH3D(3DSTATE_STENCIL_BUFFER); MATCH3D(3DSTATE_HIER_DEPTH_BUFFER); MATCH3D(3DSTATE_VERTEX_BUFFERS); MATCH3D(3DSTATE_VERTEX_ELEMENTS); MATCH3D(3DSTATE_INDEX_BUFFER); MATCH3D(3DSTATE_VF); MATCH3D(3DSTATE_MULTISAMPLE); MATCH3D(3DSTATE_CC_STATE_POINTERS); MATCH3D(3DSTATE_SCISSOR_STATE_POINTERS); MATCH3D(3DSTATE_VS); MATCH3D(3DSTATE_GS); MATCH3D(3DSTATE_CLIP); MATCH3D(3DSTATE_SF); MATCH3D(3DSTATE_WM); MATCH3D(3DSTATE_CONSTANT_VS); MATCH3D(3DSTATE_CONSTANT_GS); MATCH3D(3DSTATE_CONSTANT_PS); MATCH3D(3DSTATE_SAMPLE_MASK); MATCH3D(3DSTATE_CONSTANT_HS); MATCH3D(3DSTATE_CONSTANT_DS); MATCH3D(3DSTATE_HS); MATCH3D(3DSTATE_TE); MATCH3D(3DSTATE_DS); MATCH3D(3DSTATE_STREAMOUT); MATCH3D(3DSTATE_SBE); MATCH3D(3DSTATE_PS); MATCH3D(3DSTATE_VIEWPORT_STATE_POINTERS_SF_CLIP); MATCH3D(3DSTATE_CPS_POINTERS); MATCH3D(3DSTATE_VIEWPORT_STATE_POINTERS_CC); MATCH3D(3DSTATE_BLEND_STATE_POINTERS); MATCH3D(3DSTATE_BINDING_TABLE_POINTERS_VS); MATCH3D(3DSTATE_BINDING_TABLE_POINTERS_HS); MATCH3D(3DSTATE_BINDING_TABLE_POINTERS_DS); MATCH3D(3DSTATE_BINDING_TABLE_POINTERS_GS); MATCH3D(3DSTATE_BINDING_TABLE_POINTERS_PS); MATCH3D(3DSTATE_SAMPLER_STATE_POINTERS_VS); MATCH3D(3DSTATE_SAMPLER_STATE_POINTERS_HS); MATCH3D(3DSTATE_SAMPLER_STATE_POINTERS_DS); MATCH3D(3DSTATE_SAMPLER_STATE_POINTERS_GS); MATCH3D(3DSTATE_SAMPLER_STATE_POINTERS_PS); MATCH3D(3DSTATE_VF_INSTANCING); MATCH3D(3DSTATE_VF_SGVS); MATCH3D(3DSTATE_VF_TOPOLOGY); MATCH3D(3DSTATE_WM_CHROMAKEY); MATCH3D(3DSTATE_PS_BLEND); MATCH3D(3DSTATE_WM_DEPTH_STENCIL); MATCH3D(3DSTATE_PS_EXTRA); MATCH3D(3DSTATE_RASTER); MATCH3D(3DSTATE_SBE_SWIZ); MATCH3D(3DSTATE_WM_HZ_OP); MATCH3D(3DSTATE_VF_COMPONENT_PACKING); MATCH3D(3DSTATE_VF_SGVS_2); MATCH3D(3DSTATE_VFG); MATCH3D(3DSTATE_URB_ALLOC_VS); MATCH3D(3DSTATE_URB_ALLOC_HS); MATCH3D(3DSTATE_URB_ALLOC_DS); MATCH3D(3DSTATE_URB_ALLOC_GS); MATCH3D(3DSTATE_SO_BUFFER_INDEX_0); MATCH3D(3DSTATE_SO_BUFFER_INDEX_1); MATCH3D(3DSTATE_SO_BUFFER_INDEX_2); MATCH3D(3DSTATE_SO_BUFFER_INDEX_3); MATCH3D(3DSTATE_PRIMITIVE_REPLICATION); MATCH3D(3DSTATE_TBIMR_TILE_PASS_INFO); MATCH3D(3DSTATE_AMFS); MATCH3D(3DSTATE_DEPTH_BOUNDS); MATCH3D(3DSTATE_AMFS_TEXTURE_POINTERS); MATCH3D(3DSTATE_CONSTANT_TS_POINTER); MATCH3D(3DSTATE_MESH_CONTROL); MATCH3D(3DSTATE_MESH_DISTRIB); MATCH3D(3DSTATE_TASK_REDISTRIB); MATCH3D(3DSTATE_MESH_SHADER); MATCH3D(3DSTATE_MESH_SHADER_DATA); MATCH3D(3DSTATE_TASK_CONTROL); MATCH3D(3DSTATE_TASK_SHADER); MATCH3D(3DSTATE_TASK_SHADER_DATA); MATCH3D(3DSTATE_URB_ALLOC_MESH); MATCH3D(3DSTATE_URB_ALLOC_TASK); MATCH3D(3DSTATE_CLIP_MESH); MATCH3D(3DSTATE_SBE_MESH); MATCH3D(3DSTATE_CPSIZE_CONTROL_BUFFER); MATCH3D(3DSTATE_COARSE_PIXEL); MATCH3D(3DSTATE_DRAWING_RECTANGLE); MATCH3D(3DSTATE_CHROMA_KEY); MATCH3D(3DSTATE_POLY_STIPPLE_OFFSET); MATCH3D(3DSTATE_POLY_STIPPLE_PATTERN); MATCH3D(3DSTATE_LINE_STIPPLE); MATCH3D(3DSTATE_AA_LINE_PARAMETERS); MATCH3D(3DSTATE_MONOFILTER_SIZE); MATCH3D(3DSTATE_PUSH_CONSTANT_ALLOC_VS); MATCH3D(3DSTATE_PUSH_CONSTANT_ALLOC_HS); MATCH3D(3DSTATE_PUSH_CONSTANT_ALLOC_DS); MATCH3D(3DSTATE_PUSH_CONSTANT_ALLOC_GS); MATCH3D(3DSTATE_PUSH_CONSTANT_ALLOC_PS); MATCH3D(3DSTATE_SO_DECL_LIST); MATCH3D(3DSTATE_SO_BUFFER); MATCH3D(3DSTATE_BINDING_TABLE_POOL_ALLOC); MATCH3D(3DSTATE_SAMPLE_PATTERN); MATCH3D(3DSTATE_3D_MODE); MATCH3D(3DSTATE_SUBSLICE_HASH_TABLE); MATCH3D(3DSTATE_SLICE_TABLE_STATE_POINTERS); MATCH3D(3DSTATE_PTBR_TILE_PASS_INFO); default: drm_printf(p, "[%#010x] unknown GFXPIPE command (pipeline=%#x, opcode=%#x, subopcode=%#x), likely %d dwords\n", *dw, pipeline, opcode, subopcode, numdw); return numdw; } } static int dump_gfx_state_command(struct drm_printer *p, struct xe_gt *gt, u32 *dw, int remaining_dw) { u32 numdw = instr_dw(*dw); u32 opcode = REG_FIELD_GET(GFX_STATE_OPCODE, *dw); /* * Make sure we haven't mis-parsed a number of dwords that exceeds the * remaining size of the LRC. */ if (xe_gt_WARN_ON(gt, numdw > remaining_dw)) numdw = remaining_dw; switch (*dw & (XE_INSTR_GFX_STATE | GFX_STATE_OPCODE)) { MATCH(STATE_WRITE_INLINE); default: drm_printf(p, "[%#010x] unknown GFX_STATE command (opcode=%#x), likely %d dwords\n", *dw, opcode, numdw); return numdw; } } void xe_lrc_dump_default(struct drm_printer *p, struct xe_gt *gt, enum xe_engine_class hwe_class) { u32 *dw; int remaining_dw, num_dw; if (!gt->default_lrc[hwe_class]) { drm_printf(p, "No default LRC for class %d\n", hwe_class); return; } /* * Skip the beginning of the LRC since it contains the per-process * hardware status page. */ dw = gt->default_lrc[hwe_class] + LRC_PPHWSP_SIZE; remaining_dw = (xe_gt_lrc_size(gt, hwe_class) - LRC_PPHWSP_SIZE) / 4; while (remaining_dw > 0) { if ((*dw & XE_INSTR_CMD_TYPE) == XE_INSTR_MI) { num_dw = dump_mi_command(p, gt, dw, remaining_dw); } else if ((*dw & XE_INSTR_CMD_TYPE) == XE_INSTR_GFXPIPE) { num_dw = dump_gfxpipe_command(p, gt, dw, remaining_dw); } else if ((*dw & XE_INSTR_CMD_TYPE) == XE_INSTR_GFX_STATE) { num_dw = dump_gfx_state_command(p, gt, dw, remaining_dw); } else { num_dw = min(instr_dw(*dw), remaining_dw); drm_printf(p, "[%#10x] Unknown instruction of type %#x, likely %d dwords\n", *dw, REG_FIELD_GET(XE_INSTR_CMD_TYPE, *dw), num_dw); } dw += num_dw; remaining_dw -= num_dw; } } struct instr_state { u32 instr; u16 num_dw; }; static const struct instr_state xe_hpg_svg_state[] = { { .instr = CMD_3DSTATE_CONSTANT_VS, .num_dw = 11 }, { .instr = CMD_3DSTATE_CONSTANT_HS, .num_dw = 11 }, { .instr = CMD_3DSTATE_CONSTANT_DS, .num_dw = 11 }, { .instr = CMD_3DSTATE_CONSTANT_GS, .num_dw = 11 }, { .instr = CMD_3DSTATE_VERTEX_ELEMENTS, .num_dw = 69 }, { .instr = CMD_3DSTATE_VF_COMPONENT_PACKING, .num_dw = 5 }, { .instr = CMD_3DSTATE_VF_SGVS, .num_dw = 2 }, { .instr = CMD_3DSTATE_VF_SGVS_2, .num_dw = 3 }, { .instr = CMD_3DSTATE_VS, .num_dw = 9 }, { .instr = CMD_3DSTATE_BINDING_TABLE_POINTERS_VS, .num_dw = 2 }, { .instr = CMD_3DSTATE_SAMPLER_STATE_POINTERS_VS, .num_dw = 2 }, { .instr = CMD_3DSTATE_URB_ALLOC_VS, .num_dw = 3 }, { .instr = CMD_3DSTATE_STREAMOUT, .num_dw = 5 }, { .instr = CMD_3DSTATE_SO_BUFFER_INDEX_0, .num_dw = 8 }, { .instr = CMD_3DSTATE_SO_BUFFER_INDEX_1, .num_dw = 8 }, { .instr = CMD_3DSTATE_SO_BUFFER_INDEX_2, .num_dw = 8 }, { .instr = CMD_3DSTATE_SO_BUFFER_INDEX_3, .num_dw = 8 }, { .instr = CMD_3DSTATE_CLIP, .num_dw = 4 }, { .instr = CMD_3DSTATE_PRIMITIVE_REPLICATION, .num_dw = 6 }, { .instr = CMD_3DSTATE_CLIP_MESH, .num_dw = 2 }, { .instr = CMD_3DSTATE_SF, .num_dw = 4 }, { .instr = CMD_3DSTATE_SCISSOR_STATE_POINTERS, .num_dw = 2 }, { .instr = CMD_3DSTATE_VIEWPORT_STATE_POINTERS_SF_CLIP, .num_dw = 2 }, { .instr = CMD_3DSTATE_RASTER, .num_dw = 5 }, { .instr = CMD_3DSTATE_TBIMR_TILE_PASS_INFO, .num_dw = 4 }, { .instr = CMD_3DSTATE_WM_HZ_OP, .num_dw = 6 }, { .instr = CMD_3DSTATE_MULTISAMPLE, .num_dw = 2 }, { .instr = CMD_3DSTATE_HS, .num_dw = 9 }, { .instr = CMD_3DSTATE_BINDING_TABLE_POINTERS_HS, .num_dw = 2 }, { .instr = CMD_3DSTATE_SAMPLER_STATE_POINTERS_HS, .num_dw = 2 }, { .instr = CMD_3DSTATE_URB_ALLOC_HS, .num_dw = 3 }, { .instr = CMD_3DSTATE_TASK_CONTROL, .num_dw = 3 }, { .instr = CMD_3DSTATE_TASK_SHADER, .num_dw = 7 }, { .instr = CMD_3DSTATE_TASK_SHADER_DATA, .num_dw = 10 }, { .instr = CMD_3DSTATE_URB_ALLOC_TASK, .num_dw = 3 }, { .instr = CMD_3DSTATE_TE, .num_dw = 5 }, { .instr = CMD_3DSTATE_TASK_REDISTRIB, .num_dw = 2 }, { .instr = CMD_3DSTATE_DS, .num_dw = 11 }, { .instr = CMD_3DSTATE_BINDING_TABLE_POINTERS_DS, .num_dw = 2 }, { .instr = CMD_3DSTATE_SAMPLER_STATE_POINTERS_DS, .num_dw = 2 }, { .instr = CMD_3DSTATE_URB_ALLOC_DS, .num_dw = 3 }, { .instr = CMD_3DSTATE_GS, .num_dw = 10 }, { .instr = CMD_3DSTATE_BINDING_TABLE_POINTERS_GS, .num_dw = 2 }, { .instr = CMD_3DSTATE_SAMPLER_STATE_POINTERS_GS, .num_dw = 2 }, { .instr = CMD_3DSTATE_URB_ALLOC_GS, .num_dw = 3 }, { .instr = CMD_3DSTATE_MESH_CONTROL, .num_dw = 3 }, { .instr = CMD_3DSTATE_MESH_SHADER_DATA, .num_dw = 10 }, { .instr = CMD_3DSTATE_URB_ALLOC_MESH, .num_dw = 3 }, { .instr = CMD_3DSTATE_MESH_SHADER, .num_dw = 8 }, { .instr = CMD_3DSTATE_DRAWING_RECTANGLE, .num_dw = 4 }, }; void xe_lrc_emit_hwe_state_instructions(struct xe_exec_queue *q, struct xe_bb *bb) { struct xe_gt *gt = q->hwe->gt; struct xe_device *xe = gt_to_xe(gt); const struct instr_state *state_table = NULL; int state_table_size = 0; /* * Wa_14019789679 * * If the driver doesn't explicitly emit the SVG instructions while * setting up the default LRC, the context switch will write 0's * (noops) into the LRC memory rather than the expected instruction * headers. Application contexts start out as a copy of the default * LRC, and if they also do not emit specific settings for some SVG * state, then on context restore they'll unintentionally inherit * whatever state setting the previous context had programmed into the * hardware (i.e., the lack of a 3DSTATE_* instruction in the LRC will * prevent the hardware from resetting that state back to any specific * value). * * The official workaround only requires emitting 3DSTATE_MESH_CONTROL * since that's a specific state setting that can easily cause GPU * hangs if unintentionally inherited. However to be safe we'll * continue to emit all of the SVG state since it's best not to leak * any of the state between contexts, even if that leakage is harmless. */ if (XE_WA(gt, 14019789679) && q->hwe->class == XE_ENGINE_CLASS_RENDER) { state_table = xe_hpg_svg_state; state_table_size = ARRAY_SIZE(xe_hpg_svg_state); } if (!state_table) { xe_gt_dbg(gt, "No non-register state to emit on graphics ver %d.%02d\n", GRAPHICS_VER(xe), GRAPHICS_VERx100(xe) % 100); return; } for (int i = 0; i < state_table_size; i++) { u32 instr = state_table[i].instr; u16 num_dw = state_table[i].num_dw; bool is_single_dw = ((instr & GFXPIPE_PIPELINE) == PIPELINE_SINGLE_DW); xe_gt_assert(gt, (instr & XE_INSTR_CMD_TYPE) == XE_INSTR_GFXPIPE); xe_gt_assert(gt, num_dw != 0); xe_gt_assert(gt, is_single_dw ^ (num_dw > 1)); /* * Xe2's SVG context is the same as the one on DG2 / MTL * except that 3DSTATE_DRAWING_RECTANGLE (non-pipelined) has * been replaced by 3DSTATE_DRAWING_RECTANGLE_FAST (pipelined). * Just make the replacement here rather than defining a * whole separate table for the single trivial change. */ if (GRAPHICS_VER(xe) >= 20 && instr == CMD_3DSTATE_DRAWING_RECTANGLE) instr = CMD_3DSTATE_DRAWING_RECTANGLE_FAST; bb->cs[bb->len] = instr; if (!is_single_dw) bb->cs[bb->len] |= (num_dw - 2); bb->len += num_dw; } } struct xe_lrc_snapshot *xe_lrc_snapshot_capture(struct xe_lrc *lrc) { struct xe_lrc_snapshot *snapshot = kmalloc(sizeof(*snapshot), GFP_NOWAIT); if (!snapshot) return NULL; snapshot->context_desc = xe_lrc_ggtt_addr(lrc); snapshot->ring_addr = __xe_lrc_ring_ggtt_addr(lrc); snapshot->indirect_context_desc = xe_lrc_indirect_ring_ggtt_addr(lrc); snapshot->head = xe_lrc_ring_head(lrc); snapshot->tail.internal = lrc->ring.tail; snapshot->tail.memory = xe_lrc_ring_tail(lrc); snapshot->start = xe_lrc_ring_start(lrc); snapshot->start_seqno = xe_lrc_start_seqno(lrc); snapshot->seqno = xe_lrc_seqno(lrc); snapshot->lrc_bo = xe_bo_get(lrc->bo); snapshot->lrc_offset = xe_lrc_pphwsp_offset(lrc); snapshot->lrc_size = lrc->bo->size - snapshot->lrc_offset - LRC_WA_BB_SIZE; snapshot->lrc_snapshot = NULL; snapshot->ctx_timestamp = lower_32_bits(xe_lrc_ctx_timestamp(lrc)); snapshot->ctx_job_timestamp = xe_lrc_ctx_job_timestamp(lrc); return snapshot; } void xe_lrc_snapshot_capture_delayed(struct xe_lrc_snapshot *snapshot) { struct xe_bo *bo; struct iosys_map src; if (!snapshot) return; bo = snapshot->lrc_bo; snapshot->lrc_bo = NULL; snapshot->lrc_snapshot = kvmalloc(snapshot->lrc_size, GFP_KERNEL); if (!snapshot->lrc_snapshot) goto put_bo; xe_bo_lock(bo, false); if (!ttm_bo_vmap(&bo->ttm, &src)) { xe_map_memcpy_from(xe_bo_device(bo), snapshot->lrc_snapshot, &src, snapshot->lrc_offset, snapshot->lrc_size); ttm_bo_vunmap(&bo->ttm, &src); } else { kvfree(snapshot->lrc_snapshot); snapshot->lrc_snapshot = NULL; } xe_bo_unlock(bo); put_bo: xe_bo_put(bo); } void xe_lrc_snapshot_print(struct xe_lrc_snapshot *snapshot, struct drm_printer *p) { unsigned long i; if (!snapshot) return; drm_printf(p, "\tHW Context Desc: 0x%08x\n", snapshot->context_desc); drm_printf(p, "\tHW Ring address: 0x%08x\n", snapshot->ring_addr); drm_printf(p, "\tHW Indirect Ring State: 0x%08x\n", snapshot->indirect_context_desc); drm_printf(p, "\tLRC Head: (memory) %u\n", snapshot->head); drm_printf(p, "\tLRC Tail: (internal) %u, (memory) %u\n", snapshot->tail.internal, snapshot->tail.memory); drm_printf(p, "\tRing start: (memory) 0x%08x\n", snapshot->start); drm_printf(p, "\tStart seqno: (memory) %d\n", snapshot->start_seqno); drm_printf(p, "\tSeqno: (memory) %d\n", snapshot->seqno); drm_printf(p, "\tTimestamp: 0x%08x\n", snapshot->ctx_timestamp); drm_printf(p, "\tJob Timestamp: 0x%08x\n", snapshot->ctx_job_timestamp); if (!snapshot->lrc_snapshot) return; drm_printf(p, "\t[HWSP].length: 0x%x\n", LRC_PPHWSP_SIZE); drm_puts(p, "\t[HWSP].data: "); for (i = 0; i < LRC_PPHWSP_SIZE; i += sizeof(u32)) { u32 *val = snapshot->lrc_snapshot + i; char dumped[ASCII85_BUFSZ]; drm_puts(p, ascii85_encode(*val, dumped)); } drm_printf(p, "\n\t[HWCTX].length: 0x%lx\n", snapshot->lrc_size - LRC_PPHWSP_SIZE); drm_puts(p, "\t[HWCTX].data: "); for (; i < snapshot->lrc_size; i += sizeof(u32)) { u32 *val = snapshot->lrc_snapshot + i; char dumped[ASCII85_BUFSZ]; drm_puts(p, ascii85_encode(*val, dumped)); } drm_puts(p, "\n"); } void xe_lrc_snapshot_free(struct xe_lrc_snapshot *snapshot) { if (!snapshot) return; kvfree(snapshot->lrc_snapshot); if (snapshot->lrc_bo) xe_bo_put(snapshot->lrc_bo); kfree(snapshot); } static int get_ctx_timestamp(struct xe_lrc *lrc, u32 engine_id, u64 *reg_ctx_ts) { u16 class = REG_FIELD_GET(ENGINE_CLASS_ID, engine_id); u16 instance = REG_FIELD_GET(ENGINE_INSTANCE_ID, engine_id); struct xe_hw_engine *hwe; u64 val; hwe = xe_gt_hw_engine(lrc->gt, class, instance, false); if (xe_gt_WARN_ONCE(lrc->gt, !hwe || xe_hw_engine_is_reserved(hwe), "Unexpected engine class:instance %d:%d for context utilization\n", class, instance)) return -1; if (lrc_to_xe(lrc)->info.has_64bit_timestamp) val = xe_mmio_read64_2x32(&hwe->gt->mmio, RING_CTX_TIMESTAMP(hwe->mmio_base)); else val = xe_mmio_read32(&hwe->gt->mmio, RING_CTX_TIMESTAMP(hwe->mmio_base)); *reg_ctx_ts = val; return 0; } /** * xe_lrc_update_timestamp() - Update ctx timestamp * @lrc: Pointer to the lrc. * @old_ts: Old timestamp value * * Populate @old_ts current saved ctx timestamp, read new ctx timestamp and * update saved value. With support for active contexts, the calculation may be * slightly racy, so follow a read-again logic to ensure that the context is * still active before returning the right timestamp. * * Returns: New ctx timestamp value */ u64 xe_lrc_update_timestamp(struct xe_lrc *lrc, u64 *old_ts) { u64 lrc_ts, reg_ts; u32 engine_id; *old_ts = lrc->ctx_timestamp; lrc_ts = xe_lrc_ctx_timestamp(lrc); /* CTX_TIMESTAMP mmio read is invalid on VF, so return the LRC value */ if (IS_SRIOV_VF(lrc_to_xe(lrc))) { lrc->ctx_timestamp = lrc_ts; goto done; } if (lrc_ts == CONTEXT_ACTIVE) { engine_id = xe_lrc_engine_id(lrc); if (!get_ctx_timestamp(lrc, engine_id, ®_ts)) lrc->ctx_timestamp = reg_ts; /* read lrc again to ensure context is still active */ lrc_ts = xe_lrc_ctx_timestamp(lrc); } /* * If context switched out, just use the lrc_ts. Note that this needs to * be a separate if condition. */ if (lrc_ts != CONTEXT_ACTIVE) lrc->ctx_timestamp = lrc_ts; done: trace_xe_lrc_update_timestamp(lrc, *old_ts); return lrc->ctx_timestamp; } /** * xe_lrc_ring_is_idle() - LRC is idle * @lrc: Pointer to the lrc. * * Compare LRC ring head and tail to determine if idle. * * Return: True is ring is idle, False otherwise */ bool xe_lrc_ring_is_idle(struct xe_lrc *lrc) { return xe_lrc_ring_head(lrc) == xe_lrc_ring_tail(lrc); }
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