// SPDX-License-Identifier: MIT /* * Copyright © 2022 Intel Corporation */ #include "xe_mocs.h" #include "regs/xe_gt_regs.h" #include "xe_bo.h" #include "xe_device.h" #include "xe_exec_queue.h" #include "xe_force_wake.h" #include "xe_gt.h" #include "xe_gt_mcr.h" #include "xe_gt_printk.h" #include "xe_mmio.h" #include "xe_platform_types.h" #include "xe_pm.h" #include "xe_sriov.h" #include "xe_step_types.h" #if IS_ENABLED(CONFIG_DRM_XE_DEBUG) #define mocs_dbg xe_gt_dbg #else __printf(2, 3) static inline void mocs_dbg(const struct xe_gt *gt, const char *format, ...) { /* noop */ } #endif enum { HAS_GLOBAL_MOCS = BIT(0), HAS_LNCF_MOCS = BIT(1), }; struct xe_mocs_entry { u32 control_value; u16 l3cc_value; u16 used; }; struct xe_mocs_info; struct xe_mocs_ops { void (*dump)(struct xe_mocs_info *mocs, unsigned int flags, struct xe_gt *gt, struct drm_printer *p); }; struct xe_mocs_info { /* * Size of the spec's suggested MOCS programming table. The list of * table entries from the spec can potentially be smaller than the * number of hardware registers used to program the MOCS table; in such * cases the registers for the remaining indices will be programmed to * match unused_entries_index. */ unsigned int table_size; /* Number of MOCS entries supported by the hardware */ unsigned int num_mocs_regs; const struct xe_mocs_entry *table; const struct xe_mocs_ops *ops; u8 uc_index; u8 wb_index; u8 unused_entries_index; }; /* Defines for the tables (GLOB_MOCS_0 - GLOB_MOCS_16) */ #define IG_PAT REG_BIT(8) #define L3_CACHE_POLICY_MASK REG_GENMASK(5, 4) #define L4_CACHE_POLICY_MASK REG_GENMASK(3, 2) /* Helper defines */ #define XELP_NUM_MOCS_ENTRIES 64 /* 63-64 are reserved, but configured. */ #define PVC_NUM_MOCS_ENTRIES 3 #define MTL_NUM_MOCS_ENTRIES 16 #define XE2_NUM_MOCS_ENTRIES 16 /* (e)LLC caching options */ /* * Note: LE_0_PAGETABLE works only up to Gen11; for newer gens it means * the same as LE_UC */ #define LE_0_PAGETABLE LE_CACHEABILITY(0) #define LE_1_UC LE_CACHEABILITY(1) #define LE_2_WT LE_CACHEABILITY(2) #define LE_3_WB LE_CACHEABILITY(3) /* Target cache */ #define LE_TC_0_PAGETABLE LE_TGT_CACHE(0) #define LE_TC_1_LLC LE_TGT_CACHE(1) #define LE_TC_2_LLC_ELLC LE_TGT_CACHE(2) #define LE_TC_3_LLC_ELLC_ALT LE_TGT_CACHE(3) /* L3 caching options */ #define L3_0_DIRECT L3_CACHEABILITY(0) #define L3_1_UC L3_CACHEABILITY(1) #define L3_2_RESERVED L3_CACHEABILITY(2) #define L3_3_WB L3_CACHEABILITY(3) /* L4 caching options */ #define L4_0_WB REG_FIELD_PREP(L4_CACHE_POLICY_MASK, 0) #define L4_1_WT REG_FIELD_PREP(L4_CACHE_POLICY_MASK, 1) #define L4_3_UC REG_FIELD_PREP(L4_CACHE_POLICY_MASK, 3) #define XE2_L3_0_WB REG_FIELD_PREP(L3_CACHE_POLICY_MASK, 0) /* XD: WB Transient Display */ #define XE2_L3_1_XD REG_FIELD_PREP(L3_CACHE_POLICY_MASK, 1) #define XE2_L3_3_UC REG_FIELD_PREP(L3_CACHE_POLICY_MASK, 3) #define XE2_L3_CLOS_MASK REG_GENMASK(7, 6) #define MOCS_ENTRY(__idx, __control_value, __l3cc_value) \ [__idx] = { \ .control_value = __control_value, \ .l3cc_value = __l3cc_value, \ .used = 1, \ } /* * MOCS tables * * These are the MOCS tables that are programmed across all the rings. * The control value is programmed to all the rings that support the * MOCS registers. While the l3cc_values are only programmed to the * LNCFCMOCS0 - LNCFCMOCS32 registers. * * These tables are intended to be kept reasonably consistent across * HW platforms, and for ICL+, be identical across OSes. To achieve * that, the list of entries is published as part of bspec. * * Entries not part of the following tables are undefined as far as userspace is * concerned and shouldn't be relied upon. The last few entries are reserved by * the hardware. They should be initialized according to bspec and never used. * * NOTE1: These tables are part of bspec and defined as part of the hardware * interface. It is expected that, for specific hardware platform, existing * entries will remain constant and the table will only be updated by adding new * entries, filling unused positions. * * NOTE2: Reserved and unspecified MOCS indices have been set to L3 WB. These * reserved entries should never be used. They may be changed to low performant * variants with better coherency in the future if more entries are needed. */ static const struct xe_mocs_entry gen12_mocs_desc[] = { /* Base - L3 + LLC */ MOCS_ENTRY(2, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3), L3_3_WB), /* Base - Uncached */ MOCS_ENTRY(3, LE_1_UC | LE_TC_1_LLC, L3_1_UC), /* Base - L3 */ MOCS_ENTRY(4, LE_1_UC | LE_TC_1_LLC, L3_3_WB), /* Base - LLC */ MOCS_ENTRY(5, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3), L3_1_UC), /* Age 0 - LLC */ MOCS_ENTRY(6, LE_3_WB | LE_TC_1_LLC | LE_LRUM(1), L3_1_UC), /* Age 0 - L3 + LLC */ MOCS_ENTRY(7, LE_3_WB | LE_TC_1_LLC | LE_LRUM(1), L3_3_WB), /* Age: Don't Chg. - LLC */ MOCS_ENTRY(8, LE_3_WB | LE_TC_1_LLC | LE_LRUM(2), L3_1_UC), /* Age: Don't Chg. - L3 + LLC */ MOCS_ENTRY(9, LE_3_WB | LE_TC_1_LLC | LE_LRUM(2), L3_3_WB), /* No AOM - LLC */ MOCS_ENTRY(10, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_AOM(1), L3_1_UC), /* No AOM - L3 + LLC */ MOCS_ENTRY(11, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_AOM(1), L3_3_WB), /* No AOM; Age 0 - LLC */ MOCS_ENTRY(12, LE_3_WB | LE_TC_1_LLC | LE_LRUM(1) | LE_AOM(1), L3_1_UC), /* No AOM; Age 0 - L3 + LLC */ MOCS_ENTRY(13, LE_3_WB | LE_TC_1_LLC | LE_LRUM(1) | LE_AOM(1), L3_3_WB), /* No AOM; Age:DC - LLC */ MOCS_ENTRY(14, LE_3_WB | LE_TC_1_LLC | LE_LRUM(2) | LE_AOM(1), L3_1_UC), /* No AOM; Age:DC - L3 + LLC */ MOCS_ENTRY(15, LE_3_WB | LE_TC_1_LLC | LE_LRUM(2) | LE_AOM(1), L3_3_WB), /* Self-Snoop - L3 + LLC */ MOCS_ENTRY(18, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_SSE(3), L3_3_WB), /* Skip Caching - L3 + LLC(12.5%) */ MOCS_ENTRY(19, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_SCC(7), L3_3_WB), /* Skip Caching - L3 + LLC(25%) */ MOCS_ENTRY(20, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_SCC(3), L3_3_WB), /* Skip Caching - L3 + LLC(50%) */ MOCS_ENTRY(21, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_SCC(1), L3_3_WB), /* Skip Caching - L3 + LLC(75%) */ MOCS_ENTRY(22, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_RSC(1) | LE_SCC(3), L3_3_WB), /* Skip Caching - L3 + LLC(87.5%) */ MOCS_ENTRY(23, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3) | LE_RSC(1) | LE_SCC(7), L3_3_WB), /* Implicitly enable L1 - HDC:L1 + L3 + LLC */ MOCS_ENTRY(48, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3), L3_3_WB), /* Implicitly enable L1 - HDC:L1 + L3 */ MOCS_ENTRY(49, LE_1_UC | LE_TC_1_LLC, L3_3_WB), /* Implicitly enable L1 - HDC:L1 + LLC */ MOCS_ENTRY(50, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3), L3_1_UC), /* Implicitly enable L1 - HDC:L1 */ MOCS_ENTRY(51, LE_1_UC | LE_TC_1_LLC, L3_1_UC), /* HW Special Case (CCS) */ MOCS_ENTRY(60, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3), L3_1_UC), /* HW Special Case (Displayable) */ MOCS_ENTRY(61, LE_1_UC | LE_TC_1_LLC, L3_3_WB), /* HW Reserved - SW program but never use */ MOCS_ENTRY(62, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3), L3_1_UC), /* HW Reserved - SW program but never use */ MOCS_ENTRY(63, LE_3_WB | LE_TC_1_LLC | LE_LRUM(3), L3_1_UC) }; static bool regs_are_mcr(struct xe_gt *gt) { struct xe_device *xe = gt_to_xe(gt); if (xe_gt_is_media_type(gt)) return MEDIA_VER(xe) >= 20; else return GRAPHICS_VERx100(xe) >= 1250; } static void xelp_lncf_dump(struct xe_mocs_info *info, struct xe_gt *gt, struct drm_printer *p) { unsigned int i, j; u32 reg_val; drm_printf(p, "LNCFCMOCS[idx] = [ESC, SCC, L3CC] (value)\n\n"); for (i = 0, j = 0; i < (info->num_mocs_regs + 1) / 2; i++, j++) { if (regs_are_mcr(gt)) reg_val = xe_gt_mcr_unicast_read_any(gt, XEHP_LNCFCMOCS(i)); else reg_val = xe_mmio_read32(>->mmio, XELP_LNCFCMOCS(i)); drm_printf(p, "LNCFCMOCS[%2d] = [%u, %u, %u] (%#8x)\n", j++, !!(reg_val & L3_ESC_MASK), REG_FIELD_GET(L3_SCC_MASK, reg_val), REG_FIELD_GET(L3_CACHEABILITY_MASK, reg_val), reg_val); drm_printf(p, "LNCFCMOCS[%2d] = [%u, %u, %u] (%#8x)\n", j, !!(reg_val & L3_UPPER_IDX_ESC_MASK), REG_FIELD_GET(L3_UPPER_IDX_SCC_MASK, reg_val), REG_FIELD_GET(L3_UPPER_IDX_CACHEABILITY_MASK, reg_val), reg_val); } } static void xelp_mocs_dump(struct xe_mocs_info *info, unsigned int flags, struct xe_gt *gt, struct drm_printer *p) { unsigned int i; u32 reg_val; if (flags & HAS_GLOBAL_MOCS) { drm_printf(p, "Global mocs table configuration:\n"); drm_printf(p, "GLOB_MOCS[idx] = [LeCC, TC, LRUM, AOM, RSC, SCC, PFM, SCF, CoS, SSE] (value)\n\n"); for (i = 0; i < info->num_mocs_regs; i++) { if (regs_are_mcr(gt)) reg_val = xe_gt_mcr_unicast_read_any(gt, XEHP_GLOBAL_MOCS(i)); else reg_val = xe_mmio_read32(>->mmio, XELP_GLOBAL_MOCS(i)); drm_printf(p, "GLOB_MOCS[%2d] = [%u, %u, %u, %u, %u, %u, %u, %u, %u, %u ] (%#8x)\n", i, REG_FIELD_GET(LE_CACHEABILITY_MASK, reg_val), REG_FIELD_GET(LE_TGT_CACHE_MASK, reg_val), REG_FIELD_GET(LE_LRUM_MASK, reg_val), !!(reg_val & LE_AOM_MASK), !!(reg_val & LE_RSC_MASK), REG_FIELD_GET(LE_SCC_MASK, reg_val), REG_FIELD_GET(LE_PFM_MASK, reg_val), !!(reg_val & LE_SCF_MASK), REG_FIELD_GET(LE_COS_MASK, reg_val), REG_FIELD_GET(LE_SSE_MASK, reg_val), reg_val); } } xelp_lncf_dump(info, gt, p); } static const struct xe_mocs_ops xelp_mocs_ops = { .dump = xelp_mocs_dump, }; static const struct xe_mocs_entry dg1_mocs_desc[] = { /* UC */ MOCS_ENTRY(1, 0, L3_1_UC), /* WB - L3 */ MOCS_ENTRY(5, 0, L3_3_WB), /* WB - L3 50% */ MOCS_ENTRY(6, 0, L3_ESC(1) | L3_SCC(1) | L3_3_WB), /* WB - L3 25% */ MOCS_ENTRY(7, 0, L3_ESC(1) | L3_SCC(3) | L3_3_WB), /* WB - L3 12.5% */ MOCS_ENTRY(8, 0, L3_ESC(1) | L3_SCC(7) | L3_3_WB), /* HDC:L1 + L3 */ MOCS_ENTRY(48, 0, L3_3_WB), /* HDC:L1 */ MOCS_ENTRY(49, 0, L3_1_UC), /* HW Reserved */ MOCS_ENTRY(60, 0, L3_1_UC), MOCS_ENTRY(61, 0, L3_1_UC), MOCS_ENTRY(62, 0, L3_1_UC), MOCS_ENTRY(63, 0, L3_1_UC), }; static const struct xe_mocs_entry dg2_mocs_desc[] = { /* UC - Coherent; GO:L3 */ MOCS_ENTRY(0, 0, L3_1_UC | L3_LKUP(1)), /* UC - Coherent; GO:Memory */ MOCS_ENTRY(1, 0, L3_1_UC | L3_GLBGO(1) | L3_LKUP(1)), /* UC - Non-Coherent; GO:Memory */ MOCS_ENTRY(2, 0, L3_1_UC | L3_GLBGO(1)), /* WB - LC */ MOCS_ENTRY(3, 0, L3_3_WB | L3_LKUP(1)), }; static void xehp_lncf_dump(struct xe_mocs_info *info, unsigned int flags, struct xe_gt *gt, struct drm_printer *p) { unsigned int i, j; u32 reg_val; drm_printf(p, "LNCFCMOCS[idx] = [UCL3LOOKUP, GLBGO, L3CC] (value)\n\n"); for (i = 0, j = 0; i < (info->num_mocs_regs + 1) / 2; i++, j++) { if (regs_are_mcr(gt)) reg_val = xe_gt_mcr_unicast_read_any(gt, XEHP_LNCFCMOCS(i)); else reg_val = xe_mmio_read32(>->mmio, XELP_LNCFCMOCS(i)); drm_printf(p, "LNCFCMOCS[%2d] = [%u, %u, %u] (%#8x)\n", j++, !!(reg_val & L3_LKUP_MASK), !!(reg_val & L3_GLBGO_MASK), REG_FIELD_GET(L3_CACHEABILITY_MASK, reg_val), reg_val); drm_printf(p, "LNCFCMOCS[%2d] = [%u, %u, %u] (%#8x)\n", j, !!(reg_val & L3_UPPER_LKUP_MASK), !!(reg_val & L3_UPPER_GLBGO_MASK), REG_FIELD_GET(L3_UPPER_IDX_CACHEABILITY_MASK, reg_val), reg_val); } } static const struct xe_mocs_ops xehp_mocs_ops = { .dump = xehp_lncf_dump, }; static const struct xe_mocs_entry pvc_mocs_desc[] = { /* Error */ MOCS_ENTRY(0, 0, L3_3_WB), /* UC */ MOCS_ENTRY(1, 0, L3_1_UC), /* WB */ MOCS_ENTRY(2, 0, L3_3_WB), }; static void pvc_mocs_dump(struct xe_mocs_info *info, unsigned int flags, struct xe_gt *gt, struct drm_printer *p) { unsigned int i, j; u32 reg_val; drm_printf(p, "LNCFCMOCS[idx] = [ L3CC ] (value)\n\n"); for (i = 0, j = 0; i < (info->num_mocs_regs + 1) / 2; i++, j++) { if (regs_are_mcr(gt)) reg_val = xe_gt_mcr_unicast_read_any(gt, XEHP_LNCFCMOCS(i)); else reg_val = xe_mmio_read32(>->mmio, XELP_LNCFCMOCS(i)); drm_printf(p, "LNCFCMOCS[%2d] = [ %u ] (%#8x)\n", j++, REG_FIELD_GET(L3_CACHEABILITY_MASK, reg_val), reg_val); drm_printf(p, "LNCFCMOCS[%2d] = [ %u ] (%#8x)\n", j, REG_FIELD_GET(L3_UPPER_IDX_CACHEABILITY_MASK, reg_val), reg_val); } } static const struct xe_mocs_ops pvc_mocs_ops = { .dump = pvc_mocs_dump, }; static const struct xe_mocs_entry mtl_mocs_desc[] = { /* Error - Reserved for Non-Use */ MOCS_ENTRY(0, 0, L3_LKUP(1) | L3_3_WB), /* Cached - L3 + L4 */ MOCS_ENTRY(1, IG_PAT, L3_LKUP(1) | L3_3_WB), /* L4 - GO:L3 */ MOCS_ENTRY(2, IG_PAT, L3_LKUP(1) | L3_1_UC), /* Uncached - GO:L3 */ MOCS_ENTRY(3, IG_PAT | L4_3_UC, L3_LKUP(1) | L3_1_UC), /* L4 - GO:Mem */ MOCS_ENTRY(4, IG_PAT, L3_LKUP(1) | L3_GLBGO(1) | L3_1_UC), /* Uncached - GO:Mem */ MOCS_ENTRY(5, IG_PAT | L4_3_UC, L3_LKUP(1) | L3_GLBGO(1) | L3_1_UC), /* L4 - L3:NoLKUP; GO:L3 */ MOCS_ENTRY(6, IG_PAT, L3_1_UC), /* Uncached - L3:NoLKUP; GO:L3 */ MOCS_ENTRY(7, IG_PAT | L4_3_UC, L3_1_UC), /* L4 - L3:NoLKUP; GO:Mem */ MOCS_ENTRY(8, IG_PAT, L3_GLBGO(1) | L3_1_UC), /* Uncached - L3:NoLKUP; GO:Mem */ MOCS_ENTRY(9, IG_PAT | L4_3_UC, L3_GLBGO(1) | L3_1_UC), /* Display - L3; L4:WT */ MOCS_ENTRY(14, IG_PAT | L4_1_WT, L3_LKUP(1) | L3_3_WB), /* CCS - Non-Displayable */ MOCS_ENTRY(15, IG_PAT, L3_GLBGO(1) | L3_1_UC), }; static void mtl_mocs_dump(struct xe_mocs_info *info, unsigned int flags, struct xe_gt *gt, struct drm_printer *p) { unsigned int i; u32 reg_val; drm_printf(p, "Global mocs table configuration:\n"); drm_printf(p, "GLOB_MOCS[idx] = [IG_PAT, L4_CACHE_POLICY] (value)\n\n"); for (i = 0; i < info->num_mocs_regs; i++) { if (regs_are_mcr(gt)) reg_val = xe_gt_mcr_unicast_read_any(gt, XEHP_GLOBAL_MOCS(i)); else reg_val = xe_mmio_read32(>->mmio, XELP_GLOBAL_MOCS(i)); drm_printf(p, "GLOB_MOCS[%2d] = [%u, %u] (%#8x)\n", i, !!(reg_val & IG_PAT), REG_FIELD_GET(L4_CACHE_POLICY_MASK, reg_val), reg_val); } /* MTL lncf mocs table pattern is similar to that of xehp */ xehp_lncf_dump(info, flags, gt, p); } static const struct xe_mocs_ops mtl_mocs_ops = { .dump = mtl_mocs_dump, }; static const struct xe_mocs_entry xe2_mocs_table[] = { /* Defer to PAT */ MOCS_ENTRY(0, XE2_L3_0_WB | L4_3_UC, 0), /* Cached L3, Uncached L4 */ MOCS_ENTRY(1, IG_PAT | XE2_L3_0_WB | L4_3_UC, 0), /* Uncached L3, Cached L4 */ MOCS_ENTRY(2, IG_PAT | XE2_L3_3_UC | L4_0_WB, 0), /* Uncached L3 + L4 */ MOCS_ENTRY(3, IG_PAT | XE2_L3_3_UC | L4_3_UC, 0), /* Cached L3 + L4 */ MOCS_ENTRY(4, IG_PAT | XE2_L3_0_WB | L4_0_WB, 0), }; static void xe2_mocs_dump(struct xe_mocs_info *info, unsigned int flags, struct xe_gt *gt, struct drm_printer *p) { unsigned int i; u32 reg_val; drm_printf(p, "Global mocs table configuration:\n"); drm_printf(p, "GLOB_MOCS[idx] = [IG_PAT, L3_CLOS, L3_CACHE_POLICY, L4_CACHE_POLICY] (value)\n\n"); for (i = 0; i < info->num_mocs_regs; i++) { if (regs_are_mcr(gt)) reg_val = xe_gt_mcr_unicast_read_any(gt, XEHP_GLOBAL_MOCS(i)); else reg_val = xe_mmio_read32(>->mmio, XELP_GLOBAL_MOCS(i)); drm_printf(p, "GLOB_MOCS[%2d] = [%u, %u, %u] (%#8x)\n", i, !!(reg_val & IG_PAT), REG_FIELD_GET(XE2_L3_CLOS_MASK, reg_val), REG_FIELD_GET(L4_CACHE_POLICY_MASK, reg_val), reg_val); } } static const struct xe_mocs_ops xe2_mocs_ops = { .dump = xe2_mocs_dump, }; static unsigned int get_mocs_settings(struct xe_device *xe, struct xe_mocs_info *info) { unsigned int flags = 0; memset(info, 0, sizeof(struct xe_mocs_info)); switch (xe->info.platform) { case XE_PANTHERLAKE: case XE_LUNARLAKE: case XE_BATTLEMAGE: info->ops = &xe2_mocs_ops; info->table_size = ARRAY_SIZE(xe2_mocs_table); info->table = xe2_mocs_table; info->num_mocs_regs = XE2_NUM_MOCS_ENTRIES; info->uc_index = 3; info->wb_index = 4; info->unused_entries_index = 4; break; case XE_PVC: info->ops = &pvc_mocs_ops; info->table_size = ARRAY_SIZE(pvc_mocs_desc); info->table = pvc_mocs_desc; info->num_mocs_regs = PVC_NUM_MOCS_ENTRIES; info->uc_index = 1; info->wb_index = 2; info->unused_entries_index = 2; break; case XE_METEORLAKE: info->ops = &mtl_mocs_ops; info->table_size = ARRAY_SIZE(mtl_mocs_desc); info->table = mtl_mocs_desc; info->num_mocs_regs = MTL_NUM_MOCS_ENTRIES; info->uc_index = 9; info->unused_entries_index = 1; break; case XE_DG2: info->ops = &xehp_mocs_ops; info->table_size = ARRAY_SIZE(dg2_mocs_desc); info->table = dg2_mocs_desc; info->uc_index = 1; /* * Last entry is RO on hardware, don't bother with what was * written when checking later */ info->num_mocs_regs = XELP_NUM_MOCS_ENTRIES - 1; info->unused_entries_index = 3; break; case XE_DG1: info->ops = &xelp_mocs_ops; info->table_size = ARRAY_SIZE(dg1_mocs_desc); info->table = dg1_mocs_desc; info->uc_index = 1; info->num_mocs_regs = XELP_NUM_MOCS_ENTRIES; info->unused_entries_index = 5; break; case XE_TIGERLAKE: case XE_ROCKETLAKE: case XE_ALDERLAKE_S: case XE_ALDERLAKE_P: case XE_ALDERLAKE_N: info->ops = &xelp_mocs_ops; info->table_size = ARRAY_SIZE(gen12_mocs_desc); info->table = gen12_mocs_desc; info->num_mocs_regs = XELP_NUM_MOCS_ENTRIES; info->uc_index = 3; info->unused_entries_index = 2; break; default: drm_err(&xe->drm, "Platform that should have a MOCS table does not.\n"); return 0; } /* * Index 0 is a reserved/unused table entry on most platforms, but * even on those where it does represent a legitimate MOCS entry, it * never represents the "most cached, least coherent" behavior we want * to populate undefined table rows with. So if unused_entries_index * is still 0 at this point, we'll assume that it was omitted by * mistake in the switch statement above. */ xe_assert(xe, info->unused_entries_index != 0); xe_assert(xe, info->ops && info->ops->dump); xe_assert(xe, info->table_size <= info->num_mocs_regs); if (!IS_DGFX(xe) || GRAPHICS_VER(xe) >= 20) flags |= HAS_GLOBAL_MOCS; if (GRAPHICS_VER(xe) < 20) flags |= HAS_LNCF_MOCS; return flags; } /* * Get control_value from MOCS entry. If the table entry is not defined, the * settings from unused_entries_index will be returned. */ static u32 get_entry_control(const struct xe_mocs_info *info, unsigned int index) { if (index < info->table_size && info->table[index].used) return info->table[index].control_value; return info->table[info->unused_entries_index].control_value; } static void __init_mocs_table(struct xe_gt *gt, const struct xe_mocs_info *info) { unsigned int i; u32 mocs; mocs_dbg(gt, "mocs entries: %d\n", info->num_mocs_regs); for (i = 0; i < info->num_mocs_regs; i++) { mocs = get_entry_control(info, i); mocs_dbg(gt, "GLOB_MOCS[%d] 0x%x 0x%x\n", i, XELP_GLOBAL_MOCS(i).addr, mocs); if (regs_are_mcr(gt)) xe_gt_mcr_multicast_write(gt, XEHP_GLOBAL_MOCS(i), mocs); else xe_mmio_write32(>->mmio, XELP_GLOBAL_MOCS(i), mocs); } } /* * Get l3cc_value from MOCS entry taking into account when it's not used * then if unused_entries_index is not zero then its value will be returned * otherwise I915_MOCS_PTE's value is returned in this case. */ static u16 get_entry_l3cc(const struct xe_mocs_info *info, unsigned int index) { if (index < info->table_size && info->table[index].used) return info->table[index].l3cc_value; return info->table[info->unused_entries_index].l3cc_value; } static u32 l3cc_combine(u16 low, u16 high) { return low | (u32)high << 16; } static void init_l3cc_table(struct xe_gt *gt, const struct xe_mocs_info *info) { unsigned int i; u32 l3cc; mocs_dbg(gt, "l3cc entries: %d\n", info->num_mocs_regs); for (i = 0; i < (info->num_mocs_regs + 1) / 2; i++) { l3cc = l3cc_combine(get_entry_l3cc(info, 2 * i), get_entry_l3cc(info, 2 * i + 1)); mocs_dbg(gt, "LNCFCMOCS[%d] 0x%x 0x%x\n", i, XELP_LNCFCMOCS(i).addr, l3cc); if (regs_are_mcr(gt)) xe_gt_mcr_multicast_write(gt, XEHP_LNCFCMOCS(i), l3cc); else xe_mmio_write32(>->mmio, XELP_LNCFCMOCS(i), l3cc); } } void xe_mocs_init_early(struct xe_gt *gt) { struct xe_mocs_info table; get_mocs_settings(gt_to_xe(gt), &table); gt->mocs.uc_index = table.uc_index; gt->mocs.wb_index = table.wb_index; } void xe_mocs_init(struct xe_gt *gt) { struct xe_mocs_info table; unsigned int flags; if (IS_SRIOV_VF(gt_to_xe(gt))) return; /* * MOCS settings are split between "GLOB_MOCS" and/or "LNCFCMOCS" * registers depending on platform. * * These registers should be programmed before GuC initialization * since their values will affect some of the memory transactions * performed by the GuC. */ flags = get_mocs_settings(gt_to_xe(gt), &table); mocs_dbg(gt, "flag:0x%x\n", flags); if (IS_SRIOV_VF(gt_to_xe(gt))) return; if (flags & HAS_GLOBAL_MOCS) __init_mocs_table(gt, &table); if (flags & HAS_LNCF_MOCS) init_l3cc_table(gt, &table); } void xe_mocs_dump(struct xe_gt *gt, struct drm_printer *p) { struct xe_device *xe = gt_to_xe(gt); struct xe_mocs_info table; unsigned int fw_ref, flags; flags = get_mocs_settings(xe, &table); xe_pm_runtime_get_noresume(xe); fw_ref = xe_force_wake_get(gt_to_fw(gt), XE_FW_GT); if (!fw_ref) goto err_fw; table.ops->dump(&table, flags, gt, p); xe_force_wake_put(gt_to_fw(gt), fw_ref); err_fw: xe_pm_runtime_put(xe); } #if IS_ENABLED(CONFIG_DRM_XE_KUNIT_TEST) #include "tests/xe_mocs.c" #endif