/* SPDX-License-Identifier: MIT */ /* * Copyright © 2022-2023 Intel Corporation */ #ifndef _XE_GT_TYPES_H_ #define _XE_GT_TYPES_H_ #include "xe_force_wake_types.h" #include "xe_gt_idle_types.h" #include "xe_hw_engine_types.h" #include "xe_hw_fence_types.h" #include "xe_reg_sr_types.h" #include "xe_sa_types.h" #include "xe_uc_types.h" struct xe_exec_queue_ops; struct xe_migrate; struct xe_ring_ops; enum xe_gt_type { XE_GT_TYPE_UNINITIALIZED, XE_GT_TYPE_MAIN, XE_GT_TYPE_MEDIA, }; #define XE_MAX_DSS_FUSE_REGS 3 #define XE_MAX_EU_FUSE_REGS 1 typedef unsigned long xe_dss_mask_t[BITS_TO_LONGS(32 * XE_MAX_DSS_FUSE_REGS)]; typedef unsigned long xe_eu_mask_t[BITS_TO_LONGS(32 * XE_MAX_EU_FUSE_REGS)]; struct xe_mmio_range { u32 start; u32 end; }; /* * The hardware has multiple kinds of multicast register ranges that need * special register steering (and future platforms are expected to add * additional types). * * During driver startup, we initialize the steering control register to * direct reads to a slice/subslice that are valid for the 'subslice' class * of multicast registers. If another type of steering does not have any * overlap in valid steering targets with 'subslice' style registers, we will * need to explicitly re-steer reads of registers of the other type. * * Only the replication types that may need additional non-default steering * are listed here. */ enum xe_steering_type { L3BANK, MSLICE, LNCF, DSS, OADDRM, SQIDI_PSMI, /* * On some platforms there are multiple types of MCR registers that * will always return a non-terminated value at instance (0, 0). We'll * lump those all into a single category to keep things simple. */ INSTANCE0, /* * Register ranges that don't need special steering for each register: * it's sufficient to keep the HW-default for the selector, or only * change it once, on GT initialization. This needs to be the last * steering type. */ IMPLICIT_STEERING, NUM_STEERING_TYPES }; #define gt_to_tile(gt__) \ _Generic(gt__, \ const struct xe_gt * : (const struct xe_tile *)((gt__)->tile), \ struct xe_gt * : (gt__)->tile) #define gt_to_xe(gt__) \ _Generic(gt__, \ const struct xe_gt * : (const struct xe_device *)(gt_to_tile(gt__)->xe), \ struct xe_gt * : gt_to_tile(gt__)->xe) /** * struct xe_gt - A "Graphics Technology" unit of the GPU * * A GT ("Graphics Technology") is the subset of a GPU primarily responsible * for implementing the graphics, compute, and/or media IP. It encapsulates * the hardware engines, programmable execution units, and GuC. Each GT has * its own handling of power management (RC6+forcewake) and multicast register * steering. * * A GPU/tile may have a single GT that supplies all graphics, compute, and * media functionality, or the graphics/compute and media may be split into * separate GTs within a tile. */ struct xe_gt { /** @tile: Backpointer to GT's tile */ struct xe_tile *tile; /** @info: GT info */ struct { /** @info.type: type of GT */ enum xe_gt_type type; /** @info.id: Unique ID of this GT within the PCI Device */ u8 id; /** @info.reference_clock: clock frequency */ u32 reference_clock; /** @info.engine_mask: mask of engines present on GT */ u64 engine_mask; /** * @info.__engine_mask: mask of engines present on GT read from * xe_pci.c, used to fake reading the engine_mask from the * hwconfig blob. */ u64 __engine_mask; /** @info.gmdid: raw GMD_ID value from hardware */ u32 gmdid; } info; /** * @mmio: mmio info for GT. All GTs within a tile share the same * register space, but have their own copy of GSI registers at a * specific offset, as well as their own forcewake handling. */ struct { /** @mmio.fw: force wake for GT */ struct xe_force_wake fw; /** * @mmio.adj_limit: adjust MMIO address if address is below this * value */ u32 adj_limit; /** @mmio.adj_offset: offect to add to MMIO address when adjusting */ u32 adj_offset; } mmio; /** * @reg_sr: table with registers to be restored on GT init/resume/reset */ struct xe_reg_sr reg_sr; /** @reset: state for GT resets */ struct { /** * @reset.worker: work so GT resets can done async allowing to reset * code to safely flush all code paths */ struct work_struct worker; } reset; /** @tlb_invalidation: TLB invalidation state */ struct { /** @tlb_invalidation.seqno: TLB invalidation seqno, protected by CT lock */ #define TLB_INVALIDATION_SEQNO_MAX 0x100000 int seqno; /** * @tlb_invalidation.seqno_recv: last received TLB invalidation seqno, * protected by CT lock */ int seqno_recv; /** * @tlb_invalidation.pending_fences: list of pending fences waiting TLB * invaliations, protected by CT lock */ struct list_head pending_fences; /** * @tlb_invalidation.pending_lock: protects @tlb_invalidation.pending_fences * and updating @tlb_invalidation.seqno_recv. */ spinlock_t pending_lock; /** * @tlb_invalidation.fence_tdr: schedules a delayed call to * xe_gt_tlb_fence_timeout after the timeut interval is over. */ struct delayed_work fence_tdr; /** @tlb_invalidation.lock: protects TLB invalidation fences */ spinlock_t lock; } tlb_invalidation; /** * @ccs_mode: Number of compute engines enabled. * Allows fixed mapping of available compute slices to compute engines. * By default only the first available compute engine is enabled and all * available compute slices are allocated to it. */ u32 ccs_mode; /** @usm: unified shared memory state */ struct { /** * @usm.bb_pool: Pool from which batchbuffers, for USM operations * (e.g. migrations, fixing page tables), are allocated. * Dedicated pool needed so USM operations to not get blocked * behind any user operations which may have resulted in a * fault. */ struct xe_sa_manager *bb_pool; /** * @usm.reserved_bcs_instance: reserved BCS instance used for USM * operations (e.g. mmigrations, fixing page tables) */ u16 reserved_bcs_instance; /** @usm.pf_wq: page fault work queue, unbound, high priority */ struct workqueue_struct *pf_wq; /** @usm.acc_wq: access counter work queue, unbound, high priority */ struct workqueue_struct *acc_wq; /** * @usm.pf_queue: Page fault queue used to sync faults so faults can * be processed not under the GuC CT lock. The queue is sized so * it can sync all possible faults (1 per physical engine). * Multiple queues exists for page faults from different VMs are * be processed in parallel. */ struct pf_queue { /** @usm.pf_queue.gt: back pointer to GT */ struct xe_gt *gt; #define PF_QUEUE_NUM_DW 128 /** @usm.pf_queue.data: data in the page fault queue */ u32 data[PF_QUEUE_NUM_DW]; /** * @usm.pf_queue.tail: tail pointer in DWs for page fault queue, * moved by worker which processes faults (consumer). */ u16 tail; /** * @usm.pf_queue.head: head pointer in DWs for page fault queue, * moved by G2H handler (producer). */ u16 head; /** @usm.pf_queue.lock: protects page fault queue */ spinlock_t lock; /** @usm.pf_queue.worker: to process page faults */ struct work_struct worker; #define NUM_PF_QUEUE 4 } pf_queue[NUM_PF_QUEUE]; /** * @usm.acc_queue: Same as page fault queue, cannot process access * counters under CT lock. */ struct acc_queue { /** @usm.acc_queue.gt: back pointer to GT */ struct xe_gt *gt; #define ACC_QUEUE_NUM_DW 128 /** @usm.acc_queue.data: data in the page fault queue */ u32 data[ACC_QUEUE_NUM_DW]; /** * @usm.acc_queue.tail: tail pointer in DWs for access counter queue, * moved by worker which processes counters * (consumer). */ u16 tail; /** * @usm.acc_queue.head: head pointer in DWs for access counter queue, * moved by G2H handler (producer). */ u16 head; /** @usm.acc_queue.lock: protects page fault queue */ spinlock_t lock; /** @usm.acc_queue.worker: to process access counters */ struct work_struct worker; #define NUM_ACC_QUEUE 4 } acc_queue[NUM_ACC_QUEUE]; } usm; /** @ordered_wq: used to serialize GT resets and TDRs */ struct workqueue_struct *ordered_wq; /** @uc: micro controllers on the GT */ struct xe_uc uc; /** @gtidle: idle properties of GT */ struct xe_gt_idle gtidle; /** @exec_queue_ops: submission backend exec queue operations */ const struct xe_exec_queue_ops *exec_queue_ops; /** * @ring_ops: ring operations for this hw engine (1 per engine class) */ const struct xe_ring_ops *ring_ops[XE_ENGINE_CLASS_MAX]; /** @fence_irq: fence IRQs (1 per engine class) */ struct xe_hw_fence_irq fence_irq[XE_ENGINE_CLASS_MAX]; /** @default_lrc: default LRC state */ void *default_lrc[XE_ENGINE_CLASS_MAX]; /** @hw_engines: hardware engines on the GT */ struct xe_hw_engine hw_engines[XE_NUM_HW_ENGINES]; /** @eclass: per hardware engine class interface on the GT */ struct xe_hw_engine_class_intf eclass[XE_ENGINE_CLASS_MAX]; /** @pcode: GT's PCODE */ struct { /** @pcode.lock: protecting GT's PCODE mailbox data */ struct mutex lock; } pcode; /** @sysfs: sysfs' kobj used by xe_gt_sysfs */ struct kobject *sysfs; /** @freq: Main GT freq sysfs control */ struct kobject *freq; /** @mocs: info */ struct { /** @mocs.uc_index: UC index */ u8 uc_index; /** @mocs.wb_index: WB index, only used on L3_CCS platforms */ u8 wb_index; } mocs; /** @fuse_topo: GT topology reported by fuse registers */ struct { /** @fuse_topo.g_dss_mask: dual-subslices usable by geometry */ xe_dss_mask_t g_dss_mask; /** @fuse_topo.c_dss_mask: dual-subslices usable by compute */ xe_dss_mask_t c_dss_mask; /** @fuse_topo.eu_mask_per_dss: EU mask per DSS*/ xe_eu_mask_t eu_mask_per_dss; } fuse_topo; /** @steering: register steering for individual HW units */ struct { /** @steering.ranges: register ranges used for this steering type */ const struct xe_mmio_range *ranges; /** @steering.group_target: target to steer accesses to */ u16 group_target; /** @steering.instance_target: instance to steer accesses to */ u16 instance_target; } steering[NUM_STEERING_TYPES]; /** * @mcr_lock: protects the MCR_SELECTOR register for the duration * of a steered operation */ spinlock_t mcr_lock; /** @wa_active: keep track of active workarounds */ struct { /** @wa_active.gt: bitmap with active GT workarounds */ unsigned long *gt; /** @wa_active.engine: bitmap with active engine workarounds */ unsigned long *engine; /** @wa_active.lrc: bitmap with active LRC workarounds */ unsigned long *lrc; /** @wa_active.oob: bitmap with active OOB workaroudns */ unsigned long *oob; } wa_active; }; #endif