| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| James Morse | 11112 | 94.23% | 20 | 83.33% |
| Rohit Mathew | 604 | 5.12% | 2 | 8.33% |
| Ben Horgan | 76 | 0.64% | 2 | 8.33% |
| Total | 11792 | 24 |
// SPDX-License-Identifier: GPL-2.0 // Copyright (C) 2025 Arm Ltd. #define pr_fmt(fmt) "%s:%s: " fmt, KBUILD_MODNAME, __func__ #include <linux/acpi.h> #include <linux/atomic.h> #include <linux/arm_mpam.h> #include <linux/bitfield.h> #include <linux/bitmap.h> #include <linux/cacheinfo.h> #include <linux/cpu.h> #include <linux/cpumask.h> #include <linux/device.h> #include <linux/errno.h> #include <linux/gfp.h> #include <linux/interrupt.h> #include <linux/irq.h> #include <linux/irqdesc.h> #include <linux/list.h> #include <linux/lockdep.h> #include <linux/mutex.h> #include <linux/platform_device.h> #include <linux/printk.h> #include <linux/srcu.h> #include <linux/spinlock.h> #include <linux/types.h> #include <linux/workqueue.h> #include "mpam_internal.h" DEFINE_STATIC_KEY_FALSE(mpam_enabled); /* This moves to arch code */ /* * mpam_list_lock protects the SRCU lists when writing. Once the * mpam_enabled key is enabled these lists are read-only, * unless the error interrupt disables the driver. */ static DEFINE_MUTEX(mpam_list_lock); static LIST_HEAD(mpam_all_msc); struct srcu_struct mpam_srcu; /* * Number of MSCs that have been probed. Once all MSCs have been probed MPAM * can be enabled. */ static atomic_t mpam_num_msc; static int mpam_cpuhp_state; static DEFINE_MUTEX(mpam_cpuhp_state_lock); /* * The smallest common values for any CPU or MSC in the system. * Generating traffic outside this range will result in screaming interrupts. */ u16 mpam_partid_max; u8 mpam_pmg_max; static bool partid_max_init, partid_max_published; static DEFINE_SPINLOCK(partid_max_lock); /* * mpam is enabled once all devices have been probed from CPU online callbacks, * scheduled via this work_struct. If access to an MSC depends on a CPU that * was not brought online at boot, this can happen surprisingly late. */ static DECLARE_WORK(mpam_enable_work, &mpam_enable); /* * All mpam error interrupts indicate a software bug. On receipt, disable the * driver. */ static DECLARE_WORK(mpam_broken_work, &mpam_disable); /* When mpam is disabled, the printed reason to aid debugging */ static char *mpam_disable_reason; /* * An MSC is a physical container for controls and monitors, each identified by * their RIS index. These share a base-address, interrupts and some MMIO * registers. A vMSC is a virtual container for RIS in an MSC that control or * monitor the same thing. Members of a vMSC are all RIS in the same MSC, but * not all RIS in an MSC share a vMSC. * * Components are a group of vMSC that control or monitor the same thing but * are from different MSC, so have different base-address, interrupts etc. * Classes are the set components of the same type. * * The features of a vMSC is the union of the RIS it contains. * The features of a Class and Component are the common subset of the vMSC * they contain. * * e.g. The system cache may have bandwidth controls on multiple interfaces, * for regulating traffic from devices independently of traffic from CPUs. * If these are two RIS in one MSC, they will be treated as controlling * different things, and will not share a vMSC/component/class. * * e.g. The L2 may have one MSC and two RIS, one for cache-controls another * for bandwidth. These two RIS are members of the same vMSC. * * e.g. The set of RIS that make up the L2 are grouped as a component. These * are sometimes termed slices. They should be configured the same, as if there * were only one. * * e.g. The SoC probably has more than one L2, each attached to a distinct set * of CPUs. All the L2 components are grouped as a class. * * When creating an MSC, struct mpam_msc is added to the all mpam_all_msc list, * then linked via struct mpam_ris to a vmsc, component and class. * The same MSC may exist under different class->component->vmsc paths, but the * RIS index will be unique. */ LIST_HEAD(mpam_classes); /* List of all objects that can be free()d after synchronise_srcu() */ static LLIST_HEAD(mpam_garbage); static inline void init_garbage(struct mpam_garbage *garbage) { init_llist_node(&garbage->llist); } #define add_to_garbage(x) \ do { \ __typeof__(x) _x = (x); \ _x->garbage.to_free = _x; \ llist_add(&_x->garbage.llist, &mpam_garbage); \ } while (0) static void mpam_free_garbage(void) { struct mpam_garbage *iter, *tmp; struct llist_node *to_free = llist_del_all(&mpam_garbage); if (!to_free) return; synchronize_srcu(&mpam_srcu); llist_for_each_entry_safe(iter, tmp, to_free, llist) { if (iter->pdev) devm_kfree(&iter->pdev->dev, iter->to_free); else kfree(iter->to_free); } } /* * Once mpam is enabled, new requestors cannot further reduce the available * partid. Assert that the size is fixed, and new requestors will be turned * away. */ static void mpam_assert_partid_sizes_fixed(void) { WARN_ON_ONCE(!partid_max_published); } static u32 __mpam_read_reg(struct mpam_msc *msc, u16 reg) { WARN_ON_ONCE(!cpumask_test_cpu(smp_processor_id(), &msc->accessibility)); return readl_relaxed(msc->mapped_hwpage + reg); } static inline u32 _mpam_read_partsel_reg(struct mpam_msc *msc, u16 reg) { lockdep_assert_held_once(&msc->part_sel_lock); return __mpam_read_reg(msc, reg); } #define mpam_read_partsel_reg(msc, reg) _mpam_read_partsel_reg(msc, MPAMF_##reg) static void __mpam_write_reg(struct mpam_msc *msc, u16 reg, u32 val) { WARN_ON_ONCE(reg + sizeof(u32) > msc->mapped_hwpage_sz); WARN_ON_ONCE(!cpumask_test_cpu(smp_processor_id(), &msc->accessibility)); writel_relaxed(val, msc->mapped_hwpage + reg); } static inline void _mpam_write_partsel_reg(struct mpam_msc *msc, u16 reg, u32 val) { lockdep_assert_held_once(&msc->part_sel_lock); __mpam_write_reg(msc, reg, val); } #define mpam_write_partsel_reg(msc, reg, val) _mpam_write_partsel_reg(msc, MPAMCFG_##reg, val) static inline u32 _mpam_read_monsel_reg(struct mpam_msc *msc, u16 reg) { mpam_mon_sel_lock_held(msc); return __mpam_read_reg(msc, reg); } #define mpam_read_monsel_reg(msc, reg) _mpam_read_monsel_reg(msc, MSMON_##reg) static inline void _mpam_write_monsel_reg(struct mpam_msc *msc, u16 reg, u32 val) { mpam_mon_sel_lock_held(msc); __mpam_write_reg(msc, reg, val); } #define mpam_write_monsel_reg(msc, reg, val) _mpam_write_monsel_reg(msc, MSMON_##reg, val) static u64 mpam_msc_read_idr(struct mpam_msc *msc) { u64 idr_high = 0, idr_low; lockdep_assert_held(&msc->part_sel_lock); idr_low = mpam_read_partsel_reg(msc, IDR); if (FIELD_GET(MPAMF_IDR_EXT, idr_low)) idr_high = mpam_read_partsel_reg(msc, IDR + 4); return (idr_high << 32) | idr_low; } static void mpam_msc_clear_esr(struct mpam_msc *msc) { u64 esr_low = __mpam_read_reg(msc, MPAMF_ESR); if (!esr_low) return; /* * Clearing the high/low bits of MPAMF_ESR can not be atomic. * Clear the top half first, so that the pending error bits in the * lower half prevent hardware from updating either half of the * register. */ if (msc->has_extd_esr) __mpam_write_reg(msc, MPAMF_ESR + 4, 0); __mpam_write_reg(msc, MPAMF_ESR, 0); } static u64 mpam_msc_read_esr(struct mpam_msc *msc) { u64 esr_high = 0, esr_low; esr_low = __mpam_read_reg(msc, MPAMF_ESR); if (msc->has_extd_esr) esr_high = __mpam_read_reg(msc, MPAMF_ESR + 4); return (esr_high << 32) | esr_low; } static void __mpam_part_sel_raw(u32 partsel, struct mpam_msc *msc) { lockdep_assert_held(&msc->part_sel_lock); mpam_write_partsel_reg(msc, PART_SEL, partsel); } static void __mpam_part_sel(u8 ris_idx, u16 partid, struct mpam_msc *msc) { u32 partsel = FIELD_PREP(MPAMCFG_PART_SEL_RIS, ris_idx) | FIELD_PREP(MPAMCFG_PART_SEL_PARTID_SEL, partid); __mpam_part_sel_raw(partsel, msc); } static void __mpam_intpart_sel(u8 ris_idx, u16 intpartid, struct mpam_msc *msc) { u32 partsel = FIELD_PREP(MPAMCFG_PART_SEL_RIS, ris_idx) | FIELD_PREP(MPAMCFG_PART_SEL_PARTID_SEL, intpartid) | MPAMCFG_PART_SEL_INTERNAL; __mpam_part_sel_raw(partsel, msc); } int mpam_register_requestor(u16 partid_max, u8 pmg_max) { guard(spinlock)(&partid_max_lock); if (!partid_max_init) { mpam_partid_max = partid_max; mpam_pmg_max = pmg_max; partid_max_init = true; } else if (!partid_max_published) { mpam_partid_max = min(mpam_partid_max, partid_max); mpam_pmg_max = min(mpam_pmg_max, pmg_max); } else { /* New requestors can't lower the values */ if (partid_max < mpam_partid_max || pmg_max < mpam_pmg_max) return -EBUSY; } return 0; } EXPORT_SYMBOL(mpam_register_requestor); static struct mpam_class * mpam_class_alloc(u8 level_idx, enum mpam_class_types type) { struct mpam_class *class; lockdep_assert_held(&mpam_list_lock); class = kzalloc(sizeof(*class), GFP_KERNEL); if (!class) return ERR_PTR(-ENOMEM); init_garbage(&class->garbage); INIT_LIST_HEAD_RCU(&class->components); /* Affinity is updated when ris are added */ class->level = level_idx; class->type = type; INIT_LIST_HEAD_RCU(&class->classes_list); ida_init(&class->ida_csu_mon); ida_init(&class->ida_mbwu_mon); list_add_rcu(&class->classes_list, &mpam_classes); return class; } static void mpam_class_destroy(struct mpam_class *class) { lockdep_assert_held(&mpam_list_lock); list_del_rcu(&class->classes_list); add_to_garbage(class); } static struct mpam_class * mpam_class_find(u8 level_idx, enum mpam_class_types type) { struct mpam_class *class; lockdep_assert_held(&mpam_list_lock); list_for_each_entry(class, &mpam_classes, classes_list) { if (class->type == type && class->level == level_idx) return class; } return mpam_class_alloc(level_idx, type); } static struct mpam_component * mpam_component_alloc(struct mpam_class *class, int id) { struct mpam_component *comp; lockdep_assert_held(&mpam_list_lock); comp = kzalloc(sizeof(*comp), GFP_KERNEL); if (!comp) return ERR_PTR(-ENOMEM); init_garbage(&comp->garbage); comp->comp_id = id; INIT_LIST_HEAD_RCU(&comp->vmsc); /* Affinity is updated when RIS are added */ INIT_LIST_HEAD_RCU(&comp->class_list); comp->class = class; list_add_rcu(&comp->class_list, &class->components); return comp; } static void __destroy_component_cfg(struct mpam_component *comp); static void mpam_component_destroy(struct mpam_component *comp) { struct mpam_class *class = comp->class; lockdep_assert_held(&mpam_list_lock); __destroy_component_cfg(comp); list_del_rcu(&comp->class_list); add_to_garbage(comp); if (list_empty(&class->components)) mpam_class_destroy(class); } static struct mpam_component * mpam_component_find(struct mpam_class *class, int id) { struct mpam_component *comp; lockdep_assert_held(&mpam_list_lock); list_for_each_entry(comp, &class->components, class_list) { if (comp->comp_id == id) return comp; } return mpam_component_alloc(class, id); } static struct mpam_vmsc * mpam_vmsc_alloc(struct mpam_component *comp, struct mpam_msc *msc) { struct mpam_vmsc *vmsc; lockdep_assert_held(&mpam_list_lock); vmsc = kzalloc(sizeof(*vmsc), GFP_KERNEL); if (!vmsc) return ERR_PTR(-ENOMEM); init_garbage(&vmsc->garbage); INIT_LIST_HEAD_RCU(&vmsc->ris); INIT_LIST_HEAD_RCU(&vmsc->comp_list); vmsc->comp = comp; vmsc->msc = msc; list_add_rcu(&vmsc->comp_list, &comp->vmsc); return vmsc; } static void mpam_vmsc_destroy(struct mpam_vmsc *vmsc) { struct mpam_component *comp = vmsc->comp; lockdep_assert_held(&mpam_list_lock); list_del_rcu(&vmsc->comp_list); add_to_garbage(vmsc); if (list_empty(&comp->vmsc)) mpam_component_destroy(comp); } static struct mpam_vmsc * mpam_vmsc_find(struct mpam_component *comp, struct mpam_msc *msc) { struct mpam_vmsc *vmsc; lockdep_assert_held(&mpam_list_lock); list_for_each_entry(vmsc, &comp->vmsc, comp_list) { if (vmsc->msc->id == msc->id) return vmsc; } return mpam_vmsc_alloc(comp, msc); } /* * The cacheinfo structures are only populated when CPUs are online. * This helper walks the acpi tables to include offline CPUs too. */ int mpam_get_cpumask_from_cache_id(unsigned long cache_id, u32 cache_level, cpumask_t *affinity) { return acpi_pptt_get_cpumask_from_cache_id(cache_id, affinity); } /* * cpumask_of_node() only knows about online CPUs. This can't tell us whether * a class is represented on all possible CPUs. */ static void get_cpumask_from_node_id(u32 node_id, cpumask_t *affinity) { int cpu; for_each_possible_cpu(cpu) { if (node_id == cpu_to_node(cpu)) cpumask_set_cpu(cpu, affinity); } } static int mpam_ris_get_affinity(struct mpam_msc *msc, cpumask_t *affinity, enum mpam_class_types type, struct mpam_class *class, struct mpam_component *comp) { int err; switch (type) { case MPAM_CLASS_CACHE: err = mpam_get_cpumask_from_cache_id(comp->comp_id, class->level, affinity); if (err) { dev_warn_once(&msc->pdev->dev, "Failed to determine CPU affinity\n"); return err; } if (cpumask_empty(affinity)) dev_warn_once(&msc->pdev->dev, "no CPUs associated with cache node\n"); break; case MPAM_CLASS_MEMORY: get_cpumask_from_node_id(comp->comp_id, affinity); /* affinity may be empty for CPU-less memory nodes */ break; case MPAM_CLASS_UNKNOWN: return 0; } cpumask_and(affinity, affinity, &msc->accessibility); return 0; } static int mpam_ris_create_locked(struct mpam_msc *msc, u8 ris_idx, enum mpam_class_types type, u8 class_id, int component_id) { int err; struct mpam_vmsc *vmsc; struct mpam_msc_ris *ris; struct mpam_class *class; struct mpam_component *comp; struct platform_device *pdev = msc->pdev; lockdep_assert_held(&mpam_list_lock); if (ris_idx > MPAM_MSC_MAX_NUM_RIS) return -EINVAL; if (test_and_set_bit(ris_idx, &msc->ris_idxs)) return -EBUSY; ris = devm_kzalloc(&msc->pdev->dev, sizeof(*ris), GFP_KERNEL); if (!ris) return -ENOMEM; init_garbage(&ris->garbage); ris->garbage.pdev = pdev; class = mpam_class_find(class_id, type); if (IS_ERR(class)) return PTR_ERR(class); comp = mpam_component_find(class, component_id); if (IS_ERR(comp)) { if (list_empty(&class->components)) mpam_class_destroy(class); return PTR_ERR(comp); } vmsc = mpam_vmsc_find(comp, msc); if (IS_ERR(vmsc)) { if (list_empty(&comp->vmsc)) mpam_component_destroy(comp); return PTR_ERR(vmsc); } err = mpam_ris_get_affinity(msc, &ris->affinity, type, class, comp); if (err) { if (list_empty(&vmsc->ris)) mpam_vmsc_destroy(vmsc); return err; } ris->ris_idx = ris_idx; INIT_LIST_HEAD_RCU(&ris->msc_list); INIT_LIST_HEAD_RCU(&ris->vmsc_list); ris->vmsc = vmsc; cpumask_or(&comp->affinity, &comp->affinity, &ris->affinity); cpumask_or(&class->affinity, &class->affinity, &ris->affinity); list_add_rcu(&ris->vmsc_list, &vmsc->ris); list_add_rcu(&ris->msc_list, &msc->ris); return 0; } static void mpam_ris_destroy(struct mpam_msc_ris *ris) { struct mpam_vmsc *vmsc = ris->vmsc; struct mpam_msc *msc = vmsc->msc; struct mpam_component *comp = vmsc->comp; struct mpam_class *class = comp->class; lockdep_assert_held(&mpam_list_lock); /* * It is assumed affinities don't overlap. If they do the class becomes * unusable immediately. */ cpumask_andnot(&class->affinity, &class->affinity, &ris->affinity); cpumask_andnot(&comp->affinity, &comp->affinity, &ris->affinity); clear_bit(ris->ris_idx, &msc->ris_idxs); list_del_rcu(&ris->msc_list); list_del_rcu(&ris->vmsc_list); add_to_garbage(ris); if (list_empty(&vmsc->ris)) mpam_vmsc_destroy(vmsc); } int mpam_ris_create(struct mpam_msc *msc, u8 ris_idx, enum mpam_class_types type, u8 class_id, int component_id) { int err; mutex_lock(&mpam_list_lock); err = mpam_ris_create_locked(msc, ris_idx, type, class_id, component_id); mutex_unlock(&mpam_list_lock); if (err) mpam_free_garbage(); return err; } static struct mpam_msc_ris *mpam_get_or_create_ris(struct mpam_msc *msc, u8 ris_idx) { int err; struct mpam_msc_ris *ris; lockdep_assert_held(&mpam_list_lock); if (!test_bit(ris_idx, &msc->ris_idxs)) { err = mpam_ris_create_locked(msc, ris_idx, MPAM_CLASS_UNKNOWN, 0, 0); if (err) return ERR_PTR(err); } list_for_each_entry(ris, &msc->ris, msc_list) { if (ris->ris_idx == ris_idx) return ris; } return ERR_PTR(-ENOENT); } /* * IHI009A.a has this nugget: "If a monitor does not support automatic behaviour * of NRDY, software can use this bit for any purpose" - so hardware might not * implement this - but it isn't RES0. * * Try and see what values stick in this bit. If we can write either value, * its probably not implemented by hardware. */ static bool _mpam_ris_hw_probe_hw_nrdy(struct mpam_msc_ris *ris, u32 mon_reg) { u32 now; u64 mon_sel; bool can_set, can_clear; struct mpam_msc *msc = ris->vmsc->msc; if (WARN_ON_ONCE(!mpam_mon_sel_lock(msc))) return false; mon_sel = FIELD_PREP(MSMON_CFG_MON_SEL_MON_SEL, 0) | FIELD_PREP(MSMON_CFG_MON_SEL_RIS, ris->ris_idx); _mpam_write_monsel_reg(msc, mon_reg, mon_sel); _mpam_write_monsel_reg(msc, mon_reg, MSMON___NRDY); now = _mpam_read_monsel_reg(msc, mon_reg); can_set = now & MSMON___NRDY; _mpam_write_monsel_reg(msc, mon_reg, 0); now = _mpam_read_monsel_reg(msc, mon_reg); can_clear = !(now & MSMON___NRDY); mpam_mon_sel_unlock(msc); return (!can_set || !can_clear); } #define mpam_ris_hw_probe_hw_nrdy(_ris, _mon_reg) \ _mpam_ris_hw_probe_hw_nrdy(_ris, MSMON_##_mon_reg) static void mpam_ris_hw_probe(struct mpam_msc_ris *ris) { int err; struct mpam_msc *msc = ris->vmsc->msc; struct device *dev = &msc->pdev->dev; struct mpam_props *props = &ris->props; struct mpam_class *class = ris->vmsc->comp->class; lockdep_assert_held(&msc->probe_lock); lockdep_assert_held(&msc->part_sel_lock); /* Cache Capacity Partitioning */ if (FIELD_GET(MPAMF_IDR_HAS_CCAP_PART, ris->idr)) { u32 ccap_features = mpam_read_partsel_reg(msc, CCAP_IDR); props->cmax_wd = FIELD_GET(MPAMF_CCAP_IDR_CMAX_WD, ccap_features); if (props->cmax_wd && FIELD_GET(MPAMF_CCAP_IDR_HAS_CMAX_SOFTLIM, ccap_features)) mpam_set_feature(mpam_feat_cmax_softlim, props); if (props->cmax_wd && !FIELD_GET(MPAMF_CCAP_IDR_NO_CMAX, ccap_features)) mpam_set_feature(mpam_feat_cmax_cmax, props); if (props->cmax_wd && FIELD_GET(MPAMF_CCAP_IDR_HAS_CMIN, ccap_features)) mpam_set_feature(mpam_feat_cmax_cmin, props); props->cassoc_wd = FIELD_GET(MPAMF_CCAP_IDR_CASSOC_WD, ccap_features); if (props->cassoc_wd && FIELD_GET(MPAMF_CCAP_IDR_HAS_CASSOC, ccap_features)) mpam_set_feature(mpam_feat_cmax_cassoc, props); } /* Cache Portion partitioning */ if (FIELD_GET(MPAMF_IDR_HAS_CPOR_PART, ris->idr)) { u32 cpor_features = mpam_read_partsel_reg(msc, CPOR_IDR); props->cpbm_wd = FIELD_GET(MPAMF_CPOR_IDR_CPBM_WD, cpor_features); if (props->cpbm_wd) mpam_set_feature(mpam_feat_cpor_part, props); } /* Memory bandwidth partitioning */ if (FIELD_GET(MPAMF_IDR_HAS_MBW_PART, ris->idr)) { u32 mbw_features = mpam_read_partsel_reg(msc, MBW_IDR); /* portion bitmap resolution */ props->mbw_pbm_bits = FIELD_GET(MPAMF_MBW_IDR_BWPBM_WD, mbw_features); if (props->mbw_pbm_bits && FIELD_GET(MPAMF_MBW_IDR_HAS_PBM, mbw_features)) mpam_set_feature(mpam_feat_mbw_part, props); props->bwa_wd = FIELD_GET(MPAMF_MBW_IDR_BWA_WD, mbw_features); if (props->bwa_wd && FIELD_GET(MPAMF_MBW_IDR_HAS_MAX, mbw_features)) mpam_set_feature(mpam_feat_mbw_max, props); if (props->bwa_wd && FIELD_GET(MPAMF_MBW_IDR_HAS_MIN, mbw_features)) mpam_set_feature(mpam_feat_mbw_min, props); if (props->bwa_wd && FIELD_GET(MPAMF_MBW_IDR_HAS_PROP, mbw_features)) mpam_set_feature(mpam_feat_mbw_prop, props); } /* Priority partitioning */ if (FIELD_GET(MPAMF_IDR_HAS_PRI_PART, ris->idr)) { u32 pri_features = mpam_read_partsel_reg(msc, PRI_IDR); props->intpri_wd = FIELD_GET(MPAMF_PRI_IDR_INTPRI_WD, pri_features); if (props->intpri_wd && FIELD_GET(MPAMF_PRI_IDR_HAS_INTPRI, pri_features)) { mpam_set_feature(mpam_feat_intpri_part, props); if (FIELD_GET(MPAMF_PRI_IDR_INTPRI_0_IS_LOW, pri_features)) mpam_set_feature(mpam_feat_intpri_part_0_low, props); } props->dspri_wd = FIELD_GET(MPAMF_PRI_IDR_DSPRI_WD, pri_features); if (props->dspri_wd && FIELD_GET(MPAMF_PRI_IDR_HAS_DSPRI, pri_features)) { mpam_set_feature(mpam_feat_dspri_part, props); if (FIELD_GET(MPAMF_PRI_IDR_DSPRI_0_IS_LOW, pri_features)) mpam_set_feature(mpam_feat_dspri_part_0_low, props); } } /* Performance Monitoring */ if (FIELD_GET(MPAMF_IDR_HAS_MSMON, ris->idr)) { u32 msmon_features = mpam_read_partsel_reg(msc, MSMON_IDR); /* * If the firmware max-nrdy-us property is missing, the * CSU counters can't be used. Should we wait forever? */ err = device_property_read_u32(&msc->pdev->dev, "arm,not-ready-us", &msc->nrdy_usec); if (FIELD_GET(MPAMF_MSMON_IDR_MSMON_CSU, msmon_features)) { u32 csumonidr; csumonidr = mpam_read_partsel_reg(msc, CSUMON_IDR); props->num_csu_mon = FIELD_GET(MPAMF_CSUMON_IDR_NUM_MON, csumonidr); if (props->num_csu_mon) { bool hw_managed; mpam_set_feature(mpam_feat_msmon_csu, props); if (FIELD_GET(MPAMF_CSUMON_IDR_HAS_XCL, csumonidr)) mpam_set_feature(mpam_feat_msmon_csu_xcl, props); /* Is NRDY hardware managed? */ hw_managed = mpam_ris_hw_probe_hw_nrdy(ris, CSU); if (hw_managed) mpam_set_feature(mpam_feat_msmon_csu_hw_nrdy, props); } /* * Accept the missing firmware property if NRDY appears * un-implemented. */ if (err && mpam_has_feature(mpam_feat_msmon_csu_hw_nrdy, props)) dev_err_once(dev, "Counters are not usable because not-ready timeout was not provided by firmware."); } if (FIELD_GET(MPAMF_MSMON_IDR_MSMON_MBWU, msmon_features)) { bool has_long, hw_managed; u32 mbwumon_idr = mpam_read_partsel_reg(msc, MBWUMON_IDR); props->num_mbwu_mon = FIELD_GET(MPAMF_MBWUMON_IDR_NUM_MON, mbwumon_idr); if (props->num_mbwu_mon) { mpam_set_feature(mpam_feat_msmon_mbwu, props); if (FIELD_GET(MPAMF_MBWUMON_IDR_HAS_RWBW, mbwumon_idr)) mpam_set_feature(mpam_feat_msmon_mbwu_rwbw, props); has_long = FIELD_GET(MPAMF_MBWUMON_IDR_HAS_LONG, mbwumon_idr); if (has_long) { if (FIELD_GET(MPAMF_MBWUMON_IDR_LWD, mbwumon_idr)) mpam_set_feature(mpam_feat_msmon_mbwu_63counter, props); else mpam_set_feature(mpam_feat_msmon_mbwu_44counter, props); } else { mpam_set_feature(mpam_feat_msmon_mbwu_31counter, props); } /* Is NRDY hardware managed? */ hw_managed = mpam_ris_hw_probe_hw_nrdy(ris, MBWU); if (hw_managed) mpam_set_feature(mpam_feat_msmon_mbwu_hw_nrdy, props); /* * Don't warn about any missing firmware property for * MBWU NRDY - it doesn't make any sense! */ } } } /* * RIS with PARTID narrowing don't have enough storage for one * configuration per PARTID. If these are in a class we could use, * reduce the supported partid_max to match the number of intpartid. * If the class is unknown, just ignore it. */ if (FIELD_GET(MPAMF_IDR_HAS_PARTID_NRW, ris->idr) && class->type != MPAM_CLASS_UNKNOWN) { u32 nrwidr = mpam_read_partsel_reg(msc, PARTID_NRW_IDR); u16 partid_max = FIELD_GET(MPAMF_PARTID_NRW_IDR_INTPARTID_MAX, nrwidr); mpam_set_feature(mpam_feat_partid_nrw, props); msc->partid_max = min(msc->partid_max, partid_max); } } static int mpam_msc_hw_probe(struct mpam_msc *msc) { u64 idr; u16 partid_max; u8 ris_idx, pmg_max; struct mpam_msc_ris *ris; struct device *dev = &msc->pdev->dev; lockdep_assert_held(&msc->probe_lock); idr = __mpam_read_reg(msc, MPAMF_AIDR); if ((idr & MPAMF_AIDR_ARCH_MAJOR_REV) != MPAM_ARCHITECTURE_V1) { dev_err_once(dev, "MSC does not match MPAM architecture v1.x\n"); return -EIO; } /* Grab an IDR value to find out how many RIS there are */ mutex_lock(&msc->part_sel_lock); idr = mpam_msc_read_idr(msc); mutex_unlock(&msc->part_sel_lock); msc->ris_max = FIELD_GET(MPAMF_IDR_RIS_MAX, idr); /* Use these values so partid/pmg always starts with a valid value */ msc->partid_max = FIELD_GET(MPAMF_IDR_PARTID_MAX, idr); msc->pmg_max = FIELD_GET(MPAMF_IDR_PMG_MAX, idr); for (ris_idx = 0; ris_idx <= msc->ris_max; ris_idx++) { mutex_lock(&msc->part_sel_lock); __mpam_part_sel(ris_idx, 0, msc); idr = mpam_msc_read_idr(msc); mutex_unlock(&msc->part_sel_lock); partid_max = FIELD_GET(MPAMF_IDR_PARTID_MAX, idr); pmg_max = FIELD_GET(MPAMF_IDR_PMG_MAX, idr); msc->partid_max = min(msc->partid_max, partid_max); msc->pmg_max = min(msc->pmg_max, pmg_max); msc->has_extd_esr = FIELD_GET(MPAMF_IDR_HAS_EXTD_ESR, idr); mutex_lock(&mpam_list_lock); ris = mpam_get_or_create_ris(msc, ris_idx); mutex_unlock(&mpam_list_lock); if (IS_ERR(ris)) return PTR_ERR(ris); ris->idr = idr; mutex_lock(&msc->part_sel_lock); __mpam_part_sel(ris_idx, 0, msc); mpam_ris_hw_probe(ris); mutex_unlock(&msc->part_sel_lock); } /* Clear any stale errors */ mpam_msc_clear_esr(msc); spin_lock(&partid_max_lock); mpam_partid_max = min(mpam_partid_max, msc->partid_max); mpam_pmg_max = min(mpam_pmg_max, msc->pmg_max); spin_unlock(&partid_max_lock); msc->probed = true; return 0; } struct mon_read { struct mpam_msc_ris *ris; struct mon_cfg *ctx; enum mpam_device_features type; u64 *val; int err; }; static bool mpam_ris_has_mbwu_long_counter(struct mpam_msc_ris *ris) { return (mpam_has_feature(mpam_feat_msmon_mbwu_63counter, &ris->props) || mpam_has_feature(mpam_feat_msmon_mbwu_44counter, &ris->props)); } static u64 mpam_msc_read_mbwu_l(struct mpam_msc *msc) { int retry = 3; u32 mbwu_l_low; u64 mbwu_l_high1, mbwu_l_high2; mpam_mon_sel_lock_held(msc); WARN_ON_ONCE((MSMON_MBWU_L + sizeof(u64)) > msc->mapped_hwpage_sz); WARN_ON_ONCE(!cpumask_test_cpu(smp_processor_id(), &msc->accessibility)); mbwu_l_high2 = __mpam_read_reg(msc, MSMON_MBWU_L + 4); do { mbwu_l_high1 = mbwu_l_high2; mbwu_l_low = __mpam_read_reg(msc, MSMON_MBWU_L); mbwu_l_high2 = __mpam_read_reg(msc, MSMON_MBWU_L + 4); retry--; } while (mbwu_l_high1 != mbwu_l_high2 && retry > 0); if (mbwu_l_high1 == mbwu_l_high2) return (mbwu_l_high1 << 32) | mbwu_l_low; pr_warn("Failed to read a stable value\n"); return MSMON___L_NRDY; } static void mpam_msc_zero_mbwu_l(struct mpam_msc *msc) { mpam_mon_sel_lock_held(msc); WARN_ON_ONCE((MSMON_MBWU_L + sizeof(u64)) > msc->mapped_hwpage_sz); WARN_ON_ONCE(!cpumask_test_cpu(smp_processor_id(), &msc->accessibility)); __mpam_write_reg(msc, MSMON_MBWU_L, 0); __mpam_write_reg(msc, MSMON_MBWU_L + 4, 0); } static void gen_msmon_ctl_flt_vals(struct mon_read *m, u32 *ctl_val, u32 *flt_val) { struct mon_cfg *ctx = m->ctx; /* * For CSU counters its implementation-defined what happens when not * filtering by partid. */ *ctl_val = MSMON_CFG_x_CTL_MATCH_PARTID; *flt_val = FIELD_PREP(MSMON_CFG_x_FLT_PARTID, ctx->partid); if (m->ctx->match_pmg) { *ctl_val |= MSMON_CFG_x_CTL_MATCH_PMG; *flt_val |= FIELD_PREP(MSMON_CFG_x_FLT_PMG, ctx->pmg); } switch (m->type) { case mpam_feat_msmon_csu: *ctl_val |= MSMON_CFG_CSU_CTL_TYPE_CSU; if (mpam_has_feature(mpam_feat_msmon_csu_xcl, &m->ris->props)) *flt_val |= FIELD_PREP(MSMON_CFG_CSU_FLT_XCL, ctx->csu_exclude_clean); break; case mpam_feat_msmon_mbwu_31counter: case mpam_feat_msmon_mbwu_44counter: case mpam_feat_msmon_mbwu_63counter: *ctl_val |= MSMON_CFG_MBWU_CTL_TYPE_MBWU; if (mpam_has_feature(mpam_feat_msmon_mbwu_rwbw, &m->ris->props)) *flt_val |= FIELD_PREP(MSMON_CFG_MBWU_FLT_RWBW, ctx->opts); break; default: pr_warn("Unexpected monitor type %d\n", m->type); } } static void read_msmon_ctl_flt_vals(struct mon_read *m, u32 *ctl_val, u32 *flt_val) { struct mpam_msc *msc = m->ris->vmsc->msc; switch (m->type) { case mpam_feat_msmon_csu: *ctl_val = mpam_read_monsel_reg(msc, CFG_CSU_CTL); *flt_val = mpam_read_monsel_reg(msc, CFG_CSU_FLT); break; case mpam_feat_msmon_mbwu_31counter: case mpam_feat_msmon_mbwu_44counter: case mpam_feat_msmon_mbwu_63counter: *ctl_val = mpam_read_monsel_reg(msc, CFG_MBWU_CTL); *flt_val = mpam_read_monsel_reg(msc, CFG_MBWU_FLT); break; default: pr_warn("Unexpected monitor type %d\n", m->type); } } /* Remove values set by the hardware to prevent apparent mismatches. */ static inline void clean_msmon_ctl_val(u32 *cur_ctl) { *cur_ctl &= ~MSMON_CFG_x_CTL_OFLOW_STATUS; if (FIELD_GET(MSMON_CFG_x_CTL_TYPE, *cur_ctl) == MSMON_CFG_MBWU_CTL_TYPE_MBWU) *cur_ctl &= ~MSMON_CFG_MBWU_CTL_OFLOW_STATUS_L; } static void write_msmon_ctl_flt_vals(struct mon_read *m, u32 ctl_val, u32 flt_val) { struct mpam_msc *msc = m->ris->vmsc->msc; /* * Write the ctl_val with the enable bit cleared, reset the counter, * then enable counter. */ switch (m->type) { case mpam_feat_msmon_csu: mpam_write_monsel_reg(msc, CFG_CSU_FLT, flt_val); mpam_write_monsel_reg(msc, CFG_CSU_CTL, ctl_val); mpam_write_monsel_reg(msc, CSU, 0); mpam_write_monsel_reg(msc, CFG_CSU_CTL, ctl_val | MSMON_CFG_x_CTL_EN); break; case mpam_feat_msmon_mbwu_31counter: case mpam_feat_msmon_mbwu_44counter: case mpam_feat_msmon_mbwu_63counter: mpam_write_monsel_reg(msc, CFG_MBWU_FLT, flt_val); mpam_write_monsel_reg(msc, CFG_MBWU_CTL, ctl_val); mpam_write_monsel_reg(msc, CFG_MBWU_CTL, ctl_val | MSMON_CFG_x_CTL_EN); /* Counting monitors require NRDY to be reset by software */ if (m->type == mpam_feat_msmon_mbwu_31counter) mpam_write_monsel_reg(msc, MBWU, 0); else mpam_msc_zero_mbwu_l(m->ris->vmsc->msc); break; default: pr_warn("Unexpected monitor type %d\n", m->type); } } static u64 mpam_msmon_overflow_val(enum mpam_device_features type) { /* TODO: implement scaling counters */ switch (type) { case mpam_feat_msmon_mbwu_63counter: return BIT_ULL(hweight_long(MSMON___LWD_VALUE)); case mpam_feat_msmon_mbwu_44counter: return BIT_ULL(hweight_long(MSMON___L_VALUE)); case mpam_feat_msmon_mbwu_31counter: return BIT_ULL(hweight_long(MSMON___VALUE)); default: return 0; } } static void __ris_msmon_read(void *arg) { u64 now; bool nrdy = false; bool config_mismatch; bool overflow = false; struct mon_read *m = arg; struct mon_cfg *ctx = m->ctx; bool reset_on_next_read = false; struct mpam_msc_ris *ris = m->ris; struct msmon_mbwu_state *mbwu_state; struct mpam_props *rprops = &ris->props; struct mpam_msc *msc = m->ris->vmsc->msc; u32 mon_sel, ctl_val, flt_val, cur_ctl, cur_flt; if (!mpam_mon_sel_lock(msc)) { m->err = -EIO; return; } mon_sel = FIELD_PREP(MSMON_CFG_MON_SEL_MON_SEL, ctx->mon) | FIELD_PREP(MSMON_CFG_MON_SEL_RIS, ris->ris_idx); mpam_write_monsel_reg(msc, CFG_MON_SEL, mon_sel); switch (m->type) { case mpam_feat_msmon_mbwu_31counter: case mpam_feat_msmon_mbwu_44counter: case mpam_feat_msmon_mbwu_63counter: mbwu_state = &ris->mbwu_state[ctx->mon]; if (mbwu_state) { reset_on_next_read = mbwu_state->reset_on_next_read; mbwu_state->reset_on_next_read = false; } break; default: break; } /* * Read the existing configuration to avoid re-writing the same values. * This saves waiting for 'nrdy' on subsequent reads. */ read_msmon_ctl_flt_vals(m, &cur_ctl, &cur_flt); if (mpam_feat_msmon_mbwu_31counter == m->type) overflow = cur_ctl & MSMON_CFG_x_CTL_OFLOW_STATUS; else if (mpam_feat_msmon_mbwu_44counter == m->type || mpam_feat_msmon_mbwu_63counter == m->type) overflow = cur_ctl & MSMON_CFG_MBWU_CTL_OFLOW_STATUS_L; clean_msmon_ctl_val(&cur_ctl); gen_msmon_ctl_flt_vals(m, &ctl_val, &flt_val); config_mismatch = cur_flt != flt_val || cur_ctl != (ctl_val | MSMON_CFG_x_CTL_EN); if (config_mismatch || reset_on_next_read) { write_msmon_ctl_flt_vals(m, ctl_val, flt_val); overflow = false; } else if (overflow) { mpam_write_monsel_reg(msc, CFG_MBWU_CTL, cur_ctl & ~(MSMON_CFG_x_CTL_OFLOW_STATUS | MSMON_CFG_MBWU_CTL_OFLOW_STATUS_L)); } switch (m->type) { case mpam_feat_msmon_csu: now = mpam_read_monsel_reg(msc, CSU); if (mpam_has_feature(mpam_feat_msmon_csu_hw_nrdy, rprops)) nrdy = now & MSMON___NRDY; now = FIELD_GET(MSMON___VALUE, now); break; case mpam_feat_msmon_mbwu_31counter: case mpam_feat_msmon_mbwu_44counter: case mpam_feat_msmon_mbwu_63counter: if (m->type != mpam_feat_msmon_mbwu_31counter) { now = mpam_msc_read_mbwu_l(msc); if (mpam_has_feature(mpam_feat_msmon_mbwu_hw_nrdy, rprops)) nrdy = now & MSMON___L_NRDY; if (m->type == mpam_feat_msmon_mbwu_63counter) now = FIELD_GET(MSMON___LWD_VALUE, now); else now = FIELD_GET(MSMON___L_VALUE, now); } else { now = mpam_read_monsel_reg(msc, MBWU); if (mpam_has_feature(mpam_feat_msmon_mbwu_hw_nrdy, rprops)) nrdy = now & MSMON___NRDY; now = FIELD_GET(MSMON___VALUE, now); } if (nrdy) break; mbwu_state = &ris->mbwu_state[ctx->mon]; if (overflow) mbwu_state->correction += mpam_msmon_overflow_val(m->type); /* * Include bandwidth consumed before the last hardware reset and * a counter size increment for each overflow. */ now += mbwu_state->correction; break; default: m->err = -EINVAL; } mpam_mon_sel_unlock(msc); if (nrdy) m->err = -EBUSY; if (m->err) return; *m->val += now; } static int _msmon_read(struct mpam_component *comp, struct mon_read *arg) { int err, any_err = 0; struct mpam_vmsc *vmsc; guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(vmsc, &comp->vmsc, comp_list, srcu_read_lock_held(&mpam_srcu)) { struct mpam_msc *msc = vmsc->msc; struct mpam_msc_ris *ris; list_for_each_entry_srcu(ris, &vmsc->ris, vmsc_list, srcu_read_lock_held(&mpam_srcu)) { arg->ris = ris; err = smp_call_function_any(&msc->accessibility, __ris_msmon_read, arg, true); if (!err && arg->err) err = arg->err; /* * Save one error to be returned to the caller, but * keep reading counters so that get reprogrammed. On * platforms with NRDY this lets us wait once. */ if (err) any_err = err; } } return any_err; } static enum mpam_device_features mpam_msmon_choose_counter(struct mpam_class *class) { struct mpam_props *cprops = &class->props; if (mpam_has_feature(mpam_feat_msmon_mbwu_63counter, cprops)) return mpam_feat_msmon_mbwu_63counter; if (mpam_has_feature(mpam_feat_msmon_mbwu_44counter, cprops)) return mpam_feat_msmon_mbwu_44counter; return mpam_feat_msmon_mbwu_31counter; } int mpam_msmon_read(struct mpam_component *comp, struct mon_cfg *ctx, enum mpam_device_features type, u64 *val) { int err; struct mon_read arg; u64 wait_jiffies = 0; struct mpam_class *class = comp->class; struct mpam_props *cprops = &class->props; might_sleep(); if (!mpam_is_enabled()) return -EIO; if (!mpam_has_feature(type, cprops)) return -EOPNOTSUPP; if (type == mpam_feat_msmon_mbwu) type = mpam_msmon_choose_counter(class); arg = (struct mon_read) { .ctx = ctx, .type = type, .val = val, }; *val = 0; err = _msmon_read(comp, &arg); if (err == -EBUSY && class->nrdy_usec) wait_jiffies = usecs_to_jiffies(class->nrdy_usec); while (wait_jiffies) wait_jiffies = schedule_timeout_uninterruptible(wait_jiffies); if (err == -EBUSY) { arg = (struct mon_read) { .ctx = ctx, .type = type, .val = val, }; *val = 0; err = _msmon_read(comp, &arg); } return err; } void mpam_msmon_reset_mbwu(struct mpam_component *comp, struct mon_cfg *ctx) { struct mpam_msc *msc; struct mpam_vmsc *vmsc; struct mpam_msc_ris *ris; if (!mpam_is_enabled()) return; guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(vmsc, &comp->vmsc, comp_list, srcu_read_lock_held(&mpam_srcu)) { if (!mpam_has_feature(mpam_feat_msmon_mbwu, &vmsc->props)) continue; msc = vmsc->msc; list_for_each_entry_srcu(ris, &vmsc->ris, vmsc_list, srcu_read_lock_held(&mpam_srcu)) { if (!mpam_has_feature(mpam_feat_msmon_mbwu, &ris->props)) continue; if (WARN_ON_ONCE(!mpam_mon_sel_lock(msc))) continue; ris->mbwu_state[ctx->mon].correction = 0; ris->mbwu_state[ctx->mon].reset_on_next_read = true; mpam_mon_sel_unlock(msc); } } } static void mpam_reset_msc_bitmap(struct mpam_msc *msc, u16 reg, u16 wd) { u32 num_words, msb; u32 bm = ~0; int i; lockdep_assert_held(&msc->part_sel_lock); if (wd == 0) return; /* * Write all ~0 to all but the last 32bit-word, which may * have fewer bits... */ num_words = DIV_ROUND_UP(wd, 32); for (i = 0; i < num_words - 1; i++, reg += sizeof(bm)) __mpam_write_reg(msc, reg, bm); /* * ....and then the last (maybe) partial 32bit word. When wd is a * multiple of 32, msb should be 31 to write a full 32bit word. */ msb = (wd - 1) % 32; bm = GENMASK(msb, 0); __mpam_write_reg(msc, reg, bm); } /* Called via IPI. Call while holding an SRCU reference */ static void mpam_reprogram_ris_partid(struct mpam_msc_ris *ris, u16 partid, struct mpam_config *cfg) { u32 pri_val = 0; u16 cmax = MPAMCFG_CMAX_CMAX; struct mpam_msc *msc = ris->vmsc->msc; struct mpam_props *rprops = &ris->props; u16 dspri = GENMASK(rprops->dspri_wd, 0); u16 intpri = GENMASK(rprops->intpri_wd, 0); mutex_lock(&msc->part_sel_lock); __mpam_part_sel(ris->ris_idx, partid, msc); if (mpam_has_feature(mpam_feat_partid_nrw, rprops)) { /* Update the intpartid mapping */ mpam_write_partsel_reg(msc, INTPARTID, MPAMCFG_INTPARTID_INTERNAL | partid); /* * Then switch to the 'internal' partid to update the * configuration. */ __mpam_intpart_sel(ris->ris_idx, partid, msc); } if (mpam_has_feature(mpam_feat_cpor_part, rprops) && mpam_has_feature(mpam_feat_cpor_part, cfg)) { if (cfg->reset_cpbm) mpam_reset_msc_bitmap(msc, MPAMCFG_CPBM, rprops->cpbm_wd); else mpam_write_partsel_reg(msc, CPBM, cfg->cpbm); } if (mpam_has_feature(mpam_feat_mbw_part, rprops) && mpam_has_feature(mpam_feat_mbw_part, cfg)) { if (cfg->reset_mbw_pbm) mpam_reset_msc_bitmap(msc, MPAMCFG_MBW_PBM, rprops->mbw_pbm_bits); else mpam_write_partsel_reg(msc, MBW_PBM, cfg->mbw_pbm); } if (mpam_has_feature(mpam_feat_mbw_min, rprops) && mpam_has_feature(mpam_feat_mbw_min, cfg)) mpam_write_partsel_reg(msc, MBW_MIN, 0); if (mpam_has_feature(mpam_feat_mbw_max, rprops) && mpam_has_feature(mpam_feat_mbw_max, cfg)) { if (cfg->reset_mbw_max) mpam_write_partsel_reg(msc, MBW_MAX, MPAMCFG_MBW_MAX_MAX); else mpam_write_partsel_reg(msc, MBW_MAX, cfg->mbw_max); } if (mpam_has_feature(mpam_feat_mbw_prop, rprops) && mpam_has_feature(mpam_feat_mbw_prop, cfg)) mpam_write_partsel_reg(msc, MBW_PROP, 0); if (mpam_has_feature(mpam_feat_cmax_cmax, rprops)) mpam_write_partsel_reg(msc, CMAX, cmax); if (mpam_has_feature(mpam_feat_cmax_cmin, rprops)) mpam_write_partsel_reg(msc, CMIN, 0); if (mpam_has_feature(mpam_feat_cmax_cassoc, rprops)) mpam_write_partsel_reg(msc, CASSOC, MPAMCFG_CASSOC_CASSOC); if (mpam_has_feature(mpam_feat_intpri_part, rprops) || mpam_has_feature(mpam_feat_dspri_part, rprops)) { /* aces high? */ if (!mpam_has_feature(mpam_feat_intpri_part_0_low, rprops)) intpri = 0; if (!mpam_has_feature(mpam_feat_dspri_part_0_low, rprops)) dspri = 0; if (mpam_has_feature(mpam_feat_intpri_part, rprops)) pri_val |= FIELD_PREP(MPAMCFG_PRI_INTPRI, intpri); if (mpam_has_feature(mpam_feat_dspri_part, rprops)) pri_val |= FIELD_PREP(MPAMCFG_PRI_DSPRI, dspri); mpam_write_partsel_reg(msc, PRI, pri_val); } mutex_unlock(&msc->part_sel_lock); } /* Call with msc cfg_lock held */ static int mpam_restore_mbwu_state(void *_ris) { int i; struct mon_read mwbu_arg; struct mpam_msc_ris *ris = _ris; struct mpam_class *class = ris->vmsc->comp->class; for (i = 0; i < ris->props.num_mbwu_mon; i++) { if (ris->mbwu_state[i].enabled) { mwbu_arg.ris = ris; mwbu_arg.ctx = &ris->mbwu_state[i].cfg; mwbu_arg.type = mpam_msmon_choose_counter(class); __ris_msmon_read(&mwbu_arg); } } return 0; } /* Call with MSC cfg_lock held */ static int mpam_save_mbwu_state(void *arg) { int i; u64 val; struct mon_cfg *cfg; u32 cur_flt, cur_ctl, mon_sel; struct mpam_msc_ris *ris = arg; struct msmon_mbwu_state *mbwu_state; struct mpam_msc *msc = ris->vmsc->msc; for (i = 0; i < ris->props.num_mbwu_mon; i++) { mbwu_state = &ris->mbwu_state[i]; cfg = &mbwu_state->cfg; if (WARN_ON_ONCE(!mpam_mon_sel_lock(msc))) return -EIO; mon_sel = FIELD_PREP(MSMON_CFG_MON_SEL_MON_SEL, i) | FIELD_PREP(MSMON_CFG_MON_SEL_RIS, ris->ris_idx); mpam_write_monsel_reg(msc, CFG_MON_SEL, mon_sel); cur_flt = mpam_read_monsel_reg(msc, CFG_MBWU_FLT); cur_ctl = mpam_read_monsel_reg(msc, CFG_MBWU_CTL); mpam_write_monsel_reg(msc, CFG_MBWU_CTL, 0); if (mpam_ris_has_mbwu_long_counter(ris)) { val = mpam_msc_read_mbwu_l(msc); mpam_msc_zero_mbwu_l(msc); } else { val = mpam_read_monsel_reg(msc, MBWU); mpam_write_monsel_reg(msc, MBWU, 0); } cfg->mon = i; cfg->pmg = FIELD_GET(MSMON_CFG_x_FLT_PMG, cur_flt); cfg->match_pmg = FIELD_GET(MSMON_CFG_x_CTL_MATCH_PMG, cur_ctl); cfg->partid = FIELD_GET(MSMON_CFG_x_FLT_PARTID, cur_flt); mbwu_state->correction += val; mbwu_state->enabled = FIELD_GET(MSMON_CFG_x_CTL_EN, cur_ctl); mpam_mon_sel_unlock(msc); } return 0; } static void mpam_init_reset_cfg(struct mpam_config *reset_cfg) { *reset_cfg = (struct mpam_config) { .reset_cpbm = true, .reset_mbw_pbm = true, .reset_mbw_max = true, }; bitmap_fill(reset_cfg->features, MPAM_FEATURE_LAST); } /* * Called via smp_call_on_cpu() to prevent migration, while still being * pre-emptible. Caller must hold mpam_srcu. */ static int mpam_reset_ris(void *arg) { u16 partid, partid_max; struct mpam_config reset_cfg; struct mpam_msc_ris *ris = arg; if (ris->in_reset_state) return 0; mpam_init_reset_cfg(&reset_cfg); spin_lock(&partid_max_lock); partid_max = mpam_partid_max; spin_unlock(&partid_max_lock); for (partid = 0; partid <= partid_max; partid++) mpam_reprogram_ris_partid(ris, partid, &reset_cfg); return 0; } /* * Get the preferred CPU for this MSC. If it is accessible from this CPU, * this CPU is preferred. This can be preempted/migrated, it will only result * in more work. */ static int mpam_get_msc_preferred_cpu(struct mpam_msc *msc) { int cpu = raw_smp_processor_id(); if (cpumask_test_cpu(cpu, &msc->accessibility)) return cpu; return cpumask_first_and(&msc->accessibility, cpu_online_mask); } static int mpam_touch_msc(struct mpam_msc *msc, int (*fn)(void *a), void *arg) { lockdep_assert_irqs_enabled(); lockdep_assert_cpus_held(); WARN_ON_ONCE(!srcu_read_lock_held((&mpam_srcu))); return smp_call_on_cpu(mpam_get_msc_preferred_cpu(msc), fn, arg, true); } struct mpam_write_config_arg { struct mpam_msc_ris *ris; struct mpam_component *comp; u16 partid; }; static int __write_config(void *arg) { struct mpam_write_config_arg *c = arg; mpam_reprogram_ris_partid(c->ris, c->partid, &c->comp->cfg[c->partid]); return 0; } static void mpam_reprogram_msc(struct mpam_msc *msc) { u16 partid; bool reset; struct mpam_config *cfg; struct mpam_msc_ris *ris; struct mpam_write_config_arg arg; /* * No lock for mpam_partid_max as partid_max_published has been * set by mpam_enabled(), so the values can no longer change. */ mpam_assert_partid_sizes_fixed(); mutex_lock(&msc->cfg_lock); list_for_each_entry_srcu(ris, &msc->ris, msc_list, srcu_read_lock_held(&mpam_srcu)) { if (!mpam_is_enabled() && !ris->in_reset_state) { mpam_touch_msc(msc, &mpam_reset_ris, ris); ris->in_reset_state = true; continue; } arg.comp = ris->vmsc->comp; arg.ris = ris; reset = true; for (partid = 0; partid <= mpam_partid_max; partid++) { cfg = &ris->vmsc->comp->cfg[partid]; if (!bitmap_empty(cfg->features, MPAM_FEATURE_LAST)) reset = false; arg.partid = partid; mpam_touch_msc(msc, __write_config, &arg); } ris->in_reset_state = reset; if (mpam_has_feature(mpam_feat_msmon_mbwu, &ris->props)) mpam_touch_msc(msc, &mpam_restore_mbwu_state, ris); } mutex_unlock(&msc->cfg_lock); } static void _enable_percpu_irq(void *_irq) { int *irq = _irq; enable_percpu_irq(*irq, IRQ_TYPE_NONE); } static int mpam_cpu_online(unsigned int cpu) { struct mpam_msc *msc; guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(msc, &mpam_all_msc, all_msc_list, srcu_read_lock_held(&mpam_srcu)) { if (!cpumask_test_cpu(cpu, &msc->accessibility)) continue; if (msc->reenable_error_ppi) _enable_percpu_irq(&msc->reenable_error_ppi); if (atomic_fetch_inc(&msc->online_refs) == 0) mpam_reprogram_msc(msc); } return 0; } /* Before mpam is enabled, try to probe new MSC */ static int mpam_discovery_cpu_online(unsigned int cpu) { int err = 0; struct mpam_msc *msc; bool new_device_probed = false; if (mpam_is_enabled()) return 0; guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(msc, &mpam_all_msc, all_msc_list, srcu_read_lock_held(&mpam_srcu)) { if (!cpumask_test_cpu(cpu, &msc->accessibility)) continue; mutex_lock(&msc->probe_lock); if (!msc->probed) err = mpam_msc_hw_probe(msc); mutex_unlock(&msc->probe_lock); if (err) break; new_device_probed = true; } if (new_device_probed && !err) schedule_work(&mpam_enable_work); if (err) { mpam_disable_reason = "error during probing"; schedule_work(&mpam_broken_work); } return err; } static int mpam_cpu_offline(unsigned int cpu) { struct mpam_msc *msc; guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(msc, &mpam_all_msc, all_msc_list, srcu_read_lock_held(&mpam_srcu)) { if (!cpumask_test_cpu(cpu, &msc->accessibility)) continue; if (msc->reenable_error_ppi) disable_percpu_irq(msc->reenable_error_ppi); if (atomic_dec_and_test(&msc->online_refs)) { struct mpam_msc_ris *ris; mutex_lock(&msc->cfg_lock); list_for_each_entry_srcu(ris, &msc->ris, msc_list, srcu_read_lock_held(&mpam_srcu)) { mpam_touch_msc(msc, &mpam_reset_ris, ris); /* * The reset state for non-zero partid may be * lost while the CPUs are offline. */ ris->in_reset_state = false; if (mpam_is_enabled()) mpam_touch_msc(msc, &mpam_save_mbwu_state, ris); } mutex_unlock(&msc->cfg_lock); } } return 0; } static void mpam_register_cpuhp_callbacks(int (*online)(unsigned int online), int (*offline)(unsigned int offline), char *name) { mutex_lock(&mpam_cpuhp_state_lock); if (mpam_cpuhp_state) { cpuhp_remove_state(mpam_cpuhp_state); mpam_cpuhp_state = 0; } mpam_cpuhp_state = cpuhp_setup_state(CPUHP_AP_ONLINE_DYN, name, online, offline); if (mpam_cpuhp_state <= 0) { pr_err("Failed to register cpuhp callbacks"); mpam_cpuhp_state = 0; } mutex_unlock(&mpam_cpuhp_state_lock); } static int __setup_ppi(struct mpam_msc *msc) { int cpu; msc->error_dev_id = alloc_percpu(struct mpam_msc *); if (!msc->error_dev_id) return -ENOMEM; for_each_cpu(cpu, &msc->accessibility) *per_cpu_ptr(msc->error_dev_id, cpu) = msc; return 0; } static int mpam_msc_setup_error_irq(struct mpam_msc *msc) { int irq; irq = platform_get_irq_byname_optional(msc->pdev, "error"); if (irq <= 0) return 0; /* Allocate and initialise the percpu device pointer for PPI */ if (irq_is_percpu(irq)) return __setup_ppi(msc); /* sanity check: shared interrupts can be routed anywhere? */ if (!cpumask_equal(&msc->accessibility, cpu_possible_mask)) { pr_err_once("msc:%u is a private resource with a shared error interrupt", msc->id); return -EINVAL; } return 0; } /* * An MSC can control traffic from a set of CPUs, but may only be accessible * from a (hopefully wider) set of CPUs. The common reason for this is power * management. If all the CPUs in a cluster are in PSCI:CPU_SUSPEND, the * corresponding cache may also be powered off. By making accesses from * one of those CPUs, we ensure we don't access a cache that's powered off. */ static void update_msc_accessibility(struct mpam_msc *msc) { u32 affinity_id; int err; err = device_property_read_u32(&msc->pdev->dev, "cpu_affinity", &affinity_id); if (err) cpumask_copy(&msc->accessibility, cpu_possible_mask); else acpi_pptt_get_cpus_from_container(affinity_id, &msc->accessibility); } /* * There are two ways of reaching a struct mpam_msc_ris. Via the * class->component->vmsc->ris, or via the msc. * When destroying the msc, the other side needs unlinking and cleaning up too. */ static void mpam_msc_destroy(struct mpam_msc *msc) { struct platform_device *pdev = msc->pdev; struct mpam_msc_ris *ris, *tmp; lockdep_assert_held(&mpam_list_lock); list_for_each_entry_safe(ris, tmp, &msc->ris, msc_list) mpam_ris_destroy(ris); list_del_rcu(&msc->all_msc_list); platform_set_drvdata(pdev, NULL); add_to_garbage(msc); } static void mpam_msc_drv_remove(struct platform_device *pdev) { struct mpam_msc *msc = platform_get_drvdata(pdev); mutex_lock(&mpam_list_lock); mpam_msc_destroy(msc); mutex_unlock(&mpam_list_lock); mpam_free_garbage(); } static struct mpam_msc *do_mpam_msc_drv_probe(struct platform_device *pdev) { int err; u32 tmp; struct mpam_msc *msc; struct resource *msc_res; struct device *dev = &pdev->dev; lockdep_assert_held(&mpam_list_lock); msc = devm_kzalloc(&pdev->dev, sizeof(*msc), GFP_KERNEL); if (!msc) return ERR_PTR(-ENOMEM); init_garbage(&msc->garbage); msc->garbage.pdev = pdev; err = devm_mutex_init(dev, &msc->probe_lock); if (err) return ERR_PTR(err); err = devm_mutex_init(dev, &msc->part_sel_lock); if (err) return ERR_PTR(err); err = devm_mutex_init(dev, &msc->error_irq_lock); if (err) return ERR_PTR(err); err = devm_mutex_init(dev, &msc->cfg_lock); if (err) return ERR_PTR(err); mpam_mon_sel_lock_init(msc); msc->id = pdev->id; msc->pdev = pdev; INIT_LIST_HEAD_RCU(&msc->all_msc_list); INIT_LIST_HEAD_RCU(&msc->ris); update_msc_accessibility(msc); if (cpumask_empty(&msc->accessibility)) { dev_err_once(dev, "MSC is not accessible from any CPU!"); return ERR_PTR(-EINVAL); } err = mpam_msc_setup_error_irq(msc); if (err) return ERR_PTR(err); if (device_property_read_u32(&pdev->dev, "pcc-channel", &tmp)) msc->iface = MPAM_IFACE_MMIO; else msc->iface = MPAM_IFACE_PCC; if (msc->iface == MPAM_IFACE_MMIO) { void __iomem *io; io = devm_platform_get_and_ioremap_resource(pdev, 0, &msc_res); if (IS_ERR(io)) { dev_err_once(dev, "Failed to map MSC base address\n"); return ERR_CAST(io); } msc->mapped_hwpage_sz = msc_res->end - msc_res->start; msc->mapped_hwpage = io; } else { return ERR_PTR(-EINVAL); } list_add_rcu(&msc->all_msc_list, &mpam_all_msc); platform_set_drvdata(pdev, msc); return msc; } static int fw_num_msc; static int mpam_msc_drv_probe(struct platform_device *pdev) { int err; struct mpam_msc *msc = NULL; void *plat_data = pdev->dev.platform_data; mutex_lock(&mpam_list_lock); msc = do_mpam_msc_drv_probe(pdev); mutex_unlock(&mpam_list_lock); if (IS_ERR(msc)) return PTR_ERR(msc); /* Create RIS entries described by firmware */ err = acpi_mpam_parse_resources(msc, plat_data); if (err) { mpam_msc_drv_remove(pdev); return err; } if (atomic_add_return(1, &mpam_num_msc) == fw_num_msc) mpam_register_cpuhp_callbacks(mpam_discovery_cpu_online, NULL, "mpam:drv_probe"); return 0; } static struct platform_driver mpam_msc_driver = { .driver = { .name = "mpam_msc", }, .probe = mpam_msc_drv_probe, .remove = mpam_msc_drv_remove, }; /* Any of these features mean the BWA_WD field is valid. */ static bool mpam_has_bwa_wd_feature(struct mpam_props *props) { if (mpam_has_feature(mpam_feat_mbw_min, props)) return true; if (mpam_has_feature(mpam_feat_mbw_max, props)) return true; if (mpam_has_feature(mpam_feat_mbw_prop, props)) return true; return false; } /* Any of these features mean the CMAX_WD field is valid. */ static bool mpam_has_cmax_wd_feature(struct mpam_props *props) { if (mpam_has_feature(mpam_feat_cmax_cmax, props)) return true; if (mpam_has_feature(mpam_feat_cmax_cmin, props)) return true; return false; } #define MISMATCHED_HELPER(parent, child, helper, field, alias) \ helper(parent) && \ ((helper(child) && (parent)->field != (child)->field) || \ (!helper(child) && !(alias))) #define MISMATCHED_FEAT(parent, child, feat, field, alias) \ mpam_has_feature((feat), (parent)) && \ ((mpam_has_feature((feat), (child)) && (parent)->field != (child)->field) || \ (!mpam_has_feature((feat), (child)) && !(alias))) #define CAN_MERGE_FEAT(parent, child, feat, alias) \ (alias) && !mpam_has_feature((feat), (parent)) && \ mpam_has_feature((feat), (child)) /* * Combine two props fields. * If this is for controls that alias the same resource, it is safe to just * copy the values over. If two aliasing controls implement the same scheme * a safe value must be picked. * For non-aliasing controls, these control different resources, and the * resulting safe value must be compatible with both. When merging values in * the tree, all the aliasing resources must be handled first. * On mismatch, parent is modified. */ static void __props_mismatch(struct mpam_props *parent, struct mpam_props *child, bool alias) { if (CAN_MERGE_FEAT(parent, child, mpam_feat_cpor_part, alias)) { parent->cpbm_wd = child->cpbm_wd; } else if (MISMATCHED_FEAT(parent, child, mpam_feat_cpor_part, cpbm_wd, alias)) { pr_debug("cleared cpor_part\n"); mpam_clear_feature(mpam_feat_cpor_part, parent); parent->cpbm_wd = 0; } if (CAN_MERGE_FEAT(parent, child, mpam_feat_mbw_part, alias)) { parent->mbw_pbm_bits = child->mbw_pbm_bits; } else if (MISMATCHED_FEAT(parent, child, mpam_feat_mbw_part, mbw_pbm_bits, alias)) { pr_debug("cleared mbw_part\n"); mpam_clear_feature(mpam_feat_mbw_part, parent); parent->mbw_pbm_bits = 0; } /* bwa_wd is a count of bits, fewer bits means less precision */ if (alias && !mpam_has_bwa_wd_feature(parent) && mpam_has_bwa_wd_feature(child)) { parent->bwa_wd = child->bwa_wd; } else if (MISMATCHED_HELPER(parent, child, mpam_has_bwa_wd_feature, bwa_wd, alias)) { pr_debug("took the min bwa_wd\n"); parent->bwa_wd = min(parent->bwa_wd, child->bwa_wd); } if (alias && !mpam_has_cmax_wd_feature(parent) && mpam_has_cmax_wd_feature(child)) { parent->cmax_wd = child->cmax_wd; } else if (MISMATCHED_HELPER(parent, child, mpam_has_cmax_wd_feature, cmax_wd, alias)) { pr_debug("%s took the min cmax_wd\n", __func__); parent->cmax_wd = min(parent->cmax_wd, child->cmax_wd); } if (CAN_MERGE_FEAT(parent, child, mpam_feat_cmax_cassoc, alias)) { parent->cassoc_wd = child->cassoc_wd; } else if (MISMATCHED_FEAT(parent, child, mpam_feat_cmax_cassoc, cassoc_wd, alias)) { pr_debug("%s cleared cassoc_wd\n", __func__); mpam_clear_feature(mpam_feat_cmax_cassoc, parent); parent->cassoc_wd = 0; } /* For num properties, take the minimum */ if (CAN_MERGE_FEAT(parent, child, mpam_feat_msmon_csu, alias)) { parent->num_csu_mon = child->num_csu_mon; } else if (MISMATCHED_FEAT(parent, child, mpam_feat_msmon_csu, num_csu_mon, alias)) { pr_debug("took the min num_csu_mon\n"); parent->num_csu_mon = min(parent->num_csu_mon, child->num_csu_mon); } if (CAN_MERGE_FEAT(parent, child, mpam_feat_msmon_mbwu, alias)) { parent->num_mbwu_mon = child->num_mbwu_mon; } else if (MISMATCHED_FEAT(parent, child, mpam_feat_msmon_mbwu, num_mbwu_mon, alias)) { pr_debug("took the min num_mbwu_mon\n"); parent->num_mbwu_mon = min(parent->num_mbwu_mon, child->num_mbwu_mon); } if (CAN_MERGE_FEAT(parent, child, mpam_feat_intpri_part, alias)) { parent->intpri_wd = child->intpri_wd; } else if (MISMATCHED_FEAT(parent, child, mpam_feat_intpri_part, intpri_wd, alias)) { pr_debug("%s took the min intpri_wd\n", __func__); parent->intpri_wd = min(parent->intpri_wd, child->intpri_wd); } if (CAN_MERGE_FEAT(parent, child, mpam_feat_dspri_part, alias)) { parent->dspri_wd = child->dspri_wd; } else if (MISMATCHED_FEAT(parent, child, mpam_feat_dspri_part, dspri_wd, alias)) { pr_debug("%s took the min dspri_wd\n", __func__); parent->dspri_wd = min(parent->dspri_wd, child->dspri_wd); } /* TODO: alias support for these two */ /* {int,ds}pri may not have differing 0-low behaviour */ if (mpam_has_feature(mpam_feat_intpri_part, parent) && (!mpam_has_feature(mpam_feat_intpri_part, child) || mpam_has_feature(mpam_feat_intpri_part_0_low, parent) != mpam_has_feature(mpam_feat_intpri_part_0_low, child))) { pr_debug("%s cleared intpri_part\n", __func__); mpam_clear_feature(mpam_feat_intpri_part, parent); mpam_clear_feature(mpam_feat_intpri_part_0_low, parent); } if (mpam_has_feature(mpam_feat_dspri_part, parent) && (!mpam_has_feature(mpam_feat_dspri_part, child) || mpam_has_feature(mpam_feat_dspri_part_0_low, parent) != mpam_has_feature(mpam_feat_dspri_part_0_low, child))) { pr_debug("%s cleared dspri_part\n", __func__); mpam_clear_feature(mpam_feat_dspri_part, parent); mpam_clear_feature(mpam_feat_dspri_part_0_low, parent); } if (alias) { /* Merge features for aliased resources */ bitmap_or(parent->features, parent->features, child->features, MPAM_FEATURE_LAST); } else { /* Clear missing features for non aliasing */ bitmap_and(parent->features, parent->features, child->features, MPAM_FEATURE_LAST); } } /* * If a vmsc doesn't match class feature/configuration, do the right thing(tm). * For 'num' properties we can just take the minimum. * For properties where the mismatched unused bits would make a difference, we * nobble the class feature, as we can't configure all the resources. * e.g. The L3 cache is composed of two resources with 13 and 17 portion * bitmaps respectively. */ static void __class_props_mismatch(struct mpam_class *class, struct mpam_vmsc *vmsc) { struct mpam_props *cprops = &class->props; struct mpam_props *vprops = &vmsc->props; struct device *dev = &vmsc->msc->pdev->dev; lockdep_assert_held(&mpam_list_lock); /* we modify class */ dev_dbg(dev, "Merging features for class:0x%lx &= vmsc:0x%lx\n", (long)cprops->features, (long)vprops->features); /* Take the safe value for any common features */ __props_mismatch(cprops, vprops, false); } static void __vmsc_props_mismatch(struct mpam_vmsc *vmsc, struct mpam_msc_ris *ris) { struct mpam_props *rprops = &ris->props; struct mpam_props *vprops = &vmsc->props; struct device *dev = &vmsc->msc->pdev->dev; lockdep_assert_held(&mpam_list_lock); /* we modify vmsc */ dev_dbg(dev, "Merging features for vmsc:0x%lx |= ris:0x%lx\n", (long)vprops->features, (long)rprops->features); /* * Merge mismatched features - Copy any features that aren't common, * but take the safe value for any common features. */ __props_mismatch(vprops, rprops, true); } /* * Copy the first component's first vMSC's properties and features to the * class. __class_props_mismatch() will remove conflicts. * It is not possible to have a class with no components, or a component with * no resources. The vMSC properties have already been built. */ static void mpam_enable_init_class_features(struct mpam_class *class) { struct mpam_vmsc *vmsc; struct mpam_component *comp; comp = list_first_entry(&class->components, struct mpam_component, class_list); vmsc = list_first_entry(&comp->vmsc, struct mpam_vmsc, comp_list); class->props = vmsc->props; } static void mpam_enable_merge_vmsc_features(struct mpam_component *comp) { struct mpam_vmsc *vmsc; struct mpam_msc_ris *ris; struct mpam_class *class = comp->class; list_for_each_entry(vmsc, &comp->vmsc, comp_list) { list_for_each_entry(ris, &vmsc->ris, vmsc_list) { __vmsc_props_mismatch(vmsc, ris); class->nrdy_usec = max(class->nrdy_usec, vmsc->msc->nrdy_usec); } } } static void mpam_enable_merge_class_features(struct mpam_component *comp) { struct mpam_vmsc *vmsc; struct mpam_class *class = comp->class; list_for_each_entry(vmsc, &comp->vmsc, comp_list) __class_props_mismatch(class, vmsc); } /* * Merge all the common resource features into class. * vmsc features are bitwise-or'd together by mpam_enable_merge_vmsc_features() * as the first step so that mpam_enable_init_class_features() can initialise * the class with a representative set of features. * Next the mpam_enable_merge_class_features() bitwise-and's all the vmsc * features to form the class features. * Other features are the min/max as appropriate. * * To avoid walking the whole tree twice, the class->nrdy_usec property is * updated when working with the vmsc as it is a max(), and doesn't need * initialising first. */ static void mpam_enable_merge_features(struct list_head *all_classes_list) { struct mpam_class *class; struct mpam_component *comp; lockdep_assert_held(&mpam_list_lock); list_for_each_entry(class, all_classes_list, classes_list) { list_for_each_entry(comp, &class->components, class_list) mpam_enable_merge_vmsc_features(comp); mpam_enable_init_class_features(class); list_for_each_entry(comp, &class->components, class_list) mpam_enable_merge_class_features(comp); } } static char *mpam_errcode_names[16] = { [MPAM_ERRCODE_NONE] = "No error", [MPAM_ERRCODE_PARTID_SEL_RANGE] = "PARTID_SEL_Range", [MPAM_ERRCODE_REQ_PARTID_RANGE] = "Req_PARTID_Range", [MPAM_ERRCODE_MSMONCFG_ID_RANGE] = "MSMONCFG_ID_RANGE", [MPAM_ERRCODE_REQ_PMG_RANGE] = "Req_PMG_Range", [MPAM_ERRCODE_MONITOR_RANGE] = "Monitor_Range", [MPAM_ERRCODE_INTPARTID_RANGE] = "intPARTID_Range", [MPAM_ERRCODE_UNEXPECTED_INTERNAL] = "Unexpected_INTERNAL", [MPAM_ERRCODE_UNDEFINED_RIS_PART_SEL] = "Undefined_RIS_PART_SEL", [MPAM_ERRCODE_RIS_NO_CONTROL] = "RIS_No_Control", [MPAM_ERRCODE_UNDEFINED_RIS_MON_SEL] = "Undefined_RIS_MON_SEL", [MPAM_ERRCODE_RIS_NO_MONITOR] = "RIS_No_Monitor", [12 ... 15] = "Reserved" }; static int mpam_enable_msc_ecr(void *_msc) { struct mpam_msc *msc = _msc; __mpam_write_reg(msc, MPAMF_ECR, MPAMF_ECR_INTEN); return 0; } /* This can run in mpam_disable(), and the interrupt handler on the same CPU */ static int mpam_disable_msc_ecr(void *_msc) { struct mpam_msc *msc = _msc; __mpam_write_reg(msc, MPAMF_ECR, 0); return 0; } static irqreturn_t __mpam_irq_handler(int irq, struct mpam_msc *msc) { u64 reg; u16 partid; u8 errcode, pmg, ris; if (WARN_ON_ONCE(!msc) || WARN_ON_ONCE(!cpumask_test_cpu(smp_processor_id(), &msc->accessibility))) return IRQ_NONE; reg = mpam_msc_read_esr(msc); errcode = FIELD_GET(MPAMF_ESR_ERRCODE, reg); if (!errcode) return IRQ_NONE; /* Clear level triggered irq */ mpam_msc_clear_esr(msc); partid = FIELD_GET(MPAMF_ESR_PARTID_MON, reg); pmg = FIELD_GET(MPAMF_ESR_PMG, reg); ris = FIELD_GET(MPAMF_ESR_RIS, reg); pr_err_ratelimited("error irq from msc:%u '%s', partid:%u, pmg: %u, ris: %u\n", msc->id, mpam_errcode_names[errcode], partid, pmg, ris); /* Disable this interrupt. */ mpam_disable_msc_ecr(msc); /* Are we racing with the thread disabling MPAM? */ if (!mpam_is_enabled()) return IRQ_HANDLED; /* * Schedule the teardown work. Don't use a threaded IRQ as we can't * unregister the interrupt from the threaded part of the handler. */ mpam_disable_reason = "hardware error interrupt"; schedule_work(&mpam_broken_work); return IRQ_HANDLED; } static irqreturn_t mpam_ppi_handler(int irq, void *dev_id) { struct mpam_msc *msc = *(struct mpam_msc **)dev_id; return __mpam_irq_handler(irq, msc); } static irqreturn_t mpam_spi_handler(int irq, void *dev_id) { struct mpam_msc *msc = dev_id; return __mpam_irq_handler(irq, msc); } static int mpam_register_irqs(void) { int err, irq; struct mpam_msc *msc; lockdep_assert_cpus_held(); guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(msc, &mpam_all_msc, all_msc_list, srcu_read_lock_held(&mpam_srcu)) { irq = platform_get_irq_byname_optional(msc->pdev, "error"); if (irq <= 0) continue; /* The MPAM spec says the interrupt can be SPI, PPI or LPI */ /* We anticipate sharing the interrupt with other MSCs */ if (irq_is_percpu(irq)) { err = request_percpu_irq(irq, &mpam_ppi_handler, "mpam:msc:error", msc->error_dev_id); if (err) return err; msc->reenable_error_ppi = irq; smp_call_function_many(&msc->accessibility, &_enable_percpu_irq, &irq, true); } else { err = devm_request_irq(&msc->pdev->dev, irq, &mpam_spi_handler, IRQF_SHARED, "mpam:msc:error", msc); if (err) return err; } mutex_lock(&msc->error_irq_lock); msc->error_irq_req = true; mpam_touch_msc(msc, mpam_enable_msc_ecr, msc); msc->error_irq_hw_enabled = true; mutex_unlock(&msc->error_irq_lock); } return 0; } static void mpam_unregister_irqs(void) { int irq; struct mpam_msc *msc; guard(cpus_read_lock)(); guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(msc, &mpam_all_msc, all_msc_list, srcu_read_lock_held(&mpam_srcu)) { irq = platform_get_irq_byname_optional(msc->pdev, "error"); if (irq <= 0) continue; mutex_lock(&msc->error_irq_lock); if (msc->error_irq_hw_enabled) { mpam_touch_msc(msc, mpam_disable_msc_ecr, msc); msc->error_irq_hw_enabled = false; } if (msc->error_irq_req) { if (irq_is_percpu(irq)) { msc->reenable_error_ppi = 0; free_percpu_irq(irq, msc->error_dev_id); } else { devm_free_irq(&msc->pdev->dev, irq, msc); } msc->error_irq_req = false; } mutex_unlock(&msc->error_irq_lock); } } static void __destroy_component_cfg(struct mpam_component *comp) { struct mpam_msc *msc; struct mpam_vmsc *vmsc; struct mpam_msc_ris *ris; lockdep_assert_held(&mpam_list_lock); add_to_garbage(comp->cfg); list_for_each_entry(vmsc, &comp->vmsc, comp_list) { msc = vmsc->msc; if (mpam_mon_sel_lock(msc)) { list_for_each_entry(ris, &vmsc->ris, vmsc_list) add_to_garbage(ris->mbwu_state); mpam_mon_sel_unlock(msc); } } } static void mpam_reset_component_cfg(struct mpam_component *comp) { int i; struct mpam_props *cprops = &comp->class->props; mpam_assert_partid_sizes_fixed(); if (!comp->cfg) return; for (i = 0; i <= mpam_partid_max; i++) { comp->cfg[i] = (struct mpam_config) {}; if (cprops->cpbm_wd) comp->cfg[i].cpbm = GENMASK(cprops->cpbm_wd - 1, 0); if (cprops->mbw_pbm_bits) comp->cfg[i].mbw_pbm = GENMASK(cprops->mbw_pbm_bits - 1, 0); if (cprops->bwa_wd) comp->cfg[i].mbw_max = GENMASK(15, 16 - cprops->bwa_wd); } } static int __allocate_component_cfg(struct mpam_component *comp) { struct mpam_vmsc *vmsc; mpam_assert_partid_sizes_fixed(); if (comp->cfg) return 0; comp->cfg = kcalloc(mpam_partid_max + 1, sizeof(*comp->cfg), GFP_KERNEL); if (!comp->cfg) return -ENOMEM; /* * The array is free()d in one go, so only cfg[0]'s structure needs * to be initialised. */ init_garbage(&comp->cfg[0].garbage); mpam_reset_component_cfg(comp); list_for_each_entry(vmsc, &comp->vmsc, comp_list) { struct mpam_msc *msc; struct mpam_msc_ris *ris; struct msmon_mbwu_state *mbwu_state; if (!vmsc->props.num_mbwu_mon) continue; msc = vmsc->msc; list_for_each_entry(ris, &vmsc->ris, vmsc_list) { if (!ris->props.num_mbwu_mon) continue; mbwu_state = kcalloc(ris->props.num_mbwu_mon, sizeof(*ris->mbwu_state), GFP_KERNEL); if (!mbwu_state) { __destroy_component_cfg(comp); return -ENOMEM; } init_garbage(&mbwu_state[0].garbage); if (mpam_mon_sel_lock(msc)) { ris->mbwu_state = mbwu_state; mpam_mon_sel_unlock(msc); } } } return 0; } static int mpam_allocate_config(void) { struct mpam_class *class; struct mpam_component *comp; lockdep_assert_held(&mpam_list_lock); list_for_each_entry(class, &mpam_classes, classes_list) { list_for_each_entry(comp, &class->components, class_list) { int err = __allocate_component_cfg(comp); if (err) return err; } } return 0; } static void mpam_enable_once(void) { int err; /* * Once the cpuhp callbacks have been changed, mpam_partid_max can no * longer change. */ spin_lock(&partid_max_lock); partid_max_published = true; spin_unlock(&partid_max_lock); /* * If all the MSC have been probed, enabling the IRQs happens next. * That involves cross-calling to a CPU that can reach the MSC, and * the locks must be taken in this order: */ cpus_read_lock(); mutex_lock(&mpam_list_lock); do { mpam_enable_merge_features(&mpam_classes); err = mpam_register_irqs(); if (err) { pr_warn("Failed to register irqs: %d\n", err); break; } err = mpam_allocate_config(); if (err) { pr_err("Failed to allocate configuration arrays.\n"); break; } } while (0); mutex_unlock(&mpam_list_lock); cpus_read_unlock(); if (err) { mpam_disable_reason = "Failed to enable."; schedule_work(&mpam_broken_work); return; } static_branch_enable(&mpam_enabled); mpam_register_cpuhp_callbacks(mpam_cpu_online, mpam_cpu_offline, "mpam:online"); /* Use printk() to avoid the pr_fmt adding the function name. */ printk(KERN_INFO "MPAM enabled with %u PARTIDs and %u PMGs\n", mpam_partid_max + 1, mpam_pmg_max + 1); } static void mpam_reset_component_locked(struct mpam_component *comp) { struct mpam_vmsc *vmsc; lockdep_assert_cpus_held(); mpam_assert_partid_sizes_fixed(); mpam_reset_component_cfg(comp); guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(vmsc, &comp->vmsc, comp_list, srcu_read_lock_held(&mpam_srcu)) { struct mpam_msc *msc = vmsc->msc; struct mpam_msc_ris *ris; list_for_each_entry_srcu(ris, &vmsc->ris, vmsc_list, srcu_read_lock_held(&mpam_srcu)) { if (!ris->in_reset_state) mpam_touch_msc(msc, mpam_reset_ris, ris); ris->in_reset_state = true; } } } static void mpam_reset_class_locked(struct mpam_class *class) { struct mpam_component *comp; lockdep_assert_cpus_held(); guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(comp, &class->components, class_list, srcu_read_lock_held(&mpam_srcu)) mpam_reset_component_locked(comp); } static void mpam_reset_class(struct mpam_class *class) { cpus_read_lock(); mpam_reset_class_locked(class); cpus_read_unlock(); } /* * Called in response to an error IRQ. * All of MPAMs errors indicate a software bug, restore any modified * controls to their reset values. */ void mpam_disable(struct work_struct *ignored) { int idx; struct mpam_class *class; struct mpam_msc *msc, *tmp; mutex_lock(&mpam_cpuhp_state_lock); if (mpam_cpuhp_state) { cpuhp_remove_state(mpam_cpuhp_state); mpam_cpuhp_state = 0; } mutex_unlock(&mpam_cpuhp_state_lock); static_branch_disable(&mpam_enabled); mpam_unregister_irqs(); idx = srcu_read_lock(&mpam_srcu); list_for_each_entry_srcu(class, &mpam_classes, classes_list, srcu_read_lock_held(&mpam_srcu)) mpam_reset_class(class); srcu_read_unlock(&mpam_srcu, idx); mutex_lock(&mpam_list_lock); list_for_each_entry_safe(msc, tmp, &mpam_all_msc, all_msc_list) mpam_msc_destroy(msc); mutex_unlock(&mpam_list_lock); mpam_free_garbage(); pr_err_once("MPAM disabled due to %s\n", mpam_disable_reason); } /* * Enable mpam once all devices have been probed. * Scheduled by mpam_discovery_cpu_online() once all devices have been created. * Also scheduled when new devices are probed when new CPUs come online. */ void mpam_enable(struct work_struct *work) { static atomic_t once; struct mpam_msc *msc; bool all_devices_probed = true; /* Have we probed all the hw devices? */ guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(msc, &mpam_all_msc, all_msc_list, srcu_read_lock_held(&mpam_srcu)) { mutex_lock(&msc->probe_lock); if (!msc->probed) all_devices_probed = false; mutex_unlock(&msc->probe_lock); if (!all_devices_probed) break; } if (all_devices_probed && !atomic_fetch_inc(&once)) mpam_enable_once(); } #define maybe_update_config(cfg, feature, newcfg, member, changes) do { \ if (mpam_has_feature(feature, newcfg) && \ (newcfg)->member != (cfg)->member) { \ (cfg)->member = (newcfg)->member; \ mpam_set_feature(feature, cfg); \ \ (changes) = true; \ } \ } while (0) static bool mpam_update_config(struct mpam_config *cfg, const struct mpam_config *newcfg) { bool has_changes = false; maybe_update_config(cfg, mpam_feat_cpor_part, newcfg, cpbm, has_changes); maybe_update_config(cfg, mpam_feat_mbw_part, newcfg, mbw_pbm, has_changes); maybe_update_config(cfg, mpam_feat_mbw_max, newcfg, mbw_max, has_changes); return has_changes; } int mpam_apply_config(struct mpam_component *comp, u16 partid, struct mpam_config *cfg) { struct mpam_write_config_arg arg; struct mpam_msc_ris *ris; struct mpam_vmsc *vmsc; struct mpam_msc *msc; lockdep_assert_cpus_held(); /* Don't pass in the current config! */ WARN_ON_ONCE(&comp->cfg[partid] == cfg); if (!mpam_update_config(&comp->cfg[partid], cfg)) return 0; arg.comp = comp; arg.partid = partid; guard(srcu)(&mpam_srcu); list_for_each_entry_srcu(vmsc, &comp->vmsc, comp_list, srcu_read_lock_held(&mpam_srcu)) { msc = vmsc->msc; mutex_lock(&msc->cfg_lock); list_for_each_entry_srcu(ris, &vmsc->ris, vmsc_list, srcu_read_lock_held(&mpam_srcu)) { arg.ris = ris; mpam_touch_msc(msc, __write_config, &arg); } mutex_unlock(&msc->cfg_lock); } return 0; } static int __init mpam_msc_driver_init(void) { if (!system_supports_mpam()) return -EOPNOTSUPP; init_srcu_struct(&mpam_srcu); fw_num_msc = acpi_mpam_count_msc(); if (fw_num_msc <= 0) { pr_err("No MSC devices found in firmware\n"); return -EINVAL; } return platform_driver_register(&mpam_msc_driver); } /* Must occur after arm64_mpam_register_cpus() from arch_initcall() */ subsys_initcall(mpam_msc_driver_init); #ifdef CONFIG_MPAM_KUNIT_TEST #include "test_mpam_devices.c" #endif
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