// SPDX-License-Identifier: GPL-2.0-or-later /* * Virtio-mem device driver. * * Copyright Red Hat, Inc. 2020 * * Author(s): David Hildenbrand */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static bool unplug_online = true; module_param(unplug_online, bool, 0644); MODULE_PARM_DESC(unplug_online, "Try to unplug online memory"); static bool force_bbm; module_param(force_bbm, bool, 0444); MODULE_PARM_DESC(force_bbm, "Force Big Block Mode. Default is 0 (auto-selection)"); static unsigned long bbm_block_size; module_param(bbm_block_size, ulong, 0444); MODULE_PARM_DESC(bbm_block_size, "Big Block size in bytes. Default is 0 (auto-detection)."); /* * virtio-mem currently supports the following modes of operation: * * * Sub Block Mode (SBM): A Linux memory block spans 2..X subblocks (SB). The * size of a Sub Block (SB) is determined based on the device block size, the * pageblock size, and the maximum allocation granularity of the buddy. * Subblocks within a Linux memory block might either be plugged or unplugged. * Memory is added/removed to Linux MM in Linux memory block granularity. * * * Big Block Mode (BBM): A Big Block (BB) spans 1..X Linux memory blocks. * Memory is added/removed to Linux MM in Big Block granularity. * * The mode is determined automatically based on the Linux memory block size * and the device block size. * * User space / core MM (auto onlining) is responsible for onlining added * Linux memory blocks - and for selecting a zone. Linux Memory Blocks are * always onlined separately, and all memory within a Linux memory block is * onlined to the same zone - virtio-mem relies on this behavior. */ /* * State of a Linux memory block in SBM. */ enum virtio_mem_sbm_mb_state { /* Unplugged, not added to Linux. Can be reused later. */ VIRTIO_MEM_SBM_MB_UNUSED = 0, /* (Partially) plugged, not added to Linux. Error on add_memory(). */ VIRTIO_MEM_SBM_MB_PLUGGED, /* Fully plugged, fully added to Linux, offline. */ VIRTIO_MEM_SBM_MB_OFFLINE, /* Partially plugged, fully added to Linux, offline. */ VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL, /* Fully plugged, fully added to Linux, onlined to a kernel zone. */ VIRTIO_MEM_SBM_MB_KERNEL, /* Partially plugged, fully added to Linux, online to a kernel zone */ VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL, /* Fully plugged, fully added to Linux, onlined to ZONE_MOVABLE. */ VIRTIO_MEM_SBM_MB_MOVABLE, /* Partially plugged, fully added to Linux, onlined to ZONE_MOVABLE. */ VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL, VIRTIO_MEM_SBM_MB_COUNT }; /* * State of a Big Block (BB) in BBM, covering 1..X Linux memory blocks. */ enum virtio_mem_bbm_bb_state { /* Unplugged, not added to Linux. Can be reused later. */ VIRTIO_MEM_BBM_BB_UNUSED = 0, /* Plugged, not added to Linux. Error on add_memory(). */ VIRTIO_MEM_BBM_BB_PLUGGED, /* Plugged and added to Linux. */ VIRTIO_MEM_BBM_BB_ADDED, /* All online parts are fake-offline, ready to remove. */ VIRTIO_MEM_BBM_BB_FAKE_OFFLINE, VIRTIO_MEM_BBM_BB_COUNT }; struct virtio_mem { struct virtio_device *vdev; /* We might first have to unplug all memory when starting up. */ bool unplug_all_required; /* Workqueue that processes the plug/unplug requests. */ struct work_struct wq; atomic_t wq_active; atomic_t config_changed; /* Virtqueue for guest->host requests. */ struct virtqueue *vq; /* Wait for a host response to a guest request. */ wait_queue_head_t host_resp; /* Space for one guest request and the host response. */ struct virtio_mem_req req; struct virtio_mem_resp resp; /* The current size of the device. */ uint64_t plugged_size; /* The requested size of the device. */ uint64_t requested_size; /* The device block size (for communicating with the device). */ uint64_t device_block_size; /* The determined node id for all memory of the device. */ int nid; /* Physical start address of the memory region. */ uint64_t addr; /* Maximum region size in bytes. */ uint64_t region_size; /* Usable region size in bytes. */ uint64_t usable_region_size; /* The parent resource for all memory added via this device. */ struct resource *parent_resource; /* * Copy of "System RAM (virtio_mem)" to be used for * add_memory_driver_managed(). */ const char *resource_name; /* Memory group identification. */ int mgid; /* * We don't want to add too much memory if it's not getting onlined, * to avoid running OOM. Besides this threshold, we allow to have at * least two offline blocks at a time (whatever is bigger). */ #define VIRTIO_MEM_DEFAULT_OFFLINE_THRESHOLD (1024 * 1024 * 1024) atomic64_t offline_size; uint64_t offline_threshold; /* If set, the driver is in SBM, otherwise in BBM. */ bool in_sbm; union { struct { /* Id of the first memory block of this device. */ unsigned long first_mb_id; /* Id of the last usable memory block of this device. */ unsigned long last_usable_mb_id; /* Id of the next memory bock to prepare when needed. */ unsigned long next_mb_id; /* The subblock size. */ uint64_t sb_size; /* The number of subblocks per Linux memory block. */ uint32_t sbs_per_mb; /* * Some of the Linux memory blocks tracked as "partially * plugged" are completely unplugged and can be offlined * and removed -- which previously failed. */ bool have_unplugged_mb; /* Summary of all memory block states. */ unsigned long mb_count[VIRTIO_MEM_SBM_MB_COUNT]; /* * One byte state per memory block. Allocated via * vmalloc(). Resized (alloc+copy+free) on demand. * * With 128 MiB memory blocks, we have states for 512 * GiB of memory in one 4 KiB page. */ uint8_t *mb_states; /* * Bitmap: one bit per subblock. Allocated similar to * sbm.mb_states. * * A set bit means the corresponding subblock is * plugged, otherwise it's unblocked. * * With 4 MiB subblocks, we manage 128 GiB of memory * in one 4 KiB page. */ unsigned long *sb_states; } sbm; struct { /* Id of the first big block of this device. */ unsigned long first_bb_id; /* Id of the last usable big block of this device. */ unsigned long last_usable_bb_id; /* Id of the next device bock to prepare when needed. */ unsigned long next_bb_id; /* Summary of all big block states. */ unsigned long bb_count[VIRTIO_MEM_BBM_BB_COUNT]; /* One byte state per big block. See sbm.mb_states. */ uint8_t *bb_states; /* The block size used for plugging/adding/removing. */ uint64_t bb_size; } bbm; }; /* * Mutex that protects the sbm.mb_count, sbm.mb_states, * sbm.sb_states, bbm.bb_count, and bbm.bb_states * * When this lock is held the pointers can't change, ONLINE and * OFFLINE blocks can't change the state and no subblocks will get * plugged/unplugged. * * In kdump mode, used to serialize requests, last_block_addr and * last_block_plugged. */ struct mutex hotplug_mutex; bool hotplug_active; /* An error occurred we cannot handle - stop processing requests. */ bool broken; /* Cached valued of is_kdump_kernel() when the device was probed. */ bool in_kdump; /* The driver is being removed. */ spinlock_t removal_lock; bool removing; /* Timer for retrying to plug/unplug memory. */ struct hrtimer retry_timer; unsigned int retry_timer_ms; #define VIRTIO_MEM_RETRY_TIMER_MIN_MS 50000 #define VIRTIO_MEM_RETRY_TIMER_MAX_MS 300000 /* Memory notifier (online/offline events). */ struct notifier_block memory_notifier; /* Notifier to block hibernation image storing/reloading. */ struct notifier_block pm_notifier; #ifdef CONFIG_PROC_VMCORE /* vmcore callback for /proc/vmcore handling in kdump mode */ struct vmcore_cb vmcore_cb; uint64_t last_block_addr; bool last_block_plugged; #endif /* CONFIG_PROC_VMCORE */ /* Next device in the list of virtio-mem devices. */ struct list_head next; }; /* * We have to share a single online_page callback among all virtio-mem * devices. We use RCU to iterate the list in the callback. */ static DEFINE_MUTEX(virtio_mem_mutex); static LIST_HEAD(virtio_mem_devices); static void virtio_mem_online_page_cb(struct page *page, unsigned int order); static void virtio_mem_fake_offline_going_offline(unsigned long pfn, unsigned long nr_pages); static void virtio_mem_fake_offline_cancel_offline(unsigned long pfn, unsigned long nr_pages); static void virtio_mem_retry(struct virtio_mem *vm); static int virtio_mem_create_resource(struct virtio_mem *vm); static void virtio_mem_delete_resource(struct virtio_mem *vm); /* * Register a virtio-mem device so it will be considered for the online_page * callback. */ static int register_virtio_mem_device(struct virtio_mem *vm) { int rc = 0; /* First device registers the callback. */ mutex_lock(&virtio_mem_mutex); if (list_empty(&virtio_mem_devices)) rc = set_online_page_callback(&virtio_mem_online_page_cb); if (!rc) list_add_rcu(&vm->next, &virtio_mem_devices); mutex_unlock(&virtio_mem_mutex); return rc; } /* * Unregister a virtio-mem device so it will no longer be considered for the * online_page callback. */ static void unregister_virtio_mem_device(struct virtio_mem *vm) { /* Last device unregisters the callback. */ mutex_lock(&virtio_mem_mutex); list_del_rcu(&vm->next); if (list_empty(&virtio_mem_devices)) restore_online_page_callback(&virtio_mem_online_page_cb); mutex_unlock(&virtio_mem_mutex); synchronize_rcu(); } /* * Calculate the memory block id of a given address. */ static unsigned long virtio_mem_phys_to_mb_id(unsigned long addr) { return addr / memory_block_size_bytes(); } /* * Calculate the physical start address of a given memory block id. */ static unsigned long virtio_mem_mb_id_to_phys(unsigned long mb_id) { return mb_id * memory_block_size_bytes(); } /* * Calculate the big block id of a given address. */ static unsigned long virtio_mem_phys_to_bb_id(struct virtio_mem *vm, uint64_t addr) { return addr / vm->bbm.bb_size; } /* * Calculate the physical start address of a given big block id. */ static uint64_t virtio_mem_bb_id_to_phys(struct virtio_mem *vm, unsigned long bb_id) { return bb_id * vm->bbm.bb_size; } /* * Calculate the subblock id of a given address. */ static unsigned long virtio_mem_phys_to_sb_id(struct virtio_mem *vm, unsigned long addr) { const unsigned long mb_id = virtio_mem_phys_to_mb_id(addr); const unsigned long mb_addr = virtio_mem_mb_id_to_phys(mb_id); return (addr - mb_addr) / vm->sbm.sb_size; } /* * Set the state of a big block, taking care of the state counter. */ static void virtio_mem_bbm_set_bb_state(struct virtio_mem *vm, unsigned long bb_id, enum virtio_mem_bbm_bb_state state) { const unsigned long idx = bb_id - vm->bbm.first_bb_id; enum virtio_mem_bbm_bb_state old_state; old_state = vm->bbm.bb_states[idx]; vm->bbm.bb_states[idx] = state; BUG_ON(vm->bbm.bb_count[old_state] == 0); vm->bbm.bb_count[old_state]--; vm->bbm.bb_count[state]++; } /* * Get the state of a big block. */ static enum virtio_mem_bbm_bb_state virtio_mem_bbm_get_bb_state(struct virtio_mem *vm, unsigned long bb_id) { return vm->bbm.bb_states[bb_id - vm->bbm.first_bb_id]; } /* * Prepare the big block state array for the next big block. */ static int virtio_mem_bbm_bb_states_prepare_next_bb(struct virtio_mem *vm) { unsigned long old_bytes = vm->bbm.next_bb_id - vm->bbm.first_bb_id; unsigned long new_bytes = old_bytes + 1; int old_pages = PFN_UP(old_bytes); int new_pages = PFN_UP(new_bytes); uint8_t *new_array; if (vm->bbm.bb_states && old_pages == new_pages) return 0; new_array = vzalloc(new_pages * PAGE_SIZE); if (!new_array) return -ENOMEM; mutex_lock(&vm->hotplug_mutex); if (vm->bbm.bb_states) memcpy(new_array, vm->bbm.bb_states, old_pages * PAGE_SIZE); vfree(vm->bbm.bb_states); vm->bbm.bb_states = new_array; mutex_unlock(&vm->hotplug_mutex); return 0; } #define virtio_mem_bbm_for_each_bb(_vm, _bb_id, _state) \ for (_bb_id = vm->bbm.first_bb_id; \ _bb_id < vm->bbm.next_bb_id && _vm->bbm.bb_count[_state]; \ _bb_id++) \ if (virtio_mem_bbm_get_bb_state(_vm, _bb_id) == _state) #define virtio_mem_bbm_for_each_bb_rev(_vm, _bb_id, _state) \ for (_bb_id = vm->bbm.next_bb_id - 1; \ _bb_id >= vm->bbm.first_bb_id && _vm->bbm.bb_count[_state]; \ _bb_id--) \ if (virtio_mem_bbm_get_bb_state(_vm, _bb_id) == _state) /* * Set the state of a memory block, taking care of the state counter. */ static void virtio_mem_sbm_set_mb_state(struct virtio_mem *vm, unsigned long mb_id, uint8_t state) { const unsigned long idx = mb_id - vm->sbm.first_mb_id; uint8_t old_state; old_state = vm->sbm.mb_states[idx]; vm->sbm.mb_states[idx] = state; BUG_ON(vm->sbm.mb_count[old_state] == 0); vm->sbm.mb_count[old_state]--; vm->sbm.mb_count[state]++; } /* * Get the state of a memory block. */ static uint8_t virtio_mem_sbm_get_mb_state(struct virtio_mem *vm, unsigned long mb_id) { const unsigned long idx = mb_id - vm->sbm.first_mb_id; return vm->sbm.mb_states[idx]; } /* * Prepare the state array for the next memory block. */ static int virtio_mem_sbm_mb_states_prepare_next_mb(struct virtio_mem *vm) { int old_pages = PFN_UP(vm->sbm.next_mb_id - vm->sbm.first_mb_id); int new_pages = PFN_UP(vm->sbm.next_mb_id - vm->sbm.first_mb_id + 1); uint8_t *new_array; if (vm->sbm.mb_states && old_pages == new_pages) return 0; new_array = vzalloc(new_pages * PAGE_SIZE); if (!new_array) return -ENOMEM; mutex_lock(&vm->hotplug_mutex); if (vm->sbm.mb_states) memcpy(new_array, vm->sbm.mb_states, old_pages * PAGE_SIZE); vfree(vm->sbm.mb_states); vm->sbm.mb_states = new_array; mutex_unlock(&vm->hotplug_mutex); return 0; } #define virtio_mem_sbm_for_each_mb(_vm, _mb_id, _state) \ for (_mb_id = _vm->sbm.first_mb_id; \ _mb_id < _vm->sbm.next_mb_id && _vm->sbm.mb_count[_state]; \ _mb_id++) \ if (virtio_mem_sbm_get_mb_state(_vm, _mb_id) == _state) #define virtio_mem_sbm_for_each_mb_rev(_vm, _mb_id, _state) \ for (_mb_id = _vm->sbm.next_mb_id - 1; \ _mb_id >= _vm->sbm.first_mb_id && _vm->sbm.mb_count[_state]; \ _mb_id--) \ if (virtio_mem_sbm_get_mb_state(_vm, _mb_id) == _state) /* * Calculate the bit number in the subblock bitmap for the given subblock * inside the given memory block. */ static int virtio_mem_sbm_sb_state_bit_nr(struct virtio_mem *vm, unsigned long mb_id, int sb_id) { return (mb_id - vm->sbm.first_mb_id) * vm->sbm.sbs_per_mb + sb_id; } /* * Mark all selected subblocks plugged. * * Will not modify the state of the memory block. */ static void virtio_mem_sbm_set_sb_plugged(struct virtio_mem *vm, unsigned long mb_id, int sb_id, int count) { const int bit = virtio_mem_sbm_sb_state_bit_nr(vm, mb_id, sb_id); __bitmap_set(vm->sbm.sb_states, bit, count); } /* * Mark all selected subblocks unplugged. * * Will not modify the state of the memory block. */ static void virtio_mem_sbm_set_sb_unplugged(struct virtio_mem *vm, unsigned long mb_id, int sb_id, int count) { const int bit = virtio_mem_sbm_sb_state_bit_nr(vm, mb_id, sb_id); __bitmap_clear(vm->sbm.sb_states, bit, count); } /* * Test if all selected subblocks are plugged. */ static bool virtio_mem_sbm_test_sb_plugged(struct virtio_mem *vm, unsigned long mb_id, int sb_id, int count) { const int bit = virtio_mem_sbm_sb_state_bit_nr(vm, mb_id, sb_id); if (count == 1) return test_bit(bit, vm->sbm.sb_states); /* TODO: Helper similar to bitmap_set() */ return find_next_zero_bit(vm->sbm.sb_states, bit + count, bit) >= bit + count; } /* * Test if all selected subblocks are unplugged. */ static bool virtio_mem_sbm_test_sb_unplugged(struct virtio_mem *vm, unsigned long mb_id, int sb_id, int count) { const int bit = virtio_mem_sbm_sb_state_bit_nr(vm, mb_id, sb_id); /* TODO: Helper similar to bitmap_set() */ return find_next_bit(vm->sbm.sb_states, bit + count, bit) >= bit + count; } /* * Find the first unplugged subblock. Returns vm->sbm.sbs_per_mb in case there is * none. */ static int virtio_mem_sbm_first_unplugged_sb(struct virtio_mem *vm, unsigned long mb_id) { const int bit = virtio_mem_sbm_sb_state_bit_nr(vm, mb_id, 0); return find_next_zero_bit(vm->sbm.sb_states, bit + vm->sbm.sbs_per_mb, bit) - bit; } /* * Prepare the subblock bitmap for the next memory block. */ static int virtio_mem_sbm_sb_states_prepare_next_mb(struct virtio_mem *vm) { const unsigned long old_nb_mb = vm->sbm.next_mb_id - vm->sbm.first_mb_id; const unsigned long old_nb_bits = old_nb_mb * vm->sbm.sbs_per_mb; const unsigned long new_nb_bits = (old_nb_mb + 1) * vm->sbm.sbs_per_mb; int old_pages = PFN_UP(BITS_TO_LONGS(old_nb_bits) * sizeof(long)); int new_pages = PFN_UP(BITS_TO_LONGS(new_nb_bits) * sizeof(long)); unsigned long *new_bitmap, *old_bitmap; if (vm->sbm.sb_states && old_pages == new_pages) return 0; new_bitmap = vzalloc(new_pages * PAGE_SIZE); if (!new_bitmap) return -ENOMEM; mutex_lock(&vm->hotplug_mutex); if (vm->sbm.sb_states) memcpy(new_bitmap, vm->sbm.sb_states, old_pages * PAGE_SIZE); old_bitmap = vm->sbm.sb_states; vm->sbm.sb_states = new_bitmap; mutex_unlock(&vm->hotplug_mutex); vfree(old_bitmap); return 0; } /* * Test if we could add memory without creating too much offline memory - * to avoid running OOM if memory is getting onlined deferred. */ static bool virtio_mem_could_add_memory(struct virtio_mem *vm, uint64_t size) { if (WARN_ON_ONCE(size > vm->offline_threshold)) return false; return atomic64_read(&vm->offline_size) + size <= vm->offline_threshold; } /* * Try adding memory to Linux. Will usually only fail if out of memory. * * Must not be called with the vm->hotplug_mutex held (possible deadlock with * onlining code). * * Will not modify the state of memory blocks in virtio-mem. */ static int virtio_mem_add_memory(struct virtio_mem *vm, uint64_t addr, uint64_t size) { int rc; /* * When force-unloading the driver and we still have memory added to * Linux, the resource name has to stay. */ if (!vm->resource_name) { vm->resource_name = kstrdup_const("System RAM (virtio_mem)", GFP_KERNEL); if (!vm->resource_name) return -ENOMEM; } dev_dbg(&vm->vdev->dev, "adding memory: 0x%llx - 0x%llx\n", addr, addr + size - 1); /* Memory might get onlined immediately. */ atomic64_add(size, &vm->offline_size); rc = add_memory_driver_managed(vm->mgid, addr, size, vm->resource_name, MHP_MERGE_RESOURCE | MHP_NID_IS_MGID); if (rc) { atomic64_sub(size, &vm->offline_size); dev_warn(&vm->vdev->dev, "adding memory failed: %d\n", rc); /* * TODO: Linux MM does not properly clean up yet in all cases * where adding of memory failed - especially on -ENOMEM. */ } return rc; } /* * See virtio_mem_add_memory(): Try adding a single Linux memory block. */ static int virtio_mem_sbm_add_mb(struct virtio_mem *vm, unsigned long mb_id) { const uint64_t addr = virtio_mem_mb_id_to_phys(mb_id); const uint64_t size = memory_block_size_bytes(); return virtio_mem_add_memory(vm, addr, size); } /* * See virtio_mem_add_memory(): Try adding a big block. */ static int virtio_mem_bbm_add_bb(struct virtio_mem *vm, unsigned long bb_id) { const uint64_t addr = virtio_mem_bb_id_to_phys(vm, bb_id); const uint64_t size = vm->bbm.bb_size; return virtio_mem_add_memory(vm, addr, size); } /* * Try removing memory from Linux. Will only fail if memory blocks aren't * offline. * * Must not be called with the vm->hotplug_mutex held (possible deadlock with * onlining code). * * Will not modify the state of memory blocks in virtio-mem. */ static int virtio_mem_remove_memory(struct virtio_mem *vm, uint64_t addr, uint64_t size) { int rc; dev_dbg(&vm->vdev->dev, "removing memory: 0x%llx - 0x%llx\n", addr, addr + size - 1); rc = remove_memory(addr, size); if (!rc) { atomic64_sub(size, &vm->offline_size); /* * We might have freed up memory we can now unplug, retry * immediately instead of waiting. */ virtio_mem_retry(vm); } else { dev_dbg(&vm->vdev->dev, "removing memory failed: %d\n", rc); } return rc; } /* * See virtio_mem_remove_memory(): Try removing a single Linux memory block. */ static int virtio_mem_sbm_remove_mb(struct virtio_mem *vm, unsigned long mb_id) { const uint64_t addr = virtio_mem_mb_id_to_phys(mb_id); const uint64_t size = memory_block_size_bytes(); return virtio_mem_remove_memory(vm, addr, size); } /* * Try offlining and removing memory from Linux. * * Must not be called with the vm->hotplug_mutex held (possible deadlock with * onlining code). * * Will not modify the state of memory blocks in virtio-mem. */ static int virtio_mem_offline_and_remove_memory(struct virtio_mem *vm, uint64_t addr, uint64_t size) { int rc; dev_dbg(&vm->vdev->dev, "offlining and removing memory: 0x%llx - 0x%llx\n", addr, addr + size - 1); rc = offline_and_remove_memory(addr, size); if (!rc) { atomic64_sub(size, &vm->offline_size); /* * We might have freed up memory we can now unplug, retry * immediately instead of waiting. */ virtio_mem_retry(vm); return 0; } dev_dbg(&vm->vdev->dev, "offlining and removing memory failed: %d\n", rc); /* * We don't really expect this to fail, because we fake-offlined all * memory already. But it could fail in corner cases. */ WARN_ON_ONCE(rc != -ENOMEM && rc != -EBUSY); return rc == -ENOMEM ? -ENOMEM : -EBUSY; } /* * See virtio_mem_offline_and_remove_memory(): Try offlining and removing * a single Linux memory block. */ static int virtio_mem_sbm_offline_and_remove_mb(struct virtio_mem *vm, unsigned long mb_id) { const uint64_t addr = virtio_mem_mb_id_to_phys(mb_id); const uint64_t size = memory_block_size_bytes(); return virtio_mem_offline_and_remove_memory(vm, addr, size); } /* * Try (offlining and) removing memory from Linux in case all subblocks are * unplugged. Can be called on online and offline memory blocks. * * May modify the state of memory blocks in virtio-mem. */ static int virtio_mem_sbm_try_remove_unplugged_mb(struct virtio_mem *vm, unsigned long mb_id) { int rc; /* * Once all subblocks of a memory block were unplugged, offline and * remove it. */ if (!virtio_mem_sbm_test_sb_unplugged(vm, mb_id, 0, vm->sbm.sbs_per_mb)) return 0; /* offline_and_remove_memory() works for online and offline memory. */ mutex_unlock(&vm->hotplug_mutex); rc = virtio_mem_sbm_offline_and_remove_mb(vm, mb_id); mutex_lock(&vm->hotplug_mutex); if (!rc) virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_UNUSED); return rc; } /* * See virtio_mem_offline_and_remove_memory(): Try to offline and remove a * all Linux memory blocks covered by the big block. */ static int virtio_mem_bbm_offline_and_remove_bb(struct virtio_mem *vm, unsigned long bb_id) { const uint64_t addr = virtio_mem_bb_id_to_phys(vm, bb_id); const uint64_t size = vm->bbm.bb_size; return virtio_mem_offline_and_remove_memory(vm, addr, size); } /* * Trigger the workqueue so the device can perform its magic. */ static void virtio_mem_retry(struct virtio_mem *vm) { unsigned long flags; spin_lock_irqsave(&vm->removal_lock, flags); if (!vm->removing) queue_work(system_freezable_wq, &vm->wq); spin_unlock_irqrestore(&vm->removal_lock, flags); } static int virtio_mem_translate_node_id(struct virtio_mem *vm, uint16_t node_id) { int node = NUMA_NO_NODE; #if defined(CONFIG_ACPI_NUMA) if (virtio_has_feature(vm->vdev, VIRTIO_MEM_F_ACPI_PXM)) node = pxm_to_node(node_id); #endif return node; } /* * Test if a virtio-mem device overlaps with the given range. Can be called * from (notifier) callbacks lockless. */ static bool virtio_mem_overlaps_range(struct virtio_mem *vm, uint64_t start, uint64_t size) { return start < vm->addr + vm->region_size && vm->addr < start + size; } /* * Test if a virtio-mem device contains a given range. Can be called from * (notifier) callbacks lockless. */ static bool virtio_mem_contains_range(struct virtio_mem *vm, uint64_t start, uint64_t size) { return start >= vm->addr && start + size <= vm->addr + vm->region_size; } static int virtio_mem_sbm_notify_going_online(struct virtio_mem *vm, unsigned long mb_id) { switch (virtio_mem_sbm_get_mb_state(vm, mb_id)) { case VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL: case VIRTIO_MEM_SBM_MB_OFFLINE: return NOTIFY_OK; default: break; } dev_warn_ratelimited(&vm->vdev->dev, "memory block onlining denied\n"); return NOTIFY_BAD; } static void virtio_mem_sbm_notify_offline(struct virtio_mem *vm, unsigned long mb_id) { switch (virtio_mem_sbm_get_mb_state(vm, mb_id)) { case VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL: case VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL: virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL); break; case VIRTIO_MEM_SBM_MB_KERNEL: case VIRTIO_MEM_SBM_MB_MOVABLE: virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_OFFLINE); break; default: BUG(); break; } } static void virtio_mem_sbm_notify_online(struct virtio_mem *vm, unsigned long mb_id, unsigned long start_pfn) { const bool is_movable = is_zone_movable_page(pfn_to_page(start_pfn)); int new_state; switch (virtio_mem_sbm_get_mb_state(vm, mb_id)) { case VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL: new_state = VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL; if (is_movable) new_state = VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL; break; case VIRTIO_MEM_SBM_MB_OFFLINE: new_state = VIRTIO_MEM_SBM_MB_KERNEL; if (is_movable) new_state = VIRTIO_MEM_SBM_MB_MOVABLE; break; default: BUG(); break; } virtio_mem_sbm_set_mb_state(vm, mb_id, new_state); } static void virtio_mem_sbm_notify_going_offline(struct virtio_mem *vm, unsigned long mb_id) { const unsigned long nr_pages = PFN_DOWN(vm->sbm.sb_size); unsigned long pfn; int sb_id; for (sb_id = 0; sb_id < vm->sbm.sbs_per_mb; sb_id++) { if (virtio_mem_sbm_test_sb_plugged(vm, mb_id, sb_id, 1)) continue; pfn = PFN_DOWN(virtio_mem_mb_id_to_phys(mb_id) + sb_id * vm->sbm.sb_size); virtio_mem_fake_offline_going_offline(pfn, nr_pages); } } static void virtio_mem_sbm_notify_cancel_offline(struct virtio_mem *vm, unsigned long mb_id) { const unsigned long nr_pages = PFN_DOWN(vm->sbm.sb_size); unsigned long pfn; int sb_id; for (sb_id = 0; sb_id < vm->sbm.sbs_per_mb; sb_id++) { if (virtio_mem_sbm_test_sb_plugged(vm, mb_id, sb_id, 1)) continue; pfn = PFN_DOWN(virtio_mem_mb_id_to_phys(mb_id) + sb_id * vm->sbm.sb_size); virtio_mem_fake_offline_cancel_offline(pfn, nr_pages); } } static void virtio_mem_bbm_notify_going_offline(struct virtio_mem *vm, unsigned long bb_id, unsigned long pfn, unsigned long nr_pages) { /* * When marked as "fake-offline", all online memory of this device block * is allocated by us. Otherwise, we don't have any memory allocated. */ if (virtio_mem_bbm_get_bb_state(vm, bb_id) != VIRTIO_MEM_BBM_BB_FAKE_OFFLINE) return; virtio_mem_fake_offline_going_offline(pfn, nr_pages); } static void virtio_mem_bbm_notify_cancel_offline(struct virtio_mem *vm, unsigned long bb_id, unsigned long pfn, unsigned long nr_pages) { if (virtio_mem_bbm_get_bb_state(vm, bb_id) != VIRTIO_MEM_BBM_BB_FAKE_OFFLINE) return; virtio_mem_fake_offline_cancel_offline(pfn, nr_pages); } /* * This callback will either be called synchronously from add_memory() or * asynchronously (e.g., triggered via user space). We have to be careful * with locking when calling add_memory(). */ static int virtio_mem_memory_notifier_cb(struct notifier_block *nb, unsigned long action, void *arg) { struct virtio_mem *vm = container_of(nb, struct virtio_mem, memory_notifier); struct memory_notify *mhp = arg; const unsigned long start = PFN_PHYS(mhp->start_pfn); const unsigned long size = PFN_PHYS(mhp->nr_pages); int rc = NOTIFY_OK; unsigned long id; if (!virtio_mem_overlaps_range(vm, start, size)) return NOTIFY_DONE; if (vm->in_sbm) { id = virtio_mem_phys_to_mb_id(start); /* * In SBM, we add memory in separate memory blocks - we expect * it to be onlined/offlined in the same granularity. Bail out * if this ever changes. */ if (WARN_ON_ONCE(size != memory_block_size_bytes() || !IS_ALIGNED(start, memory_block_size_bytes()))) return NOTIFY_BAD; } else { id = virtio_mem_phys_to_bb_id(vm, start); /* * In BBM, we only care about onlining/offlining happening * within a single big block, we don't care about the * actual granularity as we don't track individual Linux * memory blocks. */ if (WARN_ON_ONCE(id != virtio_mem_phys_to_bb_id(vm, start + size - 1))) return NOTIFY_BAD; } /* * Avoid circular locking lockdep warnings. We lock the mutex * e.g., in MEM_GOING_ONLINE and unlock it in MEM_ONLINE. The * blocking_notifier_call_chain() has it's own lock, which gets unlocked * between both notifier calls and will bail out. False positive. */ lockdep_off(); switch (action) { case MEM_GOING_OFFLINE: mutex_lock(&vm->hotplug_mutex); if (vm->removing) { rc = notifier_from_errno(-EBUSY); mutex_unlock(&vm->hotplug_mutex); break; } vm->hotplug_active = true; if (vm->in_sbm) virtio_mem_sbm_notify_going_offline(vm, id); else virtio_mem_bbm_notify_going_offline(vm, id, mhp->start_pfn, mhp->nr_pages); break; case MEM_GOING_ONLINE: mutex_lock(&vm->hotplug_mutex); if (vm->removing) { rc = notifier_from_errno(-EBUSY); mutex_unlock(&vm->hotplug_mutex); break; } vm->hotplug_active = true; if (vm->in_sbm) rc = virtio_mem_sbm_notify_going_online(vm, id); break; case MEM_OFFLINE: if (vm->in_sbm) virtio_mem_sbm_notify_offline(vm, id); atomic64_add(size, &vm->offline_size); /* * Trigger the workqueue. Now that we have some offline memory, * maybe we can handle pending unplug requests. */ if (!unplug_online) virtio_mem_retry(vm); vm->hotplug_active = false; mutex_unlock(&vm->hotplug_mutex); break; case MEM_ONLINE: if (vm->in_sbm) virtio_mem_sbm_notify_online(vm, id, mhp->start_pfn); atomic64_sub(size, &vm->offline_size); /* * Start adding more memory once we onlined half of our * threshold. Don't trigger if it's possibly due to our actipn * (e.g., us adding memory which gets onlined immediately from * the core). */ if (!atomic_read(&vm->wq_active) && virtio_mem_could_add_memory(vm, vm->offline_threshold / 2)) virtio_mem_retry(vm); vm->hotplug_active = false; mutex_unlock(&vm->hotplug_mutex); break; case MEM_CANCEL_OFFLINE: if (!vm->hotplug_active) break; if (vm->in_sbm) virtio_mem_sbm_notify_cancel_offline(vm, id); else virtio_mem_bbm_notify_cancel_offline(vm, id, mhp->start_pfn, mhp->nr_pages); vm->hotplug_active = false; mutex_unlock(&vm->hotplug_mutex); break; case MEM_CANCEL_ONLINE: if (!vm->hotplug_active) break; vm->hotplug_active = false; mutex_unlock(&vm->hotplug_mutex); break; default: break; } lockdep_on(); return rc; } static int virtio_mem_pm_notifier_cb(struct notifier_block *nb, unsigned long action, void *arg) { struct virtio_mem *vm = container_of(nb, struct virtio_mem, pm_notifier); switch (action) { case PM_HIBERNATION_PREPARE: case PM_RESTORE_PREPARE: /* * When restarting the VM, all memory is unplugged. Don't * allow to hibernate and restore from an image. */ dev_err(&vm->vdev->dev, "hibernation is not supported.\n"); return NOTIFY_BAD; default: return NOTIFY_OK; } } /* * Set a range of pages PG_offline. Remember pages that were never onlined * (via generic_online_page()) using PageDirty(). */ static void virtio_mem_set_fake_offline(unsigned long pfn, unsigned long nr_pages, bool onlined) { page_offline_begin(); for (; nr_pages--; pfn++) { struct page *page = pfn_to_page(pfn); if (!onlined) /* * Pages that have not been onlined yet were initialized * to PageOffline(). Remember that we have to route them * through generic_online_page(). */ SetPageDirty(page); else __SetPageOffline(page); VM_WARN_ON_ONCE(!PageOffline(page)); } page_offline_end(); } /* * Clear PG_offline from a range of pages. If the pages were never onlined, * (via generic_online_page()), clear PageDirty(). */ static void virtio_mem_clear_fake_offline(unsigned long pfn, unsigned long nr_pages, bool onlined) { for (; nr_pages--; pfn++) { struct page *page = pfn_to_page(pfn); if (!onlined) /* generic_online_page() will clear PageOffline(). */ ClearPageDirty(page); else __ClearPageOffline(page); } } /* * Release a range of fake-offline pages to the buddy, effectively * fake-onlining them. */ static void virtio_mem_fake_online(unsigned long pfn, unsigned long nr_pages) { unsigned long order = MAX_PAGE_ORDER; unsigned long i; /* * We might get called for ranges that don't cover properly aligned * MAX_PAGE_ORDER pages; however, we can only online properly aligned * pages with an order of MAX_PAGE_ORDER at maximum. */ while (!IS_ALIGNED(pfn | nr_pages, 1 << order)) order--; for (i = 0; i < nr_pages; i += 1 << order) { struct page *page = pfn_to_page(pfn + i); /* * If the page is PageDirty(), it was kept fake-offline when * onlining the memory block. Otherwise, it was allocated * using alloc_contig_range(). All pages in a subblock are * alike. */ if (PageDirty(page)) { virtio_mem_clear_fake_offline(pfn + i, 1 << order, false); generic_online_page(page, order); } else { virtio_mem_clear_fake_offline(pfn + i, 1 << order, true); free_contig_range(pfn + i, 1 << order); adjust_managed_page_count(page, 1 << order); } } } /* * Try to allocate a range, marking pages fake-offline, effectively * fake-offlining them. */ static int virtio_mem_fake_offline(struct virtio_mem *vm, unsigned long pfn, unsigned long nr_pages) { const bool is_movable = is_zone_movable_page(pfn_to_page(pfn)); int rc, retry_count; /* * TODO: We want an alloc_contig_range() mode that tries to allocate * harder (e.g., dealing with temporarily pinned pages, PCP), especially * with ZONE_MOVABLE. So for now, retry a couple of times with * ZONE_MOVABLE before giving up - because that zone is supposed to give * some guarantees. */ for (retry_count = 0; retry_count < 5; retry_count++) { /* * If the config changed, stop immediately and go back to the * main loop: avoid trying to keep unplugging if the device * might have decided to not remove any more memory. */ if (atomic_read(&vm->config_changed)) return -EAGAIN; rc = alloc_contig_range(pfn, pfn + nr_pages, MIGRATE_MOVABLE, GFP_KERNEL); if (rc == -ENOMEM) /* whoops, out of memory */ return rc; else if (rc && !is_movable) break; else if (rc) continue; virtio_mem_set_fake_offline(pfn, nr_pages, true); adjust_managed_page_count(pfn_to_page(pfn), -nr_pages); return 0; } return -EBUSY; } /* * Handle fake-offline pages when memory is going offline - such that the * pages can be skipped by mm-core when offlining. */ static void virtio_mem_fake_offline_going_offline(unsigned long pfn, unsigned long nr_pages) { struct page *page; unsigned long i; /* Drop our reference to the pages so the memory can get offlined. */ for (i = 0; i < nr_pages; i++) { page = pfn_to_page(pfn + i); if (WARN_ON(!page_ref_dec_and_test(page))) dump_page(page, "fake-offline page referenced"); } } /* * Handle fake-offline pages when memory offlining is canceled - to undo * what we did in virtio_mem_fake_offline_going_offline(). */ static void virtio_mem_fake_offline_cancel_offline(unsigned long pfn, unsigned long nr_pages) { unsigned long i; /* * Get the reference again that we dropped via page_ref_dec_and_test() * when going offline. */ for (i = 0; i < nr_pages; i++) page_ref_inc(pfn_to_page(pfn + i)); } static void virtio_mem_online_page(struct virtio_mem *vm, struct page *page, unsigned int order) { const unsigned long start = page_to_phys(page); const unsigned long end = start + PFN_PHYS(1 << order); unsigned long addr, next, id, sb_id, count; bool do_online; /* * We can get called with any order up to MAX_PAGE_ORDER. If our subblock * size is smaller than that and we have a mixture of plugged and * unplugged subblocks within such a page, we have to process in * smaller granularity. In that case we'll adjust the order exactly once * within the loop. */ for (addr = start; addr < end; ) { next = addr + PFN_PHYS(1 << order); if (vm->in_sbm) { id = virtio_mem_phys_to_mb_id(addr); sb_id = virtio_mem_phys_to_sb_id(vm, addr); count = virtio_mem_phys_to_sb_id(vm, next - 1) - sb_id + 1; if (virtio_mem_sbm_test_sb_plugged(vm, id, sb_id, count)) { /* Fully plugged. */ do_online = true; } else if (count == 1 || virtio_mem_sbm_test_sb_unplugged(vm, id, sb_id, count)) { /* Fully unplugged. */ do_online = false; } else { /* * Mixture, process sub-blocks instead. This * will be at least the size of a pageblock. * We'll run into this case exactly once. */ order = ilog2(vm->sbm.sb_size) - PAGE_SHIFT; do_online = virtio_mem_sbm_test_sb_plugged(vm, id, sb_id, 1); continue; } } else { /* * If the whole block is marked fake offline, keep * everything that way. */ id = virtio_mem_phys_to_bb_id(vm, addr); do_online = virtio_mem_bbm_get_bb_state(vm, id) != VIRTIO_MEM_BBM_BB_FAKE_OFFLINE; } if (do_online) generic_online_page(pfn_to_page(PFN_DOWN(addr)), order); else virtio_mem_set_fake_offline(PFN_DOWN(addr), 1 << order, false); addr = next; } } static void virtio_mem_online_page_cb(struct page *page, unsigned int order) { const unsigned long addr = page_to_phys(page); struct virtio_mem *vm; rcu_read_lock(); list_for_each_entry_rcu(vm, &virtio_mem_devices, next) { /* * Pages we're onlining will never cross memory blocks and, * therefore, not virtio-mem devices. */ if (!virtio_mem_contains_range(vm, addr, PFN_PHYS(1 << order))) continue; /* * virtio_mem_set_fake_offline() might sleep. We can safely * drop the RCU lock at this point because the device * cannot go away. See virtio_mem_remove() how races * between memory onlining and device removal are handled. */ rcu_read_unlock(); virtio_mem_online_page(vm, page, order); return; } rcu_read_unlock(); /* not virtio-mem memory, but e.g., a DIMM. online it */ generic_online_page(page, order); } static uint64_t virtio_mem_send_request(struct virtio_mem *vm, const struct virtio_mem_req *req) { struct scatterlist *sgs[2], sg_req, sg_resp; unsigned int len; int rc; /* don't use the request residing on the stack (vaddr) */ vm->req = *req; /* out: buffer for request */ sg_init_one(&sg_req, &vm->req, sizeof(vm->req)); sgs[0] = &sg_req; /* in: buffer for response */ sg_init_one(&sg_resp, &vm->resp, sizeof(vm->resp)); sgs[1] = &sg_resp; rc = virtqueue_add_sgs(vm->vq, sgs, 1, 1, vm, GFP_KERNEL); if (rc < 0) return rc; virtqueue_kick(vm->vq); /* wait for a response */ wait_event(vm->host_resp, virtqueue_get_buf(vm->vq, &len)); return virtio16_to_cpu(vm->vdev, vm->resp.type); } static int virtio_mem_send_plug_request(struct virtio_mem *vm, uint64_t addr, uint64_t size) { const uint64_t nb_vm_blocks = size / vm->device_block_size; const struct virtio_mem_req req = { .type = cpu_to_virtio16(vm->vdev, VIRTIO_MEM_REQ_PLUG), .u.plug.addr = cpu_to_virtio64(vm->vdev, addr), .u.plug.nb_blocks = cpu_to_virtio16(vm->vdev, nb_vm_blocks), }; int rc = -ENOMEM; if (atomic_read(&vm->config_changed)) return -EAGAIN; dev_dbg(&vm->vdev->dev, "plugging memory: 0x%llx - 0x%llx\n", addr, addr + size - 1); switch (virtio_mem_send_request(vm, &req)) { case VIRTIO_MEM_RESP_ACK: vm->plugged_size += size; return 0; case VIRTIO_MEM_RESP_NACK: rc = -EAGAIN; break; case VIRTIO_MEM_RESP_BUSY: rc = -ETXTBSY; break; case VIRTIO_MEM_RESP_ERROR: rc = -EINVAL; break; default: break; } dev_dbg(&vm->vdev->dev, "plugging memory failed: %d\n", rc); return rc; } static int virtio_mem_send_unplug_request(struct virtio_mem *vm, uint64_t addr, uint64_t size) { const uint64_t nb_vm_blocks = size / vm->device_block_size; const struct virtio_mem_req req = { .type = cpu_to_virtio16(vm->vdev, VIRTIO_MEM_REQ_UNPLUG), .u.unplug.addr = cpu_to_virtio64(vm->vdev, addr), .u.unplug.nb_blocks = cpu_to_virtio16(vm->vdev, nb_vm_blocks), }; int rc = -ENOMEM; if (atomic_read(&vm->config_changed)) return -EAGAIN; dev_dbg(&vm->vdev->dev, "unplugging memory: 0x%llx - 0x%llx\n", addr, addr + size - 1); switch (virtio_mem_send_request(vm, &req)) { case VIRTIO_MEM_RESP_ACK: vm->plugged_size -= size; return 0; case VIRTIO_MEM_RESP_BUSY: rc = -ETXTBSY; break; case VIRTIO_MEM_RESP_ERROR: rc = -EINVAL; break; default: break; } dev_dbg(&vm->vdev->dev, "unplugging memory failed: %d\n", rc); return rc; } static int virtio_mem_send_unplug_all_request(struct virtio_mem *vm) { const struct virtio_mem_req req = { .type = cpu_to_virtio16(vm->vdev, VIRTIO_MEM_REQ_UNPLUG_ALL), }; int rc = -ENOMEM; dev_dbg(&vm->vdev->dev, "unplugging all memory"); switch (virtio_mem_send_request(vm, &req)) { case VIRTIO_MEM_RESP_ACK: vm->unplug_all_required = false; vm->plugged_size = 0; /* usable region might have shrunk */ atomic_set(&vm->config_changed, 1); return 0; case VIRTIO_MEM_RESP_BUSY: rc = -ETXTBSY; break; default: break; } dev_dbg(&vm->vdev->dev, "unplugging all memory failed: %d\n", rc); return rc; } /* * Plug selected subblocks. Updates the plugged state, but not the state * of the memory block. */ static int virtio_mem_sbm_plug_sb(struct virtio_mem *vm, unsigned long mb_id, int sb_id, int count) { const uint64_t addr = virtio_mem_mb_id_to_phys(mb_id) + sb_id * vm->sbm.sb_size; const uint64_t size = count * vm->sbm.sb_size; int rc; rc = virtio_mem_send_plug_request(vm, addr, size); if (!rc) virtio_mem_sbm_set_sb_plugged(vm, mb_id, sb_id, count); return rc; } /* * Unplug selected subblocks. Updates the plugged state, but not the state * of the memory block. */ static int virtio_mem_sbm_unplug_sb(struct virtio_mem *vm, unsigned long mb_id, int sb_id, int count) { const uint64_t addr = virtio_mem_mb_id_to_phys(mb_id) + sb_id * vm->sbm.sb_size; const uint64_t size = count * vm->sbm.sb_size; int rc; rc = virtio_mem_send_unplug_request(vm, addr, size); if (!rc) virtio_mem_sbm_set_sb_unplugged(vm, mb_id, sb_id, count); return rc; } /* * Request to unplug a big block. * * Will not modify the state of the big block. */ static int virtio_mem_bbm_unplug_bb(struct virtio_mem *vm, unsigned long bb_id) { const uint64_t addr = virtio_mem_bb_id_to_phys(vm, bb_id); const uint64_t size = vm->bbm.bb_size; return virtio_mem_send_unplug_request(vm, addr, size); } /* * Request to plug a big block. * * Will not modify the state of the big block. */ static int virtio_mem_bbm_plug_bb(struct virtio_mem *vm, unsigned long bb_id) { const uint64_t addr = virtio_mem_bb_id_to_phys(vm, bb_id); const uint64_t size = vm->bbm.bb_size; return virtio_mem_send_plug_request(vm, addr, size); } /* * Unplug the desired number of plugged subblocks of a offline or not-added * memory block. Will fail if any subblock cannot get unplugged (instead of * skipping it). * * Will not modify the state of the memory block. * * Note: can fail after some subblocks were unplugged. */ static int virtio_mem_sbm_unplug_any_sb_raw(struct virtio_mem *vm, unsigned long mb_id, uint64_t *nb_sb) { int sb_id, count; int rc; sb_id = vm->sbm.sbs_per_mb - 1; while (*nb_sb) { /* Find the next candidate subblock */ while (sb_id >= 0 && virtio_mem_sbm_test_sb_unplugged(vm, mb_id, sb_id, 1)) sb_id--; if (sb_id < 0) break; /* Try to unplug multiple subblocks at a time */ count = 1; while (count < *nb_sb && sb_id > 0 && virtio_mem_sbm_test_sb_plugged(vm, mb_id, sb_id - 1, 1)) { count++; sb_id--; } rc = virtio_mem_sbm_unplug_sb(vm, mb_id, sb_id, count); if (rc) return rc; *nb_sb -= count; sb_id--; } return 0; } /* * Unplug all plugged subblocks of an offline or not-added memory block. * * Will not modify the state of the memory block. * * Note: can fail after some subblocks were unplugged. */ static int virtio_mem_sbm_unplug_mb(struct virtio_mem *vm, unsigned long mb_id) { uint64_t nb_sb = vm->sbm.sbs_per_mb; return virtio_mem_sbm_unplug_any_sb_raw(vm, mb_id, &nb_sb); } /* * Prepare tracking data for the next memory block. */ static int virtio_mem_sbm_prepare_next_mb(struct virtio_mem *vm, unsigned long *mb_id) { int rc; if (vm->sbm.next_mb_id > vm->sbm.last_usable_mb_id) return -ENOSPC; /* Resize the state array if required. */ rc = virtio_mem_sbm_mb_states_prepare_next_mb(vm); if (rc) return rc; /* Resize the subblock bitmap if required. */ rc = virtio_mem_sbm_sb_states_prepare_next_mb(vm); if (rc) return rc; vm->sbm.mb_count[VIRTIO_MEM_SBM_MB_UNUSED]++; *mb_id = vm->sbm.next_mb_id++; return 0; } /* * Try to plug the desired number of subblocks and add the memory block * to Linux. * * Will modify the state of the memory block. */ static int virtio_mem_sbm_plug_and_add_mb(struct virtio_mem *vm, unsigned long mb_id, uint64_t *nb_sb) { const int count = min_t(int, *nb_sb, vm->sbm.sbs_per_mb); int rc; if (WARN_ON_ONCE(!count)) return -EINVAL; /* * Plug the requested number of subblocks before adding it to linux, * so that onlining will directly online all plugged subblocks. */ rc = virtio_mem_sbm_plug_sb(vm, mb_id, 0, count); if (rc) return rc; /* * Mark the block properly offline before adding it to Linux, * so the memory notifiers will find the block in the right state. */ if (count == vm->sbm.sbs_per_mb) virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_OFFLINE); else virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL); /* Add the memory block to linux - if that fails, try to unplug. */ rc = virtio_mem_sbm_add_mb(vm, mb_id); if (rc) { int new_state = VIRTIO_MEM_SBM_MB_UNUSED; if (virtio_mem_sbm_unplug_sb(vm, mb_id, 0, count)) new_state = VIRTIO_MEM_SBM_MB_PLUGGED; virtio_mem_sbm_set_mb_state(vm, mb_id, new_state); return rc; } *nb_sb -= count; return 0; } /* * Try to plug the desired number of subblocks of a memory block that * is already added to Linux. * * Will modify the state of the memory block. * * Note: Can fail after some subblocks were successfully plugged. */ static int virtio_mem_sbm_plug_any_sb(struct virtio_mem *vm, unsigned long mb_id, uint64_t *nb_sb) { const int old_state = virtio_mem_sbm_get_mb_state(vm, mb_id); unsigned long pfn, nr_pages; int sb_id, count; int rc; if (WARN_ON_ONCE(!*nb_sb)) return -EINVAL; while (*nb_sb) { sb_id = virtio_mem_sbm_first_unplugged_sb(vm, mb_id); if (sb_id >= vm->sbm.sbs_per_mb) break; count = 1; while (count < *nb_sb && sb_id + count < vm->sbm.sbs_per_mb && !virtio_mem_sbm_test_sb_plugged(vm, mb_id, sb_id + count, 1)) count++; rc = virtio_mem_sbm_plug_sb(vm, mb_id, sb_id, count); if (rc) return rc; *nb_sb -= count; if (old_state == VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL) continue; /* fake-online the pages if the memory block is online */ pfn = PFN_DOWN(virtio_mem_mb_id_to_phys(mb_id) + sb_id * vm->sbm.sb_size); nr_pages = PFN_DOWN(count * vm->sbm.sb_size); virtio_mem_fake_online(pfn, nr_pages); } if (virtio_mem_sbm_test_sb_plugged(vm, mb_id, 0, vm->sbm.sbs_per_mb)) virtio_mem_sbm_set_mb_state(vm, mb_id, old_state - 1); return 0; } static int virtio_mem_sbm_plug_request(struct virtio_mem *vm, uint64_t diff) { const int mb_states[] = { VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL, VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL, VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL, }; uint64_t nb_sb = diff / vm->sbm.sb_size; unsigned long mb_id; int rc, i; if (!nb_sb) return 0; /* Don't race with onlining/offlining */ mutex_lock(&vm->hotplug_mutex); for (i = 0; i < ARRAY_SIZE(mb_states); i++) { virtio_mem_sbm_for_each_mb(vm, mb_id, mb_states[i]) { rc = virtio_mem_sbm_plug_any_sb(vm, mb_id, &nb_sb); if (rc || !nb_sb) goto out_unlock; cond_resched(); } } /* * We won't be working on online/offline memory blocks from this point, * so we can't race with memory onlining/offlining. Drop the mutex. */ mutex_unlock(&vm->hotplug_mutex); /* Try to plug and add unused blocks */ virtio_mem_sbm_for_each_mb(vm, mb_id, VIRTIO_MEM_SBM_MB_UNUSED) { if (!virtio_mem_could_add_memory(vm, memory_block_size_bytes())) return -ENOSPC; rc = virtio_mem_sbm_plug_and_add_mb(vm, mb_id, &nb_sb); if (rc || !nb_sb) return rc; cond_resched(); } /* Try to prepare, plug and add new blocks */ while (nb_sb) { if (!virtio_mem_could_add_memory(vm, memory_block_size_bytes())) return -ENOSPC; rc = virtio_mem_sbm_prepare_next_mb(vm, &mb_id); if (rc) return rc; rc = virtio_mem_sbm_plug_and_add_mb(vm, mb_id, &nb_sb); if (rc) return rc; cond_resched(); } return 0; out_unlock: mutex_unlock(&vm->hotplug_mutex); return rc; } /* * Plug a big block and add it to Linux. * * Will modify the state of the big block. */ static int virtio_mem_bbm_plug_and_add_bb(struct virtio_mem *vm, unsigned long bb_id) { int rc; if (WARN_ON_ONCE(virtio_mem_bbm_get_bb_state(vm, bb_id) != VIRTIO_MEM_BBM_BB_UNUSED)) return -EINVAL; rc = virtio_mem_bbm_plug_bb(vm, bb_id); if (rc) return rc; virtio_mem_bbm_set_bb_state(vm, bb_id, VIRTIO_MEM_BBM_BB_ADDED); rc = virtio_mem_bbm_add_bb(vm, bb_id); if (rc) { if (!virtio_mem_bbm_unplug_bb(vm, bb_id)) virtio_mem_bbm_set_bb_state(vm, bb_id, VIRTIO_MEM_BBM_BB_UNUSED); else /* Retry from the main loop. */ virtio_mem_bbm_set_bb_state(vm, bb_id, VIRTIO_MEM_BBM_BB_PLUGGED); return rc; } return 0; } /* * Prepare tracking data for the next big block. */ static int virtio_mem_bbm_prepare_next_bb(struct virtio_mem *vm, unsigned long *bb_id) { int rc; if (vm->bbm.next_bb_id > vm->bbm.last_usable_bb_id) return -ENOSPC; /* Resize the big block state array if required. */ rc = virtio_mem_bbm_bb_states_prepare_next_bb(vm); if (rc) return rc; vm->bbm.bb_count[VIRTIO_MEM_BBM_BB_UNUSED]++; *bb_id = vm->bbm.next_bb_id; vm->bbm.next_bb_id++; return 0; } static int virtio_mem_bbm_plug_request(struct virtio_mem *vm, uint64_t diff) { uint64_t nb_bb = diff / vm->bbm.bb_size; unsigned long bb_id; int rc; if (!nb_bb) return 0; /* Try to plug and add unused big blocks */ virtio_mem_bbm_for_each_bb(vm, bb_id, VIRTIO_MEM_BBM_BB_UNUSED) { if (!virtio_mem_could_add_memory(vm, vm->bbm.bb_size)) return -ENOSPC; rc = virtio_mem_bbm_plug_and_add_bb(vm, bb_id); if (!rc) nb_bb--; if (rc || !nb_bb) return rc; cond_resched(); } /* Try to prepare, plug and add new big blocks */ while (nb_bb) { if (!virtio_mem_could_add_memory(vm, vm->bbm.bb_size)) return -ENOSPC; rc = virtio_mem_bbm_prepare_next_bb(vm, &bb_id); if (rc) return rc; rc = virtio_mem_bbm_plug_and_add_bb(vm, bb_id); if (!rc) nb_bb--; if (rc) return rc; cond_resched(); } return 0; } /* * Try to plug the requested amount of memory. */ static int virtio_mem_plug_request(struct virtio_mem *vm, uint64_t diff) { if (vm->in_sbm) return virtio_mem_sbm_plug_request(vm, diff); return virtio_mem_bbm_plug_request(vm, diff); } /* * Unplug the desired number of plugged subblocks of an offline memory block. * Will fail if any subblock cannot get unplugged (instead of skipping it). * * Will modify the state of the memory block. Might temporarily drop the * hotplug_mutex. * * Note: Can fail after some subblocks were successfully unplugged. */ static int virtio_mem_sbm_unplug_any_sb_offline(struct virtio_mem *vm, unsigned long mb_id, uint64_t *nb_sb) { int rc; rc = virtio_mem_sbm_unplug_any_sb_raw(vm, mb_id, nb_sb); /* some subblocks might have been unplugged even on failure */ if (!virtio_mem_sbm_test_sb_plugged(vm, mb_id, 0, vm->sbm.sbs_per_mb)) virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL); if (rc) return rc; if (virtio_mem_sbm_test_sb_unplugged(vm, mb_id, 0, vm->sbm.sbs_per_mb)) { /* * Remove the block from Linux - this should never fail. * Hinder the block from getting onlined by marking it * unplugged. Temporarily drop the mutex, so * any pending GOING_ONLINE requests can be serviced/rejected. */ virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_UNUSED); mutex_unlock(&vm->hotplug_mutex); rc = virtio_mem_sbm_remove_mb(vm, mb_id); BUG_ON(rc); mutex_lock(&vm->hotplug_mutex); } return 0; } /* * Unplug the given plugged subblocks of an online memory block. * * Will modify the state of the memory block. */ static int virtio_mem_sbm_unplug_sb_online(struct virtio_mem *vm, unsigned long mb_id, int sb_id, int count) { const unsigned long nr_pages = PFN_DOWN(vm->sbm.sb_size) * count; const int old_state = virtio_mem_sbm_get_mb_state(vm, mb_id); unsigned long start_pfn; int rc; start_pfn = PFN_DOWN(virtio_mem_mb_id_to_phys(mb_id) + sb_id * vm->sbm.sb_size); rc = virtio_mem_fake_offline(vm, start_pfn, nr_pages); if (rc) return rc; /* Try to unplug the allocated memory */ rc = virtio_mem_sbm_unplug_sb(vm, mb_id, sb_id, count); if (rc) { /* Return the memory to the buddy. */ virtio_mem_fake_online(start_pfn, nr_pages); return rc; } switch (old_state) { case VIRTIO_MEM_SBM_MB_KERNEL: virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL); break; case VIRTIO_MEM_SBM_MB_MOVABLE: virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL); break; } return 0; } /* * Unplug the desired number of plugged subblocks of an online memory block. * Will skip subblock that are busy. * * Will modify the state of the memory block. Might temporarily drop the * hotplug_mutex. * * Note: Can fail after some subblocks were successfully unplugged. Can * return 0 even if subblocks were busy and could not get unplugged. */ static int virtio_mem_sbm_unplug_any_sb_online(struct virtio_mem *vm, unsigned long mb_id, uint64_t *nb_sb) { int rc, sb_id; /* If possible, try to unplug the complete block in one shot. */ if (*nb_sb >= vm->sbm.sbs_per_mb && virtio_mem_sbm_test_sb_plugged(vm, mb_id, 0, vm->sbm.sbs_per_mb)) { rc = virtio_mem_sbm_unplug_sb_online(vm, mb_id, 0, vm->sbm.sbs_per_mb); if (!rc) { *nb_sb -= vm->sbm.sbs_per_mb; goto unplugged; } else if (rc != -EBUSY) return rc; } /* Fallback to single subblocks. */ for (sb_id = vm->sbm.sbs_per_mb - 1; sb_id >= 0 && *nb_sb; sb_id--) { /* Find the next candidate subblock */ while (sb_id >= 0 && !virtio_mem_sbm_test_sb_plugged(vm, mb_id, sb_id, 1)) sb_id--; if (sb_id < 0) break; rc = virtio_mem_sbm_unplug_sb_online(vm, mb_id, sb_id, 1); if (rc == -EBUSY) continue; else if (rc) return rc; *nb_sb -= 1; } unplugged: rc = virtio_mem_sbm_try_remove_unplugged_mb(vm, mb_id); if (rc) vm->sbm.have_unplugged_mb = 1; /* Ignore errors, this is not critical. We'll retry later. */ return 0; } /* * Unplug the desired number of plugged subblocks of a memory block that is * already added to Linux. Will skip subblock of online memory blocks that are * busy (by the OS). Will fail if any subblock that's not busy cannot get * unplugged. * * Will modify the state of the memory block. Might temporarily drop the * hotplug_mutex. * * Note: Can fail after some subblocks were successfully unplugged. Can * return 0 even if subblocks were busy and could not get unplugged. */ static int virtio_mem_sbm_unplug_any_sb(struct virtio_mem *vm, unsigned long mb_id, uint64_t *nb_sb) { const int old_state = virtio_mem_sbm_get_mb_state(vm, mb_id); switch (old_state) { case VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL: case VIRTIO_MEM_SBM_MB_KERNEL: case VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL: case VIRTIO_MEM_SBM_MB_MOVABLE: return virtio_mem_sbm_unplug_any_sb_online(vm, mb_id, nb_sb); case VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL: case VIRTIO_MEM_SBM_MB_OFFLINE: return virtio_mem_sbm_unplug_any_sb_offline(vm, mb_id, nb_sb); } return -EINVAL; } static int virtio_mem_sbm_unplug_request(struct virtio_mem *vm, uint64_t diff) { const int mb_states[] = { VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL, VIRTIO_MEM_SBM_MB_OFFLINE, VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL, VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL, VIRTIO_MEM_SBM_MB_MOVABLE, VIRTIO_MEM_SBM_MB_KERNEL, }; uint64_t nb_sb = diff / vm->sbm.sb_size; unsigned long mb_id; int rc, i; if (!nb_sb) return 0; /* * We'll drop the mutex a couple of times when it is safe to do so. * This might result in some blocks switching the state (online/offline) * and we could miss them in this run - we will retry again later. */ mutex_lock(&vm->hotplug_mutex); /* * We try unplug from partially plugged blocks first, to try removing * whole memory blocks along with metadata. We prioritize ZONE_MOVABLE * as it's more reliable to unplug memory and remove whole memory * blocks, and we don't want to trigger a zone imbalances by * accidentially removing too much kernel memory. */ for (i = 0; i < ARRAY_SIZE(mb_states); i++) { virtio_mem_sbm_for_each_mb_rev(vm, mb_id, mb_states[i]) { rc = virtio_mem_sbm_unplug_any_sb(vm, mb_id, &nb_sb); if (rc || !nb_sb) goto out_unlock; mutex_unlock(&vm->hotplug_mutex); cond_resched(); mutex_lock(&vm->hotplug_mutex); } if (!unplug_online && i == 1) { mutex_unlock(&vm->hotplug_mutex); return 0; } } mutex_unlock(&vm->hotplug_mutex); return nb_sb ? -EBUSY : 0; out_unlock: mutex_unlock(&vm->hotplug_mutex); return rc; } /* * Try to offline and remove a big block from Linux and unplug it. Will fail * with -EBUSY if some memory is busy and cannot get unplugged. * * Will modify the state of the memory block. Might temporarily drop the * hotplug_mutex. */ static int virtio_mem_bbm_offline_remove_and_unplug_bb(struct virtio_mem *vm, unsigned long bb_id) { const unsigned long start_pfn = PFN_DOWN(virtio_mem_bb_id_to_phys(vm, bb_id)); const unsigned long nr_pages = PFN_DOWN(vm->bbm.bb_size); unsigned long end_pfn = start_pfn + nr_pages; unsigned long pfn; struct page *page; int rc; if (WARN_ON_ONCE(virtio_mem_bbm_get_bb_state(vm, bb_id) != VIRTIO_MEM_BBM_BB_ADDED)) return -EINVAL; /* * Start by fake-offlining all memory. Once we marked the device * block as fake-offline, all newly onlined memory will * automatically be kept fake-offline. Protect from concurrent * onlining/offlining until we have a consistent state. */ mutex_lock(&vm->hotplug_mutex); virtio_mem_bbm_set_bb_state(vm, bb_id, VIRTIO_MEM_BBM_BB_FAKE_OFFLINE); for (pfn = start_pfn; pfn < end_pfn; pfn += PAGES_PER_SECTION) { page = pfn_to_online_page(pfn); if (!page) continue; rc = virtio_mem_fake_offline(vm, pfn, PAGES_PER_SECTION); if (rc) { end_pfn = pfn; goto rollback; } } mutex_unlock(&vm->hotplug_mutex); rc = virtio_mem_bbm_offline_and_remove_bb(vm, bb_id); if (rc) { mutex_lock(&vm->hotplug_mutex); goto rollback; } rc = virtio_mem_bbm_unplug_bb(vm, bb_id); if (rc) virtio_mem_bbm_set_bb_state(vm, bb_id, VIRTIO_MEM_BBM_BB_PLUGGED); else virtio_mem_bbm_set_bb_state(vm, bb_id, VIRTIO_MEM_BBM_BB_UNUSED); return rc; rollback: for (pfn = start_pfn; pfn < end_pfn; pfn += PAGES_PER_SECTION) { page = pfn_to_online_page(pfn); if (!page) continue; virtio_mem_fake_online(pfn, PAGES_PER_SECTION); } virtio_mem_bbm_set_bb_state(vm, bb_id, VIRTIO_MEM_BBM_BB_ADDED); mutex_unlock(&vm->hotplug_mutex); return rc; } /* * Test if a big block is completely offline. */ static bool virtio_mem_bbm_bb_is_offline(struct virtio_mem *vm, unsigned long bb_id) { const unsigned long start_pfn = PFN_DOWN(virtio_mem_bb_id_to_phys(vm, bb_id)); const unsigned long nr_pages = PFN_DOWN(vm->bbm.bb_size); unsigned long pfn; for (pfn = start_pfn; pfn < start_pfn + nr_pages; pfn += PAGES_PER_SECTION) { if (pfn_to_online_page(pfn)) return false; } return true; } /* * Test if a big block is completely onlined to ZONE_MOVABLE (or offline). */ static bool virtio_mem_bbm_bb_is_movable(struct virtio_mem *vm, unsigned long bb_id) { const unsigned long start_pfn = PFN_DOWN(virtio_mem_bb_id_to_phys(vm, bb_id)); const unsigned long nr_pages = PFN_DOWN(vm->bbm.bb_size); struct page *page; unsigned long pfn; for (pfn = start_pfn; pfn < start_pfn + nr_pages; pfn += PAGES_PER_SECTION) { page = pfn_to_online_page(pfn); if (!page) continue; if (page_zonenum(page) != ZONE_MOVABLE) return false; } return true; } static int virtio_mem_bbm_unplug_request(struct virtio_mem *vm, uint64_t diff) { uint64_t nb_bb = diff / vm->bbm.bb_size; uint64_t bb_id; int rc, i; if (!nb_bb) return 0; /* * Try to unplug big blocks. Similar to SBM, start with offline * big blocks. */ for (i = 0; i < 3; i++) { virtio_mem_bbm_for_each_bb_rev(vm, bb_id, VIRTIO_MEM_BBM_BB_ADDED) { cond_resched(); /* * As we're holding no locks, these checks are racy, * but we don't care. */ if (i == 0 && !virtio_mem_bbm_bb_is_offline(vm, bb_id)) continue; if (i == 1 && !virtio_mem_bbm_bb_is_movable(vm, bb_id)) continue; rc = virtio_mem_bbm_offline_remove_and_unplug_bb(vm, bb_id); if (rc == -EBUSY) continue; if (!rc) nb_bb--; if (rc || !nb_bb) return rc; } if (i == 0 && !unplug_online) return 0; } return nb_bb ? -EBUSY : 0; } /* * Try to unplug the requested amount of memory. */ static int virtio_mem_unplug_request(struct virtio_mem *vm, uint64_t diff) { if (vm->in_sbm) return virtio_mem_sbm_unplug_request(vm, diff); return virtio_mem_bbm_unplug_request(vm, diff); } /* * Try to unplug all blocks that couldn't be unplugged before, for example, * because the hypervisor was busy. Further, offline and remove any memory * blocks where we previously failed. */ static int virtio_mem_cleanup_pending_mb(struct virtio_mem *vm) { unsigned long id; int rc = 0; if (!vm->in_sbm) { virtio_mem_bbm_for_each_bb(vm, id, VIRTIO_MEM_BBM_BB_PLUGGED) { rc = virtio_mem_bbm_unplug_bb(vm, id); if (rc) return rc; virtio_mem_bbm_set_bb_state(vm, id, VIRTIO_MEM_BBM_BB_UNUSED); } return 0; } virtio_mem_sbm_for_each_mb(vm, id, VIRTIO_MEM_SBM_MB_PLUGGED) { rc = virtio_mem_sbm_unplug_mb(vm, id); if (rc) return rc; virtio_mem_sbm_set_mb_state(vm, id, VIRTIO_MEM_SBM_MB_UNUSED); } if (!vm->sbm.have_unplugged_mb) return 0; /* * Let's retry (offlining and) removing completely unplugged Linux * memory blocks. */ vm->sbm.have_unplugged_mb = false; mutex_lock(&vm->hotplug_mutex); virtio_mem_sbm_for_each_mb(vm, id, VIRTIO_MEM_SBM_MB_MOVABLE_PARTIAL) rc |= virtio_mem_sbm_try_remove_unplugged_mb(vm, id); virtio_mem_sbm_for_each_mb(vm, id, VIRTIO_MEM_SBM_MB_KERNEL_PARTIAL) rc |= virtio_mem_sbm_try_remove_unplugged_mb(vm, id); virtio_mem_sbm_for_each_mb(vm, id, VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL) rc |= virtio_mem_sbm_try_remove_unplugged_mb(vm, id); mutex_unlock(&vm->hotplug_mutex); if (rc) vm->sbm.have_unplugged_mb = true; /* Ignore errors, this is not critical. We'll retry later. */ return 0; } /* * Update all parts of the config that could have changed. */ static void virtio_mem_refresh_config(struct virtio_mem *vm) { const struct range pluggable_range = mhp_get_pluggable_range(true); uint64_t new_plugged_size, end_addr; /* the plugged_size is just a reflection of what _we_ did previously */ virtio_cread_le(vm->vdev, struct virtio_mem_config, plugged_size, &new_plugged_size); if (WARN_ON_ONCE(new_plugged_size != vm->plugged_size)) vm->plugged_size = new_plugged_size; /* calculate the last usable memory block id */ virtio_cread_le(vm->vdev, struct virtio_mem_config, usable_region_size, &vm->usable_region_size); end_addr = min(vm->addr + vm->usable_region_size - 1, pluggable_range.end); if (vm->in_sbm) { vm->sbm.last_usable_mb_id = virtio_mem_phys_to_mb_id(end_addr); if (!IS_ALIGNED(end_addr + 1, memory_block_size_bytes())) vm->sbm.last_usable_mb_id--; } else { vm->bbm.last_usable_bb_id = virtio_mem_phys_to_bb_id(vm, end_addr); if (!IS_ALIGNED(end_addr + 1, vm->bbm.bb_size)) vm->bbm.last_usable_bb_id--; } /* * If we cannot plug any of our device memory (e.g., nothing in the * usable region is addressable), the last usable memory block id will * be smaller than the first usable memory block id. We'll stop * attempting to add memory with -ENOSPC from our main loop. */ /* see if there is a request to change the size */ virtio_cread_le(vm->vdev, struct virtio_mem_config, requested_size, &vm->requested_size); dev_info(&vm->vdev->dev, "plugged size: 0x%llx", vm->plugged_size); dev_info(&vm->vdev->dev, "requested size: 0x%llx", vm->requested_size); } /* * Workqueue function for handling plug/unplug requests and config updates. */ static void virtio_mem_run_wq(struct work_struct *work) { struct virtio_mem *vm = container_of(work, struct virtio_mem, wq); uint64_t diff; int rc; if (unlikely(vm->in_kdump)) { dev_warn_once(&vm->vdev->dev, "unexpected workqueue run in kdump kernel\n"); return; } hrtimer_cancel(&vm->retry_timer); if (vm->broken) return; atomic_set(&vm->wq_active, 1); retry: rc = 0; /* Make sure we start with a clean state if there are leftovers. */ if (unlikely(vm->unplug_all_required)) rc = virtio_mem_send_unplug_all_request(vm); if (atomic_read(&vm->config_changed)) { atomic_set(&vm->config_changed, 0); virtio_mem_refresh_config(vm); } /* Cleanup any leftovers from previous runs */ if (!rc) rc = virtio_mem_cleanup_pending_mb(vm); if (!rc && vm->requested_size != vm->plugged_size) { if (vm->requested_size > vm->plugged_size) { diff = vm->requested_size - vm->plugged_size; rc = virtio_mem_plug_request(vm, diff); } else { diff = vm->plugged_size - vm->requested_size; rc = virtio_mem_unplug_request(vm, diff); } } /* * Keep retrying to offline and remove completely unplugged Linux * memory blocks. */ if (!rc && vm->in_sbm && vm->sbm.have_unplugged_mb) rc = -EBUSY; switch (rc) { case 0: vm->retry_timer_ms = VIRTIO_MEM_RETRY_TIMER_MIN_MS; break; case -ENOSPC: /* * We cannot add any more memory (alignment, physical limit) * or we have too many offline memory blocks. */ break; case -ETXTBSY: /* * The hypervisor cannot process our request right now * (e.g., out of memory, migrating); */ case -EBUSY: /* * We cannot free up any memory to unplug it (all plugged memory * is busy). */ case -ENOMEM: /* Out of memory, try again later. */ hrtimer_start(&vm->retry_timer, ms_to_ktime(vm->retry_timer_ms), HRTIMER_MODE_REL); break; case -EAGAIN: /* Retry immediately (e.g., the config changed). */ goto retry; default: /* Unknown error, mark as broken */ dev_err(&vm->vdev->dev, "unknown error, marking device broken: %d\n", rc); vm->broken = true; } atomic_set(&vm->wq_active, 0); } static enum hrtimer_restart virtio_mem_timer_expired(struct hrtimer *timer) { struct virtio_mem *vm = container_of(timer, struct virtio_mem, retry_timer); virtio_mem_retry(vm); vm->retry_timer_ms = min_t(unsigned int, vm->retry_timer_ms * 2, VIRTIO_MEM_RETRY_TIMER_MAX_MS); return HRTIMER_NORESTART; } static void virtio_mem_handle_response(struct virtqueue *vq) { struct virtio_mem *vm = vq->vdev->priv; wake_up(&vm->host_resp); } static int virtio_mem_init_vq(struct virtio_mem *vm) { struct virtqueue *vq; vq = virtio_find_single_vq(vm->vdev, virtio_mem_handle_response, "guest-request"); if (IS_ERR(vq)) return PTR_ERR(vq); vm->vq = vq; return 0; } static int virtio_mem_init_hotplug(struct virtio_mem *vm) { const struct range pluggable_range = mhp_get_pluggable_range(true); uint64_t unit_pages, sb_size, addr; int rc; /* bad device setup - warn only */ if (!IS_ALIGNED(vm->addr, memory_block_size_bytes())) dev_warn(&vm->vdev->dev, "The alignment of the physical start address can make some memory unusable.\n"); if (!IS_ALIGNED(vm->addr + vm->region_size, memory_block_size_bytes())) dev_warn(&vm->vdev->dev, "The alignment of the physical end address can make some memory unusable.\n"); if (vm->addr < pluggable_range.start || vm->addr + vm->region_size - 1 > pluggable_range.end) dev_warn(&vm->vdev->dev, "Some device memory is not addressable/pluggable. This can make some memory unusable.\n"); /* Prepare the offline threshold - make sure we can add two blocks. */ vm->offline_threshold = max_t(uint64_t, 2 * memory_block_size_bytes(), VIRTIO_MEM_DEFAULT_OFFLINE_THRESHOLD); /* * alloc_contig_range() works reliably with pageblock * granularity on ZONE_NORMAL, use pageblock_nr_pages. */ sb_size = PAGE_SIZE * pageblock_nr_pages; sb_size = max_t(uint64_t, vm->device_block_size, sb_size); if (sb_size < memory_block_size_bytes() && !force_bbm) { /* SBM: At least two subblocks per Linux memory block. */ vm->in_sbm = true; vm->sbm.sb_size = sb_size; vm->sbm.sbs_per_mb = memory_block_size_bytes() / vm->sbm.sb_size; /* Round up to the next full memory block */ addr = max_t(uint64_t, vm->addr, pluggable_range.start) + memory_block_size_bytes() - 1; vm->sbm.first_mb_id = virtio_mem_phys_to_mb_id(addr); vm->sbm.next_mb_id = vm->sbm.first_mb_id; } else { /* BBM: At least one Linux memory block. */ vm->bbm.bb_size = max_t(uint64_t, vm->device_block_size, memory_block_size_bytes()); if (bbm_block_size) { if (!is_power_of_2(bbm_block_size)) { dev_warn(&vm->vdev->dev, "bbm_block_size is not a power of 2"); } else if (bbm_block_size < vm->bbm.bb_size) { dev_warn(&vm->vdev->dev, "bbm_block_size is too small"); } else { vm->bbm.bb_size = bbm_block_size; } } /* Round up to the next aligned big block */ addr = max_t(uint64_t, vm->addr, pluggable_range.start) + vm->bbm.bb_size - 1; vm->bbm.first_bb_id = virtio_mem_phys_to_bb_id(vm, addr); vm->bbm.next_bb_id = vm->bbm.first_bb_id; /* Make sure we can add two big blocks. */ vm->offline_threshold = max_t(uint64_t, 2 * vm->bbm.bb_size, vm->offline_threshold); } dev_info(&vm->vdev->dev, "memory block size: 0x%lx", memory_block_size_bytes()); if (vm->in_sbm) dev_info(&vm->vdev->dev, "subblock size: 0x%llx", (unsigned long long)vm->sbm.sb_size); else dev_info(&vm->vdev->dev, "big block size: 0x%llx", (unsigned long long)vm->bbm.bb_size); /* create the parent resource for all memory */ rc = virtio_mem_create_resource(vm); if (rc) return rc; /* use a single dynamic memory group to cover the whole memory device */ if (vm->in_sbm) unit_pages = PHYS_PFN(memory_block_size_bytes()); else unit_pages = PHYS_PFN(vm->bbm.bb_size); rc = memory_group_register_dynamic(vm->nid, unit_pages); if (rc < 0) goto out_del_resource; vm->mgid = rc; /* * If we still have memory plugged, we have to unplug all memory first. * Registering our parent resource makes sure that this memory isn't * actually in use (e.g., trying to reload the driver). */ if (vm->plugged_size) { vm->unplug_all_required = true; dev_info(&vm->vdev->dev, "unplugging all memory is required\n"); } /* register callbacks */ vm->memory_notifier.notifier_call = virtio_mem_memory_notifier_cb; rc = register_memory_notifier(&vm->memory_notifier); if (rc) goto out_unreg_group; /* Block hibernation as early as possible. */ vm->pm_notifier.priority = INT_MAX; vm->pm_notifier.notifier_call = virtio_mem_pm_notifier_cb; rc = register_pm_notifier(&vm->pm_notifier); if (rc) goto out_unreg_mem; rc = register_virtio_mem_device(vm); if (rc) goto out_unreg_pm; virtio_device_ready(vm->vdev); return 0; out_unreg_pm: unregister_pm_notifier(&vm->pm_notifier); out_unreg_mem: unregister_memory_notifier(&vm->memory_notifier); out_unreg_group: memory_group_unregister(vm->mgid); out_del_resource: virtio_mem_delete_resource(vm); return rc; } #ifdef CONFIG_PROC_VMCORE static int virtio_mem_send_state_request(struct virtio_mem *vm, uint64_t addr, uint64_t size) { const uint64_t nb_vm_blocks = size / vm->device_block_size; const struct virtio_mem_req req = { .type = cpu_to_virtio16(vm->vdev, VIRTIO_MEM_REQ_STATE), .u.state.addr = cpu_to_virtio64(vm->vdev, addr), .u.state.nb_blocks = cpu_to_virtio16(vm->vdev, nb_vm_blocks), }; int rc = -ENOMEM; dev_dbg(&vm->vdev->dev, "requesting state: 0x%llx - 0x%llx\n", addr, addr + size - 1); switch (virtio_mem_send_request(vm, &req)) { case VIRTIO_MEM_RESP_ACK: return virtio16_to_cpu(vm->vdev, vm->resp.u.state.state); case VIRTIO_MEM_RESP_ERROR: rc = -EINVAL; break; default: break; } dev_dbg(&vm->vdev->dev, "requesting state failed: %d\n", rc); return rc; } static bool virtio_mem_vmcore_pfn_is_ram(struct vmcore_cb *cb, unsigned long pfn) { struct virtio_mem *vm = container_of(cb, struct virtio_mem, vmcore_cb); uint64_t addr = PFN_PHYS(pfn); bool is_ram; int rc; if (!virtio_mem_contains_range(vm, addr, PAGE_SIZE)) return true; if (!vm->plugged_size) return false; /* * We have to serialize device requests and access to the information * about the block queried last. */ mutex_lock(&vm->hotplug_mutex); addr = ALIGN_DOWN(addr, vm->device_block_size); if (addr != vm->last_block_addr) { rc = virtio_mem_send_state_request(vm, addr, vm->device_block_size); /* On any kind of error, we're going to signal !ram. */ if (rc == VIRTIO_MEM_STATE_PLUGGED) vm->last_block_plugged = true; else vm->last_block_plugged = false; vm->last_block_addr = addr; } is_ram = vm->last_block_plugged; mutex_unlock(&vm->hotplug_mutex); return is_ram; } #ifdef CONFIG_PROC_VMCORE_DEVICE_RAM static int virtio_mem_vmcore_add_device_ram(struct virtio_mem *vm, struct list_head *list, uint64_t start, uint64_t end) { int rc; rc = vmcore_alloc_add_range(list, start, end - start); if (rc) dev_err(&vm->vdev->dev, "Error adding device RAM range: %d\n", rc); return rc; } static int virtio_mem_vmcore_get_device_ram(struct vmcore_cb *cb, struct list_head *list) { struct virtio_mem *vm = container_of(cb, struct virtio_mem, vmcore_cb); const uint64_t device_start = vm->addr; const uint64_t device_end = vm->addr + vm->usable_region_size; uint64_t chunk_size, cur_start, cur_end, plugged_range_start = 0; LIST_HEAD(tmp_list); int rc; if (!vm->plugged_size) return 0; /* Process memory sections, unless the device block size is bigger. */ chunk_size = max_t(uint64_t, PFN_PHYS(PAGES_PER_SECTION), vm->device_block_size); mutex_lock(&vm->hotplug_mutex); /* * We process larger chunks and indicate the complete chunk if any * block in there is plugged. This reduces the number of pfn_is_ram() * callbacks and mimic what is effectively being done when the old * kernel would add complete memory sections/blocks to the elfcore hdr. */ cur_start = device_start; for (cur_start = device_start; cur_start < device_end; cur_start = cur_end) { cur_end = ALIGN_DOWN(cur_start + chunk_size, chunk_size); cur_end = min_t(uint64_t, cur_end, device_end); rc = virtio_mem_send_state_request(vm, cur_start, cur_end - cur_start); if (rc < 0) { dev_err(&vm->vdev->dev, "Error querying block states: %d\n", rc); goto out; } else if (rc != VIRTIO_MEM_STATE_UNPLUGGED) { /* Merge ranges with plugged memory. */ if (!plugged_range_start) plugged_range_start = cur_start; continue; } /* Flush any plugged range. */ if (plugged_range_start) { rc = virtio_mem_vmcore_add_device_ram(vm, &tmp_list, plugged_range_start, cur_start); if (rc) goto out; plugged_range_start = 0; } } /* Flush any plugged range. */ if (plugged_range_start) rc = virtio_mem_vmcore_add_device_ram(vm, &tmp_list, plugged_range_start, cur_start); out: mutex_unlock(&vm->hotplug_mutex); if (rc < 0) { vmcore_free_ranges(&tmp_list); return rc; } list_splice_tail(&tmp_list, list); return 0; } #endif /* CONFIG_PROC_VMCORE_DEVICE_RAM */ #endif /* CONFIG_PROC_VMCORE */ static int virtio_mem_init_kdump(struct virtio_mem *vm) { /* We must be prepared to receive a callback immediately. */ virtio_device_ready(vm->vdev); #ifdef CONFIG_PROC_VMCORE dev_info(&vm->vdev->dev, "memory hot(un)plug disabled in kdump kernel\n"); vm->vmcore_cb.pfn_is_ram = virtio_mem_vmcore_pfn_is_ram; #ifdef CONFIG_PROC_VMCORE_DEVICE_RAM vm->vmcore_cb.get_device_ram = virtio_mem_vmcore_get_device_ram; #endif /* CONFIG_PROC_VMCORE_DEVICE_RAM */ register_vmcore_cb(&vm->vmcore_cb); return 0; #else /* CONFIG_PROC_VMCORE */ dev_warn(&vm->vdev->dev, "disabled in kdump kernel without vmcore\n"); return -EBUSY; #endif /* CONFIG_PROC_VMCORE */ } static int virtio_mem_init(struct virtio_mem *vm) { uint16_t node_id; if (!vm->vdev->config->get) { dev_err(&vm->vdev->dev, "config access disabled\n"); return -EINVAL; } /* Fetch all properties that can't change. */ virtio_cread_le(vm->vdev, struct virtio_mem_config, plugged_size, &vm->plugged_size); virtio_cread_le(vm->vdev, struct virtio_mem_config, block_size, &vm->device_block_size); virtio_cread_le(vm->vdev, struct virtio_mem_config, node_id, &node_id); vm->nid = virtio_mem_translate_node_id(vm, node_id); virtio_cread_le(vm->vdev, struct virtio_mem_config, addr, &vm->addr); virtio_cread_le(vm->vdev, struct virtio_mem_config, region_size, &vm->region_size); virtio_cread_le(vm->vdev, struct virtio_mem_config, usable_region_size, &vm->usable_region_size); /* Determine the nid for the device based on the lowest address. */ if (vm->nid == NUMA_NO_NODE) vm->nid = memory_add_physaddr_to_nid(vm->addr); dev_info(&vm->vdev->dev, "start address: 0x%llx", vm->addr); dev_info(&vm->vdev->dev, "region size: 0x%llx", vm->region_size); dev_info(&vm->vdev->dev, "device block size: 0x%llx", (unsigned long long)vm->device_block_size); if (vm->nid != NUMA_NO_NODE && IS_ENABLED(CONFIG_NUMA)) dev_info(&vm->vdev->dev, "nid: %d", vm->nid); /* * We don't want to (un)plug or reuse any memory when in kdump. The * memory is still accessible (but not exposed to Linux). */ if (vm->in_kdump) return virtio_mem_init_kdump(vm); return virtio_mem_init_hotplug(vm); } static int virtio_mem_create_resource(struct virtio_mem *vm) { /* * When force-unloading the driver and removing the device, we * could have a garbage pointer. Duplicate the string. */ const char *name = kstrdup(dev_name(&vm->vdev->dev), GFP_KERNEL); if (!name) return -ENOMEM; /* Disallow mapping device memory via /dev/mem completely. */ vm->parent_resource = __request_mem_region(vm->addr, vm->region_size, name, IORESOURCE_SYSTEM_RAM | IORESOURCE_EXCLUSIVE); if (!vm->parent_resource) { kfree(name); dev_warn(&vm->vdev->dev, "could not reserve device region\n"); dev_info(&vm->vdev->dev, "reloading the driver is not supported\n"); return -EBUSY; } /* The memory is not actually busy - make add_memory() work. */ vm->parent_resource->flags &= ~IORESOURCE_BUSY; return 0; } static void virtio_mem_delete_resource(struct virtio_mem *vm) { const char *name; if (!vm->parent_resource) return; name = vm->parent_resource->name; release_resource(vm->parent_resource); kfree(vm->parent_resource); kfree(name); vm->parent_resource = NULL; } static int virtio_mem_range_has_system_ram(struct resource *res, void *arg) { return 1; } static bool virtio_mem_has_memory_added(struct virtio_mem *vm) { const unsigned long flags = IORESOURCE_SYSTEM_RAM | IORESOURCE_BUSY; return walk_iomem_res_desc(IORES_DESC_NONE, flags, vm->addr, vm->addr + vm->region_size, NULL, virtio_mem_range_has_system_ram) == 1; } static int virtio_mem_probe(struct virtio_device *vdev) { struct virtio_mem *vm; int rc; BUILD_BUG_ON(sizeof(struct virtio_mem_req) != 24); BUILD_BUG_ON(sizeof(struct virtio_mem_resp) != 10); vdev->priv = vm = kzalloc(sizeof(*vm), GFP_KERNEL); if (!vm) return -ENOMEM; init_waitqueue_head(&vm->host_resp); vm->vdev = vdev; INIT_WORK(&vm->wq, virtio_mem_run_wq); mutex_init(&vm->hotplug_mutex); INIT_LIST_HEAD(&vm->next); spin_lock_init(&vm->removal_lock); hrtimer_init(&vm->retry_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL); vm->retry_timer.function = virtio_mem_timer_expired; vm->retry_timer_ms = VIRTIO_MEM_RETRY_TIMER_MIN_MS; vm->in_kdump = is_kdump_kernel(); /* register the virtqueue */ rc = virtio_mem_init_vq(vm); if (rc) goto out_free_vm; /* initialize the device by querying the config */ rc = virtio_mem_init(vm); if (rc) goto out_del_vq; /* trigger a config update to start processing the requested_size */ if (!vm->in_kdump) { atomic_set(&vm->config_changed, 1); queue_work(system_freezable_wq, &vm->wq); } return 0; out_del_vq: vdev->config->del_vqs(vdev); out_free_vm: kfree(vm); vdev->priv = NULL; return rc; } static void virtio_mem_deinit_hotplug(struct virtio_mem *vm) { unsigned long mb_id; int rc; /* * Make sure the workqueue won't be triggered anymore and no memory * blocks can be onlined/offlined until we're finished here. */ mutex_lock(&vm->hotplug_mutex); spin_lock_irq(&vm->removal_lock); vm->removing = true; spin_unlock_irq(&vm->removal_lock); mutex_unlock(&vm->hotplug_mutex); /* wait until the workqueue stopped */ cancel_work_sync(&vm->wq); hrtimer_cancel(&vm->retry_timer); if (vm->in_sbm) { /* * After we unregistered our callbacks, user space can online * partially plugged offline blocks. Make sure to remove them. */ virtio_mem_sbm_for_each_mb(vm, mb_id, VIRTIO_MEM_SBM_MB_OFFLINE_PARTIAL) { rc = virtio_mem_sbm_remove_mb(vm, mb_id); BUG_ON(rc); virtio_mem_sbm_set_mb_state(vm, mb_id, VIRTIO_MEM_SBM_MB_UNUSED); } /* * After we unregistered our callbacks, user space can no longer * offline partially plugged online memory blocks. No need to * worry about them. */ } /* unregister callbacks */ unregister_virtio_mem_device(vm); unregister_pm_notifier(&vm->pm_notifier); unregister_memory_notifier(&vm->memory_notifier); /* * There is no way we could reliably remove all memory we have added to * the system. And there is no way to stop the driver/device from going * away. Warn at least. */ if (virtio_mem_has_memory_added(vm)) { dev_warn(&vm->vdev->dev, "device still has system memory added\n"); } else { virtio_mem_delete_resource(vm); kfree_const(vm->resource_name); memory_group_unregister(vm->mgid); } /* remove all tracking data - no locking needed */ if (vm->in_sbm) { vfree(vm->sbm.mb_states); vfree(vm->sbm.sb_states); } else { vfree(vm->bbm.bb_states); } } static void virtio_mem_deinit_kdump(struct virtio_mem *vm) { #ifdef CONFIG_PROC_VMCORE unregister_vmcore_cb(&vm->vmcore_cb); #endif /* CONFIG_PROC_VMCORE */ } static void virtio_mem_remove(struct virtio_device *vdev) { struct virtio_mem *vm = vdev->priv; if (vm->in_kdump) virtio_mem_deinit_kdump(vm); else virtio_mem_deinit_hotplug(vm); /* reset the device and cleanup the queues */ virtio_reset_device(vdev); vdev->config->del_vqs(vdev); kfree(vm); vdev->priv = NULL; } static void virtio_mem_config_changed(struct virtio_device *vdev) { struct virtio_mem *vm = vdev->priv; if (unlikely(vm->in_kdump)) return; atomic_set(&vm->config_changed, 1); virtio_mem_retry(vm); } #ifdef CONFIG_PM_SLEEP static int virtio_mem_freeze(struct virtio_device *vdev) { struct virtio_mem *vm = vdev->priv; /* * We block hibernation using the PM notifier completely. The workqueue * is already frozen by the PM core at this point, so we simply * reset the device and cleanup the queues. */ if (pm_suspend_target_state != PM_SUSPEND_TO_IDLE && vm->plugged_size && !virtio_has_feature(vm->vdev, VIRTIO_MEM_F_PERSISTENT_SUSPEND)) { dev_err(&vm->vdev->dev, "suspending with plugged memory is not supported\n"); return -EPERM; } virtio_reset_device(vdev); vdev->config->del_vqs(vdev); vm->vq = NULL; return 0; } static int virtio_mem_restore(struct virtio_device *vdev) { struct virtio_mem *vm = vdev->priv; int ret; ret = virtio_mem_init_vq(vm); if (ret) return ret; virtio_device_ready(vdev); /* Let's check if anything changed. */ virtio_mem_config_changed(vdev); return 0; } #endif static unsigned int virtio_mem_features[] = { #if defined(CONFIG_NUMA) && defined(CONFIG_ACPI_NUMA) VIRTIO_MEM_F_ACPI_PXM, #endif VIRTIO_MEM_F_UNPLUGGED_INACCESSIBLE, VIRTIO_MEM_F_PERSISTENT_SUSPEND, }; static const struct virtio_device_id virtio_mem_id_table[] = { { VIRTIO_ID_MEM, VIRTIO_DEV_ANY_ID }, { 0 }, }; static struct virtio_driver virtio_mem_driver = { .feature_table = virtio_mem_features, .feature_table_size = ARRAY_SIZE(virtio_mem_features), .driver.name = KBUILD_MODNAME, .id_table = virtio_mem_id_table, .probe = virtio_mem_probe, .remove = virtio_mem_remove, .config_changed = virtio_mem_config_changed, #ifdef CONFIG_PM_SLEEP .freeze = virtio_mem_freeze, .restore = virtio_mem_restore, #endif }; module_virtio_driver(virtio_mem_driver); MODULE_DEVICE_TABLE(virtio, virtio_mem_id_table); MODULE_AUTHOR("David Hildenbrand "); MODULE_DESCRIPTION("Virtio-mem driver"); MODULE_LICENSE("GPL");