// SPDX-License-Identifier: GPL-2.0 /* * VMware Balloon driver. * * Copyright (C) 2000-2018, VMware, Inc. All Rights Reserved. * * This is VMware physical memory management driver for Linux. The driver * acts like a "balloon" that can be inflated to reclaim physical pages by * reserving them in the guest and invalidating them in the monitor, * freeing up the underlying machine pages so they can be allocated to * other guests. The balloon can also be deflated to allow the guest to * use more physical memory. Higher level policies can control the sizes * of balloons in VMs in order to manage physical memory resources. */ //#define DEBUG #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include #include #include #include #include #include #include #include #include #include #include #include MODULE_AUTHOR("VMware, Inc."); MODULE_DESCRIPTION("VMware Memory Control (Balloon) Driver"); MODULE_VERSION("1.5.0.0-k"); MODULE_ALIAS("dmi:*:svnVMware*:*"); MODULE_ALIAS("vmware_vmmemctl"); MODULE_LICENSE("GPL"); /* * Use __GFP_HIGHMEM to allow pages from HIGHMEM zone. We don't * allow wait (__GFP_RECLAIM) for NOSLEEP page allocations. Use * __GFP_NOWARN, to suppress page allocation failure warnings. */ #define VMW_PAGE_ALLOC_NOSLEEP (__GFP_HIGHMEM|__GFP_NOWARN) /* * Use GFP_HIGHUSER when executing in a separate kernel thread * context and allocation can sleep. This is less stressful to * the guest memory system, since it allows the thread to block * while memory is reclaimed, and won't take pages from emergency * low-memory pools. */ #define VMW_PAGE_ALLOC_CANSLEEP (GFP_HIGHUSER) /* Maximum number of refused pages we accumulate during inflation cycle */ #define VMW_BALLOON_MAX_REFUSED 16 /* * Hypervisor communication port definitions. */ #define VMW_BALLOON_HV_PORT 0x5670 #define VMW_BALLOON_HV_MAGIC 0x456c6d6f #define VMW_BALLOON_GUEST_ID 1 /* Linux */ enum vmwballoon_capabilities { /* * Bit 0 is reserved and not associated to any capability. */ VMW_BALLOON_BASIC_CMDS = (1 << 1), VMW_BALLOON_BATCHED_CMDS = (1 << 2), VMW_BALLOON_BATCHED_2M_CMDS = (1 << 3), VMW_BALLOON_SIGNALLED_WAKEUP_CMD = (1 << 4), }; #define VMW_BALLOON_CAPABILITIES (VMW_BALLOON_BASIC_CMDS \ | VMW_BALLOON_BATCHED_CMDS \ | VMW_BALLOON_BATCHED_2M_CMDS \ | VMW_BALLOON_SIGNALLED_WAKEUP_CMD) #define VMW_BALLOON_2M_SHIFT (9) #define VMW_BALLOON_NUM_PAGE_SIZES (2) /* * Backdoor commands availability: * * START, GET_TARGET and GUEST_ID are always available, * * VMW_BALLOON_BASIC_CMDS: * LOCK and UNLOCK commands, * VMW_BALLOON_BATCHED_CMDS: * BATCHED_LOCK and BATCHED_UNLOCK commands. * VMW BALLOON_BATCHED_2M_CMDS: * BATCHED_2M_LOCK and BATCHED_2M_UNLOCK commands, * VMW VMW_BALLOON_SIGNALLED_WAKEUP_CMD: * VMW_BALLOON_CMD_VMCI_DOORBELL_SET command. */ #define VMW_BALLOON_CMD_START 0 #define VMW_BALLOON_CMD_GET_TARGET 1 #define VMW_BALLOON_CMD_LOCK 2 #define VMW_BALLOON_CMD_UNLOCK 3 #define VMW_BALLOON_CMD_GUEST_ID 4 #define VMW_BALLOON_CMD_BATCHED_LOCK 6 #define VMW_BALLOON_CMD_BATCHED_UNLOCK 7 #define VMW_BALLOON_CMD_BATCHED_2M_LOCK 8 #define VMW_BALLOON_CMD_BATCHED_2M_UNLOCK 9 #define VMW_BALLOON_CMD_VMCI_DOORBELL_SET 10 #define VMW_BALLOON_CMD_NUM 11 /* error codes */ #define VMW_BALLOON_SUCCESS 0 #define VMW_BALLOON_FAILURE -1 #define VMW_BALLOON_ERROR_CMD_INVALID 1 #define VMW_BALLOON_ERROR_PPN_INVALID 2 #define VMW_BALLOON_ERROR_PPN_LOCKED 3 #define VMW_BALLOON_ERROR_PPN_UNLOCKED 4 #define VMW_BALLOON_ERROR_PPN_PINNED 5 #define VMW_BALLOON_ERROR_PPN_NOTNEEDED 6 #define VMW_BALLOON_ERROR_RESET 7 #define VMW_BALLOON_ERROR_BUSY 8 #define VMW_BALLOON_SUCCESS_WITH_CAPABILITIES (0x03000000) /* Batch page description */ /* * Layout of a page in the batch page: * * +-------------+----------+--------+ * | | | | * | Page number | Reserved | Status | * | | | | * +-------------+----------+--------+ * 64 PAGE_SHIFT 6 0 * * The reserved field should be set to 0. */ #define VMW_BALLOON_BATCH_MAX_PAGES (PAGE_SIZE / sizeof(u64)) #define VMW_BALLOON_BATCH_STATUS_MASK ((1UL << 5) - 1) #define VMW_BALLOON_BATCH_PAGE_MASK (~((1UL << PAGE_SHIFT) - 1)) #define VMW_BALLOON_CMD_WITH_TARGET_MASK \ ((1UL << VMW_BALLOON_CMD_GET_TARGET) | \ (1UL << VMW_BALLOON_CMD_LOCK) | \ (1UL << VMW_BALLOON_CMD_UNLOCK) | \ (1UL << VMW_BALLOON_CMD_BATCHED_LOCK) | \ (1UL << VMW_BALLOON_CMD_BATCHED_UNLOCK) | \ (1UL << VMW_BALLOON_CMD_BATCHED_2M_LOCK) | \ (1UL << VMW_BALLOON_CMD_BATCHED_2M_UNLOCK)) static const char * const vmballoon_cmd_names[] = { [VMW_BALLOON_CMD_START] = "start", [VMW_BALLOON_CMD_GET_TARGET] = "target", [VMW_BALLOON_CMD_LOCK] = "lock", [VMW_BALLOON_CMD_UNLOCK] = "unlock", [VMW_BALLOON_CMD_GUEST_ID] = "guestType", [VMW_BALLOON_CMD_BATCHED_LOCK] = "batchLock", [VMW_BALLOON_CMD_BATCHED_UNLOCK] = "batchUnlock", [VMW_BALLOON_CMD_BATCHED_2M_LOCK] = "2m-lock", [VMW_BALLOON_CMD_BATCHED_2M_UNLOCK] = "2m-unlock", [VMW_BALLOON_CMD_VMCI_DOORBELL_SET] = "doorbellSet" }; struct vmballoon_batch_page { u64 pages[VMW_BALLOON_BATCH_MAX_PAGES]; }; static u64 vmballoon_batch_get_pa(struct vmballoon_batch_page *batch, int idx) { return batch->pages[idx] & VMW_BALLOON_BATCH_PAGE_MASK; } static int vmballoon_batch_get_status(struct vmballoon_batch_page *batch, int idx) { return (int)(batch->pages[idx] & VMW_BALLOON_BATCH_STATUS_MASK); } static void vmballoon_batch_set_pa(struct vmballoon_batch_page *batch, int idx, u64 pa) { batch->pages[idx] = pa; } #ifdef CONFIG_DEBUG_FS struct vmballoon_stats { unsigned int timer; unsigned int doorbell; /* allocation statistics */ unsigned int alloc[VMW_BALLOON_NUM_PAGE_SIZES]; unsigned int alloc_fail[VMW_BALLOON_NUM_PAGE_SIZES]; unsigned int sleep_alloc; unsigned int sleep_alloc_fail; unsigned int refused_alloc[VMW_BALLOON_NUM_PAGE_SIZES]; unsigned int refused_free[VMW_BALLOON_NUM_PAGE_SIZES]; unsigned int free[VMW_BALLOON_NUM_PAGE_SIZES]; /* Monitor operations. */ unsigned long ops[VMW_BALLOON_CMD_NUM]; unsigned long ops_fail[VMW_BALLOON_CMD_NUM]; }; #define STATS_INC(stat) (stat)++ #else #define STATS_INC(stat) #endif struct vmballoon; struct vmballoon_ops { void (*add_page)(struct vmballoon *b, int idx, struct page *p); int (*lock)(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages); int (*unlock)(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages); }; struct vmballoon_page_size { /* list of reserved physical pages */ struct list_head pages; /* transient list of non-balloonable pages */ struct list_head refused_pages; unsigned int n_refused_pages; }; struct vmballoon { struct vmballoon_page_size page_sizes[VMW_BALLOON_NUM_PAGE_SIZES]; /* supported page sizes. 1 == 4k pages only, 2 == 4k and 2m pages */ unsigned supported_page_sizes; /* balloon size in pages */ unsigned int size; unsigned int target; /* reset flag */ bool reset_required; unsigned long capabilities; struct vmballoon_batch_page *batch_page; unsigned int batch_max_pages; struct page *page; const struct vmballoon_ops *ops; #ifdef CONFIG_DEBUG_FS /* statistics */ struct vmballoon_stats stats; /* debugfs file exporting statistics */ struct dentry *dbg_entry; #endif struct sysinfo sysinfo; struct delayed_work dwork; struct vmci_handle vmci_doorbell; }; static struct vmballoon balloon; static inline unsigned long __vmballoon_cmd(struct vmballoon *b, unsigned long cmd, unsigned long arg1, unsigned long arg2, unsigned long *result) { unsigned long status, dummy1, dummy2, dummy3, local_result; STATS_INC(b->stats.ops[cmd]); asm volatile ("inl %%dx" : "=a"(status), "=c"(dummy1), "=d"(dummy2), "=b"(local_result), "=S"(dummy3) : "0"(VMW_BALLOON_HV_MAGIC), "1"(cmd), "2"(VMW_BALLOON_HV_PORT), "3"(arg1), "4"(arg2) : "memory"); /* update the result if needed */ if (result) *result = (cmd == VMW_BALLOON_CMD_START) ? dummy1 : local_result; /* update target when applicable */ if (status == VMW_BALLOON_SUCCESS && ((1ul << cmd) & VMW_BALLOON_CMD_WITH_TARGET_MASK)) b->target = local_result; if (status != VMW_BALLOON_SUCCESS && status != VMW_BALLOON_SUCCESS_WITH_CAPABILITIES) { STATS_INC(b->stats.ops_fail[cmd]); pr_debug("%s: %s [0x%lx,0x%lx) failed, returned %ld\n", __func__, vmballoon_cmd_names[cmd], arg1, arg2, status); } /* mark reset required accordingly */ if (status == VMW_BALLOON_ERROR_RESET) b->reset_required = true; return status; } static __always_inline unsigned long vmballoon_cmd(struct vmballoon *b, unsigned long cmd, unsigned long arg1, unsigned long arg2) { unsigned long dummy; return __vmballoon_cmd(b, cmd, arg1, arg2, &dummy); } /* * Send "start" command to the host, communicating supported version * of the protocol. */ static bool vmballoon_send_start(struct vmballoon *b, unsigned long req_caps) { unsigned long status, capabilities; bool success; status = __vmballoon_cmd(b, VMW_BALLOON_CMD_START, req_caps, 0, &capabilities); switch (status) { case VMW_BALLOON_SUCCESS_WITH_CAPABILITIES: b->capabilities = capabilities; success = true; break; case VMW_BALLOON_SUCCESS: b->capabilities = VMW_BALLOON_BASIC_CMDS; success = true; break; default: success = false; } /* * 2MB pages are only supported with batching. If batching is for some * reason disabled, do not use 2MB pages, since otherwise the legacy * mechanism is used with 2MB pages, causing a failure. */ if ((b->capabilities & VMW_BALLOON_BATCHED_2M_CMDS) && (b->capabilities & VMW_BALLOON_BATCHED_CMDS)) b->supported_page_sizes = 2; else b->supported_page_sizes = 1; return success; } /* * Communicate guest type to the host so that it can adjust ballooning * algorithm to the one most appropriate for the guest. This command * is normally issued after sending "start" command and is part of * standard reset sequence. */ static bool vmballoon_send_guest_id(struct vmballoon *b) { unsigned long status; status = vmballoon_cmd(b, VMW_BALLOON_CMD_GUEST_ID, VMW_BALLOON_GUEST_ID, 0); if (status == VMW_BALLOON_SUCCESS) return true; return false; } static u16 vmballoon_page_size(bool is_2m_page) { if (is_2m_page) return 1 << VMW_BALLOON_2M_SHIFT; return 1; } /* * Retrieve desired balloon size from the host. */ static bool vmballoon_send_get_target(struct vmballoon *b) { unsigned long status; unsigned long limit; u32 limit32; /* * si_meminfo() is cheap. Moreover, we want to provide dynamic * max balloon size later. So let us call si_meminfo() every * iteration. */ si_meminfo(&b->sysinfo); limit = b->sysinfo.totalram; /* Ensure limit fits in 32-bits */ limit32 = (u32)limit; if (limit != limit32) return false; status = vmballoon_cmd(b, VMW_BALLOON_CMD_GET_TARGET, limit, 0); if (status == VMW_BALLOON_SUCCESS) return true; return false; } /* * Notify the host about allocated page so that host can use it without * fear that guest will need it. Host may reject some pages, we need to * check the return value and maybe submit a different page. */ static int vmballoon_send_lock_page(struct vmballoon *b, unsigned long pfn, unsigned int *hv_status) { unsigned long status; u32 pfn32; pfn32 = (u32)pfn; if (pfn32 != pfn) return -EINVAL; *hv_status = status = vmballoon_cmd(b, VMW_BALLOON_CMD_LOCK, pfn, 0); if (status == VMW_BALLOON_SUCCESS) return 0; return -EIO; } static int vmballoon_send_batched_lock(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages) { unsigned long pfn = PHYS_PFN(virt_to_phys(b->batch_page)); unsigned long status, cmd; cmd = is_2m_pages ? VMW_BALLOON_CMD_BATCHED_2M_LOCK : VMW_BALLOON_CMD_BATCHED_LOCK; status = vmballoon_cmd(b, cmd, pfn, num_pages); if (status == VMW_BALLOON_SUCCESS) return 0; return 1; } /* * Notify the host that guest intends to release given page back into * the pool of available (to the guest) pages. */ static bool vmballoon_send_unlock_page(struct vmballoon *b, unsigned long pfn) { unsigned long status; u32 pfn32; pfn32 = (u32)pfn; if (pfn32 != pfn) return false; status = vmballoon_cmd(b, VMW_BALLOON_CMD_UNLOCK, pfn, 0); return status == VMW_BALLOON_SUCCESS; } static bool vmballoon_send_batched_unlock(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages) { unsigned long pfn = PHYS_PFN(virt_to_phys(b->batch_page)); unsigned long status, cmd; cmd = is_2m_pages ? VMW_BALLOON_CMD_BATCHED_2M_UNLOCK : VMW_BALLOON_CMD_BATCHED_UNLOCK; status = vmballoon_cmd(b, cmd, pfn, num_pages); return status == VMW_BALLOON_SUCCESS; } static struct page *vmballoon_alloc_page(gfp_t flags, bool is_2m_page) { if (is_2m_page) return alloc_pages(flags, VMW_BALLOON_2M_SHIFT); return alloc_page(flags); } static void vmballoon_free_page(struct page *page, bool is_2m_page) { if (is_2m_page) __free_pages(page, VMW_BALLOON_2M_SHIFT); else __free_page(page); } /* * Quickly release all pages allocated for the balloon. This function is * called when host decides to "reset" balloon for one reason or another. * Unlike normal "deflate" we do not (shall not) notify host of the pages * being released. */ static void vmballoon_pop(struct vmballoon *b) { struct page *page, *next; unsigned is_2m_pages; for (is_2m_pages = 0; is_2m_pages < VMW_BALLOON_NUM_PAGE_SIZES; is_2m_pages++) { struct vmballoon_page_size *page_size = &b->page_sizes[is_2m_pages]; u16 size_per_page = vmballoon_page_size(is_2m_pages); list_for_each_entry_safe(page, next, &page_size->pages, lru) { list_del(&page->lru); vmballoon_free_page(page, is_2m_pages); STATS_INC(b->stats.free[is_2m_pages]); b->size -= size_per_page; cond_resched(); } } /* Clearing the batch_page unconditionally has no adverse effect */ free_page((unsigned long)b->batch_page); b->batch_page = NULL; } /* * Notify the host of a ballooned page. If host rejects the page put it on the * refuse list, those refused page are then released at the end of the * inflation cycle. */ static int vmballoon_lock_page(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages) { int locked, hv_status; struct page *page = b->page; struct vmballoon_page_size *page_size = &b->page_sizes[false]; /* is_2m_pages can never happen as 2m pages support implies batching */ locked = vmballoon_send_lock_page(b, page_to_pfn(page), &hv_status); if (locked) { STATS_INC(b->stats.refused_alloc[false]); if (locked == -EIO && (hv_status == VMW_BALLOON_ERROR_RESET || hv_status == VMW_BALLOON_ERROR_PPN_NOTNEEDED)) { vmballoon_free_page(page, false); return -EIO; } /* * Place page on the list of non-balloonable pages * and retry allocation, unless we already accumulated * too many of them, in which case take a breather. */ if (page_size->n_refused_pages < VMW_BALLOON_MAX_REFUSED) { page_size->n_refused_pages++; list_add(&page->lru, &page_size->refused_pages); } else { vmballoon_free_page(page, false); } return locked; } /* track allocated page */ list_add(&page->lru, &page_size->pages); /* update balloon size */ b->size++; return 0; } static int vmballoon_lock_batched_page(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages) { int locked, i; u16 size_per_page = vmballoon_page_size(is_2m_pages); locked = vmballoon_send_batched_lock(b, num_pages, is_2m_pages); if (locked > 0) { for (i = 0; i < num_pages; i++) { u64 pa = vmballoon_batch_get_pa(b->batch_page, i); struct page *p = pfn_to_page(pa >> PAGE_SHIFT); vmballoon_free_page(p, is_2m_pages); } return -EIO; } for (i = 0; i < num_pages; i++) { u64 pa = vmballoon_batch_get_pa(b->batch_page, i); struct page *p = pfn_to_page(pa >> PAGE_SHIFT); struct vmballoon_page_size *page_size = &b->page_sizes[is_2m_pages]; locked = vmballoon_batch_get_status(b->batch_page, i); switch (locked) { case VMW_BALLOON_SUCCESS: list_add(&p->lru, &page_size->pages); b->size += size_per_page; break; case VMW_BALLOON_ERROR_PPN_PINNED: case VMW_BALLOON_ERROR_PPN_INVALID: if (page_size->n_refused_pages < VMW_BALLOON_MAX_REFUSED) { list_add(&p->lru, &page_size->refused_pages); page_size->n_refused_pages++; break; } /* Fallthrough */ case VMW_BALLOON_ERROR_RESET: case VMW_BALLOON_ERROR_PPN_NOTNEEDED: vmballoon_free_page(p, is_2m_pages); break; default: /* This should never happen */ WARN_ON_ONCE(true); } } return 0; } /* * Release the page allocated for the balloon. Note that we first notify * the host so it can make sure the page will be available for the guest * to use, if needed. */ static int vmballoon_unlock_page(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages) { struct page *page = b->page; struct vmballoon_page_size *page_size = &b->page_sizes[false]; /* is_2m_pages can never happen as 2m pages support implies batching */ if (!vmballoon_send_unlock_page(b, page_to_pfn(page))) { list_add(&page->lru, &page_size->pages); return -EIO; } /* deallocate page */ vmballoon_free_page(page, false); STATS_INC(b->stats.free[false]); /* update balloon size */ b->size--; return 0; } static int vmballoon_unlock_batched_page(struct vmballoon *b, unsigned int num_pages, bool is_2m_pages) { int locked, i, ret = 0; bool hv_success; u16 size_per_page = vmballoon_page_size(is_2m_pages); hv_success = vmballoon_send_batched_unlock(b, num_pages, is_2m_pages); if (!hv_success) ret = -EIO; for (i = 0; i < num_pages; i++) { u64 pa = vmballoon_batch_get_pa(b->batch_page, i); struct page *p = pfn_to_page(pa >> PAGE_SHIFT); struct vmballoon_page_size *page_size = &b->page_sizes[is_2m_pages]; locked = vmballoon_batch_get_status(b->batch_page, i); if (!hv_success || locked != VMW_BALLOON_SUCCESS) { /* * That page wasn't successfully unlocked by the * hypervisor, re-add it to the list of pages owned by * the balloon driver. */ list_add(&p->lru, &page_size->pages); } else { /* deallocate page */ vmballoon_free_page(p, is_2m_pages); STATS_INC(b->stats.free[is_2m_pages]); /* update balloon size */ b->size -= size_per_page; } } return ret; } /* * Release pages that were allocated while attempting to inflate the * balloon but were refused by the host for one reason or another. */ static void vmballoon_release_refused_pages(struct vmballoon *b, bool is_2m_pages) { struct page *page, *next; struct vmballoon_page_size *page_size = &b->page_sizes[is_2m_pages]; list_for_each_entry_safe(page, next, &page_size->refused_pages, lru) { list_del(&page->lru); vmballoon_free_page(page, is_2m_pages); STATS_INC(b->stats.refused_free[is_2m_pages]); } page_size->n_refused_pages = 0; } static void vmballoon_add_page(struct vmballoon *b, int idx, struct page *p) { b->page = p; } static void vmballoon_add_batched_page(struct vmballoon *b, int idx, struct page *p) { vmballoon_batch_set_pa(b->batch_page, idx, (u64)page_to_pfn(p) << PAGE_SHIFT); } /* * Inflate the balloon towards its target size. Note that we try to limit * the rate of allocation to make sure we are not choking the rest of the * system. */ static void vmballoon_inflate(struct vmballoon *b) { unsigned int num_pages = 0; int error = 0; gfp_t flags = VMW_PAGE_ALLOC_NOSLEEP; bool is_2m_pages; pr_debug("%s - size: %d, target %d\n", __func__, b->size, b->target); /* * First try NOSLEEP page allocations to inflate balloon. * * If we do not throttle nosleep allocations, we can drain all * free pages in the guest quickly (if the balloon target is high). * As a side-effect, draining free pages helps to inform (force) * the guest to start swapping if balloon target is not met yet, * which is a desired behavior. However, balloon driver can consume * all available CPU cycles if too many pages are allocated in a * second. Therefore, we throttle nosleep allocations even when * the guest is not under memory pressure. OTOH, if we have already * predicted that the guest is under memory pressure, then we * slowdown page allocations considerably. */ /* * Start with no sleep allocation rate which may be higher * than sleeping allocation rate. */ is_2m_pages = b->supported_page_sizes == VMW_BALLOON_NUM_PAGE_SIZES; pr_debug("%s - goal: %d", __func__, b->target - b->size); while (!b->reset_required && b->size + num_pages * vmballoon_page_size(is_2m_pages) < b->target) { struct page *page; if (flags == VMW_PAGE_ALLOC_NOSLEEP) STATS_INC(b->stats.alloc[is_2m_pages]); else STATS_INC(b->stats.sleep_alloc); page = vmballoon_alloc_page(flags, is_2m_pages); if (!page) { STATS_INC(b->stats.alloc_fail[is_2m_pages]); if (is_2m_pages) { b->ops->lock(b, num_pages, true); /* * ignore errors from locking as we now switch * to 4k pages and we might get different * errors. */ num_pages = 0; is_2m_pages = false; continue; } if (flags == VMW_PAGE_ALLOC_CANSLEEP) { /* * CANSLEEP page allocation failed, so guest * is under severe memory pressure. We just log * the event, but do not stop the inflation * due to its negative impact on performance. */ STATS_INC(b->stats.sleep_alloc_fail); break; } /* * NOSLEEP page allocation failed, so the guest is * under memory pressure. Slowing down page alloctions * seems to be reasonable, but doing so might actually * cause the hypervisor to throttle us down, resulting * in degraded performance. We will count on the * scheduler and standard memory management mechanisms * for now. */ flags = VMW_PAGE_ALLOC_CANSLEEP; continue; } b->ops->add_page(b, num_pages++, page); if (num_pages == b->batch_max_pages) { error = b->ops->lock(b, num_pages, is_2m_pages); num_pages = 0; if (error) break; } cond_resched(); } if (num_pages > 0) b->ops->lock(b, num_pages, is_2m_pages); vmballoon_release_refused_pages(b, true); vmballoon_release_refused_pages(b, false); } /* * Decrease the size of the balloon allowing guest to use more memory. */ static void vmballoon_deflate(struct vmballoon *b) { unsigned is_2m_pages; pr_debug("%s - size: %d, target %d\n", __func__, b->size, b->target); /* free pages to reach target */ for (is_2m_pages = 0; is_2m_pages < b->supported_page_sizes; is_2m_pages++) { struct page *page, *next; unsigned int num_pages = 0; struct vmballoon_page_size *page_size = &b->page_sizes[is_2m_pages]; list_for_each_entry_safe(page, next, &page_size->pages, lru) { if (b->reset_required || (b->target > 0 && b->size - num_pages * vmballoon_page_size(is_2m_pages) < b->target + vmballoon_page_size(true))) break; list_del(&page->lru); b->ops->add_page(b, num_pages++, page); if (num_pages == b->batch_max_pages) { int error; error = b->ops->unlock(b, num_pages, is_2m_pages); num_pages = 0; if (error) return; } cond_resched(); } if (num_pages > 0) b->ops->unlock(b, num_pages, is_2m_pages); } } static const struct vmballoon_ops vmballoon_basic_ops = { .add_page = vmballoon_add_page, .lock = vmballoon_lock_page, .unlock = vmballoon_unlock_page }; static const struct vmballoon_ops vmballoon_batched_ops = { .add_page = vmballoon_add_batched_page, .lock = vmballoon_lock_batched_page, .unlock = vmballoon_unlock_batched_page }; static bool vmballoon_init_batching(struct vmballoon *b) { struct page *page; page = alloc_page(GFP_KERNEL | __GFP_ZERO); if (!page) return false; b->batch_page = page_address(page); return true; } /* * Receive notification and resize balloon */ static void vmballoon_doorbell(void *client_data) { struct vmballoon *b = client_data; STATS_INC(b->stats.doorbell); mod_delayed_work(system_freezable_wq, &b->dwork, 0); } /* * Clean up vmci doorbell */ static void vmballoon_vmci_cleanup(struct vmballoon *b) { vmballoon_cmd(b, VMW_BALLOON_CMD_VMCI_DOORBELL_SET, VMCI_INVALID_ID, VMCI_INVALID_ID); if (!vmci_handle_is_invalid(b->vmci_doorbell)) { vmci_doorbell_destroy(b->vmci_doorbell); b->vmci_doorbell = VMCI_INVALID_HANDLE; } } /* * Initialize vmci doorbell, to get notified as soon as balloon changes */ static int vmballoon_vmci_init(struct vmballoon *b) { unsigned long error; if ((b->capabilities & VMW_BALLOON_SIGNALLED_WAKEUP_CMD) == 0) return 0; error = vmci_doorbell_create(&b->vmci_doorbell, VMCI_FLAG_DELAYED_CB, VMCI_PRIVILEGE_FLAG_RESTRICTED, vmballoon_doorbell, b); if (error != VMCI_SUCCESS) goto fail; error = __vmballoon_cmd(b, VMW_BALLOON_CMD_VMCI_DOORBELL_SET, b->vmci_doorbell.context, b->vmci_doorbell.resource, NULL); if (error != VMW_BALLOON_SUCCESS) goto fail; return 0; fail: vmballoon_vmci_cleanup(b); return -EIO; } /* * Perform standard reset sequence by popping the balloon (in case it * is not empty) and then restarting protocol. This operation normally * happens when host responds with VMW_BALLOON_ERROR_RESET to a command. */ static void vmballoon_reset(struct vmballoon *b) { int error; vmballoon_vmci_cleanup(b); /* free all pages, skipping monitor unlock */ vmballoon_pop(b); if (!vmballoon_send_start(b, VMW_BALLOON_CAPABILITIES)) return; if ((b->capabilities & VMW_BALLOON_BATCHED_CMDS) != 0) { b->ops = &vmballoon_batched_ops; b->batch_max_pages = VMW_BALLOON_BATCH_MAX_PAGES; if (!vmballoon_init_batching(b)) { /* * We failed to initialize batching, inform the monitor * about it by sending a null capability. * * The guest will retry in one second. */ vmballoon_send_start(b, 0); return; } } else if ((b->capabilities & VMW_BALLOON_BASIC_CMDS) != 0) { b->ops = &vmballoon_basic_ops; b->batch_max_pages = 1; } b->reset_required = false; error = vmballoon_vmci_init(b); if (error) pr_err("failed to initialize vmci doorbell\n"); if (!vmballoon_send_guest_id(b)) pr_err("failed to send guest ID to the host\n"); } /* * Balloon work function: reset protocol, if needed, get the new size and * adjust balloon as needed. Repeat in 1 sec. */ static void vmballoon_work(struct work_struct *work) { struct delayed_work *dwork = to_delayed_work(work); struct vmballoon *b = container_of(dwork, struct vmballoon, dwork); STATS_INC(b->stats.timer); if (b->reset_required) vmballoon_reset(b); if (!b->reset_required && vmballoon_send_get_target(b)) { unsigned long target = b->target; /* update target, adjust size */ if (b->size < target) vmballoon_inflate(b); else if (target == 0 || b->size > target + vmballoon_page_size(true)) vmballoon_deflate(b); } /* * We are using a freezable workqueue so that balloon operations are * stopped while the system transitions to/from sleep/hibernation. */ queue_delayed_work(system_freezable_wq, dwork, round_jiffies_relative(HZ)); } /* * DEBUGFS Interface */ #ifdef CONFIG_DEBUG_FS static int vmballoon_debug_show(struct seq_file *f, void *offset) { struct vmballoon *b = f->private; struct vmballoon_stats *stats = &b->stats; int i; /* format capabilities info */ seq_printf(f, "balloon capabilities: %#4x\n" "used capabilities: %#4lx\n" "is resetting: %c\n", VMW_BALLOON_CAPABILITIES, b->capabilities, b->reset_required ? 'y' : 'n'); /* format size info */ seq_printf(f, "target: %8d pages\n" "current: %8d pages\n", b->target, b->size); for (i = 0; i < VMW_BALLOON_CMD_NUM; i++) { if (vmballoon_cmd_names[i] == NULL) continue; seq_printf(f, "%-22s: %16lu (%lu failed)\n", vmballoon_cmd_names[i], stats->ops[i], stats->ops_fail[i]); } seq_printf(f, "\n" "timer: %8u\n" "doorbell: %8u\n" "prim2mAlloc: %8u (%4u failed)\n" "primNoSleepAlloc: %8u (%4u failed)\n" "primCanSleepAlloc: %8u (%4u failed)\n" "prim2mFree: %8u\n" "primFree: %8u\n" "err2mAlloc: %8u\n" "errAlloc: %8u\n" "err2mFree: %8u\n" "errFree: %8u\n", stats->timer, stats->doorbell, stats->alloc[true], stats->alloc_fail[true], stats->alloc[false], stats->alloc_fail[false], stats->sleep_alloc, stats->sleep_alloc_fail, stats->free[true], stats->free[false], stats->refused_alloc[true], stats->refused_alloc[false], stats->refused_free[true], stats->refused_free[false]); return 0; } static int vmballoon_debug_open(struct inode *inode, struct file *file) { return single_open(file, vmballoon_debug_show, inode->i_private); } static const struct file_operations vmballoon_debug_fops = { .owner = THIS_MODULE, .open = vmballoon_debug_open, .read = seq_read, .llseek = seq_lseek, .release = single_release, }; static int __init vmballoon_debugfs_init(struct vmballoon *b) { int error; b->dbg_entry = debugfs_create_file("vmmemctl", S_IRUGO, NULL, b, &vmballoon_debug_fops); if (IS_ERR(b->dbg_entry)) { error = PTR_ERR(b->dbg_entry); pr_err("failed to create debugfs entry, error: %d\n", error); return error; } return 0; } static void __exit vmballoon_debugfs_exit(struct vmballoon *b) { debugfs_remove(b->dbg_entry); } #else static inline int vmballoon_debugfs_init(struct vmballoon *b) { return 0; } static inline void vmballoon_debugfs_exit(struct vmballoon *b) { } #endif /* CONFIG_DEBUG_FS */ static int __init vmballoon_init(void) { int error; unsigned is_2m_pages; /* * Check if we are running on VMware's hypervisor and bail out * if we are not. */ if (x86_hyper_type != X86_HYPER_VMWARE) return -ENODEV; for (is_2m_pages = 0; is_2m_pages < VMW_BALLOON_NUM_PAGE_SIZES; is_2m_pages++) { INIT_LIST_HEAD(&balloon.page_sizes[is_2m_pages].pages); INIT_LIST_HEAD(&balloon.page_sizes[is_2m_pages].refused_pages); } INIT_DELAYED_WORK(&balloon.dwork, vmballoon_work); error = vmballoon_debugfs_init(&balloon); if (error) return error; balloon.vmci_doorbell = VMCI_INVALID_HANDLE; balloon.batch_page = NULL; balloon.page = NULL; balloon.reset_required = true; queue_delayed_work(system_freezable_wq, &balloon.dwork, 0); return 0; } /* * Using late_initcall() instead of module_init() allows the balloon to use the * VMCI doorbell even when the balloon is built into the kernel. Otherwise the * VMCI is probed only after the balloon is initialized. If the balloon is used * as a module, late_initcall() is equivalent to module_init(). */ late_initcall(vmballoon_init); static void __exit vmballoon_exit(void) { vmballoon_vmci_cleanup(&balloon); cancel_delayed_work_sync(&balloon.dwork); vmballoon_debugfs_exit(&balloon); /* * Deallocate all reserved memory, and reset connection with monitor. * Reset connection before deallocating memory to avoid potential for * additional spurious resets from guest touching deallocated pages. */ vmballoon_send_start(&balloon, 0); vmballoon_pop(&balloon); } module_exit(vmballoon_exit);