/* * (C) 2001 Clemson University and The University of Chicago * * See COPYING in top-level directory. */ #include "protocol.h" #include "orangefs-kernel.h" #include "orangefs-bufmap.h" DECLARE_WAIT_QUEUE_HEAD(orangefs_bufmap_init_waitq); /* used to describe mapped buffers */ struct orangefs_bufmap_desc { void *uaddr; /* user space address pointer */ struct page **page_array; /* array of mapped pages */ int array_count; /* size of above arrays */ struct list_head list_link; }; static struct orangefs_bufmap { atomic_t refcnt; int desc_size; int desc_shift; int desc_count; int total_size; int page_count; struct page **page_array; struct orangefs_bufmap_desc *desc_array; /* array to track usage of buffer descriptors */ int *buffer_index_array; spinlock_t buffer_index_lock; /* array to track usage of buffer descriptors for readdir */ int readdir_index_array[ORANGEFS_READDIR_DEFAULT_DESC_COUNT]; spinlock_t readdir_index_lock; } *__orangefs_bufmap; static DEFINE_SPINLOCK(orangefs_bufmap_lock); static void orangefs_bufmap_unmap(struct orangefs_bufmap *bufmap) { int i; for (i = 0; i < bufmap->page_count; i++) page_cache_release(bufmap->page_array[i]); } static void orangefs_bufmap_free(struct orangefs_bufmap *bufmap) { kfree(bufmap->page_array); kfree(bufmap->desc_array); kfree(bufmap->buffer_index_array); kfree(bufmap); } static struct orangefs_bufmap *orangefs_bufmap_ref(void) { struct orangefs_bufmap *bufmap = NULL; spin_lock(&orangefs_bufmap_lock); if (__orangefs_bufmap) { bufmap = __orangefs_bufmap; atomic_inc(&bufmap->refcnt); } spin_unlock(&orangefs_bufmap_lock); return bufmap; } static void orangefs_bufmap_unref(struct orangefs_bufmap *bufmap) { if (atomic_dec_and_lock(&bufmap->refcnt, &orangefs_bufmap_lock)) { __orangefs_bufmap = NULL; spin_unlock(&orangefs_bufmap_lock); orangefs_bufmap_unmap(bufmap); orangefs_bufmap_free(bufmap); } } /* * XXX: Can the size and shift change while the caller gives up the * XXX: lock between calling this and doing something useful? */ int orangefs_bufmap_size_query(void) { struct orangefs_bufmap *bufmap; int size = 0; bufmap = orangefs_bufmap_ref(); if (bufmap) { size = bufmap->desc_size; orangefs_bufmap_unref(bufmap); } return size; } int orangefs_bufmap_shift_query(void) { struct orangefs_bufmap *bufmap; int shift = 0; bufmap = orangefs_bufmap_ref(); if (bufmap) { shift = bufmap->desc_shift; orangefs_bufmap_unref(bufmap); } return shift; } static DECLARE_WAIT_QUEUE_HEAD(bufmap_waitq); static DECLARE_WAIT_QUEUE_HEAD(readdir_waitq); /* * orangefs_get_bufmap_init * * If bufmap_init is 1, then the shared memory system, including the * buffer_index_array, is available. Otherwise, it is not. * * returns the value of bufmap_init */ int orangefs_get_bufmap_init(void) { return __orangefs_bufmap ? 1 : 0; } static struct orangefs_bufmap * orangefs_bufmap_alloc(struct ORANGEFS_dev_map_desc *user_desc) { struct orangefs_bufmap *bufmap; bufmap = kzalloc(sizeof(*bufmap), GFP_KERNEL); if (!bufmap) goto out; atomic_set(&bufmap->refcnt, 1); bufmap->total_size = user_desc->total_size; bufmap->desc_count = user_desc->count; bufmap->desc_size = user_desc->size; bufmap->desc_shift = ilog2(bufmap->desc_size); spin_lock_init(&bufmap->buffer_index_lock); bufmap->buffer_index_array = kcalloc(bufmap->desc_count, sizeof(int), GFP_KERNEL); if (!bufmap->buffer_index_array) { gossip_err("orangefs: could not allocate %d buffer indices\n", bufmap->desc_count); goto out_free_bufmap; } spin_lock_init(&bufmap->readdir_index_lock); bufmap->desc_array = kcalloc(bufmap->desc_count, sizeof(struct orangefs_bufmap_desc), GFP_KERNEL); if (!bufmap->desc_array) { gossip_err("orangefs: could not allocate %d descriptors\n", bufmap->desc_count); goto out_free_index_array; } bufmap->page_count = bufmap->total_size / PAGE_SIZE; /* allocate storage to track our page mappings */ bufmap->page_array = kcalloc(bufmap->page_count, sizeof(struct page *), GFP_KERNEL); if (!bufmap->page_array) goto out_free_desc_array; return bufmap; out_free_desc_array: kfree(bufmap->desc_array); out_free_index_array: kfree(bufmap->buffer_index_array); out_free_bufmap: kfree(bufmap); out: return NULL; } static int orangefs_bufmap_map(struct orangefs_bufmap *bufmap, struct ORANGEFS_dev_map_desc *user_desc) { int pages_per_desc = bufmap->desc_size / PAGE_SIZE; int offset = 0, ret, i; /* map the pages */ ret = get_user_pages_fast((unsigned long)user_desc->ptr, bufmap->page_count, 1, bufmap->page_array); if (ret < 0) return ret; if (ret != bufmap->page_count) { gossip_err("orangefs error: asked for %d pages, only got %d.\n", bufmap->page_count, ret); for (i = 0; i < ret; i++) { SetPageError(bufmap->page_array[i]); page_cache_release(bufmap->page_array[i]); } return -ENOMEM; } /* * ideally we want to get kernel space pointers for each page, but * we can't kmap that many pages at once if highmem is being used. * so instead, we just kmap/kunmap the page address each time the * kaddr is needed. */ for (i = 0; i < bufmap->page_count; i++) flush_dcache_page(bufmap->page_array[i]); /* build a list of available descriptors */ for (offset = 0, i = 0; i < bufmap->desc_count; i++) { bufmap->desc_array[i].page_array = &bufmap->page_array[offset]; bufmap->desc_array[i].array_count = pages_per_desc; bufmap->desc_array[i].uaddr = (user_desc->ptr + (i * pages_per_desc * PAGE_SIZE)); offset += pages_per_desc; } return 0; } /* * orangefs_bufmap_initialize() * * initializes the mapped buffer interface * * returns 0 on success, -errno on failure */ int orangefs_bufmap_initialize(struct ORANGEFS_dev_map_desc *user_desc) { struct orangefs_bufmap *bufmap; int ret = -EINVAL; gossip_debug(GOSSIP_BUFMAP_DEBUG, "orangefs_bufmap_initialize: called (ptr (" "%p) sz (%d) cnt(%d).\n", user_desc->ptr, user_desc->size, user_desc->count); /* * sanity check alignment and size of buffer that caller wants to * work with */ if (PAGE_ALIGN((unsigned long)user_desc->ptr) != (unsigned long)user_desc->ptr) { gossip_err("orangefs error: memory alignment (front). %p\n", user_desc->ptr); goto out; } if (PAGE_ALIGN(((unsigned long)user_desc->ptr + user_desc->total_size)) != (unsigned long)(user_desc->ptr + user_desc->total_size)) { gossip_err("orangefs error: memory alignment (back).(%p + %d)\n", user_desc->ptr, user_desc->total_size); goto out; } if (user_desc->total_size != (user_desc->size * user_desc->count)) { gossip_err("orangefs error: user provided an oddly sized buffer: (%d, %d, %d)\n", user_desc->total_size, user_desc->size, user_desc->count); goto out; } if ((user_desc->size % PAGE_SIZE) != 0) { gossip_err("orangefs error: bufmap size not page size divisible (%d).\n", user_desc->size); goto out; } ret = -ENOMEM; bufmap = orangefs_bufmap_alloc(user_desc); if (!bufmap) goto out; ret = orangefs_bufmap_map(bufmap, user_desc); if (ret) goto out_free_bufmap; spin_lock(&orangefs_bufmap_lock); if (__orangefs_bufmap) { spin_unlock(&orangefs_bufmap_lock); gossip_err("orangefs: error: bufmap already initialized.\n"); ret = -EALREADY; goto out_unmap_bufmap; } __orangefs_bufmap = bufmap; spin_unlock(&orangefs_bufmap_lock); /* * If there are operations in orangefs_bufmap_init_waitq, wake them up. * This scenario occurs when the client-core is restarted and I/O * requests in the in-progress or waiting tables are restarted. I/O * requests cannot be restarted until the shared memory system is * completely re-initialized, so we put the I/O requests in this * waitq until initialization has completed. NOTE: the I/O requests * are also on a timer, so they don't wait forever just in case the * client-core doesn't come back up. */ wake_up_interruptible(&orangefs_bufmap_init_waitq); gossip_debug(GOSSIP_BUFMAP_DEBUG, "orangefs_bufmap_initialize: exiting normally\n"); return 0; out_unmap_bufmap: orangefs_bufmap_unmap(bufmap); out_free_bufmap: orangefs_bufmap_free(bufmap); out: return ret; } /* * orangefs_bufmap_finalize() * * shuts down the mapped buffer interface and releases any resources * associated with it * * no return value */ void orangefs_bufmap_finalize(void) { gossip_debug(GOSSIP_BUFMAP_DEBUG, "orangefs_bufmap_finalize: called\n"); BUG_ON(!__orangefs_bufmap); orangefs_bufmap_unref(__orangefs_bufmap); gossip_debug(GOSSIP_BUFMAP_DEBUG, "orangefs_bufmap_finalize: exiting normally\n"); } struct slot_args { int slot_count; int *slot_array; spinlock_t *slot_lock; wait_queue_head_t *slot_wq; }; static int wait_for_a_slot(struct slot_args *slargs, int *buffer_index) { int ret = -1; int i = 0; DEFINE_WAIT(wait_entry); while (1) { /* * check for available desc, slot_lock is the appropriate * index_lock */ spin_lock(slargs->slot_lock); prepare_to_wait_exclusive(slargs->slot_wq, &wait_entry, TASK_INTERRUPTIBLE); for (i = 0; i < slargs->slot_count; i++) if (slargs->slot_array[i] == 0) { slargs->slot_array[i] = 1; *buffer_index = i; ret = 0; break; } spin_unlock(slargs->slot_lock); /* if we acquired a buffer, then break out of while */ if (ret == 0) break; if (!signal_pending(current)) { gossip_debug(GOSSIP_BUFMAP_DEBUG, "[BUFMAP]: waiting %d " "seconds for a slot\n", slot_timeout_secs); if (!schedule_timeout(slot_timeout_secs * HZ)) { gossip_debug(GOSSIP_BUFMAP_DEBUG, "*** wait_for_a_slot timed out\n"); ret = -ETIMEDOUT; break; } gossip_debug(GOSSIP_BUFMAP_DEBUG, "[BUFMAP]: woken up by a slot becoming available.\n"); continue; } gossip_debug(GOSSIP_BUFMAP_DEBUG, "orangefs: %s interrupted.\n", __func__); ret = -EINTR; break; } spin_lock(slargs->slot_lock); finish_wait(slargs->slot_wq, &wait_entry); spin_unlock(slargs->slot_lock); return ret; } static void put_back_slot(struct slot_args *slargs, int buffer_index) { /* slot_lock is the appropriate index_lock */ spin_lock(slargs->slot_lock); if (buffer_index < 0 || buffer_index >= slargs->slot_count) { spin_unlock(slargs->slot_lock); return; } /* put the desc back on the queue */ slargs->slot_array[buffer_index] = 0; spin_unlock(slargs->slot_lock); /* wake up anyone who may be sleeping on the queue */ wake_up_interruptible(slargs->slot_wq); } /* * orangefs_bufmap_get() * * gets a free mapped buffer descriptor, will sleep until one becomes * available if necessary * * returns 0 on success, -errno on failure */ int orangefs_bufmap_get(struct orangefs_bufmap **mapp, int *buffer_index) { struct orangefs_bufmap *bufmap = orangefs_bufmap_ref(); struct slot_args slargs; int ret; if (!bufmap) { gossip_err("orangefs: please confirm that pvfs2-client daemon is running.\n"); return -EIO; } slargs.slot_count = bufmap->desc_count; slargs.slot_array = bufmap->buffer_index_array; slargs.slot_lock = &bufmap->buffer_index_lock; slargs.slot_wq = &bufmap_waitq; ret = wait_for_a_slot(&slargs, buffer_index); if (ret) orangefs_bufmap_unref(bufmap); *mapp = bufmap; return ret; } /* * orangefs_bufmap_put() * * returns a mapped buffer descriptor to the collection * * no return value */ void orangefs_bufmap_put(struct orangefs_bufmap *bufmap, int buffer_index) { struct slot_args slargs; slargs.slot_count = bufmap->desc_count; slargs.slot_array = bufmap->buffer_index_array; slargs.slot_lock = &bufmap->buffer_index_lock; slargs.slot_wq = &bufmap_waitq; put_back_slot(&slargs, buffer_index); orangefs_bufmap_unref(bufmap); } /* * orangefs_readdir_index_get() * * gets a free descriptor, will sleep until one becomes * available if necessary. * Although the readdir buffers are not mapped into kernel space * we could do that at a later point of time. Regardless, these * indices are used by the client-core. * * returns 0 on success, -errno on failure */ int orangefs_readdir_index_get(struct orangefs_bufmap **mapp, int *buffer_index) { struct orangefs_bufmap *bufmap = orangefs_bufmap_ref(); struct slot_args slargs; int ret; if (!bufmap) { gossip_err("orangefs: please confirm that pvfs2-client daemon is running.\n"); return -EIO; } slargs.slot_count = ORANGEFS_READDIR_DEFAULT_DESC_COUNT; slargs.slot_array = bufmap->readdir_index_array; slargs.slot_lock = &bufmap->readdir_index_lock; slargs.slot_wq = &readdir_waitq; ret = wait_for_a_slot(&slargs, buffer_index); if (ret) orangefs_bufmap_unref(bufmap); *mapp = bufmap; return ret; } void orangefs_readdir_index_put(struct orangefs_bufmap *bufmap, int buffer_index) { struct slot_args slargs; slargs.slot_count = ORANGEFS_READDIR_DEFAULT_DESC_COUNT; slargs.slot_array = bufmap->readdir_index_array; slargs.slot_lock = &bufmap->readdir_index_lock; slargs.slot_wq = &readdir_waitq; put_back_slot(&slargs, buffer_index); orangefs_bufmap_unref(bufmap); } /* * we've been handed an iovec, we need to copy it to * the shared memory descriptor at "buffer_index". */ int orangefs_bufmap_copy_from_iovec(struct orangefs_bufmap *bufmap, struct iov_iter *iter, int buffer_index, size_t size) { struct orangefs_bufmap_desc *to = &bufmap->desc_array[buffer_index]; int i; gossip_debug(GOSSIP_BUFMAP_DEBUG, "%s: buffer_index:%d: size:%zu:\n", __func__, buffer_index, size); for (i = 0; size; i++) { struct page *page = to->page_array[i]; size_t n = size; if (n > PAGE_SIZE) n = PAGE_SIZE; n = copy_page_from_iter(page, 0, n, iter); if (!n) return -EFAULT; size -= n; } return 0; } /* * we've been handed an iovec, we need to fill it from * the shared memory descriptor at "buffer_index". */ int orangefs_bufmap_copy_to_iovec(struct orangefs_bufmap *bufmap, struct iov_iter *iter, int buffer_index, size_t size) { struct orangefs_bufmap_desc *from = &bufmap->desc_array[buffer_index]; int i; gossip_debug(GOSSIP_BUFMAP_DEBUG, "%s: buffer_index:%d: size:%zu:\n", __func__, buffer_index, size); for (i = 0; size; i++) { struct page *page = from->page_array[i]; size_t n = size; if (n > PAGE_SIZE) n = PAGE_SIZE; n = copy_page_to_iter(page, 0, n, iter); if (!n) return -EFAULT; size -= n; } return 0; }