/* * Compressed RAM block device * * Copyright (C) 2008, 2009, 2010 Nitin Gupta * 2012, 2013 Minchan Kim * * This code is released using a dual license strategy: BSD/GPL * You can choose the licence that better fits your requirements. * * Released under the terms of 3-clause BSD License * Released under the terms of GNU General Public License Version 2.0 * */ #define KMSG_COMPONENT "zram" #define pr_fmt(fmt) KMSG_COMPONENT ": " fmt #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "zram_drv.h" static DEFINE_IDR(zram_index_idr); static int zram_major; static const char *default_compressor = "lzo"; /* Module params (documentation at end) */ static unsigned int num_devices = 1; static inline void deprecated_attr_warn(const char *name) { pr_warn_once("%d (%s) Attribute %s (and others) will be removed. %s\n", task_pid_nr(current), current->comm, name, "See zram documentation."); } #define ZRAM_ATTR_RO(name) \ static ssize_t name##_show(struct device *d, \ struct device_attribute *attr, char *b) \ { \ struct zram *zram = dev_to_zram(d); \ \ deprecated_attr_warn(__stringify(name)); \ return scnprintf(b, PAGE_SIZE, "%llu\n", \ (u64)atomic64_read(&zram->stats.name)); \ } \ static DEVICE_ATTR_RO(name); static inline bool init_done(struct zram *zram) { return zram->disksize; } static inline struct zram *dev_to_zram(struct device *dev) { return (struct zram *)dev_to_disk(dev)->private_data; } /* flag operations require table entry bit_spin_lock() being held */ static int zram_test_flag(struct zram_meta *meta, u32 index, enum zram_pageflags flag) { return meta->table[index].value & BIT(flag); } static void zram_set_flag(struct zram_meta *meta, u32 index, enum zram_pageflags flag) { meta->table[index].value |= BIT(flag); } static void zram_clear_flag(struct zram_meta *meta, u32 index, enum zram_pageflags flag) { meta->table[index].value &= ~BIT(flag); } static size_t zram_get_obj_size(struct zram_meta *meta, u32 index) { return meta->table[index].value & (BIT(ZRAM_FLAG_SHIFT) - 1); } static void zram_set_obj_size(struct zram_meta *meta, u32 index, size_t size) { unsigned long flags = meta->table[index].value >> ZRAM_FLAG_SHIFT; meta->table[index].value = (flags << ZRAM_FLAG_SHIFT) | size; } static inline int is_partial_io(struct bio_vec *bvec) { return bvec->bv_len != PAGE_SIZE; } /* * Check if request is within bounds and aligned on zram logical blocks. */ static inline int valid_io_request(struct zram *zram, sector_t start, unsigned int size) { u64 end, bound; /* unaligned request */ if (unlikely(start & (ZRAM_SECTOR_PER_LOGICAL_BLOCK - 1))) return 0; if (unlikely(size & (ZRAM_LOGICAL_BLOCK_SIZE - 1))) return 0; end = start + (size >> SECTOR_SHIFT); bound = zram->disksize >> SECTOR_SHIFT; /* out of range range */ if (unlikely(start >= bound || end > bound || start > end)) return 0; /* I/O request is valid */ return 1; } static void update_position(u32 *index, int *offset, struct bio_vec *bvec) { if (*offset + bvec->bv_len >= PAGE_SIZE) (*index)++; *offset = (*offset + bvec->bv_len) % PAGE_SIZE; } static inline void update_used_max(struct zram *zram, const unsigned long pages) { unsigned long old_max, cur_max; old_max = atomic_long_read(&zram->stats.max_used_pages); do { cur_max = old_max; if (pages > cur_max) old_max = atomic_long_cmpxchg( &zram->stats.max_used_pages, cur_max, pages); } while (old_max != cur_max); } static int page_zero_filled(void *ptr) { unsigned int pos; unsigned long *page; page = (unsigned long *)ptr; for (pos = 0; pos != PAGE_SIZE / sizeof(*page); pos++) { if (page[pos]) return 0; } return 1; } static void handle_zero_page(struct bio_vec *bvec) { struct page *page = bvec->bv_page; void *user_mem; user_mem = kmap_atomic(page); if (is_partial_io(bvec)) memset(user_mem + bvec->bv_offset, 0, bvec->bv_len); else clear_page(user_mem); kunmap_atomic(user_mem); flush_dcache_page(page); } static ssize_t initstate_show(struct device *dev, struct device_attribute *attr, char *buf) { u32 val; struct zram *zram = dev_to_zram(dev); down_read(&zram->init_lock); val = init_done(zram); up_read(&zram->init_lock); return scnprintf(buf, PAGE_SIZE, "%u\n", val); } static ssize_t disksize_show(struct device *dev, struct device_attribute *attr, char *buf) { struct zram *zram = dev_to_zram(dev); return scnprintf(buf, PAGE_SIZE, "%llu\n", zram->disksize); } static ssize_t orig_data_size_show(struct device *dev, struct device_attribute *attr, char *buf) { struct zram *zram = dev_to_zram(dev); deprecated_attr_warn("orig_data_size"); return scnprintf(buf, PAGE_SIZE, "%llu\n", (u64)(atomic64_read(&zram->stats.pages_stored)) << PAGE_SHIFT); } static ssize_t mem_used_total_show(struct device *dev, struct device_attribute *attr, char *buf) { u64 val = 0; struct zram *zram = dev_to_zram(dev); deprecated_attr_warn("mem_used_total"); down_read(&zram->init_lock); if (init_done(zram)) { struct zram_meta *meta = zram->meta; val = zs_get_total_pages(meta->mem_pool); } up_read(&zram->init_lock); return scnprintf(buf, PAGE_SIZE, "%llu\n", val << PAGE_SHIFT); } static ssize_t mem_limit_show(struct device *dev, struct device_attribute *attr, char *buf) { u64 val; struct zram *zram = dev_to_zram(dev); deprecated_attr_warn("mem_limit"); down_read(&zram->init_lock); val = zram->limit_pages; up_read(&zram->init_lock); return scnprintf(buf, PAGE_SIZE, "%llu\n", val << PAGE_SHIFT); } static ssize_t mem_limit_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t len) { u64 limit; char *tmp; struct zram *zram = dev_to_zram(dev); limit = memparse(buf, &tmp); if (buf == tmp) /* no chars parsed, invalid input */ return -EINVAL; down_write(&zram->init_lock); zram->limit_pages = PAGE_ALIGN(limit) >> PAGE_SHIFT; up_write(&zram->init_lock); return len; } static ssize_t mem_used_max_show(struct device *dev, struct device_attribute *attr, char *buf) { u64 val = 0; struct zram *zram = dev_to_zram(dev); deprecated_attr_warn("mem_used_max"); down_read(&zram->init_lock); if (init_done(zram)) val = atomic_long_read(&zram->stats.max_used_pages); up_read(&zram->init_lock); return scnprintf(buf, PAGE_SIZE, "%llu\n", val << PAGE_SHIFT); } static ssize_t mem_used_max_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t len) { int err; unsigned long val; struct zram *zram = dev_to_zram(dev); err = kstrtoul(buf, 10, &val); if (err || val != 0) return -EINVAL; down_read(&zram->init_lock); if (init_done(zram)) { struct zram_meta *meta = zram->meta; atomic_long_set(&zram->stats.max_used_pages, zs_get_total_pages(meta->mem_pool)); } up_read(&zram->init_lock); return len; } static ssize_t max_comp_streams_show(struct device *dev, struct device_attribute *attr, char *buf) { int val; struct zram *zram = dev_to_zram(dev); down_read(&zram->init_lock); val = zram->max_comp_streams; up_read(&zram->init_lock); return scnprintf(buf, PAGE_SIZE, "%d\n", val); } static ssize_t max_comp_streams_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t len) { int num; struct zram *zram = dev_to_zram(dev); int ret; ret = kstrtoint(buf, 0, &num); if (ret < 0) return ret; if (num < 1) return -EINVAL; down_write(&zram->init_lock); if (init_done(zram)) { if (!zcomp_set_max_streams(zram->comp, num)) { pr_info("Cannot change max compression streams\n"); ret = -EINVAL; goto out; } } zram->max_comp_streams = num; ret = len; out: up_write(&zram->init_lock); return ret; } static ssize_t comp_algorithm_show(struct device *dev, struct device_attribute *attr, char *buf) { size_t sz; struct zram *zram = dev_to_zram(dev); down_read(&zram->init_lock); sz = zcomp_available_show(zram->compressor, buf); up_read(&zram->init_lock); return sz; } static ssize_t comp_algorithm_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t len) { struct zram *zram = dev_to_zram(dev); down_write(&zram->init_lock); if (init_done(zram)) { up_write(&zram->init_lock); pr_info("Can't change algorithm for initialized device\n"); return -EBUSY; } strlcpy(zram->compressor, buf, sizeof(zram->compressor)); up_write(&zram->init_lock); return len; } static ssize_t compact_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t len) { unsigned long nr_migrated; struct zram *zram = dev_to_zram(dev); struct zram_meta *meta; down_read(&zram->init_lock); if (!init_done(zram)) { up_read(&zram->init_lock); return -EINVAL; } meta = zram->meta; nr_migrated = zs_compact(meta->mem_pool); atomic64_add(nr_migrated, &zram->stats.num_migrated); up_read(&zram->init_lock); return len; } static ssize_t io_stat_show(struct device *dev, struct device_attribute *attr, char *buf) { struct zram *zram = dev_to_zram(dev); ssize_t ret; down_read(&zram->init_lock); ret = scnprintf(buf, PAGE_SIZE, "%8llu %8llu %8llu %8llu\n", (u64)atomic64_read(&zram->stats.failed_reads), (u64)atomic64_read(&zram->stats.failed_writes), (u64)atomic64_read(&zram->stats.invalid_io), (u64)atomic64_read(&zram->stats.notify_free)); up_read(&zram->init_lock); return ret; } static ssize_t mm_stat_show(struct device *dev, struct device_attribute *attr, char *buf) { struct zram *zram = dev_to_zram(dev); u64 orig_size, mem_used = 0; long max_used; ssize_t ret; down_read(&zram->init_lock); if (init_done(zram)) mem_used = zs_get_total_pages(zram->meta->mem_pool); orig_size = atomic64_read(&zram->stats.pages_stored); max_used = atomic_long_read(&zram->stats.max_used_pages); ret = scnprintf(buf, PAGE_SIZE, "%8llu %8llu %8llu %8lu %8ld %8llu %8llu\n", orig_size << PAGE_SHIFT, (u64)atomic64_read(&zram->stats.compr_data_size), mem_used << PAGE_SHIFT, zram->limit_pages << PAGE_SHIFT, max_used << PAGE_SHIFT, (u64)atomic64_read(&zram->stats.zero_pages), (u64)atomic64_read(&zram->stats.num_migrated)); up_read(&zram->init_lock); return ret; } static DEVICE_ATTR_RO(io_stat); static DEVICE_ATTR_RO(mm_stat); ZRAM_ATTR_RO(num_reads); ZRAM_ATTR_RO(num_writes); ZRAM_ATTR_RO(failed_reads); ZRAM_ATTR_RO(failed_writes); ZRAM_ATTR_RO(invalid_io); ZRAM_ATTR_RO(notify_free); ZRAM_ATTR_RO(zero_pages); ZRAM_ATTR_RO(compr_data_size); static inline bool zram_meta_get(struct zram *zram) { if (atomic_inc_not_zero(&zram->refcount)) return true; return false; } static inline void zram_meta_put(struct zram *zram) { atomic_dec(&zram->refcount); } static void zram_meta_free(struct zram_meta *meta, u64 disksize) { size_t num_pages = disksize >> PAGE_SHIFT; size_t index; /* Free all pages that are still in this zram device */ for (index = 0; index < num_pages; index++) { unsigned long handle = meta->table[index].handle; if (!handle) continue; zs_free(meta->mem_pool, handle); } zs_destroy_pool(meta->mem_pool); vfree(meta->table); kfree(meta); } static struct zram_meta *zram_meta_alloc(int device_id, u64 disksize) { size_t num_pages; char pool_name[8]; struct zram_meta *meta = kmalloc(sizeof(*meta), GFP_KERNEL); if (!meta) return NULL; num_pages = disksize >> PAGE_SHIFT; meta->table = vzalloc(num_pages * sizeof(*meta->table)); if (!meta->table) { pr_err("Error allocating zram address table\n"); goto out_error; } snprintf(pool_name, sizeof(pool_name), "zram%d", device_id); meta->mem_pool = zs_create_pool(pool_name, GFP_NOIO | __GFP_HIGHMEM); if (!meta->mem_pool) { pr_err("Error creating memory pool\n"); goto out_error; } return meta; out_error: vfree(meta->table); kfree(meta); return NULL; } /* * To protect concurrent access to the same index entry, * caller should hold this table index entry's bit_spinlock to * indicate this index entry is accessing. */ static void zram_free_page(struct zram *zram, size_t index) { struct zram_meta *meta = zram->meta; unsigned long handle = meta->table[index].handle; if (unlikely(!handle)) { /* * No memory is allocated for zero filled pages. * Simply clear zero page flag. */ if (zram_test_flag(meta, index, ZRAM_ZERO)) { zram_clear_flag(meta, index, ZRAM_ZERO); atomic64_dec(&zram->stats.zero_pages); } return; } zs_free(meta->mem_pool, handle); atomic64_sub(zram_get_obj_size(meta, index), &zram->stats.compr_data_size); atomic64_dec(&zram->stats.pages_stored); meta->table[index].handle = 0; zram_set_obj_size(meta, index, 0); } static int zram_decompress_page(struct zram *zram, char *mem, u32 index) { int ret = 0; unsigned char *cmem; struct zram_meta *meta = zram->meta; unsigned long handle; size_t size; bit_spin_lock(ZRAM_ACCESS, &meta->table[index].value); handle = meta->table[index].handle; size = zram_get_obj_size(meta, index); if (!handle || zram_test_flag(meta, index, ZRAM_ZERO)) { bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); clear_page(mem); return 0; } cmem = zs_map_object(meta->mem_pool, handle, ZS_MM_RO); if (size == PAGE_SIZE) copy_page(mem, cmem); else ret = zcomp_decompress(zram->comp, cmem, size, mem); zs_unmap_object(meta->mem_pool, handle); bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); /* Should NEVER happen. Return bio error if it does. */ if (unlikely(ret)) { pr_err("Decompression failed! err=%d, page=%u\n", ret, index); return ret; } return 0; } static int zram_bvec_read(struct zram *zram, struct bio_vec *bvec, u32 index, int offset) { int ret; struct page *page; unsigned char *user_mem, *uncmem = NULL; struct zram_meta *meta = zram->meta; page = bvec->bv_page; bit_spin_lock(ZRAM_ACCESS, &meta->table[index].value); if (unlikely(!meta->table[index].handle) || zram_test_flag(meta, index, ZRAM_ZERO)) { bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); handle_zero_page(bvec); return 0; } bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); if (is_partial_io(bvec)) /* Use a temporary buffer to decompress the page */ uncmem = kmalloc(PAGE_SIZE, GFP_NOIO); user_mem = kmap_atomic(page); if (!is_partial_io(bvec)) uncmem = user_mem; if (!uncmem) { pr_info("Unable to allocate temp memory\n"); ret = -ENOMEM; goto out_cleanup; } ret = zram_decompress_page(zram, uncmem, index); /* Should NEVER happen. Return bio error if it does. */ if (unlikely(ret)) goto out_cleanup; if (is_partial_io(bvec)) memcpy(user_mem + bvec->bv_offset, uncmem + offset, bvec->bv_len); flush_dcache_page(page); ret = 0; out_cleanup: kunmap_atomic(user_mem); if (is_partial_io(bvec)) kfree(uncmem); return ret; } static int zram_bvec_write(struct zram *zram, struct bio_vec *bvec, u32 index, int offset) { int ret = 0; size_t clen; unsigned long handle; struct page *page; unsigned char *user_mem, *cmem, *src, *uncmem = NULL; struct zram_meta *meta = zram->meta; struct zcomp_strm *zstrm; bool locked = false; unsigned long alloced_pages; page = bvec->bv_page; if (is_partial_io(bvec)) { /* * This is a partial IO. We need to read the full page * before to write the changes. */ uncmem = kmalloc(PAGE_SIZE, GFP_NOIO); if (!uncmem) { ret = -ENOMEM; goto out; } ret = zram_decompress_page(zram, uncmem, index); if (ret) goto out; } zstrm = zcomp_strm_find(zram->comp); locked = true; user_mem = kmap_atomic(page); if (is_partial_io(bvec)) { memcpy(uncmem + offset, user_mem + bvec->bv_offset, bvec->bv_len); kunmap_atomic(user_mem); user_mem = NULL; } else { uncmem = user_mem; } if (page_zero_filled(uncmem)) { if (user_mem) kunmap_atomic(user_mem); /* Free memory associated with this sector now. */ bit_spin_lock(ZRAM_ACCESS, &meta->table[index].value); zram_free_page(zram, index); zram_set_flag(meta, index, ZRAM_ZERO); bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); atomic64_inc(&zram->stats.zero_pages); ret = 0; goto out; } ret = zcomp_compress(zram->comp, zstrm, uncmem, &clen); if (!is_partial_io(bvec)) { kunmap_atomic(user_mem); user_mem = NULL; uncmem = NULL; } if (unlikely(ret)) { pr_err("Compression failed! err=%d\n", ret); goto out; } src = zstrm->buffer; if (unlikely(clen > max_zpage_size)) { clen = PAGE_SIZE; if (is_partial_io(bvec)) src = uncmem; } handle = zs_malloc(meta->mem_pool, clen); if (!handle) { pr_info("Error allocating memory for compressed page: %u, size=%zu\n", index, clen); ret = -ENOMEM; goto out; } alloced_pages = zs_get_total_pages(meta->mem_pool); if (zram->limit_pages && alloced_pages > zram->limit_pages) { zs_free(meta->mem_pool, handle); ret = -ENOMEM; goto out; } update_used_max(zram, alloced_pages); cmem = zs_map_object(meta->mem_pool, handle, ZS_MM_WO); if ((clen == PAGE_SIZE) && !is_partial_io(bvec)) { src = kmap_atomic(page); copy_page(cmem, src); kunmap_atomic(src); } else { memcpy(cmem, src, clen); } zcomp_strm_release(zram->comp, zstrm); locked = false; zs_unmap_object(meta->mem_pool, handle); /* * Free memory associated with this sector * before overwriting unused sectors. */ bit_spin_lock(ZRAM_ACCESS, &meta->table[index].value); zram_free_page(zram, index); meta->table[index].handle = handle; zram_set_obj_size(meta, index, clen); bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); /* Update stats */ atomic64_add(clen, &zram->stats.compr_data_size); atomic64_inc(&zram->stats.pages_stored); out: if (locked) zcomp_strm_release(zram->comp, zstrm); if (is_partial_io(bvec)) kfree(uncmem); return ret; } /* * zram_bio_discard - handler on discard request * @index: physical block index in PAGE_SIZE units * @offset: byte offset within physical block */ static void zram_bio_discard(struct zram *zram, u32 index, int offset, struct bio *bio) { size_t n = bio->bi_iter.bi_size; struct zram_meta *meta = zram->meta; /* * zram manages data in physical block size units. Because logical block * size isn't identical with physical block size on some arch, we * could get a discard request pointing to a specific offset within a * certain physical block. Although we can handle this request by * reading that physiclal block and decompressing and partially zeroing * and re-compressing and then re-storing it, this isn't reasonable * because our intent with a discard request is to save memory. So * skipping this logical block is appropriate here. */ if (offset) { if (n <= (PAGE_SIZE - offset)) return; n -= (PAGE_SIZE - offset); index++; } while (n >= PAGE_SIZE) { bit_spin_lock(ZRAM_ACCESS, &meta->table[index].value); zram_free_page(zram, index); bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); atomic64_inc(&zram->stats.notify_free); index++; n -= PAGE_SIZE; } } static int zram_bvec_rw(struct zram *zram, struct bio_vec *bvec, u32 index, int offset, int rw) { unsigned long start_time = jiffies; int ret; generic_start_io_acct(rw, bvec->bv_len >> SECTOR_SHIFT, &zram->disk->part0); if (rw == READ) { atomic64_inc(&zram->stats.num_reads); ret = zram_bvec_read(zram, bvec, index, offset); } else { atomic64_inc(&zram->stats.num_writes); ret = zram_bvec_write(zram, bvec, index, offset); } generic_end_io_acct(rw, &zram->disk->part0, start_time); if (unlikely(ret)) { if (rw == READ) atomic64_inc(&zram->stats.failed_reads); else atomic64_inc(&zram->stats.failed_writes); } return ret; } static void __zram_make_request(struct zram *zram, struct bio *bio) { int offset, rw; u32 index; struct bio_vec bvec; struct bvec_iter iter; index = bio->bi_iter.bi_sector >> SECTORS_PER_PAGE_SHIFT; offset = (bio->bi_iter.bi_sector & (SECTORS_PER_PAGE - 1)) << SECTOR_SHIFT; if (unlikely(bio->bi_rw & REQ_DISCARD)) { zram_bio_discard(zram, index, offset, bio); bio_endio(bio, 0); return; } rw = bio_data_dir(bio); bio_for_each_segment(bvec, bio, iter) { int max_transfer_size = PAGE_SIZE - offset; if (bvec.bv_len > max_transfer_size) { /* * zram_bvec_rw() can only make operation on a single * zram page. Split the bio vector. */ struct bio_vec bv; bv.bv_page = bvec.bv_page; bv.bv_len = max_transfer_size; bv.bv_offset = bvec.bv_offset; if (zram_bvec_rw(zram, &bv, index, offset, rw) < 0) goto out; bv.bv_len = bvec.bv_len - max_transfer_size; bv.bv_offset += max_transfer_size; if (zram_bvec_rw(zram, &bv, index + 1, 0, rw) < 0) goto out; } else if (zram_bvec_rw(zram, &bvec, index, offset, rw) < 0) goto out; update_position(&index, &offset, &bvec); } set_bit(BIO_UPTODATE, &bio->bi_flags); bio_endio(bio, 0); return; out: bio_io_error(bio); } /* * Handler function for all zram I/O requests. */ static void zram_make_request(struct request_queue *queue, struct bio *bio) { struct zram *zram = queue->queuedata; if (unlikely(!zram_meta_get(zram))) goto error; if (!valid_io_request(zram, bio->bi_iter.bi_sector, bio->bi_iter.bi_size)) { atomic64_inc(&zram->stats.invalid_io); goto put_zram; } __zram_make_request(zram, bio); zram_meta_put(zram); return; put_zram: zram_meta_put(zram); error: bio_io_error(bio); } static void zram_slot_free_notify(struct block_device *bdev, unsigned long index) { struct zram *zram; struct zram_meta *meta; zram = bdev->bd_disk->private_data; meta = zram->meta; bit_spin_lock(ZRAM_ACCESS, &meta->table[index].value); zram_free_page(zram, index); bit_spin_unlock(ZRAM_ACCESS, &meta->table[index].value); atomic64_inc(&zram->stats.notify_free); } static int zram_rw_page(struct block_device *bdev, sector_t sector, struct page *page, int rw) { int offset, err = -EIO; u32 index; struct zram *zram; struct bio_vec bv; zram = bdev->bd_disk->private_data; if (unlikely(!zram_meta_get(zram))) goto out; if (!valid_io_request(zram, sector, PAGE_SIZE)) { atomic64_inc(&zram->stats.invalid_io); err = -EINVAL; goto put_zram; } index = sector >> SECTORS_PER_PAGE_SHIFT; offset = sector & (SECTORS_PER_PAGE - 1) << SECTOR_SHIFT; bv.bv_page = page; bv.bv_len = PAGE_SIZE; bv.bv_offset = 0; err = zram_bvec_rw(zram, &bv, index, offset, rw); put_zram: zram_meta_put(zram); out: /* * If I/O fails, just return error(ie, non-zero) without * calling page_endio. * It causes resubmit the I/O with bio request by upper functions * of rw_page(e.g., swap_readpage, __swap_writepage) and * bio->bi_end_io does things to handle the error * (e.g., SetPageError, set_page_dirty and extra works). */ if (err == 0) page_endio(page, rw, 0); return err; } static void zram_reset_device(struct zram *zram) { struct zram_meta *meta; struct zcomp *comp; u64 disksize; down_write(&zram->init_lock); zram->limit_pages = 0; if (!init_done(zram)) { up_write(&zram->init_lock); return; } meta = zram->meta; comp = zram->comp; disksize = zram->disksize; /* * Refcount will go down to 0 eventually and r/w handler * cannot handle further I/O so it will bail out by * check zram_meta_get. */ zram_meta_put(zram); /* * We want to free zram_meta in process context to avoid * deadlock between reclaim path and any other locks. */ wait_event(zram->io_done, atomic_read(&zram->refcount) == 0); /* Reset stats */ memset(&zram->stats, 0, sizeof(zram->stats)); zram->disksize = 0; zram->max_comp_streams = 1; set_capacity(zram->disk, 0); part_stat_set_all(&zram->disk->part0, 0); up_write(&zram->init_lock); /* I/O operation under all of CPU are done so let's free */ zram_meta_free(meta, disksize); zcomp_destroy(comp); } static ssize_t disksize_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t len) { u64 disksize; struct zcomp *comp; struct zram_meta *meta; struct zram *zram = dev_to_zram(dev); int err; disksize = memparse(buf, NULL); if (!disksize) return -EINVAL; disksize = PAGE_ALIGN(disksize); meta = zram_meta_alloc(zram->disk->first_minor, disksize); if (!meta) return -ENOMEM; comp = zcomp_create(zram->compressor, zram->max_comp_streams); if (IS_ERR(comp)) { pr_info("Cannot initialise %s compressing backend\n", zram->compressor); err = PTR_ERR(comp); goto out_free_meta; } down_write(&zram->init_lock); if (init_done(zram)) { pr_info("Cannot change disksize for initialized device\n"); err = -EBUSY; goto out_destroy_comp; } init_waitqueue_head(&zram->io_done); atomic_set(&zram->refcount, 1); zram->meta = meta; zram->comp = comp; zram->disksize = disksize; set_capacity(zram->disk, zram->disksize >> SECTOR_SHIFT); up_write(&zram->init_lock); /* * Revalidate disk out of the init_lock to avoid lockdep splat. * It's okay because disk's capacity is protected by init_lock * so that revalidate_disk always sees up-to-date capacity. */ revalidate_disk(zram->disk); return len; out_destroy_comp: up_write(&zram->init_lock); zcomp_destroy(comp); out_free_meta: zram_meta_free(meta, disksize); return err; } static ssize_t reset_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t len) { int ret; unsigned short do_reset; struct zram *zram; struct block_device *bdev; zram = dev_to_zram(dev); bdev = bdget_disk(zram->disk, 0); if (!bdev) return -ENOMEM; mutex_lock(&bdev->bd_mutex); /* Do not reset an active device! */ if (bdev->bd_openers) { ret = -EBUSY; goto out; } ret = kstrtou16(buf, 10, &do_reset); if (ret) goto out; if (!do_reset) { ret = -EINVAL; goto out; } /* Make sure all pending I/O is finished */ fsync_bdev(bdev); zram_reset_device(zram); mutex_unlock(&bdev->bd_mutex); revalidate_disk(zram->disk); bdput(bdev); return len; out: mutex_unlock(&bdev->bd_mutex); bdput(bdev); return ret; } static const struct block_device_operations zram_devops = { .swap_slot_free_notify = zram_slot_free_notify, .rw_page = zram_rw_page, .owner = THIS_MODULE }; static DEVICE_ATTR_WO(compact); static DEVICE_ATTR_RW(disksize); static DEVICE_ATTR_RO(initstate); static DEVICE_ATTR_WO(reset); static DEVICE_ATTR_RO(orig_data_size); static DEVICE_ATTR_RO(mem_used_total); static DEVICE_ATTR_RW(mem_limit); static DEVICE_ATTR_RW(mem_used_max); static DEVICE_ATTR_RW(max_comp_streams); static DEVICE_ATTR_RW(comp_algorithm); static struct attribute *zram_disk_attrs[] = { &dev_attr_disksize.attr, &dev_attr_initstate.attr, &dev_attr_reset.attr, &dev_attr_num_reads.attr, &dev_attr_num_writes.attr, &dev_attr_failed_reads.attr, &dev_attr_failed_writes.attr, &dev_attr_compact.attr, &dev_attr_invalid_io.attr, &dev_attr_notify_free.attr, &dev_attr_zero_pages.attr, &dev_attr_orig_data_size.attr, &dev_attr_compr_data_size.attr, &dev_attr_mem_used_total.attr, &dev_attr_mem_limit.attr, &dev_attr_mem_used_max.attr, &dev_attr_max_comp_streams.attr, &dev_attr_comp_algorithm.attr, &dev_attr_io_stat.attr, &dev_attr_mm_stat.attr, NULL, }; static struct attribute_group zram_disk_attr_group = { .attrs = zram_disk_attrs, }; /* * Allocate and initialize new zram device. the function returns * '>= 0' device_id upon success, and negative value otherwise. */ static int zram_add(void) { struct zram *zram; struct request_queue *queue; int ret, device_id; zram = kzalloc(sizeof(struct zram), GFP_KERNEL); if (!zram) return -ENOMEM; ret = idr_alloc(&zram_index_idr, zram, 0, 0, GFP_KERNEL); if (ret < 0) goto out_free_dev; device_id = ret; init_rwsem(&zram->init_lock); queue = blk_alloc_queue(GFP_KERNEL); if (!queue) { pr_err("Error allocating disk queue for device %d\n", device_id); ret = -ENOMEM; goto out_free_idr; } blk_queue_make_request(queue, zram_make_request); /* gendisk structure */ zram->disk = alloc_disk(1); if (!zram->disk) { pr_warn("Error allocating disk structure for device %d\n", device_id); ret = -ENOMEM; goto out_free_queue; } zram->disk->major = zram_major; zram->disk->first_minor = device_id; zram->disk->fops = &zram_devops; zram->disk->queue = queue; zram->disk->queue->queuedata = zram; zram->disk->private_data = zram; snprintf(zram->disk->disk_name, 16, "zram%d", device_id); /* Actual capacity set using syfs (/sys/block/zram/disksize */ set_capacity(zram->disk, 0); /* zram devices sort of resembles non-rotational disks */ queue_flag_set_unlocked(QUEUE_FLAG_NONROT, zram->disk->queue); queue_flag_clear_unlocked(QUEUE_FLAG_ADD_RANDOM, zram->disk->queue); /* * To ensure that we always get PAGE_SIZE aligned * and n*PAGE_SIZED sized I/O requests. */ blk_queue_physical_block_size(zram->disk->queue, PAGE_SIZE); blk_queue_logical_block_size(zram->disk->queue, ZRAM_LOGICAL_BLOCK_SIZE); blk_queue_io_min(zram->disk->queue, PAGE_SIZE); blk_queue_io_opt(zram->disk->queue, PAGE_SIZE); zram->disk->queue->limits.discard_granularity = PAGE_SIZE; zram->disk->queue->limits.max_discard_sectors = UINT_MAX; /* * zram_bio_discard() will clear all logical blocks if logical block * size is identical with physical block size(PAGE_SIZE). But if it is * different, we will skip discarding some parts of logical blocks in * the part of the request range which isn't aligned to physical block * size. So we can't ensure that all discarded logical blocks are * zeroed. */ if (ZRAM_LOGICAL_BLOCK_SIZE == PAGE_SIZE) zram->disk->queue->limits.discard_zeroes_data = 1; else zram->disk->queue->limits.discard_zeroes_data = 0; queue_flag_set_unlocked(QUEUE_FLAG_DISCARD, zram->disk->queue); add_disk(zram->disk); ret = sysfs_create_group(&disk_to_dev(zram->disk)->kobj, &zram_disk_attr_group); if (ret < 0) { pr_warn("Error creating sysfs group"); goto out_free_disk; } strlcpy(zram->compressor, default_compressor, sizeof(zram->compressor)); zram->meta = NULL; zram->max_comp_streams = 1; pr_info("Added device: %s\n", zram->disk->disk_name); return device_id; out_free_disk: del_gendisk(zram->disk); put_disk(zram->disk); out_free_queue: blk_cleanup_queue(queue); out_free_idr: idr_remove(&zram_index_idr, device_id); out_free_dev: kfree(zram); return ret; } static void zram_remove(struct zram *zram) { pr_info("Removed device: %s\n", zram->disk->disk_name); /* * Remove sysfs first, so no one will perform a disksize * store while we destroy the devices */ sysfs_remove_group(&disk_to_dev(zram->disk)->kobj, &zram_disk_attr_group); zram_reset_device(zram); idr_remove(&zram_index_idr, zram->disk->first_minor); blk_cleanup_queue(zram->disk->queue); del_gendisk(zram->disk); put_disk(zram->disk); kfree(zram); } static int zram_remove_cb(int id, void *ptr, void *data) { zram_remove(ptr); return 0; } static void destroy_devices(void) { idr_for_each(&zram_index_idr, &zram_remove_cb, NULL); idr_destroy(&zram_index_idr); unregister_blkdev(zram_major, "zram"); } static int __init zram_init(void) { int ret; zram_major = register_blkdev(0, "zram"); if (zram_major <= 0) { pr_warn("Unable to get major number\n"); return -EBUSY; } while (num_devices != 0) { ret = zram_add(); if (ret < 0) goto out_error; num_devices--; } return 0; out_error: destroy_devices(); return ret; } static void __exit zram_exit(void) { destroy_devices(); } module_init(zram_init); module_exit(zram_exit); module_param(num_devices, uint, 0); MODULE_PARM_DESC(num_devices, "Number of pre-created zram devices"); MODULE_LICENSE("Dual BSD/GPL"); MODULE_AUTHOR("Nitin Gupta "); MODULE_DESCRIPTION("Compressed RAM Block Device");