kernel-fxtec-pro1x/drivers/lightnvm/rrpc.c
Matias Bjørling 7386af270c lightnvm: remove linear and device addr modes
The linear and device specific address modes can be replaced with a
simple offset and bit length conversion that is generic across all
devices.

This both simplifies the specification and removes the special case for
qemu nvme, that previously relied on the linear address mapping.

Signed-off-by: Matias Bjørling <m@bjorling.me>
Signed-off-by: Jens Axboe <axboe@fb.com>
2015-11-16 15:20:34 -07:00

1354 lines
31 KiB
C

/*
* Copyright (C) 2015 IT University of Copenhagen
* Initial release: Matias Bjorling <m@bjorling.me>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License version
* 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* Implementation of a Round-robin page-based Hybrid FTL for Open-channel SSDs.
*/
#include "rrpc.h"
static struct kmem_cache *rrpc_gcb_cache, *rrpc_rq_cache;
static DECLARE_RWSEM(rrpc_lock);
static int rrpc_submit_io(struct rrpc *rrpc, struct bio *bio,
struct nvm_rq *rqd, unsigned long flags);
#define rrpc_for_each_lun(rrpc, rlun, i) \
for ((i) = 0, rlun = &(rrpc)->luns[0]; \
(i) < (rrpc)->nr_luns; (i)++, rlun = &(rrpc)->luns[(i)])
static void rrpc_page_invalidate(struct rrpc *rrpc, struct rrpc_addr *a)
{
struct rrpc_block *rblk = a->rblk;
unsigned int pg_offset;
lockdep_assert_held(&rrpc->rev_lock);
if (a->addr == ADDR_EMPTY || !rblk)
return;
spin_lock(&rblk->lock);
div_u64_rem(a->addr, rrpc->dev->pgs_per_blk, &pg_offset);
WARN_ON(test_and_set_bit(pg_offset, rblk->invalid_pages));
rblk->nr_invalid_pages++;
spin_unlock(&rblk->lock);
rrpc->rev_trans_map[a->addr - rrpc->poffset].addr = ADDR_EMPTY;
}
static void rrpc_invalidate_range(struct rrpc *rrpc, sector_t slba,
unsigned len)
{
sector_t i;
spin_lock(&rrpc->rev_lock);
for (i = slba; i < slba + len; i++) {
struct rrpc_addr *gp = &rrpc->trans_map[i];
rrpc_page_invalidate(rrpc, gp);
gp->rblk = NULL;
}
spin_unlock(&rrpc->rev_lock);
}
static struct nvm_rq *rrpc_inflight_laddr_acquire(struct rrpc *rrpc,
sector_t laddr, unsigned int pages)
{
struct nvm_rq *rqd;
struct rrpc_inflight_rq *inf;
rqd = mempool_alloc(rrpc->rq_pool, GFP_ATOMIC);
if (!rqd)
return ERR_PTR(-ENOMEM);
inf = rrpc_get_inflight_rq(rqd);
if (rrpc_lock_laddr(rrpc, laddr, pages, inf)) {
mempool_free(rqd, rrpc->rq_pool);
return NULL;
}
return rqd;
}
static void rrpc_inflight_laddr_release(struct rrpc *rrpc, struct nvm_rq *rqd)
{
struct rrpc_inflight_rq *inf = rrpc_get_inflight_rq(rqd);
rrpc_unlock_laddr(rrpc, inf);
mempool_free(rqd, rrpc->rq_pool);
}
static void rrpc_discard(struct rrpc *rrpc, struct bio *bio)
{
sector_t slba = bio->bi_iter.bi_sector / NR_PHY_IN_LOG;
sector_t len = bio->bi_iter.bi_size / RRPC_EXPOSED_PAGE_SIZE;
struct nvm_rq *rqd;
do {
rqd = rrpc_inflight_laddr_acquire(rrpc, slba, len);
schedule();
} while (!rqd);
if (IS_ERR(rqd)) {
pr_err("rrpc: unable to acquire inflight IO\n");
bio_io_error(bio);
return;
}
rrpc_invalidate_range(rrpc, slba, len);
rrpc_inflight_laddr_release(rrpc, rqd);
}
static int block_is_full(struct rrpc *rrpc, struct rrpc_block *rblk)
{
return (rblk->next_page == rrpc->dev->pgs_per_blk);
}
static u64 block_to_addr(struct rrpc *rrpc, struct rrpc_block *rblk)
{
struct nvm_block *blk = rblk->parent;
return blk->id * rrpc->dev->pgs_per_blk;
}
static struct ppa_addr linear_to_generic_addr(struct nvm_dev *dev,
struct ppa_addr r)
{
struct ppa_addr l;
int secs, pgs, blks, luns;
sector_t ppa = r.ppa;
l.ppa = 0;
div_u64_rem(ppa, dev->sec_per_pg, &secs);
l.g.sec = secs;
sector_div(ppa, dev->sec_per_pg);
div_u64_rem(ppa, dev->sec_per_blk, &pgs);
l.g.pg = pgs;
sector_div(ppa, dev->pgs_per_blk);
div_u64_rem(ppa, dev->blks_per_lun, &blks);
l.g.blk = blks;
sector_div(ppa, dev->blks_per_lun);
div_u64_rem(ppa, dev->luns_per_chnl, &luns);
l.g.lun = luns;
sector_div(ppa, dev->luns_per_chnl);
l.g.ch = ppa;
return l;
}
static struct ppa_addr rrpc_ppa_to_gaddr(struct nvm_dev *dev, u64 addr)
{
struct ppa_addr paddr;
paddr.ppa = addr;
return linear_to_generic_addr(dev, paddr);
}
/* requires lun->lock taken */
static void rrpc_set_lun_cur(struct rrpc_lun *rlun, struct rrpc_block *rblk)
{
struct rrpc *rrpc = rlun->rrpc;
BUG_ON(!rblk);
if (rlun->cur) {
spin_lock(&rlun->cur->lock);
WARN_ON(!block_is_full(rrpc, rlun->cur));
spin_unlock(&rlun->cur->lock);
}
rlun->cur = rblk;
}
static struct rrpc_block *rrpc_get_blk(struct rrpc *rrpc, struct rrpc_lun *rlun,
unsigned long flags)
{
struct nvm_block *blk;
struct rrpc_block *rblk;
blk = nvm_get_blk(rrpc->dev, rlun->parent, 0);
if (!blk)
return NULL;
rblk = &rlun->blocks[blk->id];
blk->priv = rblk;
bitmap_zero(rblk->invalid_pages, rrpc->dev->pgs_per_blk);
rblk->next_page = 0;
rblk->nr_invalid_pages = 0;
atomic_set(&rblk->data_cmnt_size, 0);
return rblk;
}
static void rrpc_put_blk(struct rrpc *rrpc, struct rrpc_block *rblk)
{
nvm_put_blk(rrpc->dev, rblk->parent);
}
static struct rrpc_lun *get_next_lun(struct rrpc *rrpc)
{
int next = atomic_inc_return(&rrpc->next_lun);
return &rrpc->luns[next % rrpc->nr_luns];
}
static void rrpc_gc_kick(struct rrpc *rrpc)
{
struct rrpc_lun *rlun;
unsigned int i;
for (i = 0; i < rrpc->nr_luns; i++) {
rlun = &rrpc->luns[i];
queue_work(rrpc->krqd_wq, &rlun->ws_gc);
}
}
/*
* timed GC every interval.
*/
static void rrpc_gc_timer(unsigned long data)
{
struct rrpc *rrpc = (struct rrpc *)data;
rrpc_gc_kick(rrpc);
mod_timer(&rrpc->gc_timer, jiffies + msecs_to_jiffies(10));
}
static void rrpc_end_sync_bio(struct bio *bio)
{
struct completion *waiting = bio->bi_private;
if (bio->bi_error)
pr_err("nvm: gc request failed (%u).\n", bio->bi_error);
complete(waiting);
}
/*
* rrpc_move_valid_pages -- migrate live data off the block
* @rrpc: the 'rrpc' structure
* @block: the block from which to migrate live pages
*
* Description:
* GC algorithms may call this function to migrate remaining live
* pages off the block prior to erasing it. This function blocks
* further execution until the operation is complete.
*/
static int rrpc_move_valid_pages(struct rrpc *rrpc, struct rrpc_block *rblk)
{
struct request_queue *q = rrpc->dev->q;
struct rrpc_rev_addr *rev;
struct nvm_rq *rqd;
struct bio *bio;
struct page *page;
int slot;
int nr_pgs_per_blk = rrpc->dev->pgs_per_blk;
u64 phys_addr;
DECLARE_COMPLETION_ONSTACK(wait);
if (bitmap_full(rblk->invalid_pages, nr_pgs_per_blk))
return 0;
bio = bio_alloc(GFP_NOIO, 1);
if (!bio) {
pr_err("nvm: could not alloc bio to gc\n");
return -ENOMEM;
}
page = mempool_alloc(rrpc->page_pool, GFP_NOIO);
while ((slot = find_first_zero_bit(rblk->invalid_pages,
nr_pgs_per_blk)) < nr_pgs_per_blk) {
/* Lock laddr */
phys_addr = (rblk->parent->id * nr_pgs_per_blk) + slot;
try:
spin_lock(&rrpc->rev_lock);
/* Get logical address from physical to logical table */
rev = &rrpc->rev_trans_map[phys_addr - rrpc->poffset];
/* already updated by previous regular write */
if (rev->addr == ADDR_EMPTY) {
spin_unlock(&rrpc->rev_lock);
continue;
}
rqd = rrpc_inflight_laddr_acquire(rrpc, rev->addr, 1);
if (IS_ERR_OR_NULL(rqd)) {
spin_unlock(&rrpc->rev_lock);
schedule();
goto try;
}
spin_unlock(&rrpc->rev_lock);
/* Perform read to do GC */
bio->bi_iter.bi_sector = rrpc_get_sector(rev->addr);
bio->bi_rw = READ;
bio->bi_private = &wait;
bio->bi_end_io = rrpc_end_sync_bio;
/* TODO: may fail when EXP_PG_SIZE > PAGE_SIZE */
bio_add_pc_page(q, bio, page, RRPC_EXPOSED_PAGE_SIZE, 0);
if (rrpc_submit_io(rrpc, bio, rqd, NVM_IOTYPE_GC)) {
pr_err("rrpc: gc read failed.\n");
rrpc_inflight_laddr_release(rrpc, rqd);
goto finished;
}
wait_for_completion_io(&wait);
bio_reset(bio);
reinit_completion(&wait);
bio->bi_iter.bi_sector = rrpc_get_sector(rev->addr);
bio->bi_rw = WRITE;
bio->bi_private = &wait;
bio->bi_end_io = rrpc_end_sync_bio;
bio_add_pc_page(q, bio, page, RRPC_EXPOSED_PAGE_SIZE, 0);
/* turn the command around and write the data back to a new
* address
*/
if (rrpc_submit_io(rrpc, bio, rqd, NVM_IOTYPE_GC)) {
pr_err("rrpc: gc write failed.\n");
rrpc_inflight_laddr_release(rrpc, rqd);
goto finished;
}
wait_for_completion_io(&wait);
rrpc_inflight_laddr_release(rrpc, rqd);
bio_reset(bio);
}
finished:
mempool_free(page, rrpc->page_pool);
bio_put(bio);
if (!bitmap_full(rblk->invalid_pages, nr_pgs_per_blk)) {
pr_err("nvm: failed to garbage collect block\n");
return -EIO;
}
return 0;
}
static void rrpc_block_gc(struct work_struct *work)
{
struct rrpc_block_gc *gcb = container_of(work, struct rrpc_block_gc,
ws_gc);
struct rrpc *rrpc = gcb->rrpc;
struct rrpc_block *rblk = gcb->rblk;
struct nvm_dev *dev = rrpc->dev;
pr_debug("nvm: block '%lu' being reclaimed\n", rblk->parent->id);
if (rrpc_move_valid_pages(rrpc, rblk))
goto done;
nvm_erase_blk(dev, rblk->parent);
rrpc_put_blk(rrpc, rblk);
done:
mempool_free(gcb, rrpc->gcb_pool);
}
/* the block with highest number of invalid pages, will be in the beginning
* of the list
*/
static struct rrpc_block *rblock_max_invalid(struct rrpc_block *ra,
struct rrpc_block *rb)
{
if (ra->nr_invalid_pages == rb->nr_invalid_pages)
return ra;
return (ra->nr_invalid_pages < rb->nr_invalid_pages) ? rb : ra;
}
/* linearly find the block with highest number of invalid pages
* requires lun->lock
*/
static struct rrpc_block *block_prio_find_max(struct rrpc_lun *rlun)
{
struct list_head *prio_list = &rlun->prio_list;
struct rrpc_block *rblock, *max;
BUG_ON(list_empty(prio_list));
max = list_first_entry(prio_list, struct rrpc_block, prio);
list_for_each_entry(rblock, prio_list, prio)
max = rblock_max_invalid(max, rblock);
return max;
}
static void rrpc_lun_gc(struct work_struct *work)
{
struct rrpc_lun *rlun = container_of(work, struct rrpc_lun, ws_gc);
struct rrpc *rrpc = rlun->rrpc;
struct nvm_lun *lun = rlun->parent;
struct rrpc_block_gc *gcb;
unsigned int nr_blocks_need;
nr_blocks_need = rrpc->dev->blks_per_lun / GC_LIMIT_INVERSE;
if (nr_blocks_need < rrpc->nr_luns)
nr_blocks_need = rrpc->nr_luns;
spin_lock(&lun->lock);
while (nr_blocks_need > lun->nr_free_blocks &&
!list_empty(&rlun->prio_list)) {
struct rrpc_block *rblock = block_prio_find_max(rlun);
struct nvm_block *block = rblock->parent;
if (!rblock->nr_invalid_pages)
break;
list_del_init(&rblock->prio);
BUG_ON(!block_is_full(rrpc, rblock));
pr_debug("rrpc: selected block '%lu' for GC\n", block->id);
gcb = mempool_alloc(rrpc->gcb_pool, GFP_ATOMIC);
if (!gcb)
break;
gcb->rrpc = rrpc;
gcb->rblk = rblock;
INIT_WORK(&gcb->ws_gc, rrpc_block_gc);
queue_work(rrpc->kgc_wq, &gcb->ws_gc);
nr_blocks_need--;
}
spin_unlock(&lun->lock);
/* TODO: Hint that request queue can be started again */
}
static void rrpc_gc_queue(struct work_struct *work)
{
struct rrpc_block_gc *gcb = container_of(work, struct rrpc_block_gc,
ws_gc);
struct rrpc *rrpc = gcb->rrpc;
struct rrpc_block *rblk = gcb->rblk;
struct nvm_lun *lun = rblk->parent->lun;
struct rrpc_lun *rlun = &rrpc->luns[lun->id - rrpc->lun_offset];
spin_lock(&rlun->lock);
list_add_tail(&rblk->prio, &rlun->prio_list);
spin_unlock(&rlun->lock);
mempool_free(gcb, rrpc->gcb_pool);
pr_debug("nvm: block '%lu' is full, allow GC (sched)\n",
rblk->parent->id);
}
static const struct block_device_operations rrpc_fops = {
.owner = THIS_MODULE,
};
static struct rrpc_lun *rrpc_get_lun_rr(struct rrpc *rrpc, int is_gc)
{
unsigned int i;
struct rrpc_lun *rlun, *max_free;
if (!is_gc)
return get_next_lun(rrpc);
/* during GC, we don't care about RR, instead we want to make
* sure that we maintain evenness between the block luns.
*/
max_free = &rrpc->luns[0];
/* prevent GC-ing lun from devouring pages of a lun with
* little free blocks. We don't take the lock as we only need an
* estimate.
*/
rrpc_for_each_lun(rrpc, rlun, i) {
if (rlun->parent->nr_free_blocks >
max_free->parent->nr_free_blocks)
max_free = rlun;
}
return max_free;
}
static struct rrpc_addr *rrpc_update_map(struct rrpc *rrpc, sector_t laddr,
struct rrpc_block *rblk, u64 paddr)
{
struct rrpc_addr *gp;
struct rrpc_rev_addr *rev;
BUG_ON(laddr >= rrpc->nr_pages);
gp = &rrpc->trans_map[laddr];
spin_lock(&rrpc->rev_lock);
if (gp->rblk)
rrpc_page_invalidate(rrpc, gp);
gp->addr = paddr;
gp->rblk = rblk;
rev = &rrpc->rev_trans_map[gp->addr - rrpc->poffset];
rev->addr = laddr;
spin_unlock(&rrpc->rev_lock);
return gp;
}
static u64 rrpc_alloc_addr(struct rrpc *rrpc, struct rrpc_block *rblk)
{
u64 addr = ADDR_EMPTY;
spin_lock(&rblk->lock);
if (block_is_full(rrpc, rblk))
goto out;
addr = block_to_addr(rrpc, rblk) + rblk->next_page;
rblk->next_page++;
out:
spin_unlock(&rblk->lock);
return addr;
}
/* Simple round-robin Logical to physical address translation.
*
* Retrieve the mapping using the active append point. Then update the ap for
* the next write to the disk.
*
* Returns rrpc_addr with the physical address and block. Remember to return to
* rrpc->addr_cache when request is finished.
*/
static struct rrpc_addr *rrpc_map_page(struct rrpc *rrpc, sector_t laddr,
int is_gc)
{
struct rrpc_lun *rlun;
struct rrpc_block *rblk;
struct nvm_lun *lun;
u64 paddr;
rlun = rrpc_get_lun_rr(rrpc, is_gc);
lun = rlun->parent;
if (!is_gc && lun->nr_free_blocks < rrpc->nr_luns * 4)
return NULL;
spin_lock(&rlun->lock);
rblk = rlun->cur;
retry:
paddr = rrpc_alloc_addr(rrpc, rblk);
if (paddr == ADDR_EMPTY) {
rblk = rrpc_get_blk(rrpc, rlun, 0);
if (rblk) {
rrpc_set_lun_cur(rlun, rblk);
goto retry;
}
if (is_gc) {
/* retry from emergency gc block */
paddr = rrpc_alloc_addr(rrpc, rlun->gc_cur);
if (paddr == ADDR_EMPTY) {
rblk = rrpc_get_blk(rrpc, rlun, 1);
if (!rblk) {
pr_err("rrpc: no more blocks");
goto err;
}
rlun->gc_cur = rblk;
paddr = rrpc_alloc_addr(rrpc, rlun->gc_cur);
}
rblk = rlun->gc_cur;
}
}
spin_unlock(&rlun->lock);
return rrpc_update_map(rrpc, laddr, rblk, paddr);
err:
spin_unlock(&rlun->lock);
return NULL;
}
static void rrpc_run_gc(struct rrpc *rrpc, struct rrpc_block *rblk)
{
struct rrpc_block_gc *gcb;
gcb = mempool_alloc(rrpc->gcb_pool, GFP_ATOMIC);
if (!gcb) {
pr_err("rrpc: unable to queue block for gc.");
return;
}
gcb->rrpc = rrpc;
gcb->rblk = rblk;
INIT_WORK(&gcb->ws_gc, rrpc_gc_queue);
queue_work(rrpc->kgc_wq, &gcb->ws_gc);
}
static void rrpc_end_io_write(struct rrpc *rrpc, struct rrpc_rq *rrqd,
sector_t laddr, uint8_t npages)
{
struct rrpc_addr *p;
struct rrpc_block *rblk;
struct nvm_lun *lun;
int cmnt_size, i;
for (i = 0; i < npages; i++) {
p = &rrpc->trans_map[laddr + i];
rblk = p->rblk;
lun = rblk->parent->lun;
cmnt_size = atomic_inc_return(&rblk->data_cmnt_size);
if (unlikely(cmnt_size == rrpc->dev->pgs_per_blk))
rrpc_run_gc(rrpc, rblk);
}
}
static int rrpc_end_io(struct nvm_rq *rqd, int error)
{
struct rrpc *rrpc = container_of(rqd->ins, struct rrpc, instance);
struct rrpc_rq *rrqd = nvm_rq_to_pdu(rqd);
uint8_t npages = rqd->nr_pages;
sector_t laddr = rrpc_get_laddr(rqd->bio) - npages;
if (bio_data_dir(rqd->bio) == WRITE)
rrpc_end_io_write(rrpc, rrqd, laddr, npages);
if (rrqd->flags & NVM_IOTYPE_GC)
return 0;
rrpc_unlock_rq(rrpc, rqd);
bio_put(rqd->bio);
if (npages > 1)
nvm_dev_dma_free(rrpc->dev, rqd->ppa_list, rqd->dma_ppa_list);
if (rqd->metadata)
nvm_dev_dma_free(rrpc->dev, rqd->metadata, rqd->dma_metadata);
mempool_free(rqd, rrpc->rq_pool);
return 0;
}
static int rrpc_read_ppalist_rq(struct rrpc *rrpc, struct bio *bio,
struct nvm_rq *rqd, unsigned long flags, int npages)
{
struct rrpc_inflight_rq *r = rrpc_get_inflight_rq(rqd);
struct rrpc_addr *gp;
sector_t laddr = rrpc_get_laddr(bio);
int is_gc = flags & NVM_IOTYPE_GC;
int i;
if (!is_gc && rrpc_lock_rq(rrpc, bio, rqd)) {
nvm_dev_dma_free(rrpc->dev, rqd->ppa_list, rqd->dma_ppa_list);
return NVM_IO_REQUEUE;
}
for (i = 0; i < npages; i++) {
/* We assume that mapping occurs at 4KB granularity */
BUG_ON(!(laddr + i >= 0 && laddr + i < rrpc->nr_pages));
gp = &rrpc->trans_map[laddr + i];
if (gp->rblk) {
rqd->ppa_list[i] = rrpc_ppa_to_gaddr(rrpc->dev,
gp->addr);
} else {
BUG_ON(is_gc);
rrpc_unlock_laddr(rrpc, r);
nvm_dev_dma_free(rrpc->dev, rqd->ppa_list,
rqd->dma_ppa_list);
return NVM_IO_DONE;
}
}
rqd->opcode = NVM_OP_HBREAD;
return NVM_IO_OK;
}
static int rrpc_read_rq(struct rrpc *rrpc, struct bio *bio, struct nvm_rq *rqd,
unsigned long flags)
{
struct rrpc_rq *rrqd = nvm_rq_to_pdu(rqd);
int is_gc = flags & NVM_IOTYPE_GC;
sector_t laddr = rrpc_get_laddr(bio);
struct rrpc_addr *gp;
if (!is_gc && rrpc_lock_rq(rrpc, bio, rqd))
return NVM_IO_REQUEUE;
BUG_ON(!(laddr >= 0 && laddr < rrpc->nr_pages));
gp = &rrpc->trans_map[laddr];
if (gp->rblk) {
rqd->ppa_addr = rrpc_ppa_to_gaddr(rrpc->dev, gp->addr);
} else {
BUG_ON(is_gc);
rrpc_unlock_rq(rrpc, rqd);
return NVM_IO_DONE;
}
rqd->opcode = NVM_OP_HBREAD;
rrqd->addr = gp;
return NVM_IO_OK;
}
static int rrpc_write_ppalist_rq(struct rrpc *rrpc, struct bio *bio,
struct nvm_rq *rqd, unsigned long flags, int npages)
{
struct rrpc_inflight_rq *r = rrpc_get_inflight_rq(rqd);
struct rrpc_addr *p;
sector_t laddr = rrpc_get_laddr(bio);
int is_gc = flags & NVM_IOTYPE_GC;
int i;
if (!is_gc && rrpc_lock_rq(rrpc, bio, rqd)) {
nvm_dev_dma_free(rrpc->dev, rqd->ppa_list, rqd->dma_ppa_list);
return NVM_IO_REQUEUE;
}
for (i = 0; i < npages; i++) {
/* We assume that mapping occurs at 4KB granularity */
p = rrpc_map_page(rrpc, laddr + i, is_gc);
if (!p) {
BUG_ON(is_gc);
rrpc_unlock_laddr(rrpc, r);
nvm_dev_dma_free(rrpc->dev, rqd->ppa_list,
rqd->dma_ppa_list);
rrpc_gc_kick(rrpc);
return NVM_IO_REQUEUE;
}
rqd->ppa_list[i] = rrpc_ppa_to_gaddr(rrpc->dev,
p->addr);
}
rqd->opcode = NVM_OP_HBWRITE;
return NVM_IO_OK;
}
static int rrpc_write_rq(struct rrpc *rrpc, struct bio *bio,
struct nvm_rq *rqd, unsigned long flags)
{
struct rrpc_rq *rrqd = nvm_rq_to_pdu(rqd);
struct rrpc_addr *p;
int is_gc = flags & NVM_IOTYPE_GC;
sector_t laddr = rrpc_get_laddr(bio);
if (!is_gc && rrpc_lock_rq(rrpc, bio, rqd))
return NVM_IO_REQUEUE;
p = rrpc_map_page(rrpc, laddr, is_gc);
if (!p) {
BUG_ON(is_gc);
rrpc_unlock_rq(rrpc, rqd);
rrpc_gc_kick(rrpc);
return NVM_IO_REQUEUE;
}
rqd->ppa_addr = rrpc_ppa_to_gaddr(rrpc->dev, p->addr);
rqd->opcode = NVM_OP_HBWRITE;
rrqd->addr = p;
return NVM_IO_OK;
}
static int rrpc_setup_rq(struct rrpc *rrpc, struct bio *bio,
struct nvm_rq *rqd, unsigned long flags, uint8_t npages)
{
if (npages > 1) {
rqd->ppa_list = nvm_dev_dma_alloc(rrpc->dev, GFP_KERNEL,
&rqd->dma_ppa_list);
if (!rqd->ppa_list) {
pr_err("rrpc: not able to allocate ppa list\n");
return NVM_IO_ERR;
}
if (bio_rw(bio) == WRITE)
return rrpc_write_ppalist_rq(rrpc, bio, rqd, flags,
npages);
return rrpc_read_ppalist_rq(rrpc, bio, rqd, flags, npages);
}
if (bio_rw(bio) == WRITE)
return rrpc_write_rq(rrpc, bio, rqd, flags);
return rrpc_read_rq(rrpc, bio, rqd, flags);
}
static int rrpc_submit_io(struct rrpc *rrpc, struct bio *bio,
struct nvm_rq *rqd, unsigned long flags)
{
int err;
struct rrpc_rq *rrq = nvm_rq_to_pdu(rqd);
uint8_t nr_pages = rrpc_get_pages(bio);
int bio_size = bio_sectors(bio) << 9;
if (bio_size < rrpc->dev->sec_size)
return NVM_IO_ERR;
else if (bio_size > rrpc->dev->max_rq_size)
return NVM_IO_ERR;
err = rrpc_setup_rq(rrpc, bio, rqd, flags, nr_pages);
if (err)
return err;
bio_get(bio);
rqd->bio = bio;
rqd->ins = &rrpc->instance;
rqd->nr_pages = nr_pages;
rrq->flags = flags;
err = nvm_submit_io(rrpc->dev, rqd);
if (err) {
pr_err("rrpc: I/O submission failed: %d\n", err);
return NVM_IO_ERR;
}
return NVM_IO_OK;
}
static blk_qc_t rrpc_make_rq(struct request_queue *q, struct bio *bio)
{
struct rrpc *rrpc = q->queuedata;
struct nvm_rq *rqd;
int err;
if (bio->bi_rw & REQ_DISCARD) {
rrpc_discard(rrpc, bio);
return BLK_QC_T_NONE;
}
rqd = mempool_alloc(rrpc->rq_pool, GFP_KERNEL);
if (!rqd) {
pr_err_ratelimited("rrpc: not able to queue bio.");
bio_io_error(bio);
return BLK_QC_T_NONE;
}
memset(rqd, 0, sizeof(struct nvm_rq));
err = rrpc_submit_io(rrpc, bio, rqd, NVM_IOTYPE_NONE);
switch (err) {
case NVM_IO_OK:
return BLK_QC_T_NONE;
case NVM_IO_ERR:
bio_io_error(bio);
break;
case NVM_IO_DONE:
bio_endio(bio);
break;
case NVM_IO_REQUEUE:
spin_lock(&rrpc->bio_lock);
bio_list_add(&rrpc->requeue_bios, bio);
spin_unlock(&rrpc->bio_lock);
queue_work(rrpc->kgc_wq, &rrpc->ws_requeue);
break;
}
mempool_free(rqd, rrpc->rq_pool);
return BLK_QC_T_NONE;
}
static void rrpc_requeue(struct work_struct *work)
{
struct rrpc *rrpc = container_of(work, struct rrpc, ws_requeue);
struct bio_list bios;
struct bio *bio;
bio_list_init(&bios);
spin_lock(&rrpc->bio_lock);
bio_list_merge(&bios, &rrpc->requeue_bios);
bio_list_init(&rrpc->requeue_bios);
spin_unlock(&rrpc->bio_lock);
while ((bio = bio_list_pop(&bios)))
rrpc_make_rq(rrpc->disk->queue, bio);
}
static void rrpc_gc_free(struct rrpc *rrpc)
{
struct rrpc_lun *rlun;
int i;
if (rrpc->krqd_wq)
destroy_workqueue(rrpc->krqd_wq);
if (rrpc->kgc_wq)
destroy_workqueue(rrpc->kgc_wq);
if (!rrpc->luns)
return;
for (i = 0; i < rrpc->nr_luns; i++) {
rlun = &rrpc->luns[i];
if (!rlun->blocks)
break;
vfree(rlun->blocks);
}
}
static int rrpc_gc_init(struct rrpc *rrpc)
{
rrpc->krqd_wq = alloc_workqueue("rrpc-lun", WQ_MEM_RECLAIM|WQ_UNBOUND,
rrpc->nr_luns);
if (!rrpc->krqd_wq)
return -ENOMEM;
rrpc->kgc_wq = alloc_workqueue("rrpc-bg", WQ_MEM_RECLAIM, 1);
if (!rrpc->kgc_wq)
return -ENOMEM;
setup_timer(&rrpc->gc_timer, rrpc_gc_timer, (unsigned long)rrpc);
return 0;
}
static void rrpc_map_free(struct rrpc *rrpc)
{
vfree(rrpc->rev_trans_map);
vfree(rrpc->trans_map);
}
static int rrpc_l2p_update(u64 slba, u32 nlb, __le64 *entries, void *private)
{
struct rrpc *rrpc = (struct rrpc *)private;
struct nvm_dev *dev = rrpc->dev;
struct rrpc_addr *addr = rrpc->trans_map + slba;
struct rrpc_rev_addr *raddr = rrpc->rev_trans_map;
sector_t max_pages = dev->total_pages * (dev->sec_size >> 9);
u64 elba = slba + nlb;
u64 i;
if (unlikely(elba > dev->total_pages)) {
pr_err("nvm: L2P data from device is out of bounds!\n");
return -EINVAL;
}
for (i = 0; i < nlb; i++) {
u64 pba = le64_to_cpu(entries[i]);
/* LNVM treats address-spaces as silos, LBA and PBA are
* equally large and zero-indexed.
*/
if (unlikely(pba >= max_pages && pba != U64_MAX)) {
pr_err("nvm: L2P data entry is out of bounds!\n");
return -EINVAL;
}
/* Address zero is a special one. The first page on a disk is
* protected. As it often holds internal device boot
* information.
*/
if (!pba)
continue;
addr[i].addr = pba;
raddr[pba].addr = slba + i;
}
return 0;
}
static int rrpc_map_init(struct rrpc *rrpc)
{
struct nvm_dev *dev = rrpc->dev;
sector_t i;
int ret;
rrpc->trans_map = vzalloc(sizeof(struct rrpc_addr) * rrpc->nr_pages);
if (!rrpc->trans_map)
return -ENOMEM;
rrpc->rev_trans_map = vmalloc(sizeof(struct rrpc_rev_addr)
* rrpc->nr_pages);
if (!rrpc->rev_trans_map)
return -ENOMEM;
for (i = 0; i < rrpc->nr_pages; i++) {
struct rrpc_addr *p = &rrpc->trans_map[i];
struct rrpc_rev_addr *r = &rrpc->rev_trans_map[i];
p->addr = ADDR_EMPTY;
r->addr = ADDR_EMPTY;
}
if (!dev->ops->get_l2p_tbl)
return 0;
/* Bring up the mapping table from device */
ret = dev->ops->get_l2p_tbl(dev->q, 0, dev->total_pages,
rrpc_l2p_update, rrpc);
if (ret) {
pr_err("nvm: rrpc: could not read L2P table.\n");
return -EINVAL;
}
return 0;
}
/* Minimum pages needed within a lun */
#define PAGE_POOL_SIZE 16
#define ADDR_POOL_SIZE 64
static int rrpc_core_init(struct rrpc *rrpc)
{
down_write(&rrpc_lock);
if (!rrpc_gcb_cache) {
rrpc_gcb_cache = kmem_cache_create("rrpc_gcb",
sizeof(struct rrpc_block_gc), 0, 0, NULL);
if (!rrpc_gcb_cache) {
up_write(&rrpc_lock);
return -ENOMEM;
}
rrpc_rq_cache = kmem_cache_create("rrpc_rq",
sizeof(struct nvm_rq) + sizeof(struct rrpc_rq),
0, 0, NULL);
if (!rrpc_rq_cache) {
kmem_cache_destroy(rrpc_gcb_cache);
up_write(&rrpc_lock);
return -ENOMEM;
}
}
up_write(&rrpc_lock);
rrpc->page_pool = mempool_create_page_pool(PAGE_POOL_SIZE, 0);
if (!rrpc->page_pool)
return -ENOMEM;
rrpc->gcb_pool = mempool_create_slab_pool(rrpc->dev->nr_luns,
rrpc_gcb_cache);
if (!rrpc->gcb_pool)
return -ENOMEM;
rrpc->rq_pool = mempool_create_slab_pool(64, rrpc_rq_cache);
if (!rrpc->rq_pool)
return -ENOMEM;
spin_lock_init(&rrpc->inflights.lock);
INIT_LIST_HEAD(&rrpc->inflights.reqs);
return 0;
}
static void rrpc_core_free(struct rrpc *rrpc)
{
mempool_destroy(rrpc->page_pool);
mempool_destroy(rrpc->gcb_pool);
mempool_destroy(rrpc->rq_pool);
}
static void rrpc_luns_free(struct rrpc *rrpc)
{
kfree(rrpc->luns);
}
static int rrpc_luns_init(struct rrpc *rrpc, int lun_begin, int lun_end)
{
struct nvm_dev *dev = rrpc->dev;
struct rrpc_lun *rlun;
int i, j;
spin_lock_init(&rrpc->rev_lock);
rrpc->luns = kcalloc(rrpc->nr_luns, sizeof(struct rrpc_lun),
GFP_KERNEL);
if (!rrpc->luns)
return -ENOMEM;
/* 1:1 mapping */
for (i = 0; i < rrpc->nr_luns; i++) {
struct nvm_lun *lun = dev->mt->get_lun(dev, lun_begin + i);
if (dev->pgs_per_blk >
MAX_INVALID_PAGES_STORAGE * BITS_PER_LONG) {
pr_err("rrpc: number of pages per block too high.");
goto err;
}
rlun = &rrpc->luns[i];
rlun->rrpc = rrpc;
rlun->parent = lun;
INIT_LIST_HEAD(&rlun->prio_list);
INIT_WORK(&rlun->ws_gc, rrpc_lun_gc);
spin_lock_init(&rlun->lock);
rrpc->total_blocks += dev->blks_per_lun;
rrpc->nr_pages += dev->sec_per_lun;
rlun->blocks = vzalloc(sizeof(struct rrpc_block) *
rrpc->dev->blks_per_lun);
if (!rlun->blocks)
goto err;
for (j = 0; j < rrpc->dev->blks_per_lun; j++) {
struct rrpc_block *rblk = &rlun->blocks[j];
struct nvm_block *blk = &lun->blocks[j];
rblk->parent = blk;
INIT_LIST_HEAD(&rblk->prio);
spin_lock_init(&rblk->lock);
}
}
return 0;
err:
return -ENOMEM;
}
static void rrpc_free(struct rrpc *rrpc)
{
rrpc_gc_free(rrpc);
rrpc_map_free(rrpc);
rrpc_core_free(rrpc);
rrpc_luns_free(rrpc);
kfree(rrpc);
}
static void rrpc_exit(void *private)
{
struct rrpc *rrpc = private;
del_timer(&rrpc->gc_timer);
flush_workqueue(rrpc->krqd_wq);
flush_workqueue(rrpc->kgc_wq);
rrpc_free(rrpc);
}
static sector_t rrpc_capacity(void *private)
{
struct rrpc *rrpc = private;
struct nvm_dev *dev = rrpc->dev;
sector_t reserved, provisioned;
/* cur, gc, and two emergency blocks for each lun */
reserved = rrpc->nr_luns * dev->max_pages_per_blk * 4;
provisioned = rrpc->nr_pages - reserved;
if (reserved > rrpc->nr_pages) {
pr_err("rrpc: not enough space available to expose storage.\n");
return 0;
}
sector_div(provisioned, 10);
return provisioned * 9 * NR_PHY_IN_LOG;
}
/*
* Looks up the logical address from reverse trans map and check if its valid by
* comparing the logical to physical address with the physical address.
* Returns 0 on free, otherwise 1 if in use
*/
static void rrpc_block_map_update(struct rrpc *rrpc, struct rrpc_block *rblk)
{
struct nvm_dev *dev = rrpc->dev;
int offset;
struct rrpc_addr *laddr;
u64 paddr, pladdr;
for (offset = 0; offset < dev->pgs_per_blk; offset++) {
paddr = block_to_addr(rrpc, rblk) + offset;
pladdr = rrpc->rev_trans_map[paddr].addr;
if (pladdr == ADDR_EMPTY)
continue;
laddr = &rrpc->trans_map[pladdr];
if (paddr == laddr->addr) {
laddr->rblk = rblk;
} else {
set_bit(offset, rblk->invalid_pages);
rblk->nr_invalid_pages++;
}
}
}
static int rrpc_blocks_init(struct rrpc *rrpc)
{
struct rrpc_lun *rlun;
struct rrpc_block *rblk;
int lun_iter, blk_iter;
for (lun_iter = 0; lun_iter < rrpc->nr_luns; lun_iter++) {
rlun = &rrpc->luns[lun_iter];
for (blk_iter = 0; blk_iter < rrpc->dev->blks_per_lun;
blk_iter++) {
rblk = &rlun->blocks[blk_iter];
rrpc_block_map_update(rrpc, rblk);
}
}
return 0;
}
static int rrpc_luns_configure(struct rrpc *rrpc)
{
struct rrpc_lun *rlun;
struct rrpc_block *rblk;
int i;
for (i = 0; i < rrpc->nr_luns; i++) {
rlun = &rrpc->luns[i];
rblk = rrpc_get_blk(rrpc, rlun, 0);
if (!rblk)
return -EINVAL;
rrpc_set_lun_cur(rlun, rblk);
/* Emergency gc block */
rblk = rrpc_get_blk(rrpc, rlun, 1);
if (!rblk)
return -EINVAL;
rlun->gc_cur = rblk;
}
return 0;
}
static struct nvm_tgt_type tt_rrpc;
static void *rrpc_init(struct nvm_dev *dev, struct gendisk *tdisk,
int lun_begin, int lun_end)
{
struct request_queue *bqueue = dev->q;
struct request_queue *tqueue = tdisk->queue;
struct rrpc *rrpc;
int ret;
if (!(dev->identity.dom & NVM_RSP_L2P)) {
pr_err("nvm: rrpc: device does not support l2p (%x)\n",
dev->identity.dom);
return ERR_PTR(-EINVAL);
}
rrpc = kzalloc(sizeof(struct rrpc), GFP_KERNEL);
if (!rrpc)
return ERR_PTR(-ENOMEM);
rrpc->instance.tt = &tt_rrpc;
rrpc->dev = dev;
rrpc->disk = tdisk;
bio_list_init(&rrpc->requeue_bios);
spin_lock_init(&rrpc->bio_lock);
INIT_WORK(&rrpc->ws_requeue, rrpc_requeue);
rrpc->nr_luns = lun_end - lun_begin + 1;
/* simple round-robin strategy */
atomic_set(&rrpc->next_lun, -1);
ret = rrpc_luns_init(rrpc, lun_begin, lun_end);
if (ret) {
pr_err("nvm: rrpc: could not initialize luns\n");
goto err;
}
rrpc->poffset = dev->sec_per_lun * lun_begin;
rrpc->lun_offset = lun_begin;
ret = rrpc_core_init(rrpc);
if (ret) {
pr_err("nvm: rrpc: could not initialize core\n");
goto err;
}
ret = rrpc_map_init(rrpc);
if (ret) {
pr_err("nvm: rrpc: could not initialize maps\n");
goto err;
}
ret = rrpc_blocks_init(rrpc);
if (ret) {
pr_err("nvm: rrpc: could not initialize state for blocks\n");
goto err;
}
ret = rrpc_luns_configure(rrpc);
if (ret) {
pr_err("nvm: rrpc: not enough blocks available in LUNs.\n");
goto err;
}
ret = rrpc_gc_init(rrpc);
if (ret) {
pr_err("nvm: rrpc: could not initialize gc\n");
goto err;
}
/* inherit the size from the underlying device */
blk_queue_logical_block_size(tqueue, queue_physical_block_size(bqueue));
blk_queue_max_hw_sectors(tqueue, queue_max_hw_sectors(bqueue));
pr_info("nvm: rrpc initialized with %u luns and %llu pages.\n",
rrpc->nr_luns, (unsigned long long)rrpc->nr_pages);
mod_timer(&rrpc->gc_timer, jiffies + msecs_to_jiffies(10));
return rrpc;
err:
rrpc_free(rrpc);
return ERR_PTR(ret);
}
/* round robin, page-based FTL, and cost-based GC */
static struct nvm_tgt_type tt_rrpc = {
.name = "rrpc",
.version = {1, 0, 0},
.make_rq = rrpc_make_rq,
.capacity = rrpc_capacity,
.end_io = rrpc_end_io,
.init = rrpc_init,
.exit = rrpc_exit,
};
static int __init rrpc_module_init(void)
{
return nvm_register_target(&tt_rrpc);
}
static void rrpc_module_exit(void)
{
nvm_unregister_target(&tt_rrpc);
}
module_init(rrpc_module_init);
module_exit(rrpc_module_exit);
MODULE_LICENSE("GPL v2");
MODULE_DESCRIPTION("Block-Device Target for Open-Channel SSDs");