/* $NetBSD: chfs_write.c,v 1.2 2011/11/24 21:09:37 agc Exp $ */ /*- * Copyright (c) 2010 Department of Software Engineering, * University of Szeged, Hungary * Copyright (C) 2010 David Tengeri * Copyright (C) 2010 Tamas Toth * Copyright (C) 2010 Adam Hoka * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by the Department of Software Engineering, University of Szeged, Hungary * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * chfs_write.c * * Created on: 2010.02.17. * Author: dtengeri */ #include #include #include "chfs.h" int chfs_write_flash_vnode(struct chfs_mount *chmp, struct chfs_inode *ip, int prio) { KASSERT(mutex_owned(&chmp->chm_lock_mountfields)); struct chfs_flash_vnode *fvnode; struct chfs_vnode_cache* chvc; struct chfs_node_ref *nref; struct iovec vec; size_t size, retlen; int err = 0, retries = 0; if (ip->ino == CHFS_ROOTINO) return 0; fvnode = chfs_alloc_flash_vnode(); if (!fvnode) return ENOMEM; chvc = ip->chvc; /* setting up flash_vnode members */ size = sizeof(*fvnode); //dbg("size: %zu | PADDED: %zu\n", size, CHFS_PAD(size)); fvnode->magic = htole16(CHFS_FS_MAGIC_BITMASK); fvnode->type = htole16(CHFS_NODETYPE_VNODE); fvnode->length = htole32(CHFS_PAD(size)); fvnode->hdr_crc = htole32(crc32(0, (uint8_t *)fvnode, CHFS_NODE_HDR_SIZE - 4)); fvnode->vno = htole64(ip->ino); fvnode->version = htole64(++ip->chvc->highest_version); fvnode->mode = htole32(ip->mode); fvnode->dn_size = htole32(ip->size); fvnode->atime = htole32(ip->atime); fvnode->ctime = htole32(ip->ctime); fvnode->mtime = htole32(ip->mtime); fvnode->gid = htole32(ip->gid); fvnode->uid = htole32(ip->uid); fvnode->node_crc = htole32(crc32(0, (uint8_t *)fvnode, size - 4)); /* write out flash_vnode */ retry: if (prio == ALLOC_GC) { /* the GC calls this function */ err = chfs_reserve_space_gc(chmp, CHFS_PAD(size)); if (err) goto out; } else { chfs_gc_trigger(chmp); if (prio == ALLOC_NORMAL) err = chfs_reserve_space_normal(chmp, CHFS_PAD(size), ALLOC_NORMAL); else err = chfs_reserve_space_normal(chmp, CHFS_PAD(size), ALLOC_DELETION); if (err) goto out; } nref = chfs_alloc_node_ref(chmp->chm_nextblock); if (!nref) { err = ENOMEM; goto out; } mutex_enter(&chmp->chm_lock_sizes); nref->nref_offset = chmp->chm_ebh->eb_size - chmp->chm_nextblock->free_size; chfs_change_size_free(chmp, chmp->chm_nextblock, -CHFS_PAD(size)); vec.iov_base = fvnode; vec.iov_len = CHFS_PAD(size); err = chfs_write_wbuf(chmp, &vec, 1, nref->nref_offset, &retlen); if (err || retlen != CHFS_PAD(size)) { chfs_err("error while writing out flash vnode to the media\n"); chfs_err("err: %d | size: %zu | retlen : %zu\n", err, CHFS_PAD(size), retlen); chfs_change_size_dirty(chmp, chmp->chm_nextblock, CHFS_PAD(size)); if (retries) { err = EIO; mutex_exit(&chmp->chm_lock_sizes); goto out; } retries++; mutex_exit(&chmp->chm_lock_sizes); goto retry; } //Everything went well chfs_change_size_used(chmp, &chmp->chm_blocks[nref->nref_lnr], CHFS_PAD(size)); mutex_exit(&chmp->chm_lock_sizes); chfs_add_vnode_ref_to_vc(chmp, chvc, nref); KASSERT(chmp->chm_blocks[nref->nref_lnr].used_size <= chmp->chm_ebh->eb_size); out: chfs_free_flash_vnode(fvnode); return err; } int chfs_write_flash_dirent(struct chfs_mount *chmp, struct chfs_inode *pdir, struct chfs_inode *ip, struct chfs_dirent *fd, ino_t ino, int prio) { KASSERT(mutex_owned(&chmp->chm_lock_mountfields)); struct chfs_flash_dirent_node *fdirent; struct chfs_node_ref *nref; struct iovec vec[2]; size_t size, retlen; int err = 0, retries = 0; uint8_t *name; size_t namelen; KASSERT(fd->vno != CHFS_ROOTINO); fdirent = chfs_alloc_flash_dirent(); if (!fdirent) return ENOMEM; size = sizeof(*fdirent) + fd->nsize; namelen = CHFS_PAD(size) - sizeof(*fdirent); name = kmem_zalloc(namelen, KM_SLEEP); memcpy(name, fd->name, fd->nsize); //dbg("namelen: %zu | nsize: %hhu\n", namelen, fd->nsize); //dbg("size: %zu | PADDED: %zu\n", size, CHFS_PAD(size)); fdirent->magic = htole16(CHFS_FS_MAGIC_BITMASK); fdirent->type = htole16(CHFS_NODETYPE_DIRENT); fdirent->length = htole32(CHFS_PAD(size)); fdirent->hdr_crc = htole32(crc32(0, (uint8_t *)fdirent, CHFS_NODE_HDR_SIZE - 4)); fdirent->vno = htole64(ino); fdirent->pvno = htole64(pdir->ino); fdirent->version = htole64(++pdir->chvc->highest_version); fdirent->mctime = ip?ip->ctime:0; fdirent->nsize = fd->nsize; fdirent->dtype = fd->type; fdirent->name_crc = crc32(0, (uint8_t *)&(fd->name), fd->nsize); fdirent->node_crc = crc32(0, (uint8_t *)fdirent, sizeof(*fdirent) - 4); vec[0].iov_base = fdirent; vec[0].iov_len = sizeof(*fdirent); vec[1].iov_base = name; vec[1].iov_len = namelen; retry: if (prio == ALLOC_GC) { /* the GC calls this function */ err = chfs_reserve_space_gc(chmp, CHFS_PAD(size)); if (err) goto out; } else { chfs_gc_trigger(chmp); if (prio == ALLOC_NORMAL) err = chfs_reserve_space_normal(chmp, CHFS_PAD(size), ALLOC_NORMAL); else err = chfs_reserve_space_normal(chmp, CHFS_PAD(size), ALLOC_DELETION); if (err) goto out; } nref = chfs_alloc_node_ref(chmp->chm_nextblock); if (!nref) { err = ENOMEM; goto out; } mutex_enter(&chmp->chm_lock_sizes); nref->nref_offset = chmp->chm_ebh->eb_size - chmp->chm_nextblock->free_size; chfs_change_size_free(chmp, chmp->chm_nextblock, -CHFS_PAD(size)); err = chfs_write_wbuf(chmp, vec, 2, nref->nref_offset, &retlen); if (err || retlen != CHFS_PAD(size)) { chfs_err("error while writing out flash dirent node to the media\n"); chfs_err("err: %d | size: %zu | retlen : %zu\n", err, CHFS_PAD(size), retlen); chfs_change_size_dirty(chmp, chmp->chm_nextblock, CHFS_PAD(size)); if (retries) { err = EIO; mutex_exit(&chmp->chm_lock_sizes); goto out; } retries++; mutex_exit(&chmp->chm_lock_sizes); goto retry; } // Everything went well chfs_change_size_used(chmp, &chmp->chm_blocks[nref->nref_lnr], CHFS_PAD(size)); mutex_exit(&chmp->chm_lock_sizes); KASSERT(chmp->chm_blocks[nref->nref_lnr].used_size <= chmp->chm_ebh->eb_size); fd->nref = nref; if (prio != ALLOC_DELETION) { chfs_add_node_to_list(chmp, pdir->chvc, nref, &pdir->chvc->dirents); } out: chfs_free_flash_dirent(fdirent); return err; } /** * chfs_write_flash_dnode - write out a data node to flash * @chmp: chfs mount structure * @vp: vnode where the data belongs to * @bp: buffer contains data */ int chfs_write_flash_dnode(struct chfs_mount *chmp, struct vnode *vp, struct buf *bp, struct chfs_full_dnode *fd) { KASSERT(mutex_owned(&chmp->chm_lock_mountfields)); int err = 0, retries = 0; size_t size, retlen; off_t ofs; struct chfs_flash_data_node *dnode; struct chfs_node_ref *nref; struct chfs_inode *ip = VTOI(vp); struct iovec vec[2]; uint32_t len; void *tmpbuf = NULL; KASSERT(ip->ino != CHFS_ROOTINO); dnode = chfs_alloc_flash_dnode(); if (!dnode) return ENOMEM; /* initialize flash data node */ ofs = bp->b_blkno * PAGE_SIZE; //dbg("vp->v_size: %ju, bp->b_blkno: %ju, bp-b_data: %p," // " bp->b_resid: %ju\n", // (uintmax_t )vp->v_size, (uintmax_t )bp->b_blkno, // bp->b_data, (uintmax_t )bp->b_resid); //dbg("[XXX]vp->v_size - ofs: %llu\n", (vp->v_size - ofs)); len = MIN((vp->v_size - ofs), bp->b_resid); size = sizeof(*dnode) + len; dnode->magic = htole16(CHFS_FS_MAGIC_BITMASK); dnode->type = htole16(CHFS_NODETYPE_DATA); dnode->length = htole32(CHFS_PAD(size)); dnode->hdr_crc = htole32(crc32(0, (uint8_t *)dnode, CHFS_NODE_HDR_SIZE - 4)); dnode->vno = htole64(ip->ino); dnode->version = htole64(++ip->chvc->highest_version); dnode->offset = htole64(ofs); dnode->data_length = htole32(len); dnode->data_crc = htole32(crc32(0, (uint8_t *)bp->b_data, len)); dnode->node_crc = htole32(crc32(0, (uint8_t *)dnode, sizeof(*dnode) - 4)); dbg("dnode @%llu %ub v%llu\n", (unsigned long long)dnode->offset, dnode->data_length, (unsigned long long)dnode->version); if (CHFS_PAD(size) - sizeof(*dnode)) { tmpbuf = kmem_zalloc(CHFS_PAD(size) - sizeof(*dnode), KM_SLEEP); memcpy(tmpbuf, bp->b_data, len); } /* creating iovecs for wbuf */ vec[0].iov_base = dnode; vec[0].iov_len = sizeof(*dnode); vec[1].iov_base = tmpbuf; vec[1].iov_len = CHFS_PAD(size) - sizeof(*dnode); fd->frags = 0; fd->ofs = ofs; fd->size = len; retry: /* Reserve space for data node. This will set up the next eraseblock * where to we will write. */ chfs_gc_trigger(chmp); err = chfs_reserve_space_normal(chmp, CHFS_PAD(size), ALLOC_NORMAL); if (err) goto out; nref = chfs_alloc_node_ref(chmp->chm_nextblock); if (!nref) { err = ENOMEM; goto out; } nref->nref_offset = chmp->chm_ebh->eb_size - chmp->chm_nextblock->free_size; KASSERT(nref->nref_offset < chmp->chm_ebh->eb_size); mutex_enter(&chmp->chm_lock_sizes); chfs_change_size_free(chmp, chmp->chm_nextblock, -CHFS_PAD(size)); //dbg("vno: %llu nref lnr: %u offset: %u\n", // dnode->vno, nref->nref_lnr, nref->nref_offset); err = chfs_write_wbuf(chmp, vec, 2, nref->nref_offset, &retlen); if (err || retlen != CHFS_PAD(size)) { chfs_err("error while writing out flash data node to the media\n"); chfs_err("err: %d | size: %zu | retlen : %zu\n", err, size, retlen); chfs_change_size_dirty(chmp, chmp->chm_nextblock, CHFS_PAD(size)); if (retries) { err = EIO; mutex_exit(&chmp->chm_lock_sizes); goto out; } retries++; mutex_exit(&chmp->chm_lock_sizes); goto retry; } /* Everything went well */ ip->write_size += fd->size; chfs_change_size_used(chmp, &chmp->chm_blocks[nref->nref_lnr], CHFS_PAD(size)); mutex_exit(&chmp->chm_lock_sizes); KASSERT(chmp->chm_blocks[nref->nref_lnr].used_size <= chmp->chm_ebh->eb_size); fd->nref = nref; chfs_add_node_to_list(chmp, ip->chvc, nref, &ip->chvc->dnode); out: chfs_free_flash_dnode(dnode); if (CHFS_PAD(size) - sizeof(*dnode)) { kmem_free(tmpbuf, CHFS_PAD(size) - sizeof(*dnode)); } return err; } /** * chfs_do_link - makes a copy from a node * @old: old node * @oldfd: dirent of old node * @parent: parent of new node * @name: name of new node * @namelen: length of name * This function writes the dirent of the new node to the media. */ int chfs_do_link(struct chfs_inode *ip, struct chfs_inode *parent, const char *name, int namelen, enum vtype type) { int error = 0; struct vnode *vp = ITOV(ip); struct ufsmount *ump = VFSTOUFS(vp->v_mount); struct chfs_mount *chmp = ump->um_chfs; struct chfs_dirent *newfd = NULL; // struct chfs_dirent *fd = NULL; //dbg("link vno: %llu\n", ip->ino); newfd = chfs_alloc_dirent(namelen + 1); newfd->vno = ip->ino; newfd->type = type; newfd->nsize = namelen; memcpy(newfd->name, name, namelen); newfd->name[newfd->nsize] = 0; // newfd->next = NULL; ip->chvc->nlink++; parent->chvc->nlink++; ip->iflag |= IN_CHANGE; chfs_update(vp, NULL, NULL, UPDATE_WAIT); mutex_enter(&chmp->chm_lock_mountfields); error = chfs_write_flash_vnode(chmp, ip, ALLOC_NORMAL); if (error) return error; error = chfs_write_flash_dirent(chmp, parent, ip, newfd, ip->ino, ALLOC_NORMAL); /* TODO: what should we do if error isn't zero? */ mutex_exit(&chmp->chm_lock_mountfields); /* add fd to the fd list */ TAILQ_INSERT_TAIL(&parent->dents, newfd, fds); #if 0 fd = parent->dents; if (!fd) { parent->dents = newfd; } else { while (fd->next) fd = fd->next; fd->next = newfd; } #endif return error; } /** * chfs_do_unlink - delete a node * @ip: node what we'd like to delete * @parent: parent of the node * @name: name of the node * @namelen: length of name * This function set the nlink and vno of the node zero and write its dirent to the media. */ int chfs_do_unlink(struct chfs_inode *ip, struct chfs_inode *parent, const char *name, int namelen) { struct chfs_dirent *fd, *tmpfd; int error = 0; struct vnode *vp = ITOV(ip); struct ufsmount *ump = VFSTOUFS(vp->v_mount); struct chfs_mount *chmp = ump->um_chfs; struct chfs_node_ref *nref; //dbg("unlink vno: %llu\n", ip->ino); vflushbuf(vp, 0); mutex_enter(&chmp->chm_lock_mountfields); /* remove the full direntry from the parent dents list */ TAILQ_FOREACH_SAFE(fd, &parent->dents, fds, tmpfd) { if (fd->vno == ip->ino && fd->nsize == namelen && !memcmp(fd->name, name, fd->nsize)) { if (fd->type == VDIR && ip->chvc->nlink == 2) ip->chvc->nlink = 0; else ip->chvc->nlink--; fd->type = VNON; TAILQ_REMOVE(&parent->dents, fd, fds); /* remove nref from dirents list */ nref = parent->chvc->dirents; if (nref == fd->nref) { nref->nref_next = fd->nref->nref_next; } else { while (nref->nref_next && nref->nref_next != fd->nref) nref = nref->nref_next; if (nref->nref_next) nref->nref_next = fd->nref->nref_next; } //dbg("FD->NREF vno: %llu, lnr: %u, ofs: %u\n", // fd->vno, fd->nref->nref_lnr, fd->nref->nref_offset); chfs_mark_node_obsolete(chmp, fd->nref); error = chfs_write_flash_dirent(chmp, parent, ip, fd, 0, ALLOC_DELETION); //dbg("FD->NREF vno: %llu, lnr: %u, ofs: %u\n", // fd->vno, fd->nref->nref_lnr, fd->nref->nref_offset); chfs_mark_node_obsolete(chmp, fd->nref); nref = ip->chvc->dnode; while (nref != (struct chfs_node_ref *)ip->chvc) { //dbg("DATA NREF\n"); chfs_mark_node_obsolete(chmp, nref); nref = nref->nref_next; } ip->chvc->dnode = (struct chfs_node_ref *)ip->chvc; nref = ip->chvc->v; while (nref != (struct chfs_node_ref *)ip->chvc) { //dbg("V NREF\n"); chfs_mark_node_obsolete(chmp, nref); nref = nref->nref_next; } ip->chvc->v = ip->chvc->v->nref_next; parent->chvc->nlink--; //TODO: if error } } mutex_exit(&chmp->chm_lock_mountfields); return error; }