#include "types.h" #include "param.h" #include "x86.h" #include "mmu.h" #include "proc.h" #include "defs.h" #include "spinlock.h" #include "buf.h" #include "fs.h" #include "fsvar.h" #include "dev.h" // these are inodes currently in use // an entry is free if count == 0 struct inode inode[NINODE]; struct spinlock inode_table_lock; uint rootdev = 1; void iinit(void) { initlock(&inode_table_lock, "inode_table"); } static uint balloc(uint dev) { int b; struct buf *bp; struct superblock *sb; int bi = 0; int size; int ninodes; uchar m; bp = bread(dev, 1); sb = (struct superblock *) bp->data; size = sb->size; ninodes = sb->ninodes; for (b = 0; b < size; b++) { if (b % BPB == 0) { brelse(bp); bp = bread(dev, BBLOCK(b, ninodes)); } bi = b % BPB; m = 0x1 << (bi % 8); if ((bp->data[bi/8] & m) == 0) { // is block free? break; } } if (b >= size) panic("balloc: out of blocks\n"); cprintf ("balloc: allocate block %d\n", b); bp->data[bi/8] |= 0x1 << (bi % 8); bwrite (dev, bp, BBLOCK(b, ninodes)); // mark it allocated on disk brelse(bp); return b; } static void bfree(int dev, uint b) { struct buf *bp; struct superblock *sb; int bi; int ninodes; uchar m; cprintf ("bfree: free block %d\n", b); bp = bread(dev, 1); sb = (struct superblock *) bp->data; ninodes = sb->ninodes; brelse(bp); bp = bread(dev, BBLOCK(b, ninodes)); bi = b % BPB; m = ~(0x1 << (bi %8)); bp->data[bi/8] &= m; bwrite (dev, bp, BBLOCK(b, ninodes)); // mark it free on disk brelse(bp); } // returns an inode with busy set and incremented reference count. struct inode * iget(uint dev, uint inum) { struct inode *ip, *nip = 0; struct dinode *dip; struct buf *bp; acquire(&inode_table_lock); loop: for(ip = &inode[0]; ip < &inode[NINODE]; ip++){ if(ip->count > 0 && ip->dev == dev && ip->inum == inum){ if(ip->busy){ sleep(ip, &inode_table_lock); goto loop; } ip->count++; ip->busy = 1; release(&inode_table_lock); return ip; } if(nip == 0 && ip->count == 0) nip = ip; } if(nip == 0) panic("out of inodes"); nip->dev = dev; nip->inum = inum; nip->count = 1; nip->busy = 1; release(&inode_table_lock); bp = bread(dev, IBLOCK(inum)); dip = &((struct dinode *)(bp->data))[inum % IPB]; nip->type = dip->type; nip->major = dip->major; nip->minor = dip->minor; nip->nlink = dip->nlink; nip->size = dip->size; memmove(nip->addrs, dip->addrs, sizeof(nip->addrs)); brelse(bp); return nip; } void iupdate (struct inode *ip) { struct buf *bp; struct dinode *dip; bp = bread(ip->dev, IBLOCK(ip->inum)); dip = &((struct dinode *)(bp->data))[ip->inum % IPB]; dip->type = ip->type; dip->major = ip->major; dip->minor = ip->minor; dip->nlink = ip->nlink; dip->size = ip->size; memmove(dip->addrs, ip->addrs, sizeof(ip->addrs)); bwrite (ip->dev, bp, IBLOCK(ip->inum)); // mark it allocated on the disk brelse(bp); } struct inode * ialloc(uint dev, short type) { struct inode *ip; struct dinode *dip = 0; struct superblock *sb; int ninodes; int inum; struct buf *bp; bp = bread(dev, 1); sb = (struct superblock *) bp->data; ninodes = sb->ninodes; brelse(bp); for (inum = 1; inum < ninodes; inum++) { // loop over inode blocks bp = bread(dev, IBLOCK(inum)); dip = &((struct dinode *)(bp->data))[inum % IPB]; if (dip->type == 0) { // a free inode break; } brelse(bp); } if (inum >= ninodes) { panic ("ialloc: no inodes left\n"); } cprintf ("ialloc: %d\n", inum); dip->type = type; bwrite (dev, bp, IBLOCK(inum)); // mark it allocated on the disk brelse(bp); ip = iget (dev, inum); return ip; } static void ifree(uint dev, struct inode *ip) { ip->type = 0; iupdate(ip); } void ilock(struct inode *ip) { if(ip->count < 1) panic("ilock"); acquire(&inode_table_lock); while(ip->busy) sleep(ip, &inode_table_lock); ip->busy = 1; release(&inode_table_lock); } // caller is holding onto a reference to this inode, but no // longer needs to examine or change it, so clear ip->busy. void iunlock(struct inode *ip) { if(ip->busy != 1) panic("iunlock"); acquire(&inode_table_lock); ip->busy = 0; wakeup(ip); release(&inode_table_lock); } // caller is releasing a reference to this inode. // you must have the inode lock. void iput(struct inode *ip) { if(ip->count < 1 || ip->busy != 1) panic("iput"); acquire(&inode_table_lock); ip->count -= 1; ip->busy = 0; wakeup(ip); release(&inode_table_lock); } void idecref(struct inode *ip) { acquire(&inode_table_lock); if(ip->count < 1) panic("idecref"); ip->count -= 1; release(&inode_table_lock); } uint bmap(struct inode *ip, uint bn) { unsigned x; if(bn >= NDIRECT) panic("bmap 1"); x = ip->addrs[bn]; if(x == 0) panic("bmap 2"); return x; } #define min(a, b) ((a) < (b) ? (a) : (b)) int readi(struct inode *ip, char *dst, uint off, uint n) { uint target = n, n1; struct buf *bp; if (ip->type == T_DEV) { if (ip->major < 0 || ip->major >= NDEV || !devsw[ip->major].d_read) return -1; return devsw[ip->major].d_read (ip->minor, dst, n); } while(n > 0 && off < ip->size){ bp = bread(ip->dev, bmap(ip, off / BSIZE)); n1 = min(n, ip->size - off); n1 = min(n1, BSIZE - (off % BSIZE)); memmove(dst, bp->data + (off % BSIZE), n1); n -= n1; off += n1; dst += n1; brelse(bp); } return target - n; } #define MIN(a, b) ((a < b) ? a : b) int writei(struct inode *ip, char *addr, uint off, uint n) { if (ip->type == T_DEV) { if (ip->major < 0 || ip->major >= NDEV || !devsw[ip->major].d_write) return -1; return devsw[ip->major].d_write (ip->minor, addr, n); } else if (ip->type == T_FILE || ip->type == T_DIR) { // XXX dir here too? struct buf *bp; int r = 0; int m; int lbn; uint b; while (r < n) { lbn = off / BSIZE; if (lbn >= NDIRECT) return r; if (ip->addrs[lbn] == 0) { b = balloc(ip->dev); if (b <= 0) return r; ip->addrs[lbn] = b; } m = MIN(BSIZE - off % BSIZE, n-r); bp = bread(ip->dev, bmap(ip, off / BSIZE)); memmove (bp->data + off % BSIZE, addr, m); bwrite (ip->dev, bp, bmap(ip, off/BSIZE)); brelse (bp); r += m; off += m; } if (r > 0) { if (off > ip->size) { ip->size = off; } iupdate(ip); } return r; } else { panic ("writei: unknown type\n"); return 0; } } struct inode * namei(char *path) { struct inode *dp; char *cp = path; uint off, dev; struct buf *bp; struct dirent *ep; int i; unsigned ninum; dp = iget(rootdev, 1); while(*cp == '/') cp++; while(1){ if(*cp == '\0') return dp; if(dp->type != T_DIR){ iput(dp); return 0; } for(off = 0; off < dp->size; off += BSIZE){ bp = bread(dp->dev, bmap(dp, off / BSIZE)); for(ep = (struct dirent *) bp->data; ep < (struct dirent *) (bp->data + BSIZE); ep++){ if(ep->inum == 0) continue; for(i = 0; i < DIRSIZ && cp[i] != '/' && cp[i]; i++) if(cp[i] != ep->name[i]) break; if((cp[i] == '\0' || cp[i] == '/') && (i >= DIRSIZ || ep->name[i] == '\0')){ ninum = ep->inum; brelse(bp); cp += i; goto found; } } brelse(bp); } iput(dp); return 0; found: dev = dp->dev; iput(dp); dp = iget(dev, ninum); while(*cp == '/') cp++; } } struct inode * mknod(struct inode *dp, char *cp, short type, short major, short minor) { struct inode *ip; struct dirent *ep = 0; int off; int i; struct buf *bp = 0; cprintf("mknod: dir %d %s %d %d %d\n", dp->inum, cp, type, major, minor); ip = ialloc(dp->dev, type); if (ip == 0) return 0; ip->major = major; ip->minor = minor; ip->size = 0; ip->nlink = 0; iupdate (ip); // write new inode to disk for(off = 0; off < dp->size; off += BSIZE) { bp = bread(dp->dev, bmap(dp, off / BSIZE)); for(ep = (struct dirent *) bp->data; ep < (struct dirent *) (bp->data + BSIZE); ep++){ if(ep->inum == 0) { goto found; } } brelse(bp); } panic("mknod: XXXX no dir entry free\n"); found: ep->inum = ip->inum; for(i = 0; i < DIRSIZ && cp[i]; i++) ep->name[i] = cp[i]; bwrite (dp->dev, bp, bmap(dp, off/BSIZE)); // write directory block brelse(bp); dp->size += sizeof(struct dirent); // update directory inode iupdate (dp); return ip; }