/* This file contains the heart of the mechanism used to read (and write) * files. Read and write requests are split up into chunks that do not cross * block boundaries. Each chunk is then processed in turn. Reads on special * files are also detected and handled. * * The entry points into this file are * do_read: perform the READ system call by calling read_write * read_write: actually do the work of READ and WRITE * read_map: given an inode and file position, look up its zone number * rd_indir: read an entry in an indirect block * read_ahead: manage the block read ahead business */ #include "fs.h" #include #include #include "buf.h" #include "file.h" #include "fproc.h" #include "inode.h" #include "param.h" #include "super.h" FORWARD _PROTOTYPE( int rw_chunk, (struct inode *rip, off_t position, unsigned off, int chunk, unsigned left, int rw_flag, char *buff, int seg, int usr, int block_size) ); /*===========================================================================* * do_read * *===========================================================================*/ PUBLIC int do_read() { return(read_write(READING)); } /*===========================================================================* * read_write * *===========================================================================*/ PUBLIC int read_write(rw_flag) int rw_flag; /* READING or WRITING */ { /* Perform read(fd, buffer, nbytes) or write(fd, buffer, nbytes) call. */ register struct inode *rip; register struct filp *f; off_t bytes_left, f_size, position; unsigned int off, cum_io; int op, oflags, r, chunk, usr, seg, block_spec, char_spec; int regular, partial_pipe = 0, partial_cnt = 0; mode_t mode_word; struct filp *wf; int block_size; /* MM loads segments by putting funny things in upper 10 bits of 'fd'. */ if (who == MM_PROC_NR && (m_in.fd & (~BYTE)) ) { usr = m_in.fd >> 7; seg = (m_in.fd >> 5) & 03; m_in.fd &= 037; /* get rid of user and segment bits */ } else { usr = who; /* normal case */ seg = D; } /* If the file descriptor is valid, get the inode, size and mode. */ if (m_in.nbytes < 0) return(EINVAL); if ((f = get_filp(m_in.fd)) == NIL_FILP) return(err_code); if (((f->filp_mode) & (rw_flag == READING ? R_BIT : W_BIT)) == 0) { return(f->filp_mode == FILP_CLOSED ? EIO : EBADF); } if (m_in.nbytes == 0) return(0); /* so char special files need not check for 0*/ position = f->filp_pos; oflags = f->filp_flags; rip = f->filp_ino; f_size = rip->i_size; r = OK; if (rip->i_pipe == I_PIPE) { /* fp->fp_cum_io_partial is only nonzero when doing partial writes */ cum_io = fp->fp_cum_io_partial; } else { cum_io = 0; } op = (rw_flag == READING ? DEV_READ : DEV_WRITE); mode_word = rip->i_mode & I_TYPE; regular = mode_word == I_REGULAR || mode_word == I_NAMED_PIPE; if((char_spec = (mode_word == I_CHAR_SPECIAL ? 1 : 0))) { if(rip->i_zone[0] == NO_DEV) panic("read_write tries to read from character device NO_DEV", NO_NUM); block_size = get_block_size(rip->i_zone[0]); } if((block_spec = (mode_word == I_BLOCK_SPECIAL ? 1 : 0))) { f_size = LONG_MAX; if(rip->i_zone[0] == NO_DEV) panic("read_write tries to read from block device NO_DEV", NO_NUM); block_size = get_block_size(rip->i_zone[0]); } if(!char_spec && !block_spec) block_size = rip->i_sp->s_block_size; rdwt_err = OK; /* set to EIO if disk error occurs */ /* Check for character special files. */ if (char_spec) { dev_t dev; dev = (dev_t) rip->i_zone[0]; r = dev_io(op, dev, usr, m_in.buffer, position, m_in.nbytes, oflags); if (r >= 0) { cum_io = r; position += r; r = OK; } } else { if (rw_flag == WRITING && block_spec == 0) { /* Check in advance to see if file will grow too big. */ if (position > rip->i_sp->s_max_size - m_in.nbytes) return(EFBIG); /* Check for O_APPEND flag. */ if (oflags & O_APPEND) position = f_size; /* Clear the zone containing present EOF if hole about * to be created. This is necessary because all unwritten * blocks prior to the EOF must read as zeros. */ if (position > f_size) clear_zone(rip, f_size, 0); } /* Pipes are a little different. Check. */ if (rip->i_pipe == I_PIPE) { r = pipe_check(rip,rw_flag,oflags, m_in.nbytes,position,&partial_cnt); if (r <= 0) return(r); } if (partial_cnt > 0) partial_pipe = 1; /* Split the transfer into chunks that don't span two blocks. */ while (m_in.nbytes != 0) { off = (unsigned int) (position % block_size);/* offset in blk*/ if (partial_pipe) { /* pipes only */ chunk = MIN(partial_cnt, block_size - off); } else chunk = MIN(m_in.nbytes, block_size - off); if (chunk < 0) chunk = block_size - off; if (rw_flag == READING) { bytes_left = f_size - position; if (position >= f_size) break; /* we are beyond EOF */ if (chunk > bytes_left) chunk = (int) bytes_left; } /* Read or write 'chunk' bytes. */ r = rw_chunk(rip, position, off, chunk, (unsigned) m_in.nbytes, rw_flag, m_in.buffer, seg, usr, block_size); if (r != OK) break; /* EOF reached */ if (rdwt_err < 0) break; /* Update counters and pointers. */ m_in.buffer += chunk; /* user buffer address */ m_in.nbytes -= chunk; /* bytes yet to be read */ cum_io += chunk; /* bytes read so far */ position += chunk; /* position within the file */ if (partial_pipe) { partial_cnt -= chunk; if (partial_cnt <= 0) break; } } } /* On write, update file size and access time. */ if (rw_flag == WRITING) { if (regular || mode_word == I_DIRECTORY) { if (position > f_size) rip->i_size = position; } } else { if (rip->i_pipe == I_PIPE && position >= rip->i_size) { /* Reset pipe pointers. */ rip->i_size = 0; /* no data left */ position = 0; /* reset reader(s) */ if ( (wf = find_filp(rip, W_BIT)) != NIL_FILP) wf->filp_pos =0; } } f->filp_pos = position; /* Check to see if read-ahead is called for, and if so, set it up. */ if (rw_flag == READING && rip->i_seek == NO_SEEK && position % block_size== 0 && (regular || mode_word == I_DIRECTORY)) { rdahed_inode = rip; rdahedpos = position; } rip->i_seek = NO_SEEK; if (rdwt_err != OK) r = rdwt_err; /* check for disk error */ if (rdwt_err == END_OF_FILE) r = OK; if (r == OK) { if (rw_flag == READING) rip->i_update |= ATIME; if (rw_flag == WRITING) rip->i_update |= CTIME | MTIME; rip->i_dirt = DIRTY; /* inode is thus now dirty */ if (partial_pipe) { partial_pipe = 0; /* partial write on pipe with */ /* O_NONBLOCK, return write count */ if (!(oflags & O_NONBLOCK)) { fp->fp_cum_io_partial = cum_io; suspend(XPIPE); /* partial write on pipe with */ return(SUSPEND); /* nbyte > PIPE_SIZE - non-atomic */ } } fp->fp_cum_io_partial = 0; return(cum_io); } else { return(r); } } /*===========================================================================* * rw_chunk * *===========================================================================*/ PRIVATE int rw_chunk(rip, position, off, chunk, left, rw_flag, buff, seg, usr, block_size) register struct inode *rip; /* pointer to inode for file to be rd/wr */ off_t position; /* position within file to read or write */ unsigned off; /* off within the current block */ int chunk; /* number of bytes to read or write */ unsigned left; /* max number of bytes wanted after position */ int rw_flag; /* READING or WRITING */ char *buff; /* virtual address of the user buffer */ int seg; /* T or D segment in user space */ int usr; /* which user process */ int block_size; { /* Read or write (part of) a block. */ register struct buf *bp; register int r; int n, block_spec; block_t b; dev_t dev; block_spec = (rip->i_mode & I_TYPE) == I_BLOCK_SPECIAL; if (block_spec) { b = position/block_size; dev = (dev_t) rip->i_zone[0]; } else { b = read_map(rip, position); dev = rip->i_dev; } if (!block_spec && b == NO_BLOCK) { if (rw_flag == READING) { /* Reading from a nonexistent block. Must read as all zeros.*/ bp = get_block(NO_DEV, NO_BLOCK, NORMAL); /* get a buffer */ zero_block(bp); } else { /* Writing to a nonexistent block. Create and enter in inode.*/ if ((bp= new_block(rip, position)) == NIL_BUF)return(err_code); } } else if (rw_flag == READING) { /* Read and read ahead if convenient. */ bp = rahead(rip, b, position, left); } else { /* Normally an existing block to be partially overwritten is first read * in. However, a full block need not be read in. If it is already in * the cache, acquire it, otherwise just acquire a free buffer. */ n = (chunk == block_size ? NO_READ : NORMAL); if (!block_spec && off == 0 && position >= rip->i_size) n = NO_READ; bp = get_block(dev, b, n); } /* In all cases, bp now points to a valid buffer. */ if (rw_flag == WRITING && chunk != block_size && !block_spec && position >= rip->i_size && off == 0) { zero_block(bp); } if (rw_flag == READING) { /* Copy a chunk from the block buffer to user space. */ r = sys_vircopy(FS_PROC_NR, D, (phys_bytes) (bp->b_data+off), usr, seg, (phys_bytes) buff, (phys_bytes) chunk); } else { /* Copy a chunk from user space to the block buffer. */ r = sys_vircopy(usr, seg, (phys_bytes) buff, FS_PROC_NR, D, (phys_bytes) (bp->b_data+off), (phys_bytes) chunk); bp->b_dirt = DIRTY; } n = (off + chunk == block_size ? FULL_DATA_BLOCK : PARTIAL_DATA_BLOCK); put_block(bp, n); return(r); } /*===========================================================================* * read_map * *===========================================================================*/ PUBLIC block_t read_map(rip, position) register struct inode *rip; /* ptr to inode to map from */ off_t position; /* position in file whose blk wanted */ { /* Given an inode and a position within the corresponding file, locate the * block (not zone) number in which that position is to be found and return it. */ register struct buf *bp; register zone_t z; int scale, boff, dzones, nr_indirects, index, zind, ex; block_t b; long excess, zone, block_pos; scale = rip->i_sp->s_log_zone_size; /* for block-zone conversion */ block_pos = position/rip->i_sp->s_block_size; /* relative blk # in file */ zone = block_pos >> scale; /* position's zone */ boff = (int) (block_pos - (zone << scale) ); /* relative blk # within zone */ dzones = rip->i_ndzones; nr_indirects = rip->i_nindirs; /* Is 'position' to be found in the inode itself? */ if (zone < dzones) { zind = (int) zone; /* index should be an int */ z = rip->i_zone[zind]; if (z == NO_ZONE) return(NO_BLOCK); b = ((block_t) z << scale) + boff; return(b); } /* It is not in the inode, so it must be single or double indirect. */ excess = zone - dzones; /* first Vx_NR_DZONES don't count */ if (excess < nr_indirects) { /* 'position' can be located via the single indirect block. */ z = rip->i_zone[dzones]; } else { /* 'position' can be located via the double indirect block. */ if ( (z = rip->i_zone[dzones+1]) == NO_ZONE) return(NO_BLOCK); excess -= nr_indirects; /* single indir doesn't count*/ b = (block_t) z << scale; bp = get_block(rip->i_dev, b, NORMAL); /* get double indirect block */ index = (int) (excess/nr_indirects); z = rd_indir(bp, index); /* z= zone for single*/ put_block(bp, INDIRECT_BLOCK); /* release double ind block */ excess = excess % nr_indirects; /* index into single ind blk */ } /* 'z' is zone num for single indirect block; 'excess' is index into it. */ if (z == NO_ZONE) return(NO_BLOCK); b = (block_t) z << scale; /* b is blk # for single ind */ bp = get_block(rip->i_dev, b, NORMAL); /* get single indirect block */ ex = (int) excess; /* need an integer */ z = rd_indir(bp, ex); /* get block pointed to */ put_block(bp, INDIRECT_BLOCK); /* release single indir blk */ if (z == NO_ZONE) return(NO_BLOCK); b = ((block_t) z << scale) + boff; return(b); } /*===========================================================================* * rd_indir * *===========================================================================*/ PUBLIC zone_t rd_indir(bp, index) struct buf *bp; /* pointer to indirect block */ int index; /* index into *bp */ { /* Given a pointer to an indirect block, read one entry. The reason for * making a separate routine out of this is that there are four cases: * V1 (IBM and 68000), and V2 (IBM and 68000). */ struct super_block *sp; zone_t zone; /* V2 zones are longs (shorts in V1) */ sp = get_super(bp->b_dev); /* need super block to find file sys type */ /* read a zone from an indirect block */ if (sp->s_version == V1) zone = (zone_t) conv2(sp->s_native, (int) bp->b_v1_ind[index]); else zone = (zone_t) conv4(sp->s_native, (long) bp->b_v2_ind[index]); if (zone != NO_ZONE && (zone < (zone_t) sp->s_firstdatazone || zone >= sp->s_zones)) { printf("Illegal zone number %ld in indirect block, index %d\n", (long) zone, index); panic("check file system", NO_NUM); } return(zone); } /*===========================================================================* * read_ahead * *===========================================================================*/ PUBLIC void read_ahead() { /* Read a block into the cache before it is needed. */ int block_size; register struct inode *rip; struct buf *bp; block_t b; rip = rdahed_inode; /* pointer to inode to read ahead from */ block_size = get_block_size(rip->i_dev); rdahed_inode = NIL_INODE; /* turn off read ahead */ if ( (b = read_map(rip, rdahedpos)) == NO_BLOCK) return; /* at EOF */ bp = rahead(rip, b, rdahedpos, block_size); put_block(bp, PARTIAL_DATA_BLOCK); } /*===========================================================================* * rahead * *===========================================================================*/ PUBLIC struct buf *rahead(rip, baseblock, position, bytes_ahead) register struct inode *rip; /* pointer to inode for file to be read */ block_t baseblock; /* block at current position */ off_t position; /* position within file */ unsigned bytes_ahead; /* bytes beyond position for immediate use */ { /* Fetch a block from the cache or the device. If a physical read is * required, prefetch as many more blocks as convenient into the cache. * This usually covers bytes_ahead and is at least BLOCKS_MINIMUM. * The device driver may decide it knows better and stop reading at a * cylinder boundary (or after an error). Rw_scattered() puts an optional * flag on all reads to allow this. */ int block_size; /* Minimum number of blocks to prefetch. */ # define BLOCKS_MINIMUM (NR_BUFS < 50 ? 18 : 32) int block_spec, scale, read_q_size; unsigned int blocks_ahead, fragment; block_t block, blocks_left; off_t ind1_pos; dev_t dev; struct buf *bp; static struct buf *read_q[NR_BUFS]; block_spec = (rip->i_mode & I_TYPE) == I_BLOCK_SPECIAL; if (block_spec) { dev = (dev_t) rip->i_zone[0]; } else { dev = rip->i_dev; } block_size = get_block_size(dev); block = baseblock; bp = get_block(dev, block, PREFETCH); if (bp->b_dev != NO_DEV) return(bp); /* The best guess for the number of blocks to prefetch: A lot. * It is impossible to tell what the device looks like, so we don't even * try to guess the geometry, but leave it to the driver. * * The floppy driver can read a full track with no rotational delay, and it * avoids reading partial tracks if it can, so handing it enough buffers to * read two tracks is perfect. (Two, because some diskette types have * an odd number of sectors per track, so a block may span tracks.) * * The disk drivers don't try to be smart. With todays disks it is * impossible to tell what the real geometry looks like, so it is best to * read as much as you can. With luck the caching on the drive allows * for a little time to start the next read. * * The current solution below is a bit of a hack, it just reads blocks from * the current file position hoping that more of the file can be found. A * better solution must look at the already available zone pointers and * indirect blocks (but don't call read_map!). */ fragment = position % block_size; position -= fragment; bytes_ahead += fragment; blocks_ahead = (bytes_ahead + block_size - 1) / block_size; if (block_spec && rip->i_size == 0) { blocks_left = NR_IOREQS; } else { blocks_left = (rip->i_size - position + block_size - 1) / block_size; /* Go for the first indirect block if we are in its neighborhood. */ if (!block_spec) { scale = rip->i_sp->s_log_zone_size; ind1_pos = (off_t) rip->i_ndzones * (block_size << scale); if (position <= ind1_pos && rip->i_size > ind1_pos) { blocks_ahead++; blocks_left++; } } } /* No more than the maximum request. */ if (blocks_ahead > NR_IOREQS) blocks_ahead = NR_IOREQS; /* Read at least the minimum number of blocks, but not after a seek. */ if (blocks_ahead < BLOCKS_MINIMUM && rip->i_seek == NO_SEEK) blocks_ahead = BLOCKS_MINIMUM; /* Can't go past end of file. */ if (blocks_ahead > blocks_left) blocks_ahead = blocks_left; read_q_size = 0; /* Acquire block buffers. */ for (;;) { read_q[read_q_size++] = bp; if (--blocks_ahead == 0) break; /* Don't trash the cache, leave 4 free. */ if (bufs_in_use >= NR_BUFS - 4) break; block++; bp = get_block(dev, block, PREFETCH); if (bp->b_dev != NO_DEV) { /* Oops, block already in the cache, get out. */ put_block(bp, FULL_DATA_BLOCK); break; } } rw_scattered(dev, read_q, read_q_size, READING); return(get_block(dev, baseblock, NORMAL)); }