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minix/servers/mfs/write.c
Ben Gras bd3cde4571 Move primary cache code to libminixfs. 
Add primary cache management feature to libminixfs as mfs and ext2
currently do separately, remove cache code from mfs and ext2, and make
them use the libminixfs interface. This makes all fields of the buf
struct private to libminixfs and FS clients aren't supposed to access
them at all. Only the opaque 'void *data' field (the FS block contents,
used to be called bp) is to be accessed by the FS client.

The main purpose is to implement the interface to the 2ndary vm cache
just once, get rid of some code duplication, and add a little
abstraction to reduce the code inertia of the whole caching business.

Some minor sanity checking and prohibition done by mfs in this code
as removed from the generic primary cache code as a result:
        - checking all inodes are not in use when allocating/resizing
          the cache
        - checking readonly filesystems aren't written to
        - checking the superblock isn't written to on mounted filesystems

The minixfslib code relies on fs_blockstats() in the client filesystem to
return some FS usage information.
2012-10-23 19:48:38 +02:00

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/* This file is the counterpart of "read.c". It contains the code for writing
* insofar as this is not contained in fs_readwrite().
*
* The entry points into this file are
* write_map: write a new zone into an inode
* clear_zone: erase a zone in the middle of a file
* new_block: acquire a new block
* zero_block: overwrite a block with zeroes
*
*/
#include "fs.h"
#include <string.h>
#include "buf.h"
#include "inode.h"
#include "super.h"
static void wr_indir(struct buf *bp, int index, zone_t zone);
static int empty_indir(struct buf *, struct super_block *);
/*===========================================================================*
* write_map *
*===========================================================================*/
int write_map(rip, position, new_zone, op)
struct inode *rip; /* pointer to inode to be changed */
off_t position; /* file address to be mapped */
zone_t new_zone; /* zone # to be inserted */
int op; /* special actions */
{
/* Write a new zone into an inode.
*
* If op includes WMAP_FREE, free the data zone corresponding to that position
* in the inode ('new_zone' is ignored then). Also free the indirect block
* if that was the last entry in the indirect block.
* Also free the double indirect block if that was the last entry in the
* double indirect block.
*/
int scale, ind_ex = 0, new_ind, new_dbl,
zones, nr_indirects, single, zindex, ex;
zone_t z, z1, z2 = NO_ZONE, old_zone;
register block_t b;
long excess, zone;
struct buf *bp_dindir = NULL, *bp = NULL;
IN_MARKDIRTY(rip);
scale = rip->i_sp->s_log_zone_size; /* for zone-block conversion */
/* relative zone # to insert */
zone = (position/rip->i_sp->s_block_size) >> scale;
zones = rip->i_ndzones; /* # direct zones in the inode */
nr_indirects = rip->i_nindirs;/* # indirect zones per indirect block */
/* Is 'position' to be found in the inode itself? */
if (zone < zones) {
zindex = (int) zone; /* we need an integer here */
if(rip->i_zone[zindex] != NO_ZONE && (op & WMAP_FREE)) {
free_zone(rip->i_dev, rip->i_zone[zindex]);
rip->i_zone[zindex] = NO_ZONE;
} else {
rip->i_zone[zindex] = new_zone;
}
return(OK);
}
/* It is not in the inode, so it must be single or double indirect. */
excess = zone - zones; /* first Vx_NR_DZONES don't count */
new_ind = FALSE;
new_dbl = FALSE;
if (excess < nr_indirects) {
/* 'position' can be located via the single indirect block. */
z1 = rip->i_zone[zones]; /* single indirect zone */
single = TRUE;
} else {
/* 'position' can be located via the double indirect block. */
if ( (z2 = z = rip->i_zone[zones+1]) == NO_ZONE &&
!(op & WMAP_FREE)) {
/* Create the double indirect block. */
if ( (z = alloc_zone(rip->i_dev, rip->i_zone[0])) == NO_ZONE)
return(err_code);
rip->i_zone[zones+1] = z;
new_dbl = TRUE; /* set flag for later */
}
/* 'z' is zone number for double indirect block, either old
* or newly created.
* If there wasn't one and WMAP_FREE is set, 'z' is NO_ZONE.
*/
excess -= nr_indirects; /* single indirect doesn't count */
ind_ex = (int) (excess / nr_indirects);
excess = excess % nr_indirects;
if (ind_ex >= nr_indirects) return(EFBIG);
if(z == NO_ZONE && (op & WMAP_FREE)) {
/* WMAP_FREE and no double indirect block - then no
* single indirect block either.
*/
z1 = NO_ZONE;
} else {
b = (block_t) z << scale;
bp_dindir = get_block(rip->i_dev, b, (new_dbl?NO_READ:NORMAL));
if (new_dbl) zero_block(bp_dindir);
z1 = rd_indir(bp_dindir, ind_ex);
}
single = FALSE;
}
/* z1 is now single indirect zone, or NO_ZONE; 'excess' is index.
* We have to create the indirect zone if it's NO_ZONE. Unless
* we're freeing (WMAP_FREE).
*/
if (z1 == NO_ZONE && !(op & WMAP_FREE)) {
z1 = alloc_zone(rip->i_dev, rip->i_zone[0]);
if (single)
rip->i_zone[zones] = z1; /* update inode w. single indirect */
else
wr_indir(bp_dindir, ind_ex, z1); /* update dbl indir */
new_ind = TRUE;
/* If double ind, it is dirty. */
if (bp_dindir != NULL) MARKDIRTY(bp_dindir);
if (z1 == NO_ZONE) {
/* Release dbl indirect blk. */
put_block(bp_dindir, INDIRECT_BLOCK);
return(err_code); /* couldn't create single ind */
}
}
/* z1 is indirect block's zone number (unless it's NO_ZONE when we're
* freeing).
*/
if(z1 != NO_ZONE) {
ex = (int) excess; /* we need an int here */
b = (block_t) z1 << scale;
bp = get_block(rip->i_dev, b, (new_ind ? NO_READ : NORMAL) );
if (new_ind) zero_block(bp);
if(op & WMAP_FREE) {
if((old_zone = rd_indir(bp, ex)) != NO_ZONE) {
free_zone(rip->i_dev, old_zone);
wr_indir(bp, ex, NO_ZONE);
}
/* Last reference in the indirect block gone? Then
* free the indirect block.
*/
if(empty_indir(bp, rip->i_sp)) {
free_zone(rip->i_dev, z1);
z1 = NO_ZONE;
/* Update the reference to the indirect block to
* NO_ZONE - in the double indirect block if there
* is one, otherwise in the inode directly.
*/
if(single) {
rip->i_zone[zones] = z1;
} else {
wr_indir(bp_dindir, ind_ex, z1);
MARKDIRTY(bp_dindir);
}
}
} else {
wr_indir(bp, ex, new_zone);
}
/* z1 equals NO_ZONE only when we are freeing up the indirect block. */
if(z1 == NO_ZONE) { MARKCLEAN(bp); } else { MARKDIRTY(bp); }
put_block(bp, INDIRECT_BLOCK);
}
/* If the single indirect block isn't there (or was just freed),
* see if we have to keep the double indirect block, if any.
* If we don't have to keep it, don't bother writing it out.
*/
if(z1 == NO_ZONE && !single && z2 != NO_ZONE &&
empty_indir(bp_dindir, rip->i_sp)) {
MARKCLEAN(bp_dindir);
free_zone(rip->i_dev, z2);
rip->i_zone[zones+1] = NO_ZONE;
}
put_block(bp_dindir, INDIRECT_BLOCK); /* release double indirect blk */
return(OK);
}
/*===========================================================================*
* wr_indir *
*===========================================================================*/
static void wr_indir(bp, index, zone)
struct buf *bp; /* pointer to indirect block */
int index; /* index into *bp */
zone_t zone; /* zone to write */
{
/* Given a pointer to an indirect block, write one entry. */
struct super_block *sp;
if(bp == NULL)
panic("wr_indir() on NULL");
sp = get_super(lmfs_dev(bp)); /* need super block to find file sys type */
/* write a zone into an indirect block */
if (sp->s_version == V1)
b_v1_ind(bp)[index] = (zone1_t) conv2(sp->s_native, (int) zone);
else
b_v2_ind(bp)[index] = (zone_t) conv4(sp->s_native, (long) zone);
}
/*===========================================================================*
* empty_indir *
*===========================================================================*/
static int empty_indir(bp, sb)
struct buf *bp; /* pointer to indirect block */
struct super_block *sb; /* superblock of device block resides on */
{
/* Return nonzero if the indirect block pointed to by bp contains
* only NO_ZONE entries.
*/
unsigned int i;
for(i = 0; i < V2_INDIRECTS(sb->s_block_size); i++)
if( b_v2_ind(bp)[i] != NO_ZONE)
return(0);
return(1);
}
/*===========================================================================*
* clear_zone *
*===========================================================================*/
void clear_zone(rip, pos, flag)
register struct inode *rip; /* inode to clear */
off_t pos; /* points to block to clear */
int flag; /* 1 if called by new_block, 0 otherwise */
{
/* Zero a zone, possibly starting in the middle. The parameter 'pos' gives
* a byte in the first block to be zeroed. Clearzone() is called from
* fs_readwrite(), truncate_inode(), and new_block().
*/
struct buf *bp;
block_t b, blo, bhi;
off_t next;
int scale, zone_size;
/* If the block size and zone size are the same, clear_zone() not needed. */
scale = rip->i_sp->s_log_zone_size;
if (scale == 0) return;
zone_size = rip->i_sp->s_block_size << scale;
if (flag == 1) pos = (off_t) ((pos/zone_size) * zone_size);
next = pos + rip->i_sp->s_block_size - 1;
/* If 'pos' is in the last block of a zone, do not clear the zone. */
if (next/zone_size != pos/zone_size) return;
if ( (blo = read_map(rip, next)) == NO_BLOCK) return;
bhi = (block_t) ( ((blo>>scale)+1) << scale) - 1;
/* Clear all the blocks between 'blo' and 'bhi'. */
for (b = blo; b <= bhi; b++) {
bp = get_block(rip->i_dev, b, NO_READ);
zero_block(bp);
put_block(bp, FULL_DATA_BLOCK);
}
}
/*===========================================================================*
* new_block *
*===========================================================================*/
struct buf *new_block(rip, position)
register struct inode *rip; /* pointer to inode */
off_t position; /* file pointer */
{
/* Acquire a new block and return a pointer to it. Doing so may require
* allocating a complete zone, and then returning the initial block.
* On the other hand, the current zone may still have some unused blocks.
*/
register struct buf *bp;
block_t b, base_block;
zone_t z;
zone_t zone_size;
int scale, r;
/* Is another block available in the current zone? */
if ( (b = read_map(rip, position)) == NO_BLOCK) {
if (rip->i_zsearch == NO_ZONE) {
/* First search for this file. Start looking from
* the file's first data zone to prevent fragmentation
*/
if ( (z = rip->i_zone[0]) == NO_ZONE) {
/* No first zone for file either, let alloc_zone
* decide. */
z = (zone_t) rip->i_sp->s_firstdatazone;
}
} else {
/* searched before, start from last find */
z = rip->i_zsearch;
}
if ( (z = alloc_zone(rip->i_dev, z)) == NO_ZONE) return(NULL);
rip->i_zsearch = z; /* store for next lookup */
if ( (r = write_map(rip, position, z, 0)) != OK) {
free_zone(rip->i_dev, z);
err_code = r;
return(NULL);
}
/* If we are not writing at EOF, clear the zone, just to be safe. */
if ( position != rip->i_size) clear_zone(rip, position, 1);
scale = rip->i_sp->s_log_zone_size;
base_block = (block_t) z << scale;
zone_size = (zone_t) rip->i_sp->s_block_size << scale;
b = base_block + (block_t)((position % zone_size)/rip->i_sp->s_block_size);
}
bp = get_block(rip->i_dev, b, NO_READ);
zero_block(bp);
return(bp);
}
/*===========================================================================*
* zero_block *
*===========================================================================*/
void zero_block(bp)
register struct buf *bp; /* pointer to buffer to zero */
{
/* Zero a block. */
ASSERT(lmfs_bytes(bp) > 0);
ASSERT(bp->data);
memset(b_data(bp), 0, (size_t) lmfs_bytes(bp));
MARKDIRTY(bp);
}
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