/* 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 #include #include #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 */ assert(sp->s_version == V3); 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(). */ int scale; /* If the block size and zone size are the same, clear_zone() not needed. */ scale = rip->i_sp->s_log_zone_size; assert(scale == 0); return; } /*===========================================================================* * 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, 0)) == 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 = lmfs_get_block_ino(rip->i_dev, b, NO_READ, rip->i_num, rounddown(position, rip->i_sp->s_block_size)); 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); }