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1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857 1858 1859 1860 1861 1862 1863 1864 1865 1866 1867 1868 1869 1870 1871 1872 1873 1874 1875 1876 1877 1878 1879 1880 1881 1882 1883 1884 1885 1886 1887 1888 1889 1890 1891 1892 1893 1894 1895 1896 1897 1898 1899 1900 1901 1902 1903 1904 1905 1906 1907 1908 1909 1910 1911 1912 1913 1914 1915 1916 1917 1918 1919 1920 1921 1922 1923 1924 1925 1926 1927 1928 1929 1930 1931 1932 1933 1934 1935 1936 1937 1938 | /* * linux/fs/buffer.c * * Copyright (C) 1991, 1992 Linus Torvalds */ /* * 'buffer.c' implements the buffer-cache functions. Race-conditions have * been avoided by NEVER letting an interrupt change a buffer (except for the * data, of course), but instead letting the caller do it. */ /* * NOTE! There is one discordant note here: checking floppies for * disk change. This is where it fits best, I think, as it should * invalidate changed floppy-disk-caches. */ #include <linux/sched.h> #include <linux/kernel.h> #include <linux/major.h> #include <linux/string.h> #include <linux/locks.h> #include <linux/errno.h> #include <linux/malloc.h> #include <asm/system.h> #include <asm/segment.h> #include <asm/io.h> #define NR_SIZES 4 static char buffersize_index[9] = {-1, 0, 1, -1, 2, -1, -1, -1, 3}; static short int bufferindex_size[NR_SIZES] = {512, 1024, 2048, 4096}; #define BUFSIZE_INDEX(X) ((int) buffersize_index[(X)>>9]) #define MAX_BUF_PER_PAGE (PAGE_SIZE / 512) static int grow_buffers(int pri, int size); static int shrink_specific_buffers(unsigned int priority, int size); static int maybe_shrink_lav_buffers(int); static int nr_hash = 0; /* Size of hash table */ static struct buffer_head ** hash_table; struct buffer_head ** buffer_pages; static struct buffer_head * lru_list[NR_LIST] = {NULL, }; static struct buffer_head * free_list[NR_SIZES] = {NULL, }; static struct buffer_head * unused_list = NULL; static struct wait_queue * buffer_wait = NULL; int nr_buffers = 0; int nr_buffers_type[NR_LIST] = {0,}; int nr_buffers_size[NR_SIZES] = {0,}; int nr_buffers_st[NR_SIZES][NR_LIST] = {{0,},}; int buffer_usage[NR_SIZES] = {0,}; /* Usage counts used to determine load average */ int buffers_lav[NR_SIZES] = {0,}; /* Load average of buffer usage */ int nr_free[NR_SIZES] = {0,}; int buffermem = 0; int nr_buffer_heads = 0; extern int *blksize_size[]; /* Here is the parameter block for the bdflush process. */ static void wakeup_bdflush(int); #define N_PARAM 9 #define LAV static union bdflush_param{ struct { int nfract; /* Percentage of buffer cache dirty to activate bdflush */ int ndirty; /* Maximum number of dirty blocks to write out per wake-cycle */ int nrefill; /* Number of clean buffers to try and obtain each time we call refill */ int nref_dirt; /* Dirty buffer threshold for activating bdflush when trying to refill buffers. */ int clu_nfract; /* Percentage of buffer cache to scan to search for free clusters */ int age_buffer; /* Time for normal buffer to age before we flush it */ int age_super; /* Time for superblock to age before we flush it */ int lav_const; /* Constant used for load average (time constant */ int lav_ratio; /* Used to determine how low a lav for a particular size can go before we start to trim back the buffers */ } b_un; unsigned int data[N_PARAM]; } bdf_prm = {{25, 500, 64, 256, 15, 30*HZ, 5*HZ, 1884, 2}}; /* The lav constant is set for 1 minute, as long as the update process runs every 5 seconds. If you change the frequency of update, the time constant will also change. */ /* These are the min and max parameter values that we will allow to be assigned */ static int bdflush_min[N_PARAM] = { 0, 10, 5, 25, 0, 100, 100, 1, 1}; static int bdflush_max[N_PARAM] = {100,5000, 2000, 2000,100, 60000, 60000, 2047, 5}; /* * Rewrote the wait-routines to use the "new" wait-queue functionality, * and getting rid of the cli-sti pairs. The wait-queue routines still * need cli-sti, but now it's just a couple of 386 instructions or so. * * Note that the real wait_on_buffer() is an inline function that checks * if 'b_wait' is set before calling this, so that the queues aren't set * up unnecessarily. */ void __wait_on_buffer(struct buffer_head * bh) { struct wait_queue wait = { current, NULL }; bh->b_count++; add_wait_queue(&bh->b_wait, &wait); repeat: current->state = TASK_UNINTERRUPTIBLE; if (bh->b_lock) { schedule(); goto repeat; } remove_wait_queue(&bh->b_wait, &wait); bh->b_count--; current->state = TASK_RUNNING; } /* Call sync_buffers with wait!=0 to ensure that the call does not return until all buffer writes have completed. Sync() may return before the writes have finished; fsync() may not. */ /* Godamity-damn. Some buffers (bitmaps for filesystems) spontaneously dirty themselves without ever brelse being called. We will ultimately want to put these in a separate list, but for now we search all of the lists for dirty buffers */ static int sync_buffers(kdev_t dev, int wait) { int i, retry, pass = 0, err = 0; int nlist, ncount; struct buffer_head * bh, *next; /* One pass for no-wait, three for wait: 0) write out all dirty, unlocked buffers; 1) write out all dirty buffers, waiting if locked; 2) wait for completion by waiting for all buffers to unlock. */ repeat: retry = 0; repeat2: ncount = 0; /* We search all lists as a failsafe mechanism, not because we expect there to be dirty buffers on any of the other lists. */ for(nlist = 0; nlist < NR_LIST; nlist++) { repeat1: bh = lru_list[nlist]; if(!bh) continue; for (i = nr_buffers_type[nlist]*2 ; i-- > 0 ; bh = next) { if(bh->b_list != nlist) goto repeat1; next = bh->b_next_free; if(!lru_list[nlist]) break; if (dev && bh->b_dev != dev) continue; if (bh->b_lock) { /* Buffer is locked; skip it unless wait is requested AND pass > 0. */ if (!wait || !pass) { retry = 1; continue; } wait_on_buffer (bh); goto repeat2; } /* If an unlocked buffer is not uptodate, there has been an IO error. Skip it. */ if (wait && bh->b_req && !bh->b_lock && !bh->b_dirt && !bh->b_uptodate) { err = 1; printk("Weird - unlocked, clean and not " "uptodate buffer on list %d %s %lu\n", nlist, kdevname(bh->b_dev), bh->b_blocknr); continue; } /* Don't write clean buffers. Don't write ANY buffers on the third pass. */ if (!bh->b_dirt || pass>=2) continue; /* don't bother about locked buffers */ if (bh->b_lock) continue; bh->b_count++; bh->b_flushtime = 0; ll_rw_block(WRITE, 1, &bh); if(nlist != BUF_DIRTY) { printk("[%d %s %ld] ", nlist, kdevname(bh->b_dev), bh->b_blocknr); ncount++; }; bh->b_count--; retry = 1; } } if (ncount) printk("sys_sync: %d dirty buffers not on dirty list\n", ncount); /* If we are waiting for the sync to succeed, and if any dirty blocks were written, then repeat; on the second pass, only wait for buffers being written (do not pass to write any more buffers on the second pass). */ if (wait && retry && ++pass<=2) goto repeat; return err; } void sync_dev(kdev_t dev) { sync_buffers(dev, 0); sync_supers(dev); sync_inodes(dev); sync_buffers(dev, 0); } int fsync_dev(kdev_t dev) { sync_buffers(dev, 0); sync_supers(dev); sync_inodes(dev); return sync_buffers(dev, 1); } asmlinkage int sys_sync(void) { fsync_dev(0); return 0; } int file_fsync (struct inode *inode, struct file *filp) { return fsync_dev(inode->i_dev); } asmlinkage int sys_fsync(unsigned int fd) { struct file * file; struct inode * inode; if (fd>=NR_OPEN || !(file=current->files->fd[fd]) || !(inode=file->f_inode)) return -EBADF; if (!file->f_op || !file->f_op->fsync) return -EINVAL; if (file->f_op->fsync(inode,file)) return -EIO; return 0; } void invalidate_buffers(kdev_t dev) { int i; int nlist; struct buffer_head * bh; for(nlist = 0; nlist < NR_LIST; nlist++) { bh = lru_list[nlist]; for (i = nr_buffers_type[nlist]*2 ; --i > 0 ; bh = bh->b_next_free) { if (bh->b_dev != dev) continue; wait_on_buffer(bh); if (bh->b_dev != dev) continue; if (bh->b_count) continue; bh->b_flushtime = bh->b_uptodate = bh->b_dirt = bh->b_req = 0; } } } #define _hashfn(dev,block) (((unsigned)(HASHDEV(dev)^block))%nr_hash) #define hash(dev,block) hash_table[_hashfn(dev,block)] static inline void remove_from_hash_queue(struct buffer_head * bh) { if (bh->b_next) bh->b_next->b_prev = bh->b_prev; if (bh->b_prev) bh->b_prev->b_next = bh->b_next; if (hash(bh->b_dev,bh->b_blocknr) == bh) hash(bh->b_dev,bh->b_blocknr) = bh->b_next; bh->b_next = bh->b_prev = NULL; } static inline void remove_from_lru_list(struct buffer_head * bh) { if (!(bh->b_prev_free) || !(bh->b_next_free)) panic("VFS: LRU block list corrupted"); if (bh->b_dev == B_FREE) panic("LRU list corrupted"); bh->b_prev_free->b_next_free = bh->b_next_free; bh->b_next_free->b_prev_free = bh->b_prev_free; if (lru_list[bh->b_list] == bh) lru_list[bh->b_list] = bh->b_next_free; if(lru_list[bh->b_list] == bh) lru_list[bh->b_list] = NULL; bh->b_next_free = bh->b_prev_free = NULL; } static inline void remove_from_free_list(struct buffer_head * bh) { int isize = BUFSIZE_INDEX(bh->b_size); if (!(bh->b_prev_free) || !(bh->b_next_free)) panic("VFS: Free block list corrupted"); if(bh->b_dev != B_FREE) panic("Free list corrupted"); if(!free_list[isize]) panic("Free list empty"); nr_free[isize]--; if(bh->b_next_free == bh) free_list[isize] = NULL; else { bh->b_prev_free->b_next_free = bh->b_next_free; bh->b_next_free->b_prev_free = bh->b_prev_free; if (free_list[isize] == bh) free_list[isize] = bh->b_next_free; }; bh->b_next_free = bh->b_prev_free = NULL; } static inline void remove_from_queues(struct buffer_head * bh) { if(bh->b_dev == B_FREE) { remove_from_free_list(bh); /* Free list entries should not be in the hash queue */ return; }; nr_buffers_type[bh->b_list]--; nr_buffers_st[BUFSIZE_INDEX(bh->b_size)][bh->b_list]--; remove_from_hash_queue(bh); remove_from_lru_list(bh); } static inline void put_last_lru(struct buffer_head * bh) { if (!bh) return; if (bh == lru_list[bh->b_list]) { lru_list[bh->b_list] = bh->b_next_free; return; } if(bh->b_dev == B_FREE) panic("Wrong block for lru list"); remove_from_lru_list(bh); /* add to back of free list */ if(!lru_list[bh->b_list]) { lru_list[bh->b_list] = bh; lru_list[bh->b_list]->b_prev_free = bh; }; bh->b_next_free = lru_list[bh->b_list]; bh->b_prev_free = lru_list[bh->b_list]->b_prev_free; lru_list[bh->b_list]->b_prev_free->b_next_free = bh; lru_list[bh->b_list]->b_prev_free = bh; } static inline void put_last_free(struct buffer_head * bh) { int isize; if (!bh) return; isize = BUFSIZE_INDEX(bh->b_size); bh->b_dev = B_FREE; /* So it is obvious we are on the free list */ /* add to back of free list */ if(!free_list[isize]) { free_list[isize] = bh; bh->b_prev_free = bh; }; nr_free[isize]++; bh->b_next_free = free_list[isize]; bh->b_prev_free = free_list[isize]->b_prev_free; free_list[isize]->b_prev_free->b_next_free = bh; free_list[isize]->b_prev_free = bh; } static inline void insert_into_queues(struct buffer_head * bh) { /* put at end of free list */ if(bh->b_dev == B_FREE) { put_last_free(bh); return; }; if(!lru_list[bh->b_list]) { lru_list[bh->b_list] = bh; bh->b_prev_free = bh; }; if (bh->b_next_free) panic("VFS: buffer LRU pointers corrupted"); bh->b_next_free = lru_list[bh->b_list]; bh->b_prev_free = lru_list[bh->b_list]->b_prev_free; lru_list[bh->b_list]->b_prev_free->b_next_free = bh; lru_list[bh->b_list]->b_prev_free = bh; nr_buffers_type[bh->b_list]++; nr_buffers_st[BUFSIZE_INDEX(bh->b_size)][bh->b_list]++; /* put the buffer in new hash-queue if it has a device */ bh->b_prev = NULL; bh->b_next = NULL; if (!(bh->b_dev)) return; bh->b_next = hash(bh->b_dev,bh->b_blocknr); hash(bh->b_dev,bh->b_blocknr) = bh; if (bh->b_next) bh->b_next->b_prev = bh; } static struct buffer_head * find_buffer(kdev_t dev, int block, int size) { struct buffer_head * tmp; for (tmp = hash(dev,block) ; tmp != NULL ; tmp = tmp->b_next) if (tmp->b_dev == dev && tmp->b_blocknr == block) if (tmp->b_size == size) return tmp; else { printk("VFS: Wrong blocksize on device %s\n", kdevname(dev)); return NULL; } return NULL; } /* * Why like this, I hear you say... The reason is race-conditions. * As we don't lock buffers (unless we are reading them, that is), * something might happen to it while we sleep (ie a read-error * will force it bad). This shouldn't really happen currently, but * the code is ready. */ struct buffer_head * get_hash_table(kdev_t dev, int block, int size) { struct buffer_head * bh; for (;;) { if (!(bh=find_buffer(dev,block,size))) return NULL; bh->b_reuse=0; bh->b_count++; wait_on_buffer(bh); if (bh->b_dev == dev && bh->b_blocknr == block && bh->b_size == size) return bh; bh->b_count--; } } void set_blocksize(kdev_t dev, int size) { int i, nlist; struct buffer_head * bh, *bhnext; if (!blksize_size[MAJOR(dev)]) return; switch(size) { default: panic("Invalid blocksize passed to set_blocksize"); case 512: case 1024: case 2048: case 4096:; } if (blksize_size[MAJOR(dev)][MINOR(dev)] == 0 && size == BLOCK_SIZE) { blksize_size[MAJOR(dev)][MINOR(dev)] = size; return; } if (blksize_size[MAJOR(dev)][MINOR(dev)] == size) return; sync_buffers(dev, 2); blksize_size[MAJOR(dev)][MINOR(dev)] = size; /* We need to be quite careful how we do this - we are moving entries around on the free list, and we can get in a loop if we are not careful.*/ for(nlist = 0; nlist < NR_LIST; nlist++) { bh = lru_list[nlist]; for (i = nr_buffers_type[nlist]*2 ; --i > 0 ; bh = bhnext) { if(!bh) break; bhnext = bh->b_next_free; if (bh->b_dev != dev) continue; if (bh->b_size == size) continue; wait_on_buffer(bh); if (bh->b_dev == dev && bh->b_size != size) { bh->b_uptodate = bh->b_dirt = bh->b_req = bh->b_flushtime = 0; }; remove_from_hash_queue(bh); } } } #define BADNESS(bh) (((bh)->b_dirt<<1)+(bh)->b_lock) void refill_freelist(int size) { struct buffer_head * bh, * tmp; struct buffer_head * candidate[NR_LIST]; unsigned int best_time, winner; int isize = BUFSIZE_INDEX(size); int buffers[NR_LIST]; int i; int needed; /* First see if we even need this. Sometimes it is advantageous to request some blocks in a filesystem that we know that we will be needing ahead of time. */ if (nr_free[isize] > 100) return; /* If there are too many dirty buffers, we wake up the update process now so as to ensure that there are still clean buffers available for user processes to use (and dirty) */ /* We are going to try and locate this much memory */ needed =bdf_prm.b_un.nrefill * size; while (nr_free_pages > min_free_pages*2 && needed > 0 && grow_buffers(GFP_BUFFER, size)) { needed -= PAGE_SIZE; } if(needed <= 0) return; /* See if there are too many buffers of a different size. If so, victimize them */ while(maybe_shrink_lav_buffers(size)) { if(!grow_buffers(GFP_BUFFER, size)) break; needed -= PAGE_SIZE; if(needed <= 0) return; }; /* OK, we cannot grow the buffer cache, now try and get some from the lru list */ /* First set the candidate pointers to usable buffers. This should be quick nearly all of the time. */ repeat0: for(i=0; i<NR_LIST; i++){ if(i == BUF_DIRTY || i == BUF_SHARED || nr_buffers_type[i] == 0) { candidate[i] = NULL; buffers[i] = 0; continue; } buffers[i] = nr_buffers_type[i]; for (bh = lru_list[i]; buffers[i] > 0; bh = tmp, buffers[i]--) { if(buffers[i] < 0) panic("Here is the problem"); tmp = bh->b_next_free; if (!bh) break; if (mem_map[MAP_NR((unsigned long) bh->b_data)].count != 1 || bh->b_dirt) { refile_buffer(bh); continue; }; if (bh->b_count || bh->b_size != size) continue; /* Buffers are written in the order they are placed on the locked list. If we encounter a locked buffer here, this means that the rest of them are also locked */ if(bh->b_lock && (i == BUF_LOCKED || i == BUF_LOCKED1)) { buffers[i] = 0; break; } if (BADNESS(bh)) continue; break; }; if(!buffers[i]) candidate[i] = NULL; /* Nothing on this list */ else candidate[i] = bh; if(candidate[i] && candidate[i]->b_count) panic("Here is the problem"); } repeat: if(needed <= 0) return; /* Now see which candidate wins the election */ winner = best_time = UINT_MAX; for(i=0; i<NR_LIST; i++){ if(!candidate[i]) continue; if(candidate[i]->b_lru_time < best_time){ best_time = candidate[i]->b_lru_time; winner = i; } } /* If we have a winner, use it, and then get a new candidate from that list */ if(winner != UINT_MAX) { i = winner; bh = candidate[i]; candidate[i] = bh->b_next_free; if(candidate[i] == bh) candidate[i] = NULL; /* Got last one */ if (bh->b_count || bh->b_size != size) panic("Busy buffer in candidate list\n"); if (mem_map[MAP_NR((unsigned long) bh->b_data)].count != 1) panic("Shared buffer in candidate list\n"); if (BADNESS(bh)) panic("Buffer in candidate list with BADNESS != 0\n"); if(bh->b_dev == B_FREE) panic("Wrong list"); remove_from_queues(bh); bh->b_dev = B_FREE; put_last_free(bh); needed -= bh->b_size; buffers[i]--; if(buffers[i] < 0) panic("Here is the problem"); if(buffers[i] == 0) candidate[i] = NULL; /* Now all we need to do is advance the candidate pointer from the winner list to the next usable buffer */ if(candidate[i] && buffers[i] > 0){ if(buffers[i] <= 0) panic("Here is another problem"); for (bh = candidate[i]; buffers[i] > 0; bh = tmp, buffers[i]--) { if(buffers[i] < 0) panic("Here is the problem"); tmp = bh->b_next_free; if (!bh) break; if (mem_map[MAP_NR((unsigned long) bh->b_data)].count != 1 || bh->b_dirt) { refile_buffer(bh); continue; }; if (bh->b_count || bh->b_size != size) continue; /* Buffers are written in the order they are placed on the locked list. If we encounter a locked buffer here, this means that the rest of them are also locked */ if(bh->b_lock && (i == BUF_LOCKED || i == BUF_LOCKED1)) { buffers[i] = 0; break; } if (BADNESS(bh)) continue; break; }; if(!buffers[i]) candidate[i] = NULL; /* Nothing here */ else candidate[i] = bh; if(candidate[i] && candidate[i]->b_count) panic("Here is the problem"); } goto repeat; } if(needed <= 0) return; /* Too bad, that was not enough. Try a little harder to grow some. */ if (nr_free_pages > 5) { if (grow_buffers(GFP_BUFFER, size)) { needed -= PAGE_SIZE; goto repeat0; }; } /* and repeat until we find something good */ if (!grow_buffers(GFP_ATOMIC, size)) wakeup_bdflush(1); needed -= PAGE_SIZE; goto repeat0; } /* * Ok, this is getblk, and it isn't very clear, again to hinder * race-conditions. Most of the code is seldom used, (ie repeating), * so it should be much more efficient than it looks. * * The algorithm is changed: hopefully better, and an elusive bug removed. * * 14.02.92: changed it to sync dirty buffers a bit: better performance * when the filesystem starts to get full of dirty blocks (I hope). */ struct buffer_head * getblk(kdev_t dev, int block, int size) { struct buffer_head * bh; int isize = BUFSIZE_INDEX(size); /* Update this for the buffer size lav. */ buffer_usage[isize]++; /* If there are too many dirty buffers, we wake up the update process now so as to ensure that there are still clean buffers available for user processes to use (and dirty) */ repeat: bh = get_hash_table(dev, block, size); if (bh) { if (bh->b_uptodate && !bh->b_dirt) put_last_lru(bh); if(!bh->b_dirt) bh->b_flushtime = 0; return bh; } while(!free_list[isize]) refill_freelist(size); if (find_buffer(dev,block,size)) goto repeat; bh = free_list[isize]; remove_from_free_list(bh); /* OK, FINALLY we know that this buffer is the only one of its kind, */ /* and that it's unused (b_count=0), unlocked (b_lock=0), and clean */ bh->b_count=1; bh->b_dirt=0; bh->b_lock=0; bh->b_uptodate=0; bh->b_flushtime=0; bh->b_req=0; bh->b_reuse=0; bh->b_dev=dev; bh->b_blocknr=block; insert_into_queues(bh); return bh; } void set_writetime(struct buffer_head * buf, int flag) { int newtime; if (buf->b_dirt){ /* Move buffer to dirty list if jiffies is clear */ newtime = jiffies + (flag ? bdf_prm.b_un.age_super : bdf_prm.b_un.age_buffer); if(!buf->b_flushtime || buf->b_flushtime > newtime) buf->b_flushtime = newtime; } else { buf->b_flushtime = 0; } } void refile_buffer(struct buffer_head * buf){ int dispose; if(buf->b_dev == B_FREE) panic("Attempt to refile free buffer\n"); if (buf->b_dirt) dispose = BUF_DIRTY; else if (mem_map[MAP_NR((unsigned long) buf->b_data)].count > 1) dispose = BUF_SHARED; else if (buf->b_lock) dispose = BUF_LOCKED; else if (buf->b_list == BUF_SHARED) dispose = BUF_UNSHARED; else dispose = BUF_CLEAN; if(dispose == BUF_CLEAN) buf->b_lru_time = jiffies; if(dispose != buf->b_list) { if(dispose == BUF_DIRTY || dispose == BUF_UNSHARED) buf->b_lru_time = jiffies; if(dispose == BUF_LOCKED && (buf->b_flushtime - buf->b_lru_time) <= bdf_prm.b_un.age_super) dispose = BUF_LOCKED1; remove_from_queues(buf); buf->b_list = dispose; insert_into_queues(buf); if(dispose == BUF_DIRTY && nr_buffers_type[BUF_DIRTY] > (nr_buffers - nr_buffers_type[BUF_SHARED]) * bdf_prm.b_un.nfract/100) wakeup_bdflush(0); } } void brelse(struct buffer_head * buf) { if (!buf) return; wait_on_buffer(buf); /* If dirty, mark the time this buffer should be written back */ set_writetime(buf, 0); refile_buffer(buf); if (buf->b_count) { if (--buf->b_count) return; wake_up(&buffer_wait); #if 0 if (buf->b_reuse) { buf->b_reuse = 0; if (!buf->b_lock && !buf->b_dirt && !buf->b_wait) { if(buf->b_dev == B_FREE) panic("brelse: Wrong list"); remove_from_queues(buf); buf->b_dev = B_FREE; put_last_free(buf); } } #endif return; } printk("VFS: brelse: Trying to free free buffer\n"); } /* * bread() reads a specified block and returns the buffer that contains * it. It returns NULL if the block was unreadable. */ struct buffer_head * bread(kdev_t dev, int block, int size) { struct buffer_head * bh; if (!(bh = getblk(dev, block, size))) { printk("VFS: bread: READ error on device %s\n", kdevname(dev)); return NULL; } if (bh->b_uptodate) return bh; ll_rw_block(READ, 1, &bh); wait_on_buffer(bh); if (bh->b_uptodate) return bh; brelse(bh); return NULL; } /* * Ok, breada can be used as bread, but additionally to mark other * blocks for reading as well. End the argument list with a negative * number. */ #define NBUF 16 struct buffer_head * breada(kdev_t dev, int block, int bufsize, unsigned int pos, unsigned int filesize) { struct buffer_head * bhlist[NBUF]; unsigned int blocks; struct buffer_head * bh; int index; int i, j; if (pos >= filesize) return NULL; if (block < 0 || !(bh = getblk(dev,block,bufsize))) return NULL; index = BUFSIZE_INDEX(bh->b_size); if (bh->b_uptodate) return bh; blocks = ((filesize & (bufsize - 1)) - (pos & (bufsize - 1))) >> (9+index); if (blocks > (read_ahead[MAJOR(dev)] >> index)) blocks = read_ahead[MAJOR(dev)] >> index; if (blocks > NBUF) blocks = NBUF; bhlist[0] = bh; j = 1; for(i=1; i<blocks; i++) { bh = getblk(dev,block+i,bufsize); if (bh->b_uptodate) { brelse(bh); break; } bhlist[j++] = bh; } /* Request the read for these buffers, and then release them */ ll_rw_block(READ, j, bhlist); for(i=1; i<j; i++) brelse(bhlist[i]); /* Wait for this buffer, and then continue on */ bh = bhlist[0]; wait_on_buffer(bh); if (bh->b_uptodate) return bh; brelse(bh); return NULL; } /* * See fs/inode.c for the weird use of volatile.. */ static void put_unused_buffer_head(struct buffer_head * bh) { struct wait_queue * wait; wait = ((volatile struct buffer_head *) bh)->b_wait; memset(bh,0,sizeof(*bh)); ((volatile struct buffer_head *) bh)->b_wait = wait; bh->b_next_free = unused_list; unused_list = bh; } static void get_more_buffer_heads(void) { int i; struct buffer_head * bh; if (unused_list) return; if (!(bh = (struct buffer_head*) get_free_page(GFP_BUFFER))) return; for (nr_buffer_heads+=i=PAGE_SIZE/sizeof*bh ; i>0; i--) { bh->b_next_free = unused_list; /* only make link */ unused_list = bh++; } } static struct buffer_head * get_unused_buffer_head(void) { struct buffer_head * bh; get_more_buffer_heads(); if (!unused_list) return NULL; bh = unused_list; unused_list = bh->b_next_free; bh->b_next_free = NULL; bh->b_data = NULL; bh->b_size = 0; bh->b_req = 0; return bh; } /* * Create the appropriate buffers when given a page for data area and * the size of each buffer.. Use the bh->b_this_page linked list to * follow the buffers created. Return NULL if unable to create more * buffers. */ static struct buffer_head * create_buffers(unsigned long page, unsigned long size) { struct buffer_head *bh, *head; unsigned long offset; head = NULL; offset = PAGE_SIZE; while ((offset -= size) < PAGE_SIZE) { bh = get_unused_buffer_head(); if (!bh) goto no_grow; bh->b_this_page = head; head = bh; bh->b_data = (char *) (page+offset); bh->b_size = size; bh->b_dev = B_FREE; /* Flag as unused */ } return head; /* * In case anything failed, we just free everything we got. */ no_grow: bh = head; while (bh) { head = bh; bh = bh->b_this_page; put_unused_buffer_head(head); } return NULL; } static void read_buffers(struct buffer_head * bh[], int nrbuf) { int i; int bhnum = 0; struct buffer_head * bhr[MAX_BUF_PER_PAGE]; for (i = 0 ; i < nrbuf ; i++) { if (bh[i] && !bh[i]->b_uptodate) bhr[bhnum++] = bh[i]; } if (bhnum) ll_rw_block(READ, bhnum, bhr); for (i = nrbuf ; --i >= 0 ; ) { if (bh[i]) { wait_on_buffer(bh[i]); } } } /* * This actually gets enough info to try to align the stuff, * but we don't bother yet.. We'll have to check that nobody * else uses the buffers etc. * * "address" points to the new page we can use to move things * around.. */ static unsigned long try_to_align(struct buffer_head ** bh, int nrbuf, unsigned long address) { while (nrbuf-- > 0) brelse(bh[nrbuf]); return 0; } static unsigned long check_aligned(struct buffer_head * first, unsigned long address, kdev_t dev, int *b, int size) { struct buffer_head * bh[MAX_BUF_PER_PAGE]; unsigned long page; unsigned long offset; int block; int nrbuf; int aligned = 1; bh[0] = first; nrbuf = 1; page = (unsigned long) first->b_data; if (page & ~PAGE_MASK) aligned = 0; for (offset = size ; offset < PAGE_SIZE ; offset += size) { block = *++b; if (!block) goto no_go; first = get_hash_table(dev, block, size); if (!first) goto no_go; bh[nrbuf++] = first; if (page+offset != (unsigned long) first->b_data) aligned = 0; } if (!aligned) return try_to_align(bh, nrbuf, address); mem_map[MAP_NR(page)].count++; read_buffers(bh,nrbuf); /* make sure they are actually read correctly */ while (nrbuf-- > 0) brelse(bh[nrbuf]); free_page(address); ++current->min_flt; return page; no_go: while (nrbuf-- > 0) brelse(bh[nrbuf]); return 0; } static unsigned long try_to_load_aligned(unsigned long address, kdev_t dev, int b[], int size) { struct buffer_head * bh, * tmp, * arr[MAX_BUF_PER_PAGE]; unsigned long offset; int isize = BUFSIZE_INDEX(size); int * p; int block; bh = create_buffers(address, size); if (!bh) return 0; /* do any of the buffers already exist? punt if so.. */ p = b; for (offset = 0 ; offset < PAGE_SIZE ; offset += size) { block = *(p++); if (!block) goto not_aligned; if (find_buffer(dev, block, size)) goto not_aligned; } tmp = bh; p = b; block = 0; while (1) { arr[block++] = bh; bh->b_count = 1; bh->b_dirt = 0; bh->b_reuse = 0; bh->b_flushtime = 0; bh->b_uptodate = 0; bh->b_req = 0; bh->b_dev = dev; bh->b_blocknr = *(p++); bh->b_list = BUF_CLEAN; nr_buffers++; nr_buffers_size[isize]++; insert_into_queues(bh); if (bh->b_this_page) bh = bh->b_this_page; else break; } buffermem += PAGE_SIZE; bh->b_this_page = tmp; mem_map[MAP_NR(address)].count++; buffer_pages[MAP_NR(address)] = bh; read_buffers(arr,block); while (block-- > 0) brelse(arr[block]); ++current->maj_flt; return address; not_aligned: while ((tmp = bh) != NULL) { bh = bh->b_this_page; put_unused_buffer_head(tmp); } return 0; } /* * Try-to-share-buffers tries to minimize memory use by trying to keep * both code pages and the buffer area in the same page. This is done by * (a) checking if the buffers are already aligned correctly in memory and * (b) if none of the buffer heads are in memory at all, trying to load * them into memory the way we want them. * * This doesn't guarantee that the memory is shared, but should under most * circumstances work very well indeed (ie >90% sharing of code pages on * demand-loadable executables). */ static inline unsigned long try_to_share_buffers(unsigned long address, kdev_t dev, int *b, int size) { struct buffer_head * bh; int block; block = b[0]; if (!block) return 0; bh = get_hash_table(dev, block, size); if (bh) return check_aligned(bh, address, dev, b, size); return try_to_load_aligned(address, dev, b, size); } /* * bread_page reads four buffers into memory at the desired address. It's * a function of its own, as there is some speed to be got by reading them * all at the same time, not waiting for one to be read, and then another * etc. This also allows us to optimize memory usage by sharing code pages * and filesystem buffers.. */ unsigned long bread_page(unsigned long address, kdev_t dev, int b[], int size, int no_share) { struct buffer_head * bh[MAX_BUF_PER_PAGE]; unsigned long where; int i, j; if (!no_share) { where = try_to_share_buffers(address, dev, b, size); if (where) return where; } ++current->maj_flt; for (i=0, j=0; j<PAGE_SIZE ; i++, j+= size) { bh[i] = NULL; if (b[i]) bh[i] = getblk(dev, b[i], size); } read_buffers(bh,i); where = address; for (i=0, j=0; j<PAGE_SIZE ; i++, j += size, where += size) { if (bh[i]) { if (bh[i]->b_uptodate) memcpy((void *) where, bh[i]->b_data, size); brelse(bh[i]); } else memset((void *) where, 0, size); } return address; } #if 0 /* * bwrite_page writes a page out to the buffer cache and/or the physical device. * It's used for mmap writes (the same way bread_page() is used for mmap reads). */ void bwrite_page(unsigned long address, kdev_t dev, int b[], int size) { struct buffer_head * bh[MAX_BUF_PER_PAGE]; int i, j; for (i=0, j=0; j<PAGE_SIZE ; i++, j+= size) { bh[i] = NULL; if (b[i]) bh[i] = getblk(dev, b[i], size); } for (i=0, j=0; j<PAGE_SIZE ; i++, j += size, address += size) { if (bh[i]) { memcpy(bh[i]->b_data, (void *) address, size); bh[i]->b_uptodate = 1; mark_buffer_dirty(bh[i], 0); brelse(bh[i]); } else memset((void *) address, 0, size); /* ???!?!! */ } } #endif /* * Try to increase the number of buffers available: the size argument * is used to determine what kind of buffers we want. */ static int grow_buffers(int pri, int size) { unsigned long page; struct buffer_head *bh, *tmp; struct buffer_head * insert_point; int isize; if ((size & 511) || (size > PAGE_SIZE)) { printk("VFS: grow_buffers: size = %d\n",size); return 0; } isize = BUFSIZE_INDEX(size); if (!(page = __get_free_page(pri))) return 0; bh = create_buffers(page, size); if (!bh) { free_page(page); return 0; } insert_point = free_list[isize]; tmp = bh; while (1) { nr_free[isize]++; if (insert_point) { tmp->b_next_free = insert_point->b_next_free; tmp->b_prev_free = insert_point; insert_point->b_next_free->b_prev_free = tmp; insert_point->b_next_free = tmp; } else { tmp->b_prev_free = tmp; tmp->b_next_free = tmp; } insert_point = tmp; ++nr_buffers; if (tmp->b_this_page) tmp = tmp->b_this_page; else break; } free_list[isize] = bh; buffer_pages[MAP_NR(page)] = bh; tmp->b_this_page = bh; wake_up(&buffer_wait); buffermem += PAGE_SIZE; return 1; } /* =========== Reduce the buffer memory ============= */ /* * try_to_free() checks if all the buffers on this particular page * are unused, and free's the page if so. */ static int try_to_free(struct buffer_head * bh, struct buffer_head ** bhp) { unsigned long page; struct buffer_head * tmp, * p; int isize = BUFSIZE_INDEX(bh->b_size); *bhp = bh; page = (unsigned long) bh->b_data; page &= PAGE_MASK; tmp = bh; do { if (!tmp) return 0; if (tmp->b_count || tmp->b_dirt || tmp->b_lock || tmp->b_wait) return 0; tmp = tmp->b_this_page; } while (tmp != bh); tmp = bh; do { p = tmp; tmp = tmp->b_this_page; nr_buffers--; nr_buffers_size[isize]--; if (p == *bhp) { *bhp = p->b_prev_free; if (p == *bhp) /* Was this the last in the list? */ *bhp = NULL; } remove_from_queues(p); put_unused_buffer_head(p); } while (tmp != bh); buffermem -= PAGE_SIZE; buffer_pages[MAP_NR(page)] = NULL; free_page(page); return !mem_map[MAP_NR(page)].count; } /* * Consult the load average for buffers and decide whether or not * we should shrink the buffers of one size or not. If we decide yes, * do it and return 1. Else return 0. Do not attempt to shrink size * that is specified. * * I would prefer not to use a load average, but the way things are now it * seems unavoidable. The way to get rid of it would be to force clustering * universally, so that when we reclaim buffers we always reclaim an entire * page. Doing this would mean that we all need to move towards QMAGIC. */ static int maybe_shrink_lav_buffers(int size) { int nlist; int isize; int total_lav, total_n_buffers, n_sizes; /* Do not consider the shared buffers since they would not tend to have getblk called very often, and this would throw off the lav. They are not easily reclaimable anyway (let the swapper make the first move). */ total_lav = total_n_buffers = n_sizes = 0; for(nlist = 0; nlist < NR_SIZES; nlist++) { total_lav += buffers_lav[nlist]; if(nr_buffers_size[nlist]) n_sizes++; total_n_buffers += nr_buffers_size[nlist]; total_n_buffers -= nr_buffers_st[nlist][BUF_SHARED]; } /* See if we have an excessive number of buffers of a particular size - if so, victimize that bunch. */ isize = (size ? BUFSIZE_INDEX(size) : -1); if (n_sizes > 1) for(nlist = 0; nlist < NR_SIZES; nlist++) { if(nlist == isize) continue; if(nr_buffers_size[nlist] && bdf_prm.b_un.lav_const * buffers_lav[nlist]*total_n_buffers < total_lav * (nr_buffers_size[nlist] - nr_buffers_st[nlist][BUF_SHARED])) if(shrink_specific_buffers(6, bufferindex_size[nlist])) return 1; } return 0; } /* * Try to free up some pages by shrinking the buffer-cache * * Priority tells the routine how hard to try to shrink the * buffers: 3 means "don't bother too much", while a value * of 0 means "we'd better get some free pages now". * * "limit" is meant to limit the shrink-action only to pages * that are in the 0 - limit address range, for DMA re-allocations. * We ignore that right now. */ int shrink_buffers(unsigned int priority, unsigned long limit) { if (priority < 2) { sync_buffers(0,0); } if(priority == 2) wakeup_bdflush(1); if(maybe_shrink_lav_buffers(0)) return 1; /* No good candidate size - take any size we can find */ return shrink_specific_buffers(priority, 0); } static int shrink_specific_buffers(unsigned int priority, int size) { struct buffer_head *bh; int nlist; int i, isize, isize1; #ifdef DEBUG if(size) printk("Shrinking buffers of size %d\n", size); #endif /* First try the free lists, and see if we can get a complete page from here */ isize1 = (size ? BUFSIZE_INDEX(size) : -1); for(isize = 0; isize<NR_SIZES; isize++){ if(isize1 != -1 && isize1 != isize) continue; bh = free_list[isize]; if(!bh) continue; for (i=0 ; !i || bh != free_list[isize]; bh = bh->b_next_free, i++) { if (bh->b_count || !bh->b_this_page) continue; if (try_to_free(bh, &bh)) return 1; if(!bh) break; /* Some interrupt must have used it after we freed the page. No big deal - keep looking */ } } /* Not enough in the free lists, now try the lru list */ for(nlist = 0; nlist < NR_LIST; nlist++) { repeat1: if(priority > 3 && nlist == BUF_SHARED) continue; bh = lru_list[nlist]; if(!bh) continue; i = 2*nr_buffers_type[nlist] >> priority; for ( ; i-- > 0 ; bh = bh->b_next_free) { /* We may have stalled while waiting for I/O to complete. */ if(bh->b_list != nlist) goto repeat1; if (bh->b_count || !bh->b_this_page) continue; if(size && bh->b_size != size) continue; if (bh->b_lock) if (priority) continue; else wait_on_buffer(bh); if (bh->b_dirt) { bh->b_count++; bh->b_flushtime = 0; ll_rw_block(WRITEA, 1, &bh); bh->b_count--; continue; } if (try_to_free(bh, &bh)) return 1; if(!bh) break; } } return 0; } /* ================== Debugging =================== */ void show_buffers(void) { struct buffer_head * bh; int found = 0, locked = 0, dirty = 0, used = 0, lastused = 0; int shared; int nlist, isize; printk("Buffer memory: %6dkB\n",buffermem>>10); printk("Buffer heads: %6d\n",nr_buffer_heads); printk("Buffer blocks: %6d\n",nr_buffers); for(nlist = 0; nlist < NR_LIST; nlist++) { shared = found = locked = dirty = used = lastused = 0; bh = lru_list[nlist]; if(!bh) continue; do { found++; if (bh->b_lock) locked++; if (bh->b_dirt) dirty++; if(mem_map[MAP_NR(((unsigned long) bh->b_data))].count !=1) shared++; if (bh->b_count) used++, lastused = found; bh = bh->b_next_free; } while (bh != lru_list[nlist]); printk("Buffer[%d] mem: %d buffers, %d used (last=%d), %d locked, %d dirty %d shrd\n", nlist, found, used, lastused, locked, dirty, shared); }; printk("Size [LAV] Free Clean Unshar Lck Lck1 Dirty Shared\n"); for(isize = 0; isize<NR_SIZES; isize++){ printk("%5d [%5d]: %7d ", bufferindex_size[isize], buffers_lav[isize], nr_free[isize]); for(nlist = 0; nlist < NR_LIST; nlist++) printk("%7d ", nr_buffers_st[isize][nlist]); printk("\n"); } } /* ====================== Cluster patches for ext2 ==================== */ /* * try_to_reassign() checks if all the buffers on this particular page * are unused, and reassign to a new cluster them if this is true. */ static inline int try_to_reassign(struct buffer_head * bh, struct buffer_head ** bhp, kdev_t dev, unsigned int starting_block) { unsigned long page; struct buffer_head * tmp, * p; *bhp = bh; page = (unsigned long) bh->b_data; page &= PAGE_MASK; if(mem_map[MAP_NR(page)].count != 1) return 0; tmp = bh; do { if (!tmp) return 0; if (tmp->b_count || tmp->b_dirt || tmp->b_lock) return 0; tmp = tmp->b_this_page; } while (tmp != bh); tmp = bh; while((unsigned long) tmp->b_data & (PAGE_SIZE - 1)) tmp = tmp->b_this_page; /* This is the buffer at the head of the page */ bh = tmp; do { p = tmp; tmp = tmp->b_this_page; remove_from_queues(p); p->b_dev = dev; p->b_uptodate = 0; p->b_req = 0; p->b_blocknr = starting_block++; insert_into_queues(p); } while (tmp != bh); return 1; } /* * Try to find a free cluster by locating a page where * all of the buffers are unused. We would like this function * to be atomic, so we do not call anything that might cause * the process to sleep. The priority is somewhat similar to * the priority used in shrink_buffers. * * My thinking is that the kernel should end up using whole * pages for the buffer cache as much of the time as possible. * This way the other buffers on a particular page are likely * to be very near each other on the free list, and we will not * be expiring data prematurely. For now we only cannibalize buffers * of the same size to keep the code simpler. */ static int reassign_cluster(kdev_t dev, unsigned int starting_block, int size) { struct buffer_head *bh; int isize = BUFSIZE_INDEX(size); int i; /* We want to give ourselves a really good shot at generating a cluster, and since we only take buffers from the free list, we "overfill" it a little. */ while(nr_free[isize] < 32) refill_freelist(size); bh = free_list[isize]; if(bh) for (i=0 ; !i || bh != free_list[isize] ; bh = bh->b_next_free, i++) { if (!bh->b_this_page) continue; if (try_to_reassign(bh, &bh, dev, starting_block)) return 4; } return 0; } /* This function tries to generate a new cluster of buffers * from a new page in memory. We should only do this if we have * not expanded the buffer cache to the maximum size that we allow. */ static unsigned long try_to_generate_cluster(kdev_t dev, int block, int size) { struct buffer_head * bh, * tmp, * arr[MAX_BUF_PER_PAGE]; int isize = BUFSIZE_INDEX(size); unsigned long offset; unsigned long page; int nblock; page = get_free_page(GFP_NOBUFFER); if(!page) return 0; bh = create_buffers(page, size); if (!bh) { free_page(page); return 0; }; nblock = block; for (offset = 0 ; offset < PAGE_SIZE ; offset += size) { if (find_buffer(dev, nblock++, size)) goto not_aligned; } tmp = bh; nblock = 0; while (1) { arr[nblock++] = bh; bh->b_count = 1; bh->b_dirt = 0; bh->b_flushtime = 0; bh->b_lock = 0; bh->b_uptodate = 0; bh->b_req = 0; bh->b_dev = dev; bh->b_list = BUF_CLEAN; bh->b_blocknr = block++; nr_buffers++; nr_buffers_size[isize]++; insert_into_queues(bh); if (bh->b_this_page) bh = bh->b_this_page; else break; } buffermem += PAGE_SIZE; buffer_pages[MAP_NR(page)] = bh; bh->b_this_page = tmp; while (nblock-- > 0) brelse(arr[nblock]); return 4; /* ?? */ not_aligned: while ((tmp = bh) != NULL) { bh = bh->b_this_page; put_unused_buffer_head(tmp); } free_page(page); return 0; } unsigned long generate_cluster(kdev_t dev, int b[], int size) { int i, offset; for (i = 0, offset = 0 ; offset < PAGE_SIZE ; i++, offset += size) { if(i && b[i]-1 != b[i-1]) return 0; /* No need to cluster */ if(find_buffer(dev, b[i], size)) return 0; }; /* OK, we have a candidate for a new cluster */ /* See if one size of buffer is over-represented in the buffer cache, if so reduce the numbers of buffers */ if(maybe_shrink_lav_buffers(size)) { int retval; retval = try_to_generate_cluster(dev, b[0], size); if(retval) return retval; }; if (nr_free_pages > min_free_pages*2) return try_to_generate_cluster(dev, b[0], size); else return reassign_cluster(dev, b[0], size); } /* ===================== Init ======================= */ /* * This initializes the initial buffer free list. nr_buffers_type is set * to one less the actual number of buffers, as a sop to backwards * compatibility --- the old code did this (I think unintentionally, * but I'm not sure), and programs in the ps package expect it. * - TYT 8/30/92 */ void buffer_init(void) { int i; int isize = BUFSIZE_INDEX(BLOCK_SIZE); long memsize = MAP_NR(high_memory) << PAGE_SHIFT; if (memsize >= 4*1024*1024) { if(memsize >= 16*1024*1024) nr_hash = 16381; else nr_hash = 4093; } else { nr_hash = 997; }; hash_table = (struct buffer_head **) vmalloc(nr_hash * sizeof(struct buffer_head *)); buffer_pages = (struct buffer_head **) vmalloc(MAP_NR(high_memory) * sizeof(struct buffer_head *)); for (i = 0 ; i < MAP_NR(high_memory) ; i++) buffer_pages[i] = NULL; for (i = 0 ; i < nr_hash ; i++) hash_table[i] = NULL; lru_list[BUF_CLEAN] = 0; grow_buffers(GFP_KERNEL, BLOCK_SIZE); if (!free_list[isize]) panic("VFS: Unable to initialize buffer free list!"); return; } /* ====================== bdflush support =================== */ /* This is a simple kernel daemon, whose job it is to provide a dynamically * response to dirty buffers. Once this process is activated, we write back * a limited number of buffers to the disks and then go back to sleep again. * In effect this is a process which never leaves kernel mode, and does not have * any user memory associated with it except for the stack. There is also * a kernel stack page, which obviously must be separate from the user stack. */ struct wait_queue * bdflush_wait = NULL; struct wait_queue * bdflush_done = NULL; static int bdflush_running = 0; static void wakeup_bdflush(int wait) { if(!bdflush_running){ printk("Warning - bdflush not running\n"); sync_buffers(0,0); return; }; wake_up(&bdflush_wait); if(wait) sleep_on(&bdflush_done); } /* * Here we attempt to write back old buffers. We also try and flush inodes * and supers as well, since this function is essentially "update", and * otherwise there would be no way of ensuring that these quantities ever * get written back. Ideally, we would have a timestamp on the inodes * and superblocks so that we could write back only the old ones as well */ asmlinkage int sync_old_buffers(void) { int i, isize; int ndirty, nwritten; int nlist; int ncount; struct buffer_head * bh, *next; sync_supers(0); sync_inodes(0); ncount = 0; #ifdef DEBUG for(nlist = 0; nlist < NR_LIST; nlist++) #else for(nlist = BUF_DIRTY; nlist <= BUF_DIRTY; nlist++) #endif { ndirty = 0; nwritten = 0; repeat: bh = lru_list[nlist]; if(bh) for (i = nr_buffers_type[nlist]; i-- > 0; bh = next) { /* We may have stalled while waiting for I/O to complete. */ if(bh->b_list != nlist) goto repeat; next = bh->b_next_free; if(!lru_list[nlist]) { printk("Dirty list empty %d\n", i); break; } /* Clean buffer on dirty list? Refile it */ if (nlist == BUF_DIRTY && !bh->b_dirt && !bh->b_lock) { refile_buffer(bh); continue; } if (bh->b_lock || !bh->b_dirt) continue; ndirty++; if(bh->b_flushtime > jiffies) continue; nwritten++; bh->b_count++; bh->b_flushtime = 0; #ifdef DEBUG if(nlist != BUF_DIRTY) ncount++; #endif ll_rw_block(WRITE, 1, &bh); bh->b_count--; } } #ifdef DEBUG if (ncount) printk("sync_old_buffers: %d dirty buffers not on dirty list\n", ncount); printk("Wrote %d/%d buffers\n", nwritten, ndirty); #endif /* We assume that we only come through here on a regular schedule, like every 5 seconds. Now update load averages. Shift usage counts to prevent overflow. */ for(isize = 0; isize<NR_SIZES; isize++){ CALC_LOAD(buffers_lav[isize], bdf_prm.b_un.lav_const, buffer_usage[isize]); buffer_usage[isize] = 0; }; return 0; } /* This is the interface to bdflush. As we get more sophisticated, we can * pass tuning parameters to this "process", to adjust how it behaves. If you * invoke this again after you have done this once, you would simply modify * the tuning parameters. We would want to verify each parameter, however, * to make sure that it is reasonable. */ asmlinkage int sys_bdflush(int func, long data) { int i, error; int ndirty; int nlist; int ncount; struct buffer_head * bh, *next; if (!suser()) return -EPERM; if (func == 1) return sync_old_buffers(); /* Basically func 0 means start, 1 means read param 1, 2 means write param 1, etc */ if (func >= 2) { i = (func-2) >> 1; if (i < 0 || i >= N_PARAM) return -EINVAL; if((func & 1) == 0) { error = verify_area(VERIFY_WRITE, (void *) data, sizeof(int)); if (error) return error; put_user(bdf_prm.data[i], (int*)data); return 0; }; if (data < bdflush_min[i] || data > bdflush_max[i]) return -EINVAL; bdf_prm.data[i] = data; return 0; }; if (bdflush_running) return -EBUSY; /* Only one copy of this running at one time */ bdflush_running++; /* OK, from here on is the daemon */ for (;;) { #ifdef DEBUG printk("bdflush() activated..."); #endif ncount = 0; #ifdef DEBUG for(nlist = 0; nlist < NR_LIST; nlist++) #else for(nlist = BUF_DIRTY; nlist <= BUF_DIRTY; nlist++) #endif { ndirty = 0; repeat: bh = lru_list[nlist]; if(bh) for (i = nr_buffers_type[nlist]; i-- > 0 && ndirty < bdf_prm.b_un.ndirty; bh = next) { /* We may have stalled while waiting for I/O to complete. */ if(bh->b_list != nlist) goto repeat; next = bh->b_next_free; if(!lru_list[nlist]) { printk("Dirty list empty %d\n", i); break; } /* Clean buffer on dirty list? Refile it */ if (nlist == BUF_DIRTY && !bh->b_dirt && !bh->b_lock) { refile_buffer(bh); continue; } if (bh->b_lock || !bh->b_dirt) continue; /* Should we write back buffers that are shared or not?? currently dirty buffers are not shared, so it does not matter */ bh->b_count++; ndirty++; bh->b_flushtime = 0; ll_rw_block(WRITE, 1, &bh); #ifdef DEBUG if(nlist != BUF_DIRTY) ncount++; #endif bh->b_count--; } } #ifdef DEBUG if (ncount) printk("sys_bdflush: %d dirty buffers not on dirty list\n", ncount); printk("sleeping again.\n"); #endif wake_up(&bdflush_done); /* If there are still a lot of dirty buffers around, skip the sleep and flush some more */ if(nr_buffers_type[BUF_DIRTY] <= (nr_buffers - nr_buffers_type[BUF_SHARED]) * bdf_prm.b_un.nfract/100) { if (current->signal & (1 << (SIGKILL-1))) { bdflush_running--; return 0; } current->signal = 0; interruptible_sleep_on(&bdflush_wait); } } } /* * Overrides for Emacs so that we follow Linus's tabbing style. * Emacs will notice this stuff at the end of the file and automatically * adjust the settings for this buffer only. This must remain at the end * of the file. * --------------------------------------------------------------------------- * Local variables: * c-indent-level: 8 * c-brace-imaginary-offset: 0 * c-brace-offset: -8 * c-argdecl-indent: 8 * c-label-offset: -8 * c-continued-statement-offset: 8 * c-continued-brace-offset: 0 * End: */ |