/* Copyright (C) 1997, 1999 Free Software Foundation, Inc. Written by Thomas Bushnell, n/BSG. This file is part of the GNU Hurd. The GNU Hurd is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. The GNU Hurd is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111, USA. */ #include #include #include "isofs.h" pthread_spinlock_t node2pagelock = PTHREAD_SPINLOCK_INITIALIZER; struct port_bucket *pager_bucket; /* Mapped image of the disk */ void *disk_image; /* Implement the pager_read_page callback from the pager library. See for the interface definition. */ error_t pager_read_page (struct user_pager_info *upi, vm_offset_t page, vm_address_t *buf, int *writelock) { error_t err; daddr_t addr; struct node *np = upi->np; size_t read = 0; size_t overrun = 0; /* This is a read-only medium */ *writelock = 1; if (upi->type == FILE_DATA) { addr = np->dn->file_start + (page >> store->log2_block_size); if (page >= np->dn_stat.st_size) { *buf = (vm_address_t) mmap (0, vm_page_size, PROT_READ|PROT_WRITE, MAP_ANON, 0, 0); return 0; } if (page + vm_page_size > np->dn_stat.st_size) overrun = page + vm_page_size - np->dn_stat.st_size; } else { assert (upi->type == DISK); addr = page >> store->log2_block_size; } err = store_read (store, addr, vm_page_size, (void **) buf, &read); if (err) return err; if (read != vm_page_size) return EIO; if (overrun) bzero ((void *) *buf + vm_page_size - overrun, overrun); return 0; } /* This function should never be called. */ error_t pager_write_page (struct user_pager_info *pager, vm_offset_t page, vm_address_t buf) { assert (0); } /* Never permit unlocks to succeed. */ error_t pager_unlock_page (struct user_pager_info *pager, vm_offset_t address) { return EROFS; } void pager_notify_evict (struct user_pager_info *pager, vm_offset_t page) { assert (!"unrequested notification on eviction"); } /* Tell how big the file is. */ error_t pager_report_extent (struct user_pager_info *pager, vm_address_t *offset, vm_size_t *size) { *offset = 0; *size = pager->np->dn_stat.st_size; return 0; } /* Implement the pager_clear_user_data callback from the pager library. */ void pager_clear_user_data (struct user_pager_info *upi) { if (upi->type == FILE_DATA) { pthread_spin_lock (&node2pagelock); if (upi->np->dn->fileinfo == upi) upi->np->dn->fileinfo = 0; pthread_spin_unlock (&node2pagelock); diskfs_nrele_light (upi->np); } free (upi); } void pager_dropweak (struct user_pager_info *upi) { } /* Create the disk pager */ void create_disk_pager (void) { struct user_pager_info *upi = malloc (sizeof (struct user_pager_info)); if (!upi) error (1, errno, "Could not create disk pager"); upi->type = DISK; upi->np = 0; pager_bucket = ports_create_bucket (); diskfs_start_disk_pager (upi, pager_bucket, 1, 0, store->size, &disk_image); upi->p = diskfs_disk_pager; } /* This need not do anything */ void diskfs_file_update (struct node *np, int wait) { } /* Create a FILE_DATA pager for the specified node */ mach_port_t diskfs_get_filemap (struct node *np, vm_prot_t prot) { struct user_pager_info *upi; mach_port_t right; assert (S_ISDIR (np->dn_stat.st_mode) || S_ISREG (np->dn_stat.st_mode) || S_ISLNK (np->dn_stat.st_mode)); pthread_spin_lock (&node2pagelock); do if (!np->dn->fileinfo) { upi = malloc (sizeof (struct user_pager_info)); upi->type = FILE_DATA; upi->np = np; diskfs_nref_light (np); upi->p = pager_create (upi, pager_bucket, 1, MEMORY_OBJECT_COPY_DELAY, 0); if (upi->p == 0) { diskfs_nrele_light (np); free (upi); pthread_spin_unlock (&node2pagelock); return MACH_PORT_NULL; } np->dn->fileinfo = upi; right = pager_get_port (np->dn->fileinfo->p); ports_port_deref (np->dn->fileinfo->p); } else { /* Because NP->dn->fileinfo->p is not a real reference, this might be nearly deallocated. If that's so, then the port right will be null. In that case, clear here and loop. The deallocation will complete separately. */ right = pager_get_port (np->dn->fileinfo->p); if (right == MACH_PORT_NULL) np->dn->fileinfo = 0; } while (right == MACH_PORT_NULL); pthread_spin_unlock (&node2pagelock); mach_port_insert_right (mach_task_self (), right, right, MACH_MSG_TYPE_MAKE_SEND); return right; } /* Call this when we should turn off caching so that unused memory object ports get freed. */ void drop_pager_softrefs (struct node *np) { struct user_pager_info *upi; pthread_spin_lock (&node2pagelock); upi = np->dn->fileinfo; if (upi) ports_port_ref (upi->p); pthread_spin_unlock (&node2pagelock); if (upi) { pager_change_attributes (upi->p, 0, MEMORY_OBJECT_COPY_DELAY, 0); ports_port_deref (upi->p); } } /* Call this when we should turn on caching because it's no longer important for unused memory object ports to get freed. */ void allow_pager_softrefs (struct node *np) { struct user_pager_info *upi; pthread_spin_lock (&node2pagelock); upi = np->dn->fileinfo; if (upi) ports_port_ref (upi->p); pthread_spin_unlock (&node2pagelock); if (upi) { pager_change_attributes (upi->p, 1, MEMORY_OBJECT_COPY_DELAY, 0); ports_port_deref (upi->p); } } static void block_caching () { error_t block_cache (void *arg) { struct pager *p = arg; pager_change_attributes (p, 0, MEMORY_OBJECT_COPY_DELAY, 1); return 0; } /* Loop through the pagers and turn off caching one by one, synchronously. That should cause termination of each pager. */ ports_bucket_iterate (pager_bucket, block_cache); } static void enable_caching () { error_t enable_cache (void *arg) { struct pager *p = arg; struct user_pager_info *upi = pager_get_upi (p); pager_change_attributes (p, 1, MEMORY_OBJECT_COPY_DELAY, 0); /* It's possible that we didn't have caching on before, because the user here is the only reference to the underlying node (actually, that's quite likely inside this particular routine), and if that node has no links. So dinkle the node ref counting scheme here, which will cause caching to be turned off, if that's really necessary. */ if (upi->type == FILE_DATA) { diskfs_nref (upi->np); diskfs_nrele (upi->np); } return 0; } ports_bucket_iterate (pager_bucket, enable_cache); } /* Tell diskfs if there are pagers exported, and if none, then prevent any new ones from showing up. */ int diskfs_pager_users () { int npagers = ports_count_bucket (pager_bucket); if (npagers <= 1) return 0; block_caching (); /* Give it a second; the kernel doesn't actually shutdown immediately. XXX */ sleep (1); npagers = ports_count_bucket (pager_bucket); if (npagers <= 1) return 0; /* Darn, there are actual honest users. Turn caching back on, and return failure. */ enable_caching (); ports_enable_bucket (pager_bucket); return 1; } /* Return the bitwise or of the maximum prot parameter (the second arg to diskfs_get_filemap) for all active user pagers. */ vm_prot_t diskfs_max_user_pager_prot () { /* We never allow writing, so there's no need to carefully check it. */ return VM_PROT_READ | VM_PROT_EXECUTE; } /* Call this to find out the struct pager * corresponding to the FILE_DATA pager of inode IP. This should be used *only* as a subsequent argument to register_memory_fault_area, and will be deleted when the kernel interface is fixed. NP must be locked. */ struct pager * diskfs_get_filemap_pager_struct (struct node *np) { /* This is safe because fileinfo can't be cleared; there must be an active mapping for this to be called. */ return np->dn->fileinfo->p; } /* Shutdown all the pagers. */ void diskfs_shutdown_pager () { /* Because there's no need to ever sync, we don't have to do anything here. */ } /* Sync all the pagers. */ void diskfs_sync_everything (int wait) { /* ditto */ }