/* * Server-side device support * * Copyright (C) 2007 Alexandre Julliard * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #include "config.h" #include "wine/port.h" #include "wine/rbtree.h" #include #include #include #include #include #include "ntstatus.h" #define WIN32_NO_STATUS #include "windef.h" #include "winternl.h" #include "ddk/wdm.h" #include "object.h" #include "file.h" #include "handle.h" #include "request.h" #include "process.h" /* IRP object */ struct irp_call { struct object obj; /* object header */ struct list dev_entry; /* entry in device queue */ struct list mgr_entry; /* entry in manager queue */ struct device_file *file; /* file containing this irp */ struct thread *thread; /* thread that queued the irp */ struct async *async; /* pending async op */ irp_params_t params; /* irp parameters */ struct iosb *iosb; /* I/O status block */ int canceled; /* the call was canceled */ client_ptr_t user_ptr; /* client side pointer */ }; static void irp_call_dump( struct object *obj, int verbose ); static void irp_call_destroy( struct object *obj ); static const struct object_ops irp_call_ops = { sizeof(struct irp_call), /* size */ &no_type, /* type */ irp_call_dump, /* dump */ no_add_queue, /* add_queue */ NULL, /* remove_queue */ NULL, /* signaled */ NULL, /* satisfied */ no_signal, /* signal */ no_get_fd, /* get_fd */ default_map_access, /* map_access */ default_get_sd, /* get_sd */ default_set_sd, /* set_sd */ no_get_full_name, /* get_full_name */ no_lookup_name, /* lookup_name */ no_link_name, /* link_name */ NULL, /* unlink_name */ no_open_file, /* open_file */ no_kernel_obj_list, /* get_kernel_obj_list */ no_close_handle, /* close_handle */ irp_call_destroy /* destroy */ }; /* device manager (a list of devices managed by the same client process) */ struct device_manager { struct object obj; /* object header */ struct list devices; /* list of devices */ struct list requests; /* list of pending irps across all devices */ struct irp_call *current_call; /* call currently executed on client side */ struct wine_rb_tree kernel_objects; /* map of objects that have client side pointer associated */ }; static void device_manager_dump( struct object *obj, int verbose ); static int device_manager_signaled( struct object *obj, struct wait_queue_entry *entry ); static void device_manager_destroy( struct object *obj ); static const struct object_ops device_manager_ops = { sizeof(struct device_manager), /* size */ &no_type, /* type */ device_manager_dump, /* dump */ add_queue, /* add_queue */ remove_queue, /* remove_queue */ device_manager_signaled, /* signaled */ no_satisfied, /* satisfied */ no_signal, /* signal */ no_get_fd, /* get_fd */ default_map_access, /* map_access */ default_get_sd, /* get_sd */ default_set_sd, /* set_sd */ no_get_full_name, /* get_full_name */ no_lookup_name, /* lookup_name */ no_link_name, /* link_name */ NULL, /* unlink_name */ no_open_file, /* open_file */ no_kernel_obj_list, /* get_kernel_obj_list */ no_close_handle, /* close_handle */ device_manager_destroy /* destroy */ }; /* device (a single device object) */ static const WCHAR device_name[] = {'D','e','v','i','c','e'}; struct type_descr device_type = { { device_name, sizeof(device_name) }, /* name */ FILE_ALL_ACCESS, /* valid_access */ { /* mapping */ FILE_GENERIC_READ, FILE_GENERIC_WRITE, FILE_GENERIC_EXECUTE, FILE_ALL_ACCESS }, }; struct device { struct object obj; /* object header */ struct device_manager *manager; /* manager for this device (or NULL if deleted) */ char *unix_path; /* path to unix device if any */ struct list kernel_object; /* list of kernel object pointers */ struct list entry; /* entry in device manager list */ struct list files; /* list of open files */ }; static void device_dump( struct object *obj, int verbose ); static void device_destroy( struct object *obj ); static struct object *device_open_file( struct object *obj, unsigned int access, unsigned int sharing, unsigned int options ); static struct list *device_get_kernel_obj_list( struct object *obj ); static const struct object_ops device_ops = { sizeof(struct device), /* size */ &device_type, /* type */ device_dump, /* dump */ no_add_queue, /* add_queue */ NULL, /* remove_queue */ NULL, /* signaled */ no_satisfied, /* satisfied */ no_signal, /* signal */ no_get_fd, /* get_fd */ default_map_access, /* map_access */ default_get_sd, /* get_sd */ default_set_sd, /* set_sd */ default_get_full_name, /* get_full_name */ no_lookup_name, /* lookup_name */ directory_link_name, /* link_name */ default_unlink_name, /* unlink_name */ device_open_file, /* open_file */ device_get_kernel_obj_list, /* get_kernel_obj_list */ no_close_handle, /* close_handle */ device_destroy /* destroy */ }; /* device file (an open file handle to a device) */ struct device_file { struct object obj; /* object header */ struct device *device; /* device for this file */ struct fd *fd; /* file descriptor for irp */ struct list kernel_object; /* list of kernel object pointers */ int closed; /* closed file flag */ struct list entry; /* entry in device list */ struct list requests; /* list of pending irp requests */ }; static void device_file_dump( struct object *obj, int verbose ); static struct fd *device_file_get_fd( struct object *obj ); static WCHAR *device_file_get_full_name( struct object *obj, data_size_t *len ); static struct list *device_file_get_kernel_obj_list( struct object *obj ); static int device_file_close_handle( struct object *obj, struct process *process, obj_handle_t handle ); static void device_file_destroy( struct object *obj ); static enum server_fd_type device_file_get_fd_type( struct fd *fd ); static void device_file_read( struct fd *fd, struct async *async, file_pos_t pos ); static void device_file_write( struct fd *fd, struct async *async, file_pos_t pos ); static void device_file_flush( struct fd *fd, struct async *async ); static void device_file_ioctl( struct fd *fd, ioctl_code_t code, struct async *async ); static void device_file_reselect_async( struct fd *fd, struct async_queue *queue ); static void device_file_get_volume_info( struct fd *fd, struct async *async, unsigned int info_class ); static const struct object_ops device_file_ops = { sizeof(struct device_file), /* size */ &file_type, /* type */ device_file_dump, /* dump */ add_queue, /* add_queue */ remove_queue, /* remove_queue */ default_fd_signaled, /* signaled */ no_satisfied, /* satisfied */ no_signal, /* signal */ device_file_get_fd, /* get_fd */ default_map_access, /* map_access */ default_get_sd, /* get_sd */ default_set_sd, /* set_sd */ device_file_get_full_name, /* get_full_name */ no_lookup_name, /* lookup_name */ no_link_name, /* link_name */ NULL, /* unlink_name */ no_open_file, /* open_file */ device_file_get_kernel_obj_list, /* get_kernel_obj_list */ device_file_close_handle, /* close_handle */ device_file_destroy /* destroy */ }; static const struct fd_ops device_file_fd_ops = { default_fd_get_poll_events, /* get_poll_events */ default_poll_event, /* poll_event */ device_file_get_fd_type, /* get_fd_type */ device_file_read, /* read */ device_file_write, /* write */ device_file_flush, /* flush */ default_fd_get_file_info, /* get_file_info */ device_file_get_volume_info, /* get_volume_info */ device_file_ioctl, /* ioctl */ default_fd_queue_async, /* queue_async */ device_file_reselect_async /* reselect_async */ }; struct list *no_kernel_obj_list( struct object *obj ) { return NULL; } struct kernel_object { struct device_manager *manager; client_ptr_t user_ptr; struct object *object; int owned; struct list list_entry; struct wine_rb_entry rb_entry; }; static int compare_kernel_object( const void *k, const struct wine_rb_entry *entry ) { struct kernel_object *ptr = WINE_RB_ENTRY_VALUE( entry, struct kernel_object, rb_entry ); return memcmp( k, &ptr->user_ptr, sizeof(client_ptr_t) ); } static struct kernel_object *kernel_object_from_obj( struct device_manager *manager, struct object *obj ) { struct kernel_object *kernel_object; struct list *list; if (!(list = obj->ops->get_kernel_obj_list( obj ))) return NULL; LIST_FOR_EACH_ENTRY( kernel_object, list, struct kernel_object, list_entry ) { if (kernel_object->manager != manager) continue; return kernel_object; } return NULL; } static client_ptr_t get_kernel_object_ptr( struct device_manager *manager, struct object *obj ) { struct kernel_object *kernel_object = kernel_object_from_obj( manager, obj ); return kernel_object ? kernel_object->user_ptr : 0; } static struct kernel_object *set_kernel_object( struct device_manager *manager, struct object *obj, client_ptr_t user_ptr ) { struct kernel_object *kernel_object; struct list *list; if (!(list = obj->ops->get_kernel_obj_list( obj ))) return NULL; if (!(kernel_object = malloc( sizeof(*kernel_object) ))) return NULL; kernel_object->manager = manager; kernel_object->user_ptr = user_ptr; kernel_object->object = obj; kernel_object->owned = 0; if (wine_rb_put( &manager->kernel_objects, &user_ptr, &kernel_object->rb_entry )) { /* kernel_object pointer already set */ free( kernel_object ); return NULL; } list_add_head( list, &kernel_object->list_entry ); return kernel_object; } static struct kernel_object *kernel_object_from_ptr( struct device_manager *manager, client_ptr_t client_ptr ) { struct wine_rb_entry *entry = wine_rb_get( &manager->kernel_objects, &client_ptr ); return entry ? WINE_RB_ENTRY_VALUE( entry, struct kernel_object, rb_entry ) : NULL; } static void grab_kernel_object( struct kernel_object *ptr ) { if (!ptr->owned) { grab_object( ptr->object ); ptr->owned = 1; } } static void irp_call_dump( struct object *obj, int verbose ) { struct irp_call *irp = (struct irp_call *)obj; fprintf( stderr, "IRP call file=%p\n", irp->file ); } static void irp_call_destroy( struct object *obj ) { struct irp_call *irp = (struct irp_call *)obj; if (irp->async) { async_terminate( irp->async, STATUS_CANCELLED ); release_object( irp->async ); } if (irp->iosb) release_object( irp->iosb ); if (irp->file) release_object( irp->file ); if (irp->thread) release_object( irp->thread ); } static struct irp_call *create_irp( struct device_file *file, const irp_params_t *params, struct async *async ) { struct irp_call *irp; if (file && !file->device->manager) /* it has been deleted */ { set_error( STATUS_FILE_DELETED ); return NULL; } if ((irp = alloc_object( &irp_call_ops ))) { irp->file = file ? (struct device_file *)grab_object( file ) : NULL; irp->thread = NULL; irp->async = NULL; irp->params = *params; irp->iosb = NULL; irp->canceled = 0; irp->user_ptr = 0; if (async) irp->iosb = async_get_iosb( async ); } return irp; } static void set_irp_result( struct irp_call *irp, unsigned int status, const void *out_data, data_size_t out_size, data_size_t result ) { struct device_file *file = irp->file; if (!file) return; /* already finished */ /* remove it from the device queue */ list_remove( &irp->dev_entry ); irp->file = NULL; if (irp->async) { out_size = min( irp->iosb->out_size, out_size ); async_request_complete_alloc( irp->async, status, result, out_size, out_data ); release_object( irp->async ); irp->async = NULL; } release_object( irp ); /* no longer on the device queue */ release_object( file ); } static void device_dump( struct object *obj, int verbose ) { fputs( "Device\n", stderr ); } static void device_destroy( struct object *obj ) { struct device *device = (struct device *)obj; assert( list_empty( &device->files )); free( device->unix_path ); if (device->manager) list_remove( &device->entry ); } static void add_irp_to_queue( struct device_manager *manager, struct irp_call *irp, struct thread *thread ) { grab_object( irp ); /* grab reference for queued irp */ irp->thread = thread ? (struct thread *)grab_object( thread ) : NULL; if (irp->file) list_add_tail( &irp->file->requests, &irp->dev_entry ); list_add_tail( &manager->requests, &irp->mgr_entry ); if (list_head( &manager->requests ) == &irp->mgr_entry) wake_up( &manager->obj, 0 ); /* first one */ } static struct object *device_open_file( struct object *obj, unsigned int access, unsigned int sharing, unsigned int options ) { struct device *device = (struct device *)obj; struct device_file *file; struct unicode_str nt_name; if (!(file = alloc_object( &device_file_ops ))) return NULL; file->device = (struct device *)grab_object( device ); file->closed = 0; list_init( &file->kernel_object ); list_init( &file->requests ); list_add_tail( &device->files, &file->entry ); if (device->unix_path) { mode_t mode = 0666; access = file->obj.ops->map_access( &file->obj, access ); nt_name.str = device->obj.ops->get_full_name( &device->obj, &nt_name.len ); file->fd = open_fd( NULL, device->unix_path, nt_name, O_NONBLOCK | O_LARGEFILE, &mode, access, sharing, options ); if (file->fd) set_fd_user( file->fd, &device_file_fd_ops, &file->obj ); } else file->fd = alloc_pseudo_fd( &device_file_fd_ops, &file->obj, options ); if (!file->fd) { release_object( file ); return NULL; } allow_fd_caching( file->fd ); if (device->manager) { struct irp_call *irp; irp_params_t params; memset( ¶ms, 0, sizeof(params) ); params.create.type = IRP_CALL_CREATE; params.create.access = access; params.create.sharing = sharing; params.create.options = options; params.create.device = get_kernel_object_ptr( device->manager, &device->obj ); if ((irp = create_irp( file, ¶ms, NULL ))) { add_irp_to_queue( device->manager, irp, current ); release_object( irp ); } } return &file->obj; } static struct list *device_get_kernel_obj_list( struct object *obj ) { struct device *device = (struct device *)obj; return &device->kernel_object; } static void device_file_dump( struct object *obj, int verbose ) { struct device_file *file = (struct device_file *)obj; fprintf( stderr, "File on device %p\n", file->device ); } static struct fd *device_file_get_fd( struct object *obj ) { struct device_file *file = (struct device_file *)obj; return (struct fd *)grab_object( file->fd ); } static WCHAR *device_file_get_full_name( struct object *obj, data_size_t *len ) { struct device_file *file = (struct device_file *)obj; return file->device->obj.ops->get_full_name( &file->device->obj, len ); } static struct list *device_file_get_kernel_obj_list( struct object *obj ) { struct device_file *file = (struct device_file *)obj; return &file->kernel_object; } static int device_file_close_handle( struct object *obj, struct process *process, obj_handle_t handle ) { struct device_file *file = (struct device_file *)obj; if (!file->closed && file->device->manager && obj->handle_count == 1) /* last handle */ { struct irp_call *irp; irp_params_t params; file->closed = 1; memset( ¶ms, 0, sizeof(params) ); params.close.type = IRP_CALL_CLOSE; if ((irp = create_irp( file, ¶ms, NULL ))) { add_irp_to_queue( file->device->manager, irp, current ); release_object( irp ); } } return 1; } static void device_file_destroy( struct object *obj ) { struct device_file *file = (struct device_file *)obj; struct irp_call *irp, *next; LIST_FOR_EACH_ENTRY_SAFE( irp, next, &file->requests, struct irp_call, dev_entry ) { list_remove( &irp->dev_entry ); release_object( irp ); /* no longer on the device queue */ } if (file->fd) release_object( file->fd ); list_remove( &file->entry ); release_object( file->device ); } static int fill_irp_params( struct device_manager *manager, struct irp_call *irp, irp_params_t *params ) { switch (irp->params.type) { case IRP_CALL_NONE: case IRP_CALL_FREE: case IRP_CALL_CANCEL: break; case IRP_CALL_CREATE: irp->params.create.file = alloc_handle( current->process, irp->file, irp->params.create.access, 0 ); if (!irp->params.create.file) return 0; break; case IRP_CALL_CLOSE: irp->params.close.file = get_kernel_object_ptr( manager, &irp->file->obj ); break; case IRP_CALL_READ: irp->params.read.file = get_kernel_object_ptr( manager, &irp->file->obj ); irp->params.read.out_size = irp->iosb->out_size; break; case IRP_CALL_WRITE: irp->params.write.file = get_kernel_object_ptr( manager, &irp->file->obj ); break; case IRP_CALL_FLUSH: irp->params.flush.file = get_kernel_object_ptr( manager, &irp->file->obj ); break; case IRP_CALL_IOCTL: irp->params.ioctl.file = get_kernel_object_ptr( manager, &irp->file->obj ); irp->params.ioctl.out_size = irp->iosb->out_size; break; case IRP_CALL_VOLUME: irp->params.volume.file = get_kernel_object_ptr( manager, &irp->file->obj ); irp->params.volume.out_size = irp->iosb->out_size; break; } *params = irp->params; return 1; } static void free_irp_params( struct irp_call *irp ) { switch (irp->params.type) { case IRP_CALL_CREATE: close_handle( current->process, irp->params.create.file ); break; default: break; } } /* queue an irp to the device */ static void queue_irp( struct device_file *file, const irp_params_t *params, struct async *async ) { struct irp_call *irp = create_irp( file, params, async ); if (!irp) return; fd_queue_async( file->fd, async, ASYNC_TYPE_WAIT ); irp->async = (struct async *)grab_object( async ); add_irp_to_queue( file->device->manager, irp, current ); release_object( irp ); async_set_unknown_status( async ); } static enum server_fd_type device_file_get_fd_type( struct fd *fd ) { return FD_TYPE_DEVICE; } static void device_file_get_volume_info( struct fd *fd, struct async *async, unsigned int info_class ) { struct device_file *file = get_fd_user( fd ); irp_params_t params; memset( ¶ms, 0, sizeof(params) ); params.volume.type = IRP_CALL_VOLUME; params.volume.info_class = info_class; queue_irp( file, ¶ms, async ); } static void device_file_read( struct fd *fd, struct async *async, file_pos_t pos ) { struct device_file *file = get_fd_user( fd ); irp_params_t params; memset( ¶ms, 0, sizeof(params) ); params.read.type = IRP_CALL_READ; params.read.key = 0; params.read.pos = pos; queue_irp( file, ¶ms, async ); } static void device_file_write( struct fd *fd, struct async *async, file_pos_t pos ) { struct device_file *file = get_fd_user( fd ); irp_params_t params; memset( ¶ms, 0, sizeof(params) ); params.write.type = IRP_CALL_WRITE; params.write.key = 0; params.write.pos = pos; queue_irp( file, ¶ms, async ); } static void device_file_flush( struct fd *fd, struct async *async ) { struct device_file *file = get_fd_user( fd ); irp_params_t params; memset( ¶ms, 0, sizeof(params) ); params.flush.type = IRP_CALL_FLUSH; queue_irp( file, ¶ms, async ); } static void device_file_ioctl( struct fd *fd, ioctl_code_t code, struct async *async ) { struct device_file *file = get_fd_user( fd ); irp_params_t params; memset( ¶ms, 0, sizeof(params) ); params.ioctl.type = IRP_CALL_IOCTL; params.ioctl.code = code; queue_irp( file, ¶ms, async ); } static void cancel_irp_call( struct irp_call *irp ) { struct irp_call *cancel_irp; irp_params_t params; irp->canceled = 1; if (!irp->user_ptr || !irp->file || !irp->file->device->manager) return; memset( ¶ms, 0, sizeof(params) ); params.cancel.type = IRP_CALL_CANCEL; params.cancel.irp = irp->user_ptr; if ((cancel_irp = create_irp( NULL, ¶ms, NULL ))) { add_irp_to_queue( irp->file->device->manager, cancel_irp, NULL ); release_object( cancel_irp ); } set_irp_result( irp, STATUS_CANCELLED, NULL, 0, 0 ); } static void device_file_reselect_async( struct fd *fd, struct async_queue *queue ) { struct device_file *file = get_fd_user( fd ); struct irp_call *irp; LIST_FOR_EACH_ENTRY( irp, &file->requests, struct irp_call, dev_entry ) if (irp->iosb->status != STATUS_PENDING) { cancel_irp_call( irp ); return; } } static struct device *create_device( struct object *root, const struct unicode_str *name, struct device_manager *manager ) { struct device *device; if ((device = create_named_object( root, &device_ops, name, 0, NULL ))) { device->unix_path = NULL; device->manager = manager; grab_object( device ); list_add_tail( &manager->devices, &device->entry ); list_init( &device->kernel_object ); list_init( &device->files ); } return device; } struct object *create_unix_device( struct object *root, const struct unicode_str *name, unsigned int attr, const struct security_descriptor *sd, const char *unix_path ) { struct device *device; if ((device = create_named_object( root, &device_ops, name, attr, sd ))) { device->unix_path = strdup( unix_path ); device->manager = NULL; /* no manager, requests go straight to the Unix device */ list_init( &device->kernel_object ); list_init( &device->files ); } return &device->obj; } /* terminate requests when the underlying device is deleted */ static void delete_file( struct device_file *file ) { struct irp_call *irp, *next; /* the pending requests may be the only thing holding a reference to the file */ grab_object( file ); /* terminate all pending requests */ LIST_FOR_EACH_ENTRY_SAFE( irp, next, &file->requests, struct irp_call, dev_entry ) { list_remove( &irp->mgr_entry ); set_irp_result( irp, STATUS_FILE_DELETED, NULL, 0, 0 ); } release_object( file ); } static void delete_device( struct device *device ) { struct device_file *file, *next; if (!device->manager) return; /* already deleted */ LIST_FOR_EACH_ENTRY_SAFE( file, next, &device->files, struct device_file, entry ) delete_file( file ); unlink_named_object( &device->obj ); list_remove( &device->entry ); device->manager = NULL; release_object( device ); } static void device_manager_dump( struct object *obj, int verbose ) { fprintf( stderr, "Device manager\n" ); } static int device_manager_signaled( struct object *obj, struct wait_queue_entry *entry ) { struct device_manager *manager = (struct device_manager *)obj; return !list_empty( &manager->requests ); } static void device_manager_destroy( struct object *obj ) { struct device_manager *manager = (struct device_manager *)obj; struct kernel_object *kernel_object; struct list *ptr; if (manager->current_call) { release_object( manager->current_call ); manager->current_call = NULL; } while (manager->kernel_objects.root) { kernel_object = WINE_RB_ENTRY_VALUE( manager->kernel_objects.root, struct kernel_object, rb_entry ); wine_rb_remove( &manager->kernel_objects, &kernel_object->rb_entry ); list_remove( &kernel_object->list_entry ); if (kernel_object->owned) release_object( kernel_object->object ); free( kernel_object ); } while ((ptr = list_head( &manager->devices ))) { struct device *device = LIST_ENTRY( ptr, struct device, entry ); delete_device( device ); } while ((ptr = list_head( &manager->requests ))) { struct irp_call *irp = LIST_ENTRY( ptr, struct irp_call, mgr_entry ); list_remove( &irp->mgr_entry ); assert( !irp->file && !irp->async ); release_object( irp ); } } static struct device_manager *create_device_manager(void) { struct device_manager *manager; if ((manager = alloc_object( &device_manager_ops ))) { manager->current_call = NULL; list_init( &manager->devices ); list_init( &manager->requests ); wine_rb_init( &manager->kernel_objects, compare_kernel_object ); } return manager; } void free_kernel_objects( struct object *obj ) { struct list *ptr, *list; if (!(list = obj->ops->get_kernel_obj_list( obj ))) return; while ((ptr = list_head( list ))) { struct kernel_object *kernel_object = LIST_ENTRY( ptr, struct kernel_object, list_entry ); struct irp_call *irp; irp_params_t params; assert( !kernel_object->owned ); memset( ¶ms, 0, sizeof(params) ); params.free.type = IRP_CALL_FREE; params.free.obj = kernel_object->user_ptr; if ((irp = create_irp( NULL, ¶ms, NULL ))) { add_irp_to_queue( kernel_object->manager, irp, NULL ); release_object( irp ); } list_remove( &kernel_object->list_entry ); wine_rb_remove( &kernel_object->manager->kernel_objects, &kernel_object->rb_entry ); free( kernel_object ); } } /* create a device manager */ DECL_HANDLER(create_device_manager) { struct device_manager *manager = create_device_manager(); if (manager) { reply->handle = alloc_handle( current->process, manager, req->access, req->attributes ); release_object( manager ); } } /* create a device */ DECL_HANDLER(create_device) { struct device *device; struct unicode_str name = get_req_unicode_str(); struct device_manager *manager; struct object *root = NULL; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if (req->rootdir && !(root = get_directory_obj( current->process, req->rootdir ))) { release_object( manager ); return; } if ((device = create_device( root, &name, manager ))) { struct kernel_object *ptr = set_kernel_object( manager, &device->obj, req->user_ptr ); if (ptr) grab_kernel_object( ptr ); else set_error( STATUS_NO_MEMORY ); release_object( device ); } if (root) release_object( root ); release_object( manager ); } /* delete a device */ DECL_HANDLER(delete_device) { struct device_manager *manager; struct kernel_object *ref; struct device *device; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if ((ref = kernel_object_from_ptr( manager, req->device )) && ref->object->ops == &device_ops) { device = (struct device *)grab_object( ref->object ); delete_device( device ); release_object( device ); } else set_error( STATUS_INVALID_HANDLE ); release_object( manager ); } /* retrieve the next pending device irp request */ DECL_HANDLER(get_next_device_request) { struct irp_call *irp; struct device_manager *manager; struct list *ptr; struct iosb *iosb; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if (req->prev) close_handle( current->process, req->prev ); /* avoid an extra round-trip for close */ /* process result of previous call */ if (manager->current_call) { irp = manager->current_call; irp->user_ptr = req->user_ptr; if (req->status) set_irp_result( irp, req->status, NULL, 0, 0 ); if (irp->canceled) /* if it was canceled during dispatch, we couldn't queue cancel call without client pointer, * so we need to do it now */ cancel_irp_call( irp ); else if (irp->async) set_async_pending( irp->async, irp->file && is_fd_overlapped( irp->file->fd ) ); free_irp_params( irp ); release_object( irp ); manager->current_call = NULL; } clear_error(); if ((ptr = list_head( &manager->requests ))) { struct thread *thread; irp = LIST_ENTRY( ptr, struct irp_call, mgr_entry ); thread = irp->thread ? irp->thread : current; reply->client_thread = get_kernel_object_ptr( manager, &thread->obj ); reply->client_tid = get_thread_id( thread ); iosb = irp->iosb; if (iosb) reply->in_size = iosb->in_size; if (iosb && iosb->in_size > get_reply_max_size()) set_error( STATUS_BUFFER_OVERFLOW ); else if (!irp->file || (reply->next = alloc_handle( current->process, irp, 0, 0 ))) { if (fill_irp_params( manager, irp, &reply->params )) { if (iosb) { set_reply_data_ptr( iosb->in_data, iosb->in_size ); iosb->in_data = NULL; iosb->in_size = 0; } list_remove( &irp->mgr_entry ); list_init( &irp->mgr_entry ); /* we already own the object if it's only on manager queue */ if (irp->file) grab_object( irp ); manager->current_call = irp; } else close_handle( current->process, reply->next ); } } else set_error( STATUS_PENDING ); release_object( manager ); } /* store results of an async irp */ DECL_HANDLER(set_irp_result) { struct irp_call *irp; if ((irp = (struct irp_call *)get_handle_obj( current->process, req->handle, 0, &irp_call_ops ))) { if (!irp->canceled) set_irp_result( irp, req->status, get_req_data(), get_req_data_size(), req->size ); else if(irp->user_ptr) /* cancel already queued */ set_error( STATUS_MORE_PROCESSING_REQUIRED ); else /* we may be still dispatching the IRP. don't bother queuing cancel if it's already complete */ irp->canceled = 0; close_handle( current->process, req->handle ); /* avoid an extra round-trip for close */ release_object( irp ); } } /* get kernel pointer from server object */ DECL_HANDLER(get_kernel_object_ptr) { struct device_manager *manager; struct object *object = NULL; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if ((object = get_handle_obj( current->process, req->handle, 0, NULL ))) { reply->user_ptr = get_kernel_object_ptr( manager, object ); release_object( object ); } release_object( manager ); } /* associate kernel pointer with server object */ DECL_HANDLER(set_kernel_object_ptr) { struct device_manager *manager; struct object *object = NULL; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if (!(object = get_handle_obj( current->process, req->handle, 0, NULL ))) { release_object( manager ); return; } if (!set_kernel_object( manager, object, req->user_ptr )) set_error( STATUS_INVALID_HANDLE ); release_object( object ); release_object( manager ); } /* grab server object reference from kernel object pointer */ DECL_HANDLER(grab_kernel_object) { struct device_manager *manager; struct kernel_object *ref; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if ((ref = kernel_object_from_ptr( manager, req->user_ptr )) && !ref->owned) grab_kernel_object( ref ); else set_error( STATUS_INVALID_HANDLE ); release_object( manager ); } /* release server object reference from kernel object pointer */ DECL_HANDLER(release_kernel_object) { struct device_manager *manager; struct kernel_object *ref; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if ((ref = kernel_object_from_ptr( manager, req->user_ptr )) && ref->owned) { ref->owned = 0; release_object( ref->object ); } else set_error( STATUS_INVALID_HANDLE ); release_object( manager ); } /* get handle from kernel object pointer */ DECL_HANDLER(get_kernel_object_handle) { struct device_manager *manager; struct kernel_object *ref; if (!(manager = (struct device_manager *)get_handle_obj( current->process, req->manager, 0, &device_manager_ops ))) return; if ((ref = kernel_object_from_ptr( manager, req->user_ptr ))) reply->handle = alloc_handle( current->process, ref->object, req->access, 0 ); else set_error( STATUS_INVALID_HANDLE ); release_object( manager ); }