// SPDX-License-Identifier: GPL-2.0 //! Generic disk abstraction. //! //! C header: [`include/linux/blkdev.h`](srctree/include/linux/blkdev.h) //! C header: [`include/linux/blk_mq.h`](srctree/include/linux/blk_mq.h) use crate::block::mq::{raw_writer::RawWriter, Operations, TagSet}; use crate::{bindings, error::from_err_ptr, error::Result, sync::Arc}; use crate::{error, static_lock_class}; use core::fmt::{self, Write}; /// A builder for [`GenDisk`]. /// /// Use this struct to configure and add new [`GenDisk`] to the VFS. pub struct GenDiskBuilder { rotational: bool, logical_block_size: u32, physical_block_size: u32, capacity_sectors: u64, } impl Default for GenDiskBuilder { fn default() -> Self { Self { rotational: false, logical_block_size: bindings::PAGE_SIZE as u32, physical_block_size: bindings::PAGE_SIZE as u32, capacity_sectors: 0, } } } impl GenDiskBuilder { /// Create a new instance. pub fn new() -> Self { Self::default() } /// Set the rotational media attribute for the device to be built. pub fn rotational(mut self, rotational: bool) -> Self { self.rotational = rotational; self } /// Validate block size by verifying that it is between 512 and `PAGE_SIZE`, /// and that it is a power of two. fn validate_block_size(size: u32) -> Result<()> { if !(512..=bindings::PAGE_SIZE as u32).contains(&size) || !size.is_power_of_two() { Err(error::code::EINVAL) } else { Ok(()) } } /// Set the logical block size of the device to be built. /// /// This method will check that block size is a power of two and between 512 /// and 4096. If not, an error is returned and the block size is not set. /// /// This is the smallest unit the storage device can address. It is /// typically 4096 bytes. pub fn logical_block_size(mut self, block_size: u32) -> Result { Self::validate_block_size(block_size)?; self.logical_block_size = block_size; Ok(self) } /// Set the physical block size of the device to be built. /// /// This method will check that block size is a power of two and between 512 /// and 4096. If not, an error is returned and the block size is not set. /// /// This is the smallest unit a physical storage device can write /// atomically. It is usually the same as the logical block size but may be /// bigger. One example is SATA drives with 4096 byte physical block size /// that expose a 512 byte logical block size to the operating system. pub fn physical_block_size(mut self, block_size: u32) -> Result { Self::validate_block_size(block_size)?; self.physical_block_size = block_size; Ok(self) } /// Set the capacity of the device to be built, in sectors (512 bytes). pub fn capacity_sectors(mut self, capacity: u64) -> Self { self.capacity_sectors = capacity; self } /// Build a new `GenDisk` and add it to the VFS. pub fn build( self, name: fmt::Arguments<'_>, tagset: Arc>, ) -> Result> { // SAFETY: `bindings::queue_limits` contain only fields that are valid when zeroed. let mut lim: bindings::queue_limits = unsafe { core::mem::zeroed() }; lim.logical_block_size = self.logical_block_size; lim.physical_block_size = self.physical_block_size; if self.rotational { lim.features = bindings::BLK_FEAT_ROTATIONAL; } // SAFETY: `tagset.raw_tag_set()` points to a valid and initialized tag set let gendisk = from_err_ptr(unsafe { bindings::__blk_mq_alloc_disk( tagset.raw_tag_set(), &mut lim, core::ptr::null_mut(), static_lock_class!().as_ptr(), ) })?; const TABLE: bindings::block_device_operations = bindings::block_device_operations { submit_bio: None, open: None, release: None, ioctl: None, compat_ioctl: None, check_events: None, unlock_native_capacity: None, getgeo: None, set_read_only: None, swap_slot_free_notify: None, report_zones: None, devnode: None, alternative_gpt_sector: None, get_unique_id: None, // TODO: Set to THIS_MODULE. Waiting for const_refs_to_static feature to // be merged (unstable in rustc 1.78 which is staged for linux 6.10) // https://github.com/rust-lang/rust/issues/119618 owner: core::ptr::null_mut(), pr_ops: core::ptr::null_mut(), free_disk: None, poll_bio: None, }; // SAFETY: `gendisk` is a valid pointer as we initialized it above unsafe { (*gendisk).fops = &TABLE }; let mut raw_writer = RawWriter::from_array( // SAFETY: `gendisk` points to a valid and initialized instance. We // have exclusive access, since the disk is not added to the VFS // yet. unsafe { &mut (*gendisk).disk_name }, )?; raw_writer.write_fmt(name)?; raw_writer.write_char('\0')?; // SAFETY: `gendisk` points to a valid and initialized instance of // `struct gendisk`. `set_capacity` takes a lock to synchronize this // operation, so we will not race. unsafe { bindings::set_capacity(gendisk, self.capacity_sectors) }; crate::error::to_result( // SAFETY: `gendisk` points to a valid and initialized instance of // `struct gendisk`. unsafe { bindings::device_add_disk(core::ptr::null_mut(), gendisk, core::ptr::null_mut()) }, )?; // INVARIANT: `gendisk` was initialized above. // INVARIANT: `gendisk` was added to the VFS via `device_add_disk` above. Ok(GenDisk { _tagset: tagset, gendisk, }) } } /// A generic block device. /// /// # Invariants /// /// - `gendisk` must always point to an initialized and valid `struct gendisk`. /// - `gendisk` was added to the VFS through a call to /// `bindings::device_add_disk`. pub struct GenDisk { _tagset: Arc>, gendisk: *mut bindings::gendisk, } // SAFETY: `GenDisk` is an owned pointer to a `struct gendisk` and an `Arc` to a // `TagSet` It is safe to send this to other threads as long as T is Send. unsafe impl Send for GenDisk {} impl Drop for GenDisk { fn drop(&mut self) { // SAFETY: By type invariant, `self.gendisk` points to a valid and // initialized instance of `struct gendisk`, and it was previously added // to the VFS. unsafe { bindings::del_gendisk(self.gendisk) }; } }