diff options
Diffstat (limited to 'rust/kernel/dma_fence.rs')
-rw-r--r-- | rust/kernel/dma_fence.rs | 532 |
1 files changed, 532 insertions, 0 deletions
diff --git a/rust/kernel/dma_fence.rs b/rust/kernel/dma_fence.rs new file mode 100644 index 000000000000..ca93380d9da2 --- /dev/null +++ b/rust/kernel/dma_fence.rs @@ -0,0 +1,532 @@ +// SPDX-License-Identifier: GPL-2.0 + +//! DMA fence abstraction. +//! +//! C header: [`include/linux/dma_fence.h`](../../include/linux/dma_fence.h) + +use crate::{ + bindings, + error::{to_result, Result}, + prelude::*, + sync::LockClassKey, + types::Opaque, +}; +use core::fmt::Write; +use core::ops::{Deref, DerefMut}; +use core::ptr::addr_of_mut; +use core::sync::atomic::{AtomicU64, Ordering}; + +/// Any kind of DMA Fence Object +/// +/// # Invariants +/// raw() returns a valid pointer to a dma_fence and we own a reference to it. +pub trait RawDmaFence: crate::private::Sealed { + /// Returns the raw `struct dma_fence` pointer. + fn raw(&self) -> *mut bindings::dma_fence; + + /// Returns the raw `struct dma_fence` pointer and consumes the object. + /// + /// The caller is responsible for dropping the reference. + fn into_raw(self) -> *mut bindings::dma_fence + where + Self: Sized, + { + let ptr = self.raw(); + core::mem::forget(self); + ptr + } + + /// Advances this fence to the chain node which will signal this sequence number. + /// If no sequence number is provided, this returns `self` again. + fn chain_find_seqno(self, seqno: u64) -> Result<Fence> + where + Self: Sized, + { + let mut ptr = self.into_raw(); + + // SAFETY: This will safely fail if this DmaFence is not a chain. + // `ptr` is valid per the type invariant. + let ret = unsafe { bindings::dma_fence_chain_find_seqno(&mut ptr, seqno) }; + + if ret != 0 { + // SAFETY: This is either an owned reference or NULL, dma_fence_put can handle both. + unsafe { bindings::dma_fence_put(ptr) }; + Err(Error::from_kernel_errno(ret)) + } else if ptr.is_null() { + Err(EINVAL) // When can this happen? + } else { + // SAFETY: ptr is valid and non-NULL as checked above. + Ok(unsafe { Fence::from_raw(ptr) }) + } + } + + /// Signal completion of this fence + fn signal(&self) -> Result { + to_result(unsafe { bindings::dma_fence_signal(self.raw()) }) + } + + /// Set the error flag on this fence + fn set_error(&self, err: Error) { + unsafe { bindings::dma_fence_set_error(self.raw(), err.to_kernel_errno()) }; + } +} + +/// A generic DMA Fence Object +/// +/// # Invariants +/// ptr is a valid pointer to a dma_fence and we own a reference to it. +pub struct Fence { + ptr: *mut bindings::dma_fence, +} + +impl Fence { + /// Create a new Fence object from a raw pointer to a dma_fence. + /// + /// # Safety + /// The caller must own a reference to the dma_fence, which is transferred to the new object. + pub(crate) unsafe fn from_raw(ptr: *mut bindings::dma_fence) -> Fence { + Fence { ptr } + } + + /// Create a new Fence object from a raw pointer to a dma_fence. + /// + /// # Safety + /// Takes a borrowed reference to the dma_fence, and increments the reference count. + pub(crate) unsafe fn get_raw(ptr: *mut bindings::dma_fence) -> Fence { + // SAFETY: Pointer is valid per the safety contract + unsafe { bindings::dma_fence_get(ptr) }; + Fence { ptr } + } + + /// Create a new Fence object from a RawDmaFence. + pub fn from_fence(fence: &dyn RawDmaFence) -> Fence { + // SAFETY: Pointer is valid per the RawDmaFence contract + unsafe { Self::get_raw(fence.raw()) } + } +} + +impl crate::private::Sealed for Fence {} + +impl RawDmaFence for Fence { + fn raw(&self) -> *mut bindings::dma_fence { + self.ptr + } +} + +impl Drop for Fence { + fn drop(&mut self) { + // SAFETY: We own a reference to this syncobj. + unsafe { bindings::dma_fence_put(self.ptr) }; + } +} + +impl Clone for Fence { + fn clone(&self) -> Self { + // SAFETY: `ptr` is valid per the type invariant and we own a reference to it. + unsafe { + bindings::dma_fence_get(self.ptr); + Self::from_raw(self.ptr) + } + } +} + +unsafe impl Sync for Fence {} +unsafe impl Send for Fence {} + +/// Trait which must be implemented by driver-specific fence objects. +#[vtable] +pub trait FenceOps: Sized + Send + Sync { + /// True if this dma_fence implementation uses 64bit seqno, false otherwise. + const USE_64BIT_SEQNO: bool; + + /// Returns the driver name. This is a callback to allow drivers to compute the name at + /// runtime, without having it to store permanently for each fence, or build a cache of + /// some sort. + fn get_driver_name<'a>(self: &'a FenceObject<Self>) -> &'a CStr; + + /// Return the name of the context this fence belongs to. This is a callback to allow drivers + /// to compute the name at runtime, without having it to store permanently for each fence, or + /// build a cache of some sort. + fn get_timeline_name<'a>(self: &'a FenceObject<Self>) -> &'a CStr; + + /// Enable software signaling of fence. + fn enable_signaling(self: &FenceObject<Self>) -> bool { + false + } + + /// Peek whether the fence is signaled, as a fastpath optimization for e.g. dma_fence_wait() or + /// dma_fence_add_callback(). + fn signaled(self: &FenceObject<Self>) -> bool { + false + } + + /// Callback to fill in free-form debug info specific to this fence, like the sequence number. + fn fence_value_str(self: &FenceObject<Self>, _output: &mut dyn Write) {} + + /// Fills in the current value of the timeline as a string, like the sequence number. Note that + /// the specific fence passed to this function should not matter, drivers should only use it to + /// look up the corresponding timeline structures. + fn timeline_value_str(self: &FenceObject<Self>, _output: &mut dyn Write) {} +} + +unsafe extern "C" fn get_driver_name_cb<T: FenceOps>( + fence: *mut bindings::dma_fence, +) -> *const core::ffi::c_char { + // SAFETY: All of our fences are FenceObject<T>. + let p = crate::container_of!(fence, FenceObject<T>, fence) as *mut FenceObject<T>; + + // SAFETY: The caller is responsible for passing a valid dma_fence subtype + T::get_driver_name(unsafe { &mut *p }).as_char_ptr() +} + +unsafe extern "C" fn get_timeline_name_cb<T: FenceOps>( + fence: *mut bindings::dma_fence, +) -> *const core::ffi::c_char { + // SAFETY: All of our fences are FenceObject<T>. + let p = crate::container_of!(fence, FenceObject<T>, fence) as *mut FenceObject<T>; + + // SAFETY: The caller is responsible for passing a valid dma_fence subtype + T::get_timeline_name(unsafe { &mut *p }).as_char_ptr() +} + +unsafe extern "C" fn enable_signaling_cb<T: FenceOps>(fence: *mut bindings::dma_fence) -> bool { + // SAFETY: All of our fences are FenceObject<T>. + let p = crate::container_of!(fence, FenceObject<T>, fence) as *mut FenceObject<T>; + + // SAFETY: The caller is responsible for passing a valid dma_fence subtype + T::enable_signaling(unsafe { &mut *p }) +} + +unsafe extern "C" fn signaled_cb<T: FenceOps>(fence: *mut bindings::dma_fence) -> bool { + // SAFETY: All of our fences are FenceObject<T>. + let p = crate::container_of!(fence, FenceObject<T>, fence) as *mut FenceObject<T>; + + // SAFETY: The caller is responsible for passing a valid dma_fence subtype + T::signaled(unsafe { &mut *p }) +} + +unsafe extern "C" fn release_cb<T: FenceOps>(fence: *mut bindings::dma_fence) { + // SAFETY: All of our fences are FenceObject<T>. + let p = crate::container_of!(fence, FenceObject<T>, fence) as *mut FenceObject<T>; + + // SAFETY: p is never used after this + unsafe { + core::ptr::drop_in_place(&mut (*p).inner); + } + + // SAFETY: All of our fences are allocated using kmalloc, so this is safe. + unsafe { bindings::dma_fence_free(fence) }; +} + +unsafe extern "C" fn fence_value_str_cb<T: FenceOps>( + fence: *mut bindings::dma_fence, + string: *mut core::ffi::c_char, + size: core::ffi::c_int, +) { + let size: usize = size.try_into().unwrap_or(0); + + if size == 0 { + return; + } + + // SAFETY: All of our fences are FenceObject<T>. + let p = crate::container_of!(fence, FenceObject<T>, fence) as *mut FenceObject<T>; + + // SAFETY: The caller is responsible for the validity of string/size + let mut f = unsafe { crate::str::Formatter::from_buffer(string as *mut _, size) }; + + // SAFETY: The caller is responsible for passing a valid dma_fence subtype + T::fence_value_str(unsafe { &mut *p }, &mut f); + let _ = f.write_str("\0"); + + // SAFETY: `size` is at least 1 per the check above + unsafe { *string.add(size - 1) = 0 }; +} + +unsafe extern "C" fn timeline_value_str_cb<T: FenceOps>( + fence: *mut bindings::dma_fence, + string: *mut core::ffi::c_char, + size: core::ffi::c_int, +) { + let size: usize = size.try_into().unwrap_or(0); + + if size == 0 { + return; + } + + // SAFETY: All of our fences are FenceObject<T>. + let p = crate::container_of!(fence, FenceObject<T>, fence) as *mut FenceObject<T>; + + // SAFETY: The caller is responsible for the validity of string/size + let mut f = unsafe { crate::str::Formatter::from_buffer(string as *mut _, size) }; + + // SAFETY: The caller is responsible for passing a valid dma_fence subtype + T::timeline_value_str(unsafe { &mut *p }, &mut f); + let _ = f.write_str("\0"); + + // SAFETY: `size` is at least 1 per the check above + unsafe { *string.add(size - 1) = 0 }; +} + +// Allow FenceObject<Self> to be used as a self argument, for ergonomics +impl<T: FenceOps> core::ops::Receiver for FenceObject<T> {} + +/// A driver-specific DMA Fence Object +/// +/// # Invariants +/// ptr is a valid pointer to a dma_fence and we own a reference to it. +#[repr(C)] +pub struct FenceObject<T: FenceOps> { + fence: bindings::dma_fence, + lock: Opaque<bindings::spinlock>, + inner: T, +} + +impl<T: FenceOps> FenceObject<T> { + const SIZE: usize = core::mem::size_of::<Self>(); + + const VTABLE: bindings::dma_fence_ops = bindings::dma_fence_ops { + use_64bit_seqno: T::USE_64BIT_SEQNO, + get_driver_name: Some(get_driver_name_cb::<T>), + get_timeline_name: Some(get_timeline_name_cb::<T>), + enable_signaling: if T::HAS_ENABLE_SIGNALING { + Some(enable_signaling_cb::<T>) + } else { + None + }, + signaled: if T::HAS_SIGNALED { + Some(signaled_cb::<T>) + } else { + None + }, + wait: None, // Deprecated + release: Some(release_cb::<T>), + fence_value_str: if T::HAS_FENCE_VALUE_STR { + Some(fence_value_str_cb::<T>) + } else { + None + }, + timeline_value_str: if T::HAS_TIMELINE_VALUE_STR { + Some(timeline_value_str_cb::<T>) + } else { + None + }, + }; +} + +impl<T: FenceOps> Deref for FenceObject<T> { + type Target = T; + + fn deref(&self) -> &T { + &self.inner + } +} + +impl<T: FenceOps> DerefMut for FenceObject<T> { + fn deref_mut(&mut self) -> &mut T { + &mut self.inner + } +} + +impl<T: FenceOps> crate::private::Sealed for FenceObject<T> {} +impl<T: FenceOps> RawDmaFence for FenceObject<T> { + fn raw(&self) -> *mut bindings::dma_fence { + &self.fence as *const _ as *mut _ + } +} + +/// A unique reference to a driver-specific fence object +pub struct UniqueFence<T: FenceOps>(*mut FenceObject<T>); + +impl<T: FenceOps> Deref for UniqueFence<T> { + type Target = FenceObject<T>; + + fn deref(&self) -> &FenceObject<T> { + unsafe { &*self.0 } + } +} + +impl<T: FenceOps> DerefMut for UniqueFence<T> { + fn deref_mut(&mut self) -> &mut FenceObject<T> { + unsafe { &mut *self.0 } + } +} + +impl<T: FenceOps> crate::private::Sealed for UniqueFence<T> {} +impl<T: FenceOps> RawDmaFence for UniqueFence<T> { + fn raw(&self) -> *mut bindings::dma_fence { + unsafe { addr_of_mut!((*self.0).fence) } + } +} + +impl<T: FenceOps> From<UniqueFence<T>> for UserFence<T> { + fn from(value: UniqueFence<T>) -> Self { + let ptr = value.0; + core::mem::forget(value); + + UserFence(ptr) + } +} + +impl<T: FenceOps> Drop for UniqueFence<T> { + fn drop(&mut self) { + // SAFETY: We own a reference to this fence. + unsafe { bindings::dma_fence_put(self.raw()) }; + } +} + +unsafe impl<T: FenceOps> Sync for UniqueFence<T> {} +unsafe impl<T: FenceOps> Send for UniqueFence<T> {} + +/// A shared reference to a driver-specific fence object +pub struct UserFence<T: FenceOps>(*mut FenceObject<T>); + +impl<T: FenceOps> Deref for UserFence<T> { + type Target = FenceObject<T>; + + fn deref(&self) -> &FenceObject<T> { + unsafe { &*self.0 } + } +} + +impl<T: FenceOps> Clone for UserFence<T> { + fn clone(&self) -> Self { + // SAFETY: `ptr` is valid per the type invariant and we own a reference to it. + unsafe { + bindings::dma_fence_get(self.raw()); + Self(self.0) + } + } +} + +impl<T: FenceOps> crate::private::Sealed for UserFence<T> {} +impl<T: FenceOps> RawDmaFence for UserFence<T> { + fn raw(&self) -> *mut bindings::dma_fence { + unsafe { addr_of_mut!((*self.0).fence) } + } +} + +impl<T: FenceOps> Drop for UserFence<T> { + fn drop(&mut self) { + // SAFETY: We own a reference to this fence. + unsafe { bindings::dma_fence_put(self.raw()) }; + } +} + +unsafe impl<T: FenceOps> Sync for UserFence<T> {} +unsafe impl<T: FenceOps> Send for UserFence<T> {} + +/// An array of fence contexts, out of which fences can be created. +pub struct FenceContexts { + start: u64, + count: u32, + seqnos: Vec<AtomicU64>, + lock_name: &'static CStr, + lock_key: &'static LockClassKey, +} + +impl FenceContexts { + /// Create a new set of fence contexts. + pub fn new( + count: u32, + name: &'static CStr, + key: &'static LockClassKey, + ) -> Result<FenceContexts> { + let mut seqnos: Vec<AtomicU64> = Vec::new(); + + seqnos.try_reserve(count as usize)?; + + for _ in 0..count { + seqnos.try_push(Default::default())?; + } + + let start = unsafe { bindings::dma_fence_context_alloc(count as core::ffi::c_uint) }; + + Ok(FenceContexts { + start, + count, + seqnos, + lock_name: name, + lock_key: key, + }) + } + + /// Create a new fence in a given context index. + pub fn new_fence<T: FenceOps>(&self, context: u32, inner: T) -> Result<UniqueFence<T>> { + if context > self.count { + return Err(EINVAL); + } + + let p = unsafe { + bindings::krealloc( + core::ptr::null_mut(), + FenceObject::<T>::SIZE, + bindings::GFP_KERNEL | bindings::__GFP_ZERO, + ) as *mut FenceObject<T> + }; + + if p.is_null() { + return Err(ENOMEM); + } + + let seqno = self.seqnos[context as usize].fetch_add(1, Ordering::Relaxed); + + // SAFETY: The pointer is valid, so pointers to members are too. + // After this, all fields are initialized. + unsafe { + addr_of_mut!((*p).inner).write(inner); + bindings::__spin_lock_init( + addr_of_mut!((*p).lock) as *mut _, + self.lock_name.as_char_ptr(), + self.lock_key.get(), + ); + bindings::dma_fence_init( + addr_of_mut!((*p).fence), + &FenceObject::<T>::VTABLE, + addr_of_mut!((*p).lock) as *mut _, + self.start + context as u64, + seqno, + ); + }; + + Ok(UniqueFence(p)) + } +} + +/// A DMA Fence Chain Object +/// +/// # Invariants +/// ptr is a valid pointer to a dma_fence_chain which we own. +pub struct FenceChain { + ptr: *mut bindings::dma_fence_chain, +} + +impl FenceChain { + /// Create a new DmaFenceChain object. + pub fn new() -> Result<Self> { + // SAFETY: This function is safe to call and takes no arguments. + let ptr = unsafe { bindings::dma_fence_chain_alloc() }; + + if ptr.is_null() { + Err(ENOMEM) + } else { + Ok(FenceChain { ptr }) + } + } + + /// Convert the DmaFenceChain into the underlying raw pointer. + /// + /// This assumes the caller will take ownership of the object. + pub(crate) fn into_raw(self) -> *mut bindings::dma_fence_chain { + let ptr = self.ptr; + core::mem::forget(self); + ptr + } +} + +impl Drop for FenceChain { + fn drop(&mut self) { + // SAFETY: We own this dma_fence_chain. + unsafe { bindings::dma_fence_chain_free(self.ptr) }; + } +} |