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oxicuda_memory/
host_buffer.rs

1//! Pinned (page-locked) host memory buffer.
2//!
3//! [`PinnedBuffer<T>`] allocates host memory via `cuMemAllocHost_v2`, which
4//! pins the pages so that the CUDA driver can perform DMA transfers without
5//! an intermediate staging copy.  This is the recommended source/destination
6//! for asynchronous host-device transfers.
7//!
8//! # Deref
9//!
10//! `PinnedBuffer<T>` implements [`Deref`] and [`DerefMut`] to `[T]`, so it
11//! can be used anywhere a slice is expected.
12//!
13//! # Ownership
14//!
15//! The allocation is freed with `cuMemFreeHost` on drop.  Errors during
16//! drop are logged via [`tracing::warn`].
17//!
18//! # Example
19//!
20//! ```rust,no_run
21//! # use oxicuda_memory::PinnedBuffer;
22//! let mut pinned = PinnedBuffer::<f32>::alloc(256)?;
23//! for (i, v) in pinned.iter_mut().enumerate() {
24//!     *v = i as f32;
25//! }
26//! assert_eq!(pinned.len(), 256);
27//! # Ok::<(), oxicuda_driver::error::CudaError>(())
28//! ```
29
30use std::ffi::c_void;
31use std::ops::{Deref, DerefMut};
32
33use oxicuda_driver::error::{CudaError, CudaResult};
34use oxicuda_driver::loader::try_driver;
35
36// ---------------------------------------------------------------------------
37// PinnedBuffer<T>
38// ---------------------------------------------------------------------------
39
40/// A contiguous buffer of `T` elements in page-locked (pinned) host memory.
41///
42/// Pinned memory enables the CUDA driver to use DMA for host-device
43/// transfers, avoiding an extra copy through a staging buffer.  This makes
44/// pinned buffers the preferred choice for async copy operations.
45///
46/// The buffer dereferences to `&[T]` / `&mut [T]` for ergonomic access.
47pub struct PinnedBuffer<T: Copy> {
48    /// Pointer to the start of the pinned allocation.
49    ptr: *mut T,
50    /// Number of `T` elements (not bytes).
51    len: usize,
52}
53
54// SAFETY: The pinned host memory is not thread-local; it is a plain heap
55// allocation that is safe to access from any thread.
56unsafe impl<T: Copy + Send> Send for PinnedBuffer<T> {}
57unsafe impl<T: Copy + Sync> Sync for PinnedBuffer<T> {}
58
59impl<T: Copy> PinnedBuffer<T> {
60    /// Allocates a pinned host buffer capable of holding `n` elements of type `T`.
61    ///
62    /// # Errors
63    ///
64    /// * [`CudaError::InvalidValue`] if `n` is zero.
65    /// * [`CudaError::OutOfMemory`] if the host cannot satisfy the request.
66    /// * Other driver errors from `cuMemAllocHost_v2`.
67    pub fn alloc(n: usize) -> CudaResult<Self> {
68        if n == 0 {
69            return Err(CudaError::InvalidValue);
70        }
71        let byte_size = n
72            .checked_mul(std::mem::size_of::<T>())
73            .ok_or(CudaError::InvalidValue)?;
74        let api = try_driver()?;
75        let mut raw_ptr: *mut c_void = std::ptr::null_mut();
76        // SAFETY: `cu_mem_alloc_host_v2` writes a valid host pointer on success.
77        let rc = unsafe { (api.cu_mem_alloc_host_v2)(&mut raw_ptr, byte_size) };
78        oxicuda_driver::check(rc)?;
79        // SAFETY: `raw_ptr` was just allocated by `cu_mem_alloc_host_v2` and
80        // is valid for `byte_size` bytes; zero-initialising it here means
81        // `as_slice`/`as_mut_slice` below never expose driver-uninitialised
82        // memory as a safe `&[T]` (all-zero bytes are a valid `T` for every
83        // in-tree usage of `PinnedBuffer`, e.g. `u8`/`f32`). Skipped when
84        // `T` is zero-sized (byte_size == 0 despite `n > 0`) to avoid a
85        // no-op write through a possibly-unusual pointer.
86        if byte_size > 0 {
87            unsafe {
88                std::ptr::write_bytes(raw_ptr.cast::<u8>(), 0, byte_size);
89            }
90        }
91        Ok(Self {
92            ptr: raw_ptr.cast::<T>(),
93            len: n,
94        })
95    }
96
97    /// Allocates a pinned host buffer and copies the contents of `data` into it.
98    ///
99    /// # Errors
100    ///
101    /// * [`CudaError::InvalidValue`] if `data` is empty.
102    /// * Other driver errors from allocation.
103    pub fn from_slice(data: &[T]) -> CudaResult<Self> {
104        let buf = Self::alloc(data.len())?;
105        // SAFETY: both `data` and `buf.ptr` point to valid memory of
106        // `data.len() * size_of::<T>()` bytes, and `T: Copy`.
107        unsafe {
108            std::ptr::copy_nonoverlapping(data.as_ptr(), buf.ptr, data.len());
109        }
110        Ok(buf)
111    }
112
113    /// Returns the number of `T` elements in this buffer.
114    #[inline]
115    pub fn len(&self) -> usize {
116        self.len
117    }
118
119    /// Returns `true` if the buffer contains zero elements.
120    #[inline]
121    pub fn is_empty(&self) -> bool {
122        self.len == 0
123    }
124
125    /// Returns a raw const pointer to the buffer's data.
126    #[inline]
127    pub fn as_ptr(&self) -> *const T {
128        self.ptr
129    }
130
131    /// Returns a raw mutable pointer to the buffer's data.
132    #[inline]
133    pub fn as_mut_ptr(&mut self) -> *mut T {
134        self.ptr
135    }
136
137    /// Returns a shared slice over the buffer's contents.
138    #[inline]
139    pub fn as_slice(&self) -> &[T] {
140        // SAFETY: `self.ptr` is a valid, aligned allocation of `self.len`
141        // elements, zero-initialised at `alloc` time, and we have `&self` so
142        // no mutable alias exists.
143        unsafe { std::slice::from_raw_parts(self.ptr, self.len) }
144    }
145
146    /// Returns a mutable slice over the buffer's contents.
147    #[inline]
148    pub fn as_mut_slice(&mut self) -> &mut [T] {
149        // SAFETY: `self.ptr` is a valid, aligned allocation of `self.len`
150        // elements, zero-initialised at `alloc` time, and we have `&mut self`
151        // so no other alias exists.
152        unsafe { std::slice::from_raw_parts_mut(self.ptr, self.len) }
153    }
154}
155
156impl<T: Copy> Deref for PinnedBuffer<T> {
157    type Target = [T];
158
159    #[inline]
160    fn deref(&self) -> &[T] {
161        self.as_slice()
162    }
163}
164
165impl<T: Copy> DerefMut for PinnedBuffer<T> {
166    #[inline]
167    fn deref_mut(&mut self) -> &mut [T] {
168        self.as_mut_slice()
169    }
170}
171
172impl<T: Copy> Drop for PinnedBuffer<T> {
173    fn drop(&mut self) {
174        if let Ok(api) = try_driver() {
175            // SAFETY: `self.ptr` was allocated by `cu_mem_alloc_host_v2` and
176            // has not yet been freed.
177            let rc = unsafe { (api.cu_mem_free_host)(self.ptr.cast::<c_void>()) };
178            if rc != 0 {
179                tracing::warn!(
180                    cuda_error = rc,
181                    len = self.len,
182                    "cuMemFreeHost failed during PinnedBuffer drop"
183                );
184            }
185        }
186    }
187}
188
189// ---------------------------------------------------------------------------
190// Tests
191// ---------------------------------------------------------------------------
192
193#[cfg(test)]
194mod tests {
195    use super::*;
196
197    #[test]
198    fn alloc_signature_compiles() {
199        let _: fn(usize) -> CudaResult<PinnedBuffer<f32>> = PinnedBuffer::alloc;
200    }
201
202    #[cfg(feature = "gpu-tests")]
203    mod gpu_tests {
204        use super::*;
205
206        /// Establishes a real CUDA context on device 0 so driver calls that
207        /// require a current context (e.g. `cuMemAllocHost_v2`) succeed.
208        /// Returns `None` if no driver/GPU is available, so tests can skip
209        /// gracefully.
210        fn real_context() -> Option<oxicuda_driver::context::Context> {
211            if oxicuda_driver::init().is_err()
212                || oxicuda_driver::device::Device::count().unwrap_or(0) == 0
213            {
214                return None;
215            }
216            let dev = oxicuda_driver::device::Device::get(0).ok()?;
217            oxicuda_driver::context::Context::new(&dev).ok()
218        }
219
220        /// Regression test for F070: a freshly allocated `PinnedBuffer` must
221        /// never expose driver-uninitialised bytes through the safe
222        /// `as_slice`/`Deref` accessors — it must read back as all-zero.
223        #[test]
224        fn alloc_is_zero_initialized() {
225            let Some(_ctx) = real_context() else {
226                eprintln!("skipping: no CUDA driver/device");
227                return;
228            };
229            let Ok(buf) = PinnedBuffer::<u8>::alloc(4096) else {
230                eprintln!("skipping: alloc failed");
231                return;
232            };
233            assert_eq!(buf.len(), 4096);
234            assert!(buf.as_slice().iter().all(|&b| b == 0));
235        }
236
237        #[test]
238        fn from_slice_round_trips() {
239            let Some(_ctx) = real_context() else {
240                eprintln!("skipping: no CUDA driver/device");
241                return;
242            };
243            let data: Vec<f32> = (0..64).map(|i| i as f32).collect();
244            let Ok(buf) = PinnedBuffer::from_slice(&data) else {
245                eprintln!("skipping: alloc failed");
246                return;
247            };
248            assert_eq!(&*buf, data.as_slice());
249        }
250    }
251}