use super::Blob; use std::convert::TryFrom; use std::mem::MaybeUninit; use std::slice::from_raw_parts_mut; use crate::ffi; use crate::{Error, Result}; impl<'conn> Blob<'conn> { /// Write `buf` to `self` starting at `write_start`, returning an error if /// `write_start + buf.len()` is past the end of the blob. /// /// If an error is returned, no data is written. /// /// Note: the blob cannot be resized using this function -- that must be /// done using SQL (for example, an `UPDATE` statement). /// /// Note: This is part of the positional I/O API, and thus takes an absolute /// position write to, instead of using the internal position that can be /// manipulated by the `std::io` traits. /// /// Unlike the similarly named [`FileExt::write_at`][fext_write_at] function /// (from `std::os::unix`), it's always an error to perform a "short write". /// /// [fext_write_at]: https://doc.rust-lang.org/std/os/unix/fs/trait.FileExt.html#tymethod.write_at #[inline] pub fn write_at(&mut self, buf: &[u8], write_start: usize) -> Result<()> { let len = self.len(); if buf.len().saturating_add(write_start) > len { return Err(Error::BlobSizeError); } // We know `len` fits in an `i32`, so either: // // 1. `buf.len() + write_start` overflows, in which case we'd hit the // return above (courtesy of `saturating_add`). // // 2. `buf.len() + write_start` doesn't overflow but is larger than len, // in which case ditto. // // 3. `buf.len() + write_start` doesn't overflow but is less than len. // This means that both `buf.len()` and `write_start` can also be // losslessly converted to i32, since `len` came from an i32. // Sanity check the above. debug_assert!(i32::try_from(write_start).is_ok() && i32::try_from(buf.len()).is_ok()); self.conn.decode_result(unsafe { ffi::sqlite3_blob_write( self.blob, buf.as_ptr().cast(), buf.len() as i32, write_start as i32, ) }) } /// An alias for `write_at` provided for compatibility with the conceptually /// equivalent [`std::os::unix::FileExt::write_all_at`][write_all_at] /// function from libstd: /// /// [write_all_at]: https://doc.rust-lang.org/std/os/unix/fs/trait.FileExt.html#method.write_all_at #[inline] pub fn write_all_at(&mut self, buf: &[u8], write_start: usize) -> Result<()> { self.write_at(buf, write_start) } /// Read as much as possible from `offset` to `offset + buf.len()` out of /// `self`, writing into `buf`. On success, returns the number of bytes /// written. /// /// If there's insufficient data in `self`, then the returned value will be /// less than `buf.len()`. /// /// See also [`Blob::raw_read_at`], which can take an uninitialized buffer, /// or [`Blob::read_at_exact`] which returns an error if the entire `buf` is /// not read. /// /// Note: This is part of the positional I/O API, and thus takes an absolute /// position to read from, instead of using the internal position that can /// be manipulated by the `std::io` traits. Consequently, it does not change /// that value either. #[inline] pub fn read_at(&self, buf: &mut [u8], read_start: usize) -> Result { // Safety: this is safe because `raw_read_at` never stores uninitialized // data into `as_uninit`. let as_uninit: &mut [MaybeUninit] = unsafe { from_raw_parts_mut(buf.as_mut_ptr().cast(), buf.len()) }; self.raw_read_at(as_uninit, read_start).map(|s| s.len()) } /// Read as much as possible from `offset` to `offset + buf.len()` out of /// `self`, writing into `buf`. On success, returns the portion of `buf` /// which was initialized by this call. /// /// If there's insufficient data in `self`, then the returned value will be /// shorter than `buf`. /// /// See also [`Blob::read_at`], which takes a `&mut [u8]` buffer instead of /// a slice of `MaybeUninit`. /// /// Note: This is part of the positional I/O API, and thus takes an absolute /// position to read from, instead of using the internal position that can /// be manipulated by the `std::io` traits. Consequently, it does not change /// that value either. #[inline] pub fn raw_read_at<'a>( &self, buf: &'a mut [MaybeUninit], read_start: usize, ) -> Result<&'a mut [u8]> { let len = self.len(); let read_len = match len.checked_sub(read_start) { None | Some(0) => 0, Some(v) => v.min(buf.len()), }; if read_len == 0 { // We could return `Ok(&mut [])`, but it seems confusing that the // pointers don't match, so fabricate a empty slice of u8 with the // same base pointer as `buf`. let empty = unsafe { from_raw_parts_mut(buf.as_mut_ptr().cast::(), 0) }; return Ok(empty); } // At this point we believe `read_start as i32` is lossless because: // // 1. `len as i32` is known to be lossless, since it comes from a SQLite // api returning an i32. // // 2. If we got here, `len.checked_sub(read_start)` was Some (or else // we'd have hit the `if read_len == 0` early return), so `len` must // be larger than `read_start`, and so it must fit in i32 as well. debug_assert!(i32::try_from(read_start).is_ok()); // We also believe that `read_start + read_len <= len` because: // // 1. This is equivalent to `read_len <= len - read_start` via algebra. // 2. We know that `read_len` is `min(len - read_start, buf.len())` // 3. Expanding, this is `min(len - read_start, buf.len()) <= len - read_start`, // or `min(A, B) <= A` which is clearly true. // // Note that this stuff is in debug_assert so no need to use checked_add // and such -- we'll always panic on overflow in debug builds. debug_assert!(read_start + read_len <= len); // These follow naturally. debug_assert!(buf.len() >= read_len); debug_assert!(i32::try_from(buf.len()).is_ok()); debug_assert!(i32::try_from(read_len).is_ok()); unsafe { self.conn.decode_result(ffi::sqlite3_blob_read( self.blob, buf.as_mut_ptr().cast(), read_len as i32, read_start as i32, ))?; Ok(from_raw_parts_mut(buf.as_mut_ptr().cast::(), read_len)) } } /// Equivalent to [`Blob::read_at`], but returns a `BlobSizeError` if `buf` /// is not fully initialized. #[inline] pub fn read_at_exact(&self, buf: &mut [u8], read_start: usize) -> Result<()> { let n = self.read_at(buf, read_start)?; if n != buf.len() { Err(Error::BlobSizeError) } else { Ok(()) } } /// Equivalent to [`Blob::raw_read_at`], but returns a `BlobSizeError` if /// `buf` is not fully initialized. #[inline] pub fn raw_read_at_exact<'a>( &self, buf: &'a mut [MaybeUninit], read_start: usize, ) -> Result<&'a mut [u8]> { let buflen = buf.len(); let initted = self.raw_read_at(buf, read_start)?; if initted.len() != buflen { Err(Error::BlobSizeError) } else { Ok(initted) } } } #[cfg(test)] mod test { use crate::{Connection, DatabaseName, Result}; // to ensure we don't modify seek pos use std::io::Seek as _; #[test] fn test_pos_io() -> Result<()> { let db = Connection::open_in_memory()?; db.execute_batch("CREATE TABLE test_table(content BLOB);")?; db.execute("INSERT INTO test_table(content) VALUES (ZEROBLOB(10))", [])?; let rowid = db.last_insert_rowid(); let mut blob = db.blob_open(DatabaseName::Main, "test_table", "content", rowid, false)?; // modify the seek pos to ensure we aren't using it or modifying it. blob.seek(std::io::SeekFrom::Start(1)).unwrap(); let one2ten: [u8; 10] = [1u8, 2, 3, 4, 5, 6, 7, 8, 9, 10]; blob.write_at(&one2ten, 0).unwrap(); let mut s = [0u8; 10]; blob.read_at_exact(&mut s, 0).unwrap(); assert_eq!(&s, &one2ten, "write should go through"); assert!(blob.read_at_exact(&mut s, 1).is_err()); blob.read_at_exact(&mut s, 0).unwrap(); assert_eq!(&s, &one2ten, "should be unchanged"); let mut fives = [0u8; 5]; blob.read_at_exact(&mut fives, 0).unwrap(); assert_eq!(&fives, &[1u8, 2, 3, 4, 5]); blob.read_at_exact(&mut fives, 5).unwrap(); assert_eq!(&fives, &[6u8, 7, 8, 9, 10]); assert!(blob.read_at_exact(&mut fives, 7).is_err()); assert!(blob.read_at_exact(&mut fives, 12).is_err()); assert!(blob.read_at_exact(&mut fives, 10).is_err()); assert!(blob.read_at_exact(&mut fives, i32::MAX as usize).is_err()); assert!(blob .read_at_exact(&mut fives, i32::MAX as usize + 1) .is_err()); // zero length writes are fine if in bounds blob.read_at_exact(&mut [], 10).unwrap(); blob.read_at_exact(&mut [], 0).unwrap(); blob.read_at_exact(&mut [], 5).unwrap(); blob.write_all_at(&[16, 17, 18, 19, 20], 5).unwrap(); blob.read_at_exact(&mut s, 0).unwrap(); assert_eq!(&s, &[1u8, 2, 3, 4, 5, 16, 17, 18, 19, 20]); assert!(blob.write_at(&[100, 99, 98, 97, 96], 6).is_err()); assert!(blob .write_at(&[100, 99, 98, 97, 96], i32::MAX as usize) .is_err()); assert!(blob .write_at(&[100, 99, 98, 97, 96], i32::MAX as usize + 1) .is_err()); blob.read_at_exact(&mut s, 0).unwrap(); assert_eq!(&s, &[1u8, 2, 3, 4, 5, 16, 17, 18, 19, 20]); let mut s2: [std::mem::MaybeUninit; 10] = [std::mem::MaybeUninit::uninit(); 10]; { let read = blob.raw_read_at_exact(&mut s2, 0).unwrap(); assert_eq!(read, &s); assert!(std::ptr::eq(read.as_ptr(), s2.as_ptr().cast())); } let mut empty = []; assert!(std::ptr::eq( blob.raw_read_at_exact(&mut empty, 0).unwrap().as_ptr(), empty.as_ptr().cast(), )); assert!(blob.raw_read_at_exact(&mut s2, 5).is_err()); let end_pos = blob.seek(std::io::SeekFrom::Current(0)).unwrap(); assert_eq!(end_pos, 1); Ok(()) } }