//! Incremental BLOB I/O. //! //! Note that SQLite does not provide API-level access to change the size of a BLOB; that must //! be performed through SQL statements. //! //! `Blob` conforms to `std::io::Read`, `std::io::Write`, and `std::io::Seek`, so it plays //! nicely with other types that build on these (such as `std::io::BufReader` and //! `std::io::BufWriter`). However, you must be careful with the size of the blob. For example, //! when using a `BufWriter`, the `BufWriter` will accept more data than the `Blob` will allow, //! so make sure to call `flush` and check for errors. (See the unit tests in this module for //! an example.) //! //! ## Example //! //! ```rust //! extern crate libsqlite3_sys; //! extern crate rusqlite; //! //! use rusqlite::{Connection, DatabaseName}; //! use std::io::{Read, Write, Seek, SeekFrom}; //! //! fn main() { //! let db = Connection::open_in_memory().unwrap(); //! db.execute_batch("CREATE TABLE test (content BLOB);").unwrap(); //! db.execute("INSERT INTO test (content) VALUES (ZEROBLOB(10))", &[]).unwrap(); //! //! let rowid = db.last_insert_rowid(); //! let mut blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, false).unwrap(); //! //! // Make sure to test that the number of bytes written matches what you expect; //! // if you try to write too much, the data will be truncated to the size of the BLOB. //! let bytes_written = blob.write(b"01234567").unwrap(); //! assert_eq!(bytes_written, 8); //! //! // Same guidance - make sure you check the number of bytes read! //! blob.seek(SeekFrom::Start(0)).unwrap(); //! let mut buf = [0u8; 20]; //! let bytes_read = blob.read(&mut buf[..]).unwrap(); //! assert_eq!(bytes_read, 10); // note we read 10 bytes because the blob has size 10 //! //! db.execute("INSERT INTO test (content) VALUES (ZEROBLOB(64))", &[]).unwrap(); //! //! // given a new row ID, we can reopen the blob on that row //! let rowid = db.last_insert_rowid(); //! blob.reopen(rowid).unwrap(); //! //! assert_eq!(blob.size(), 64); //! } //! ``` use std::io; use std::cmp::min; use std::mem; use std::ptr; use super::ffi; use {Result, Connection, DatabaseName}; /// Handle to an open BLOB. pub struct Blob<'conn> { conn: &'conn Connection, blob: *mut ffi::sqlite3_blob, pos: i32, } impl Connection { /// Open a handle to the BLOB located in `row`, `column`, `table` in database `db`. /// /// # Failure /// /// Will return `Err` if `db`/`table`/`column` cannot be converted to a C-compatible string /// or if the underlying SQLite BLOB open call fails. pub fn blob_open<'a>(&'a self, db: DatabaseName, table: &str, column: &str, row: i64, read_only: bool) -> Result> { let mut c = self.db.borrow_mut(); let mut blob = ptr::null_mut(); let db = try!(db.to_cstring()); let table = try!(super::str_to_cstring(table)); let column = try!(super::str_to_cstring(column)); let rc = unsafe { ffi::sqlite3_blob_open(c.db(), db.as_ptr(), table.as_ptr(), column.as_ptr(), row, if read_only { 0 } else { 1 }, &mut blob) }; c.decode_result(rc).map(|_| { Blob { conn: self, blob: blob, pos: 0, } }) } } impl<'conn> Blob<'conn> { /// Move a BLOB handle to a new row. /// /// # Failure /// /// Will return `Err` if the underlying SQLite BLOB reopen call fails. pub fn reopen(&mut self, row: i64) -> Result<()> { let rc = unsafe { ffi::sqlite3_blob_reopen(self.blob, row) }; if rc != ffi::SQLITE_OK { return self.conn.decode_result(rc); } self.pos = 0; Ok(()) } /// Return the size in bytes of the BLOB. pub fn size(&self) -> i32 { unsafe { ffi::sqlite3_blob_bytes(self.blob) } } /// Close a BLOB handle. /// /// Calling `close` explicitly is not required (the BLOB will be closed when the /// `Blob` is dropped), but it is available so you can get any errors that occur. /// /// # Failure /// /// Will return `Err` if the underlying SQLite close call fails. pub fn close(mut self) -> Result<()> { self.close_() } fn close_(&mut self) -> Result<()> { let rc = unsafe { ffi::sqlite3_blob_close(self.blob) }; self.blob = ptr::null_mut(); self.conn.decode_result(rc) } } impl<'conn> io::Read for Blob<'conn> { /// Read data from a BLOB incrementally. Will return Ok(0) if the end of the blob /// has been reached. /// /// # Failure /// /// Will return `Err` if the underlying SQLite read call fails. fn read(&mut self, buf: &mut [u8]) -> io::Result { let max_allowed_len = (self.size() - self.pos) as usize; let n = min(buf.len(), max_allowed_len) as i32; if n <= 0 { return Ok(0); } let rc = unsafe { ffi::sqlite3_blob_read(self.blob, mem::transmute(buf.as_ptr()), n, self.pos) }; self.conn .decode_result(rc) .map(|_| { self.pos += n; n as usize }) .map_err(|err| io::Error::new(io::ErrorKind::Other, err)) } } impl<'conn> io::Write for Blob<'conn> { /// Write data into a BLOB incrementally. Will return `Ok(0)` if the end of the blob /// has been reached; consider using `Write::write_all(buf)` if you want to get an /// error if the entirety of the buffer cannot be written. /// /// This function may only modify the contents of the BLOB; it is not possible to increase /// the size of a BLOB using this API. /// /// # Failure /// /// Will return `Err` if the underlying SQLite write call fails. fn write(&mut self, buf: &[u8]) -> io::Result { let max_allowed_len = (self.size() - self.pos) as usize; let n = min(buf.len(), max_allowed_len) as i32; if n <= 0 { return Ok(0); } let rc = unsafe { ffi::sqlite3_blob_write(self.blob, mem::transmute(buf.as_ptr()), n, self.pos) }; self.conn .decode_result(rc) .map(|_| { self.pos += n; n as usize }) .map_err(|err| io::Error::new(io::ErrorKind::Other, err)) } fn flush(&mut self) -> io::Result<()> { Ok(()) } } impl<'conn> io::Seek for Blob<'conn> { /// Seek to an offset, in bytes, in BLOB. fn seek(&mut self, pos: io::SeekFrom) -> io::Result { let pos = match pos { io::SeekFrom::Start(offset) => offset as i64, io::SeekFrom::Current(offset) => self.pos as i64 + offset, io::SeekFrom::End(offset) => self.size() as i64 + offset, }; if pos < 0 { Err(io::Error::new(io::ErrorKind::InvalidInput, "invalid seek to negative position")) } else if pos > self.size() as i64 { Err(io::Error::new(io::ErrorKind::InvalidInput, "invalid seek to position past end of blob")) } else { self.pos = pos as i32; Ok(pos as u64) } } } #[allow(unused_must_use)] impl<'conn> Drop for Blob<'conn> { fn drop(&mut self) { self.close_(); } } #[cfg(test)] mod test { use std::io::{BufReader, BufRead, BufWriter, Read, Write, Seek, SeekFrom}; use {Connection, DatabaseName, Result}; #[cfg_attr(rustfmt, rustfmt_skip)] fn db_with_test_blob() -> Result<(Connection, i64)> { let db = try!(Connection::open_in_memory()); let sql = "BEGIN; CREATE TABLE test (content BLOB); INSERT INTO test VALUES (ZEROBLOB(10)); END;"; try!(db.execute_batch(sql)); let rowid = db.last_insert_rowid(); Ok((db, rowid)) } #[test] fn test_blob() { let (db, rowid) = db_with_test_blob().unwrap(); let mut blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, false).unwrap(); assert_eq!(4, blob.write(b"Clob").unwrap()); assert_eq!(6, blob.write(b"567890xxxxxx").unwrap()); // cannot write past 10 assert_eq!(0, blob.write(b"5678").unwrap()); // still cannot write past 10 blob.reopen(rowid).unwrap(); blob.close().unwrap(); blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, true).unwrap(); let mut bytes = [0u8; 5]; assert_eq!(5, blob.read(&mut bytes[..]).unwrap()); assert_eq!(&bytes, b"Clob5"); assert_eq!(5, blob.read(&mut bytes[..]).unwrap()); assert_eq!(&bytes, b"67890"); assert_eq!(0, blob.read(&mut bytes[..]).unwrap()); blob.seek(SeekFrom::Start(2)).unwrap(); assert_eq!(5, blob.read(&mut bytes[..]).unwrap()); assert_eq!(&bytes, b"ob567"); // only first 4 bytes of `bytes` should be read into blob.seek(SeekFrom::Current(-1)).unwrap(); assert_eq!(4, blob.read(&mut bytes[..]).unwrap()); assert_eq!(&bytes, b"78907"); blob.seek(SeekFrom::End(-6)).unwrap(); assert_eq!(5, blob.read(&mut bytes[..]).unwrap()); assert_eq!(&bytes, b"56789"); blob.reopen(rowid).unwrap(); assert_eq!(5, blob.read(&mut bytes[..]).unwrap()); assert_eq!(&bytes, b"Clob5"); // should not be able to seek negative or past end assert!(blob.seek(SeekFrom::Current(-20)).is_err()); assert!(blob.seek(SeekFrom::End(0)).is_ok()); assert!(blob.seek(SeekFrom::Current(1)).is_err()); // write_all should detect when we return Ok(0) because there is no space left, // and return a write error blob.reopen(rowid).unwrap(); assert!(blob.write_all(b"0123456789x").is_err()); } #[test] fn test_blob_in_bufreader() { let (db, rowid) = db_with_test_blob().unwrap(); let mut blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, false).unwrap(); assert_eq!(8, blob.write(b"one\ntwo\n").unwrap()); blob.reopen(rowid).unwrap(); let mut reader = BufReader::new(blob); let mut line = String::new(); assert_eq!(4, reader.read_line(&mut line).unwrap()); assert_eq!("one\n", line); line.truncate(0); assert_eq!(4, reader.read_line(&mut line).unwrap()); assert_eq!("two\n", line); line.truncate(0); assert_eq!(2, reader.read_line(&mut line).unwrap()); assert_eq!("\0\0", line); } #[test] fn test_blob_in_bufwriter() { let (db, rowid) = db_with_test_blob().unwrap(); { let blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, false).unwrap(); let mut writer = BufWriter::new(blob); // trying to write too much and then flush should fail assert_eq!(8, writer.write(b"01234567").unwrap()); assert_eq!(8, writer.write(b"01234567").unwrap()); assert!(writer.flush().is_err()); } { // ... but it should've written the first 10 bytes let mut blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, false).unwrap(); let mut bytes = [0u8; 10]; assert_eq!(10, blob.read(&mut bytes[..]).unwrap()); assert_eq!(b"0123456701", &bytes); } { let blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, false).unwrap(); let mut writer = BufWriter::new(blob); // trying to write_all too much should fail writer.write_all(b"aaaaaaaaaabbbbb").unwrap(); assert!(writer.flush().is_err()); } { // ... but it should've written the first 10 bytes let mut blob = db.blob_open(DatabaseName::Main, "test", "content", rowid, false).unwrap(); let mut bytes = [0u8; 10]; assert_eq!(10, blob.read(&mut bytes[..]).unwrap()); assert_eq!(b"aaaaaaaaaa", &bytes); } } }