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* If SQLITE3_LIB_DIR is present in the environment, we use that. * If SQLITE3_LIB_DIR is not present, we try to use pkg-config. * If SQLITE3_LIB_DIR is not present and pkg-config fails, we fall back to /usr/lib (if it exists). |
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libsqlite3-sys | ||
src | ||
.gitignore | ||
.travis.yml | ||
build.rs | ||
Cargo.toml | ||
Changelog.md | ||
CONTRIBUTORS.md | ||
LICENSE | ||
README.md |
Rusqlite
Rusqlite is an ergonomic wrapper for using SQLite from Rust. It attempts to expose an interface similar to rust-postgres. View the full API documentation.
extern crate rusqlite;
extern crate time;
use time::Timespec;
use rusqlite::SqliteConnection;
#[derive(Debug)]
struct Person {
id: i32,
name: String,
time_created: Timespec,
data: Option<Vec<u8>>
}
fn main() {
let conn = SqliteConnection::open_in_memory().unwrap();
conn.execute("CREATE TABLE person (
id INTEGER PRIMARY KEY,
name TEXT NOT NULL,
time_created TEXT NOT NULL,
data BLOB
)", &[]).unwrap();
let me = Person {
id: 0,
name: "Steven".to_string(),
time_created: time::get_time(),
data: None
};
conn.execute("INSERT INTO person (name, time_created, data)
VALUES ($1, $2, $3)",
&[&me.name, &me.time_created, &me.data]).unwrap();
let mut stmt = conn.prepare("SELECT id, name, time_created, data FROM person").unwrap();
let mut person_iter = stmt.query_map(&[], |row| {
Person {
id: row.get(0),
name: row.get(1),
time_created: row.get(2),
data: row.get(3)
}
}).unwrap();
for person in person_iter {
println!("Found person {:?}", person.unwrap());
}
}
Design of SqliteRows and SqliteRow
To retrieve the result rows from a query, SQLite requires you to call
sqlite3_step() on a prepared statement. You can only
retrieve the values of the "current" row. From the Rust point of view, this means that each row
is only valid until the next row is fetched. rust-sqlite3
solves this the correct way with lifetimes. However, this means that the result rows do not
satisfy the Iterator trait, which means
you cannot (as easily) loop over the rows, or use many of the helpful Iterator methods like map
and filter
.
Instead, Rusqlite's SqliteRows
handle does conform to Iterator
. It ensures safety by
performing checks at runtime to ensure you do not try to retrieve the values of a "stale" row, and
will panic if you do so. A specific example that will panic:
fn bad_function_will_panic(conn: &SqliteConnection) -> SqliteResult<i64> {
let mut stmt = try!(conn.prepare("SELECT id FROM my_table"));
let mut rows = try!(stmt.query(&[]));
let row0 = try!(rows.next().unwrap());
// row 0 is valid now...
let row1 = try!(rows.next().unwrap());
// row 0 is now STALE, and row 1 is valid
let my_id = row0.get(0); // WILL PANIC because row 0 is stale
Ok(my_id)
}
There are other, less obvious things that may result in a panic as well, such as calling
collect()
on a SqliteRows
and then trying to use the collected rows.
Strongly consider using the method query_map()
instead, if you can.
query_map()
returns an iterator over rows-mapped-to-some-type. This
iterator does not have any of the above issues with panics due to attempting to
access stale rows.
Author
John Gallagher, johnkgallagher@gmail.com
License
Rusqlite is available under the MIT license. See the LICENSE file for more info.