rusqlite 0.4.0

//! Traits dealing with SQLite data types.
//!
//! SQLite uses a [dynamic type system](https://www.sqlite.org/datatype3.html). Implementations of
//! the `ToSql` and `FromSql` traits are provided for the basic types that SQLite provides methods
//! for:
//!
//! * C integers and doubles (`c_int` and `c_double`)
//! * Strings (`String` and `&str`)
//! * Blobs (`Vec<u8>` and `&[u8]`)
//!
//! Additionally, because it is such a common data type, implementations are provided for
//! `time::Timespec` that use a string for storage (using the same format string,
//! `"%Y-%m-%d %H:%M:%S"`, as SQLite's builtin
//! [datetime](https://www.sqlite.org/lang_datefunc.html) function.  Note that this storage
//! truncates timespecs to the nearest second. If you want different storage for timespecs, you can
//! use a newtype. For example, to store timespecs as doubles:
//!
//! `ToSql` and `FromSql` are also implemented for `Option<T>` where `T` implements `ToSql` or
//! `FromSql` for the cases where you want to know if a value was NULL (which gets translated to
//! `None`). If you get a value that was NULL in SQLite but you store it into a non-`Option` value
//! in Rust, you will get a "sensible" zero value - 0 for numeric types (including timespecs), an
//! empty string, or an empty vector of bytes.
//!
//! ```rust,ignore
//! extern crate rusqlite;
//! extern crate libc;
//!
//! use rusqlite::types::{FromSql, ToSql, sqlite3_stmt};
//! use rusqlite::{SqliteResult};
//! use libc::c_int;
//! use time;
//!
//! pub struct TimespecSql(pub time::Timespec);
//!
//! impl FromSql for TimespecSql {
//!     unsafe fn column_result(stmt: *mut sqlite3_stmt, col: c_int)
//!             -> SqliteResult<TimespecSql> {
//!         let as_f64_result = FromSql::column_result(stmt, col);
//!         as_f64_result.map(|as_f64: f64| {
//!             TimespecSql(time::Timespec{ sec: as_f64.trunc() as i64,
//!                                         nsec: (as_f64.fract() * 1.0e9) as i32 })
//!         })
//!     }
//! }
//!
//! impl ToSql for TimespecSql {
//!     unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
//!         let TimespecSql(ts) = *self;
//!         let as_f64 = ts.sec as f64 + (ts.nsec as f64) / 1.0e9;
//!         as_f64.bind_parameter(stmt, col)
//!     }
//! }
//! ```

extern crate time;

use libc::{c_int, c_double, c_char};
use std::ffi::{CStr};
use std::mem;
use std::str;
use super::ffi;
use super::{SqliteResult, SqliteError, str_to_cstring};

pub use ffi::sqlite3_stmt as sqlite3_stmt;
pub use ffi::sqlite3_column_type as sqlite3_column_type;

pub use ffi::{SQLITE_INTEGER, SQLITE_FLOAT, SQLITE_TEXT, SQLITE_BLOB, SQLITE_NULL};

const SQLITE_DATETIME_FMT: &'static str = "%Y-%m-%d %H:%M:%S";

/// A trait for types that can be converted into SQLite values.
pub trait ToSql {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int;
}

/// A trait for types that can be created from a SQLite value.
pub trait FromSql: Sized {
    unsafe fn column_result(stmt: *mut sqlite3_stmt, col: c_int) -> SqliteResult<Self>;

    /// FromSql types can implement this method and use sqlite3_column_type to check that
    /// the type reported by SQLite matches a type suitable for Self. This method is used
    /// by `SqliteRow::get_checked` to confirm that the column contains a valid type before
    /// attempting to retrieve the value.
    unsafe fn column_has_valid_sqlite_type(_: *mut sqlite3_stmt, _: c_int) -> bool {
        true
    }
}

macro_rules! raw_to_impl(
    ($t:ty, $f:ident) => (
        impl ToSql for $t {
            unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
                ffi::$f(stmt, col, *self)
            }
        }
    )
);

raw_to_impl!(c_int, sqlite3_bind_int);
raw_to_impl!(i64, sqlite3_bind_int64);
raw_to_impl!(c_double, sqlite3_bind_double);

impl<'a> ToSql for &'a str {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
        let length = self.len();
        if length > ::std::i32::MAX as usize {
            return ffi::SQLITE_TOOBIG;
        }
        match str_to_cstring(self) {
            Ok(c_str) => ffi::sqlite3_bind_text(stmt, col, c_str.as_ptr(), length as c_int,
                                                ffi::SQLITE_TRANSIENT()),
            Err(_)    => ffi::SQLITE_MISUSE,
        }
    }
}

impl ToSql for String {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
        (&self[..]).bind_parameter(stmt, col)
    }
}

impl<'a> ToSql for &'a [u8] {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
        if self.len() > ::std::i32::MAX as usize {
            return ffi::SQLITE_TOOBIG;
        }
        ffi::sqlite3_bind_blob(
            stmt, col, mem::transmute(self.as_ptr()), self.len() as c_int, ffi::SQLITE_TRANSIENT())
    }
}

impl ToSql for Vec<u8> {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
        (&self[..]).bind_parameter(stmt, col)
    }
}

impl ToSql for time::Timespec {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
        let time_str = time::at_utc(*self).strftime(SQLITE_DATETIME_FMT).unwrap().to_string();
        time_str.bind_parameter(stmt, col)
    }
}

impl<T: ToSql> ToSql for Option<T> {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
        match *self {
            None => ffi::sqlite3_bind_null(stmt, col),
            Some(ref t) => t.bind_parameter(stmt, col),
        }
    }
}

/// Empty struct that can be used to fill in a query parameter as `NULL`.
///
/// ## Example
///
/// ```rust,no_run
/// # extern crate libc;
/// # extern crate rusqlite;
/// # use rusqlite::{SqliteConnection, SqliteResult};
/// # use rusqlite::types::{Null};
/// # use libc::{c_int};
/// fn main() {
/// }
/// fn insert_null(conn: &SqliteConnection) -> SqliteResult<c_int> {
///     conn.execute("INSERT INTO people (name) VALUES (?)", &[&Null])
/// }
/// ```
#[derive(Copy,Clone)]
pub struct Null;

impl ToSql for Null {
    unsafe fn bind_parameter(&self, stmt: *mut sqlite3_stmt, col: c_int) -> c_int {
        ffi::sqlite3_bind_null(stmt, col)
    }
}

macro_rules! raw_from_impl(
    ($t:ty, $f:ident, $c:expr) => (
        impl FromSql for $t {
            unsafe fn column_result(stmt: *mut sqlite3_stmt, col: c_int) -> SqliteResult<$t> {
                Ok(ffi::$f(stmt, col))
            }

            unsafe fn column_has_valid_sqlite_type(stmt: *mut sqlite3_stmt, col: c_int) -> bool {
                sqlite3_column_type(stmt, col) == $c
            }
        }
    )
);

raw_from_impl!(c_int, sqlite3_column_int, ffi::SQLITE_INTEGER);
raw_from_impl!(i64, sqlite3_column_int64, ffi::SQLITE_INTEGER);
raw_from_impl!(c_double, sqlite3_column_double, ffi::SQLITE_FLOAT);

impl FromSql for String {
    unsafe fn column_result(stmt: *mut sqlite3_stmt, col: c_int) -> SqliteResult<String> {
        let c_text = ffi::sqlite3_column_text(stmt, col);
        if c_text.is_null() {
            Ok("".to_string())
        } else {
            let c_slice = CStr::from_ptr(c_text as *const c_char).to_bytes();
            let utf8_str = str::from_utf8(c_slice);
            utf8_str
                .map(|s| { s.to_string() })
                .map_err(|e| { SqliteError{code: 0, message: e.to_string()} })
        }
    }

    unsafe fn column_has_valid_sqlite_type(stmt: *mut sqlite3_stmt, col: c_int) -> bool {
        sqlite3_column_type(stmt, col) == ffi::SQLITE_TEXT
    }
}

impl FromSql for Vec<u8> {
    unsafe fn column_result(stmt: *mut sqlite3_stmt, col: c_int) -> SqliteResult<Vec<u8>> {
        use std::slice::from_raw_parts;
        let c_blob = ffi::sqlite3_column_blob(stmt, col);
        let len = ffi::sqlite3_column_bytes(stmt, col);

        // The documentation for sqlite3_column_bytes indicates it is always non-negative,
        // but we should assert here just to be sure.
        assert!(len >= 0, "unexpected negative return from sqlite3_column_bytes");
        let len = len as usize;

        Ok(from_raw_parts(mem::transmute(c_blob), len).to_vec())
    }

    unsafe fn column_has_valid_sqlite_type(stmt: *mut sqlite3_stmt, col: c_int) -> bool {
        sqlite3_column_type(stmt, col) == ffi::SQLITE_BLOB
    }
}

impl FromSql for time::Timespec {
    unsafe fn column_result(stmt: *mut sqlite3_stmt,
                            col: c_int) -> SqliteResult<time::Timespec> {
        let col_str = FromSql::column_result(stmt, col);
        col_str.and_then(|txt: String| {
            time::strptime(&txt, SQLITE_DATETIME_FMT).map(|tm| {
                tm.to_timespec()
            }).map_err(|parse_error| {
                SqliteError{ code: ffi::SQLITE_MISMATCH, message: format!("{}", parse_error) }
            })
        })
    }

    unsafe fn column_has_valid_sqlite_type(stmt: *mut sqlite3_stmt, col: c_int) -> bool {
        String::column_has_valid_sqlite_type(stmt, col)
    }
}

impl<T: FromSql> FromSql for Option<T> {
    unsafe fn column_result(stmt: *mut sqlite3_stmt, col: c_int) -> SqliteResult<Option<T>> {
        if sqlite3_column_type(stmt, col) == ffi::SQLITE_NULL {
            Ok(None)
        } else {
            FromSql::column_result(stmt, col).map(|t| Some(t))
        }
    }

    unsafe fn column_has_valid_sqlite_type(stmt: *mut sqlite3_stmt, col: c_int) -> bool {
        sqlite3_column_type(stmt, col) == ffi::SQLITE_NULL ||
            T::column_has_valid_sqlite_type(stmt, col)
    }
}

#[cfg(test)]
mod test {
    use SqliteConnection;
    use ffi;
    use super::time;
    use libc::{c_int, c_double};

    fn checked_memory_handle() -> SqliteConnection {
        let db = SqliteConnection::open_in_memory().unwrap();
        db.execute_batch("CREATE TABLE foo (b BLOB, t TEXT, i INTEGER, f FLOAT, n)").unwrap();
        db
    }

    #[test]
    fn test_blob() {
        let db = checked_memory_handle();

        let v1234 = vec![1u8,2,3,4];
        db.execute("INSERT INTO foo(b) VALUES (?)", &[&v1234]).unwrap();

        let v: Vec<u8> = db.query_row("SELECT b FROM foo", &[], |r| r.get(0)).unwrap();
        assert_eq!(v, v1234);
    }

    #[test]
    fn test_str() {
        let db = checked_memory_handle();

        let s = "hello, world!";
        db.execute("INSERT INTO foo(t) VALUES (?)", &[&s.to_string()]).unwrap();

        let from: String = db.query_row("SELECT t FROM foo", &[], |r| r.get(0)).unwrap();
        assert_eq!(from, s);
    }

    #[test]
    fn test_timespec() {
        let db = checked_memory_handle();

        let ts = time::Timespec{sec: 10_000, nsec: 0 };
        db.execute("INSERT INTO foo(t) VALUES (?)", &[&ts]).unwrap();

        let from: time::Timespec = db.query_row("SELECT t FROM foo", &[], |r| r.get(0)).unwrap();
        assert_eq!(from, ts);
    }

    #[test]
    fn test_option() {
        let db = checked_memory_handle();

        let s = Some("hello, world!");
        let b = Some(vec![1u8,2,3,4]);

        db.execute("INSERT INTO foo(t) VALUES (?)", &[&s]).unwrap();
        db.execute("INSERT INTO foo(b) VALUES (?)", &[&b]).unwrap();

        let mut stmt = db.prepare("SELECT t, b FROM foo ORDER BY ROWID ASC").unwrap();
        let mut rows = stmt.query(&[]).unwrap();

        let row1 = rows.next().unwrap().unwrap();
        let s1: Option<String> = row1.get(0);
        let b1: Option<Vec<u8>> = row1.get(1);
        assert_eq!(s.unwrap(), s1.unwrap());
        assert!(b1.is_none());

        let row2 = rows.next().unwrap().unwrap();
        let s2: Option<String> = row2.get(0);
        let b2: Option<Vec<u8>> = row2.get(1);
        assert!(s2.is_none());
        assert_eq!(b, b2);
    }

    #[test]
    fn test_mismatched_types() {
        let db = checked_memory_handle();

        db.execute("INSERT INTO foo(b, t, i, f) VALUES (X'0102', 'text', 1, 1.5)", &[]).unwrap();

        let mut stmt = db.prepare("SELECT b, t, i, f, n FROM foo").unwrap();
        let mut rows = stmt.query(&[]).unwrap();

        let row = rows.next().unwrap().unwrap();

        // check the correct types come back as expected
        assert_eq!(vec![1,2], row.get_checked::<Vec<u8>>(0).unwrap());
        assert_eq!("text",    row.get_checked::<String>(1).unwrap());
        assert_eq!(1,         row.get_checked::<c_int>(2).unwrap());
        assert_eq!(1.5,       row.get_checked::<c_double>(3).unwrap());
        assert!(row.get_checked::<Option<c_int>>(4).unwrap().is_none());
        assert!(row.get_checked::<Option<c_double>>(4).unwrap().is_none());
        assert!(row.get_checked::<Option<String>>(4).unwrap().is_none());

        // check some invalid types

        // 0 is actually a blob (Vec<u8>)
        assert_eq!(row.get_checked::<c_int>(0).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<i64>(0).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<c_double>(0).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<String>(0).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<time::Timespec>(0).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Option<c_int>>(0).err().unwrap().code, ffi::SQLITE_MISMATCH);

        // 1 is actually a text (String)
        assert_eq!(row.get_checked::<c_int>(1).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<i64>(1).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<c_double>(1).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Vec<u8>>(1).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Option<c_int>>(1).err().unwrap().code, ffi::SQLITE_MISMATCH);

        // 2 is actually an integer
        assert_eq!(row.get_checked::<c_double>(2).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<String>(2).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Vec<u8>>(2).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<time::Timespec>(2).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Option<c_double>>(2).err().unwrap().code, ffi::SQLITE_MISMATCH);

        // 3 is actually a float (c_double)
        assert_eq!(row.get_checked::<c_int>(3).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<i64>(3).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<String>(3).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Vec<u8>>(3).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<time::Timespec>(3).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Option<c_int>>(3).err().unwrap().code, ffi::SQLITE_MISMATCH);

        // 4 is actually NULL
        assert_eq!(row.get_checked::<c_int>(4).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<i64>(4).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<c_double>(4).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<String>(4).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<Vec<u8>>(4).err().unwrap().code, ffi::SQLITE_MISMATCH);
        assert_eq!(row.get_checked::<time::Timespec>(4).err().unwrap().code, ffi::SQLITE_MISMATCH);
    }
}