params.rs - mozsearch

use crate::{Result, Statement, ToSql};

mod sealed {

    /// This trait exists just to ensure that the only impls of `trait Params`

    /// that are allowed are ones in this crate.

    pub trait Sealed {}

use sealed::Sealed;

/// Trait used for [sets of parameter][params] passed into SQL

/// statements/queries.

///

/// [params]: https://www.sqlite.org/c3ref/bind_blob.html

///

/// Note: Currently, this trait can only be implemented inside this crate.

/// Additionally, it's methods (which are `doc(hidden)`) should currently not be

/// considered part of the stable API, although it's possible they will

/// stabilize in the future.

///

/// # Passing parameters to SQLite

///

/// Many functions in this library let you pass parameters to SQLite. Doing this

/// lets you avoid any risk of SQL injection, and is simpler than escaping

/// things manually. Aside from deprecated functions and a few helpers, this is

/// indicated by the function taking a generic argument that implements `Params`

/// (this trait).

///

/// ## Positional parameters

///

/// For cases where you want to pass a list of parameters where the number of

/// parameters is known at compile time, this can be done in one of the

/// following ways:

///

/// - For small lists of parameters up to 16 items, they may alternatively be

///   passed as a tuple, as in `thing.query((1, "foo"))`.

///

///     This is somewhat inconvenient for a single item, since you need a

///     weird-looking trailing comma: `thing.query(("example",))`. That case is

///     perhaps more cleanly expressed as `thing.query(["example"])`.

///

/// - Using the [`rusqlite::params!`](crate::params!) macro, e.g.

///   `thing.query(rusqlite::params![1, "foo", bar])`. This is mostly useful for

///   heterogeneous lists where the number of parameters greater than 16, or

///   homogenous lists of parameters where the number of parameters exceeds 32.

///

/// - For small homogeneous lists of parameters, they can either be passed as:

///

///     - an array, as in `thing.query([1i32, 2, 3, 4])` or `thing.query(["foo",

///       "bar", "baz"])`.

///

///     - a reference to an array of references, as in `thing.query(&["foo",

///       "bar", "baz"])` or `thing.query(&[&1i32, &2, &3])`.

///

///         (Note: in this case we don't implement this for slices for coherence

///         reasons, so it really is only for the "reference to array" types —

///         hence why the number of parameters must be <= 32 or you need to

///         reach for `rusqlite::params!`)

///

///     Unfortunately, in the current design it's not possible to allow this for

///     references to arrays of non-references (e.g. `&[1i32, 2, 3]`). Code like

///     this should instead either use `params!`, an array literal, a `&[&dyn

///     ToSql]` or if none of those work, [`ParamsFromIter`].

///

/// - As a slice of `ToSql` trait object references, e.g. `&[&dyn ToSql]`. This

///   is mostly useful for passing parameter lists around as arguments without

///   having every function take a generic `P: Params`.

///

/// ### Example (positional)

///

/// ```rust,no_run

/// # use rusqlite::{Connection, Result, params};

/// fn update_rows(conn: &Connection) -> Result<()> {

///     let mut stmt = conn.prepare("INSERT INTO test (a, b) VALUES (?1, ?2)")?;

///

///     // Using a tuple:

///     stmt.execute((0, "foobar"))?;

///

///     // Using `rusqlite::params!`:

///     stmt.execute(params![1i32, "blah"])?;

///

///     // array literal — non-references

///     stmt.execute([2i32, 3i32])?;

///

///     // array literal — references

///     stmt.execute(["foo", "bar"])?;

///

///     // Slice literal, references:

///     stmt.execute(&[&2i32, &3i32])?;

///

///     // Note: The types behind the references don't have to be `Sized`

///     stmt.execute(&["foo", "bar"])?;

///

///     // However, this doesn't work (see above):

///     // stmt.execute(&[1i32, 2i32])?;

///     Ok(())

/// }

/// ```

///

/// ## Named parameters

///

/// SQLite lets you name parameters using a number of conventions (":foo",

/// "@foo", "$foo"). You can pass named parameters in to SQLite using rusqlite

/// in a few ways:

///

/// - Using the [`rusqlite::named_params!`](crate::named_params!) macro, as in

///   `stmt.execute(named_params!{ ":name": "foo", ":age": 99 })`. Similar to

///   the `params` macro, this is most useful for heterogeneous lists of

///   parameters, or lists where the number of parameters exceeds 32.

///

/// - As a slice of `&[(&str, &dyn ToSql)]`. This is what essentially all of

///   these boil down to in the end, conceptually at least. In theory you can

///   pass this as `stmt`.

///

/// - As array references, similar to the positional params. This looks like

///   `thing.query(&[(":foo", &1i32), (":bar", &2i32)])` or

///   `thing.query(&[(":foo", "abc"), (":bar", "def")])`.

///

/// Note: Unbound named parameters will be left to the value they previously

/// were bound with, falling back to `NULL` for parameters which have never been

/// bound.

///

/// ### Example (named)

///

/// ```rust,no_run

/// # use rusqlite::{Connection, Result, named_params};

/// fn insert(conn: &Connection) -> Result<()> {

///     let mut stmt = conn.prepare("INSERT INTO test (key, value) VALUES (:key, :value)")?;

///     // Using `rusqlite::params!`:

///     stmt.execute(named_params! { ":key": "one", ":val": 2 })?;

///     // Alternatively:

///     stmt.execute(&[(":key", "three"), (":val", "four")])?;

///     // Or:

///     stmt.execute(&[(":key", &100), (":val", &200)])?;

///     Ok(())

/// }

/// ```

///

/// ## No parameters

///

/// You can just use an empty tuple or the empty array literal to run a query

/// that accepts no parameters.

///

/// ### Example (no parameters)

///

/// The empty tuple:

///

/// ```rust,no_run

/// # use rusqlite::{Connection, Result, params};

/// fn delete_all_users(conn: &Connection) -> Result<()> {

///     // You may also use `()`.

///     conn.execute("DELETE FROM users", ())?;

///     Ok(())

/// }

/// ```

///

/// The empty array:

///

/// ```rust,no_run

/// # use rusqlite::{Connection, Result, params};

/// fn delete_all_users(conn: &Connection) -> Result<()> {

///     // Just use an empty array (e.g. `[]`) for no params.

///     conn.execute("DELETE FROM users", [])?;

///     Ok(())

/// }

/// ```

///

/// ## Dynamic parameter list

///

/// If you have a number of parameters which is unknown at compile time (for

/// example, building a dynamic query at runtime), you have two choices:

///

/// - Use a `&[&dyn ToSql]`. This is often annoying to construct if you don't

///   already have this type on-hand.

/// - Use the [`ParamsFromIter`] type. This essentially lets you wrap an

///   iterator some `T: ToSql` with something that implements `Params`. The

///   usage of this looks like `rusqlite::params_from_iter(something)`.

///

/// A lot of the considerations here are similar either way, so you should see

/// the [`ParamsFromIter`] documentation for more info / examples.

pub trait Params: Sealed {

    // XXX not public api, might not need to expose.

//

    // Binds the parameters to the statement. It is unlikely calling this

    // explicitly will do what you want. Please use `Statement::query` or

    // similar directly.

//

    // For now, just hide the function in the docs...

    #[doc(hidden)]

    fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()>;

// Explicitly impl for empty array. Critically, for `conn.execute([])` to be

// unambiguous, this must be the *only* implementation for an empty array.

//

// This sadly prevents `impl<T: ToSql, const N: usize> Params for [T; N]`, which

// forces people to use `params![...]` or `rusqlite::params_from_iter` for long

// homogenous lists of parameters. This is not that big of a deal, but is

// unfortunate, especially because I mostly did it because I wanted a simple

// syntax for no-params that didnt require importing -- the empty tuple fits

// that nicely, but I didn't think of it until much later.

//

// Admittedly, if we did have the generic impl, then we *wouldn't* support the

// empty array literal as a parameter, since the `T` there would fail to be

// inferred. The error message here would probably be quite bad, and so on

// further thought, probably would end up causing *more* surprises, not less.

impl Sealed for [&(dyn ToSql + Send + Sync); 0] {}

impl Params for [&(dyn ToSql + Send + Sync); 0] {

    #[inline]

    fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

        stmt.ensure_parameter_count(0)

impl Sealed for &[&dyn ToSql] {}

impl Params for &[&dyn ToSql] {

    #[inline]

    fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

        stmt.bind_parameters(self)

impl Sealed for &[(&str, &dyn ToSql)] {}

impl Params for &[(&str, &dyn ToSql)] {

    #[inline]

    fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

        stmt.bind_parameters_named(self)

// Manual impls for the empty and singleton tuple, although the rest are covered

// by macros.

impl Sealed for () {}

impl Params for () {

    #[inline]

    fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

        stmt.ensure_parameter_count(0)

// I'm pretty sure you could tweak the `single_tuple_impl` to accept this.

impl<T: ToSql> Sealed for (T,) {}

impl<T: ToSql> Params for (T,) {

    #[inline]

    fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

        stmt.ensure_parameter_count(1)?;

        stmt.raw_bind_parameter(1, self.0)?;

        Ok(())

macro_rules! single_tuple_impl {

    ($count:literal : $(($field:tt $ftype:ident)),* $(,)?) => {

        impl<$($ftype,)*> Sealed for ($($ftype,)*) where $($ftype: ToSql,)* {}

        impl<$($ftype,)*> Params for ($($ftype,)*) where $($ftype: ToSql,)* {

            fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

                stmt.ensure_parameter_count($count)?;

$({

                    debug_assert!($field < $count);

                    stmt.raw_bind_parameter($field + 1, self.$field)?;

})+

                Ok(())

// We use a the macro for the rest, but don't bother with trying to implement it

// in a single invocation (it's possible to do, but my attempts were almost the

// same amount of code as just writing it out this way, and much more dense --

// it is a more complicated case than the TryFrom macro we have for row->tuple).

//

// Note that going up to 16 (rather than the 12 that the impls in the stdlib

// usually support) is just because we did the same in the `TryFrom<Row>` impl.

// I didn't catch that then, but there's no reason to remove it, and it seems

// nice to be consistent here; this way putting data in the database and getting

// data out of the database are more symmetric in a (mostly superficial) sense.

single_tuple_impl!(2: (0 A), (1 B));

single_tuple_impl!(3: (0 A), (1 B), (2 C));

single_tuple_impl!(4: (0 A), (1 B), (2 C), (3 D));

single_tuple_impl!(5: (0 A), (1 B), (2 C), (3 D), (4 E));

single_tuple_impl!(6: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F));

single_tuple_impl!(7: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G));

single_tuple_impl!(8: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H));

single_tuple_impl!(9: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I));

single_tuple_impl!(10: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I), (9 J));

single_tuple_impl!(11: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I), (9 J), (10 K));

single_tuple_impl!(12: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I), (9 J), (10 K), (11 L));

single_tuple_impl!(13: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I), (9 J), (10 K), (11 L), (12 M));

single_tuple_impl!(14: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I), (9 J), (10 K), (11 L), (12 M), (13 N));

single_tuple_impl!(15: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I), (9 J), (10 K), (11 L), (12 M), (13 N), (14 O));

single_tuple_impl!(16: (0 A), (1 B), (2 C), (3 D), (4 E), (5 F), (6 G), (7 H), (8 I), (9 J), (10 K), (11 L), (12 M), (13 N), (14 O), (15 P));

macro_rules! impl_for_array_ref {

    ($($N:literal)+) => {$(

        // These are already generic, and there's a shedload of them, so lets

        // avoid the compile time hit from making them all inline for now.

        impl<T: ToSql + ?Sized> Sealed for &[&T; $N] {}

        impl<T: ToSql + ?Sized> Params for &[&T; $N] {

            fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

                stmt.bind_parameters(self)

        impl<T: ToSql + ?Sized> Sealed for &[(&str, &T); $N] {}

        impl<T: ToSql + ?Sized> Params for &[(&str, &T); $N] {

            fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

                stmt.bind_parameters_named(self)

        impl<T: ToSql> Sealed for [T; $N] {}

        impl<T: ToSql> Params for [T; $N] {

            #[inline]

            fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

                stmt.bind_parameters(&self)

    )+};

// Following libstd/libcore's (old) lead, implement this for arrays up to `[_;

// 32]`. Note `[_; 0]` is intentionally omitted for coherence reasons, see the

// note above the impl of `[&dyn ToSql; 0]` for more information.

//

// Note that this unfortunately means we can't use const generics here, but I

// don't really think it matters -- users who hit that can use `params!` anyway.

impl_for_array_ref!(

    1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17

    18 19 20 21 22 23 24 25 26 27 28 29 30 31 32

);

/// Adapter type which allows any iterator over [`ToSql`] values to implement

/// [`Params`].

///

/// This struct is created by the [`params_from_iter`] function.

///

/// This can be useful if you have something like an `&[String]` (of unknown

/// length), and you want to use them with an API that wants something

/// implementing `Params`. This way, you can avoid having to allocate storage

/// for something like a `&[&dyn ToSql]`.

///

/// This essentially is only ever actually needed when dynamically generating

/// SQL — static SQL (by definition) has the number of parameters known

/// statically. As dynamically generating SQL is itself pretty advanced, this

/// API is itself for advanced use cases (See "Realistic use case" in the

/// examples).

///

/// # Example

///

/// ## Basic usage

///

/// ```rust,no_run

/// use rusqlite::{params_from_iter, Connection, Result};

/// use std::collections::BTreeSet;

///

/// fn query(conn: &Connection, ids: &BTreeSet<String>) -> Result<()> {

///     assert_eq!(ids.len(), 3, "Unrealistic sample code");

///

///     let mut stmt = conn.prepare("SELECT * FROM users WHERE id IN (?1, ?2, ?3)")?;

///     let _rows = stmt.query(params_from_iter(ids.iter()))?;

///

///     // use _rows...

///     Ok(())

/// }

/// ```

///

/// ## Realistic use case

///

/// Here's how you'd use `ParamsFromIter` to call [`Statement::exists`] with a

/// dynamic number of parameters.

///

/// ```rust,no_run

/// use rusqlite::{Connection, Result};

///

/// pub fn any_active_users(conn: &Connection, usernames: &[String]) -> Result<bool> {

///     if usernames.is_empty() {

///         return Ok(false);

///     }

///

///     // Note: `repeat_vars` never returns anything attacker-controlled, so

///     // it's fine to use it in a dynamically-built SQL string.

///     let vars = repeat_vars(usernames.len());

///

///     let sql = format!(

///         // In practice this would probably be better as an `EXISTS` query.

///         "SELECT 1 FROM user WHERE is_active AND name IN ({}) LIMIT 1",

///         vars,

///     );

///     let mut stmt = conn.prepare(&sql)?;

///     stmt.exists(rusqlite::params_from_iter(usernames))

/// }

///

/// // Helper function to return a comma-separated sequence of `?`.

/// // - `repeat_vars(0) => panic!(...)`

/// // - `repeat_vars(1) => "?"`

/// // - `repeat_vars(2) => "?,?"`

/// // - `repeat_vars(3) => "?,?,?"`

/// // - ...

/// fn repeat_vars(count: usize) -> String {

///     assert_ne!(count, 0);

///     let mut s = "?,".repeat(count);

///     // Remove trailing comma

///     s.pop();

///     s

/// }

/// ```

///

/// That is fairly complex, and even so would need even more work to be fully

/// production-ready:

///

/// - production code should ensure `usernames` isn't so large that it will

///   surpass [`conn.limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER)`][limits]),

///   chunking if too large. (Note that the limits api requires rusqlite to have

///   the "limits" feature).

///

/// - `repeat_vars` can be implemented in a way that avoids needing to allocate

///   a String.

///

/// - Etc...

///

/// [limits]: crate::Connection::limit

///

/// This complexity reflects the fact that `ParamsFromIter` is mainly intended

/// for advanced use cases — most of the time you should know how many

/// parameters you have statically (and if you don't, you're either doing

/// something tricky, or should take a moment to think about the design).

#[derive(Clone, Debug)]

pub struct ParamsFromIter<I>(I);

/// Constructor function for a [`ParamsFromIter`]. See its documentation for

/// more.

#[inline]

pub fn params_from_iter<I>(iter: I) -> ParamsFromIter<I>

where

    I: IntoIterator,

    I::Item: ToSql,

    ParamsFromIter(iter)

impl<I> Sealed for ParamsFromIter<I>

where

    I: IntoIterator,

    I::Item: ToSql,

impl<I> Params for ParamsFromIter<I>

where

    I: IntoIterator,

    I::Item: ToSql,

    #[inline]

    fn __bind_in(self, stmt: &mut Statement<'_>) -> Result<()> {

        stmt.bind_parameters(self.0)

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