use crate::{Dialect, Sql};
use nautilus_core::{BinaryOp, Delete, Expr, Insert, Result, Select, Update, Value};
#[derive(Debug, Clone, Copy)]
pub struct PostgresDialect;
impl Dialect for PostgresDialect {
fn render_select(&self, select: &Select) -> Result<Sql> {
let mut ctx = RenderContext::new();
render_select_body_core!(&mut ctx, select, quote_identifier, render_expr, true, false);
Ok(Sql {
text: ctx.sql,
params: ctx.params,
})
}
fn render_insert(&self, insert: &Insert) -> Result<Sql> {
let mut ctx = RenderContext::new();
render_insert_body!(&mut ctx, insert, quote_identifier, true, true);
Ok(Sql {
text: ctx.sql,
params: ctx.params,
})
}
fn render_update(&self, update: &Update) -> Result<Sql> {
let mut ctx = RenderContext::new();
render_update_body!(&mut ctx, update, quote_identifier, render_expr, true, true);
Ok(Sql {
text: ctx.sql,
params: ctx.params,
})
}
fn render_delete(&self, delete: &Delete) -> Result<Sql> {
let mut ctx = RenderContext::new();
render_delete_body!(&mut ctx, delete, quote_identifier, render_expr, true);
Ok(Sql {
text: ctx.sql,
params: ctx.params,
})
}
}
fn quote_identifier(name: &str) -> String {
crate::double_quote_identifier(name)
}
struct RenderContext {
sql: String,
params: Vec<Value>,
}
impl RenderContext {
fn new() -> Self {
Self {
sql: String::new(),
params: Vec::new(),
}
}
fn push_param(&mut self, value: Value) -> String {
self.params.push(value);
format!("${}", self.params.len())
}
}
fn render_select_body(ctx: &mut RenderContext, select: &crate::Select) {
render_select_body_core!(ctx, select, quote_identifier, render_expr, true, false);
}
fn render_expr(ctx: &mut RenderContext, expr: &Expr) {
render_expr_common!(ctx, expr, quote_identifier, render_expr, render_select_body, {
Expr::Param(value) => {
if matches!(value, Value::Null) {
ctx.sql.push_str("NULL");
} else {
let placeholder = ctx.push_param(value.clone());
ctx.sql.push_str(&placeholder);
if matches!(value, Value::Uuid(_)) {
ctx.sql.push_str("::uuid");
} else if matches!(value, Value::Json(_)) {
ctx.sql.push_str("::json");
} else if matches!(value, Value::Vector(_)) {
ctx.sql.push_str("::vector");
} else if matches!(value, Value::Geometry(_)) {
ctx.sql.push_str("::geometry");
} else if matches!(value, Value::Geography(_)) {
ctx.sql.push_str("::geography");
} else if is_homogeneous_geometry_array(value) {
ctx.sql.push_str("::geometry[]");
} else if is_homogeneous_geography_array(value) {
ctx.sql.push_str("::geography[]");
} else if let Value::Enum { type_name, .. } = value {
ctx.sql.push_str("::");
ctx.sql.push_str(type_name);
}
}
}
Expr::Binary { left, op, right } => {
if matches!(op, BinaryOp::In | BinaryOp::NotIn) {
ctx.sql.push('(');
render_expr(ctx, left);
ctx.sql.push(' ');
ctx.sql.push_str(if matches!(op, BinaryOp::In) { "IN" } else { "NOT IN" });
ctx.sql.push_str(" (");
if let Expr::List(exprs) = right.as_ref() {
for (i, e) in exprs.iter().enumerate() {
if i > 0 { ctx.sql.push_str(", "); }
render_expr(ctx, e);
}
} else {
render_expr(ctx, right);
}
ctx.sql.push(')');
ctx.sql.push(')');
} else {
ctx.sql.push('(');
render_expr(ctx, left);
ctx.sql.push(' ');
ctx.sql.push_str(match op {
BinaryOp::ArrayContains => "@>",
BinaryOp::ArrayContainedBy => "<@",
BinaryOp::ArrayOverlaps => "&&",
_ => crate::binary_op_sql(op),
});
ctx.sql.push(' ');
render_expr(ctx, right);
ctx.sql.push(')');
}
}
Expr::FunctionCall { name, args } => {
if args.len() == 2 {
let op = match name.as_str() {
nautilus_core::expr::VECTOR_L2_DISTANCE_FUNCTION => Some("<->"),
nautilus_core::expr::VECTOR_INNER_PRODUCT_FUNCTION => Some("<#>"),
nautilus_core::expr::VECTOR_COSINE_DISTANCE_FUNCTION => Some("<=>"),
_ => None,
};
if let Some(op) = op {
ctx.sql.push('(');
render_expr(ctx, &args[0]);
ctx.sql.push(' ');
ctx.sql.push_str(op);
ctx.sql.push(' ');
render_expr(ctx, &args[1]);
ctx.sql.push(')');
return;
}
}
ctx.sql.push_str(name);
ctx.sql.push('(');
for (i, arg) in args.iter().enumerate() {
if i > 0 { ctx.sql.push_str(", "); }
render_expr(ctx, arg);
}
ctx.sql.push(')');
}
Expr::Filter { expr, predicate } => {
render_expr(ctx, expr);
ctx.sql.push_str(" FILTER (WHERE ");
render_expr(ctx, predicate);
ctx.sql.push(')');
}
});
}
fn is_homogeneous_geometry_array(value: &Value) -> bool {
matches!(
value,
Value::Array(items) if !items.is_empty() && items.iter().all(|item| matches!(item, Value::Geometry(_)))
)
}
fn is_homogeneous_geography_array(value: &Value) -> bool {
matches!(
value,
Value::Array(items) if !items.is_empty() && items.iter().all(|item| matches!(item, Value::Geography(_)))
)
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_quote_identifier() {
assert_eq!(quote_identifier("users"), "\"users\"");
assert_eq!(quote_identifier("email"), "\"email\"");
assert_eq!(quote_identifier("foo\"bar"), "\"foo\"\"bar\"");
assert_eq!(quote_identifier("a\"b\"c"), "\"a\"\"b\"\"c\"");
}
#[test]
fn test_array_contains_operator() {
let dialect = PostgresDialect;
let expr = Expr::Binary {
left: Box::new(Expr::column("posts__tags")),
op: BinaryOp::ArrayContains,
right: Box::new(Expr::param(Value::Array(vec![Value::String(
"rust".to_string(),
)]))),
};
let select = Select::from_table("posts").filter(expr).build().unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"posts\" WHERE (\"posts\".\"tags\" @> $1)"
);
assert_eq!(sql.params.len(), 1);
match &sql.params[0] {
Value::Array(arr) => {
assert_eq!(arr.len(), 1);
assert_eq!(arr[0], Value::String("rust".to_string()));
}
_ => panic!("Expected Array value"),
}
}
#[test]
fn test_array_contained_by_operator() {
let dialect = PostgresDialect;
let expr = Expr::Binary {
left: Box::new(Expr::column("posts__tags")),
op: BinaryOp::ArrayContainedBy,
right: Box::new(Expr::param(Value::Array(vec![
Value::String("rust".to_string()),
Value::String("go".to_string()),
]))),
};
let select = Select::from_table("posts").filter(expr).build().unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"posts\" WHERE (\"posts\".\"tags\" <@ $1)"
);
assert_eq!(sql.params.len(), 1);
match &sql.params[0] {
Value::Array(arr) => {
assert_eq!(arr.len(), 2);
assert_eq!(arr[0], Value::String("rust".to_string()));
assert_eq!(arr[1], Value::String("go".to_string()));
}
_ => panic!("Expected Array value"),
}
}
#[test]
fn test_array_overlaps_operator() {
let dialect = PostgresDialect;
let expr = Expr::Binary {
left: Box::new(Expr::column("posts__tags")),
op: BinaryOp::ArrayOverlaps,
right: Box::new(Expr::param(Value::Array(vec![
Value::String("rust".to_string()),
Value::String("python".to_string()),
]))),
};
let select = Select::from_table("posts").filter(expr).build().unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"posts\" WHERE (\"posts\".\"tags\" && $1)"
);
assert_eq!(sql.params.len(), 1);
match &sql.params[0] {
Value::Array(arr) => {
assert_eq!(arr.len(), 2);
assert_eq!(arr[0], Value::String("rust".to_string()));
assert_eq!(arr[1], Value::String("python".to_string()));
}
_ => panic!("Expected Array value"),
}
}
#[test]
fn test_array_operators_with_integers() {
let dialect = PostgresDialect;
let expr = Expr::Binary {
left: Box::new(Expr::column("posts__scores")),
op: BinaryOp::ArrayContains,
right: Box::new(Expr::param(Value::Array(vec![
Value::I32(100),
Value::I32(200),
]))),
};
let select = Select::from_table("posts").filter(expr).build().unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"posts\" WHERE (\"posts\".\"scores\" @> $1)"
);
assert_eq!(sql.params.len(), 1);
match &sql.params[0] {
Value::Array(arr) => {
assert_eq!(arr.len(), 2);
assert_eq!(arr[0], Value::I32(100));
assert_eq!(arr[1], Value::I32(200));
}
_ => panic!("Expected Array value"),
}
}
#[test]
fn vector_params_are_cast_to_pgvector_type() {
let dialect = PostgresDialect;
let select = Select::from_table("embeddings")
.filter(
Expr::column("embeddings__vector")
.eq(Expr::param(Value::Vector(vec![1.0, 2.0, 3.0]))),
)
.build()
.unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"embeddings\" WHERE (\"embeddings\".\"vector\" = $1::vector)"
);
assert_eq!(sql.params, vec![Value::Vector(vec![1.0, 2.0, 3.0])]);
}
#[test]
fn postgis_params_are_cast_to_spatial_types() {
let dialect = PostgresDialect;
let select = Select::from_table("places")
.filter(
Expr::column("places__geom")
.eq(Expr::param(Value::Geometry("POINT(1 2)".to_string()))),
)
.build()
.unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"places\" WHERE (\"places\".\"geom\" = $1::geometry)"
);
assert_eq!(sql.params, vec![Value::Geometry("POINT(1 2)".to_string())]);
let select = Select::from_table("places")
.filter(
Expr::column("places__geog")
.eq(Expr::param(Value::Geography("POINT(1 2)".to_string()))),
)
.build()
.unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"places\" WHERE (\"places\".\"geog\" = $1::geography)"
);
assert_eq!(sql.params, vec![Value::Geography("POINT(1 2)".to_string())]);
}
#[test]
fn vector_distance_ordering_uses_pgvector_operator() {
let dialect = PostgresDialect;
let select = Select::from_table("embeddings")
.order_by_expr(
Expr::vector_distance(
nautilus_core::VectorMetric::Cosine,
Expr::column("embeddings__vector"),
Expr::param(Value::Vector(vec![1.0, 2.0, 3.0])),
),
nautilus_core::OrderDir::Asc,
)
.take(5)
.build()
.unwrap();
let sql = dialect.render_select(&select).unwrap();
assert_eq!(
sql.text,
"SELECT * FROM \"embeddings\" ORDER BY (\"embeddings\".\"vector\" <=> $1::vector) ASC LIMIT 5"
);
assert_eq!(sql.params, vec![Value::Vector(vec![1.0, 2.0, 3.0])]);
}
}