clippy again

nac3core/src/expression_inference.rs

@@ -111,12 +111,12 @@ fn infer_tuple<'b: 'a, 'a>(ctx: &mut InferenceContext<'a>, elements: &'b [Expres
     }
 }
 
-fn infer_attribute<'b: 'a, 'a>(
+fn infer_attribute<'a>(
     ctx: &mut InferenceContext<'a>,
     value: &'a Expression,
-    name: &String,
+    name: &str,
 ) -> ParserResult {
-    let value = infer_expr(ctx, value)?.ok_or("no value".to_string())?;
+    let value = infer_expr(ctx, value)?.ok_or_else(|| "no value".to_string())?;
     if let TypeVariable(id) = value.as_ref() {
         let v = ctx.get_variable_def(*id);
         if v.bound.is_empty() {
@@ -124,12 +124,12 @@ fn infer_attribute<'b: 'a, 'a>(
         }
         let ty = v.bound[0]
             .get_base(ctx)
-            .and_then(|v| v.fields.get(name.as_str()));
+            .and_then(|v| v.fields.get(name));
         if ty.is_none() {
             return Err("unknown field".into());
         }
         for x in v.bound[1..].iter() {
-            let ty1 = x.get_base(ctx).and_then(|v| v.fields.get(name.as_str()));
+            let ty1 = x.get_base(ctx).and_then(|v| v.fields.get(name));
             if ty1 != ty {
                 return Err("unknown field (type mismatch between variants)".into());
             }
@@ -138,7 +138,7 @@ fn infer_attribute<'b: 'a, 'a>(
     }
 
     match value.get_base(ctx) {
-        Some(b) => match b.fields.get(name.as_str()) {
+        Some(b) => match b.fields.get(name) {
             Some(t) => Ok(Some(t.clone())),
             None => Err("no such field".into()),
         },
@@ -146,13 +146,13 @@ fn infer_attribute<'b: 'a, 'a>(
     }
 }
 
-fn infer_bool_ops<'b: 'a, 'a>(
+fn infer_bool_ops<'a>(
     ctx: &mut InferenceContext<'a>,
     values: &'a [Expression],
 ) -> ParserResult {
     assert_eq!(values.len(), 2);
-    let left = infer_expr(ctx, &values[0])?.ok_or("no value".to_string())?;
+    let left = infer_expr(ctx, &values[0])?.ok_or_else(|| "no value".to_string())?;
-    let right = infer_expr(ctx, &values[1])?.ok_or("no value".to_string())?;
+    let right = infer_expr(ctx, &values[1])?.ok_or_else(|| "no value".to_string())?;
 
     let b = ctx.get_primitive(BOOL_TYPE);
     if left == b && right == b {
@@ -168,8 +168,8 @@ fn infer_bin_ops<'b: 'a, 'a>(
     left: &'b Expression,
     right: &'b Expression,
 ) -> ParserResult {
-    let left = infer_expr(ctx, left)?.ok_or("no value".to_string())?;
+    let left = infer_expr(ctx, left)?.ok_or_else(|| "no value".to_string())?;
-    let right = infer_expr(ctx, right)?.ok_or("no value".to_string())?;
+    let right = infer_expr(ctx, right)?.ok_or_else(|| "no value".to_string())?;
     let fun = binop_name(op);
     resolve_call(ctx, Some(left), fun, &[right])
 }
@@ -179,7 +179,7 @@ fn infer_unary_ops<'b: 'a, 'a>(
     op: &UnaryOperator,
     obj: &'b Expression,
 ) -> ParserResult {
-    let ty = infer_expr(ctx, obj)?.ok_or("no value".to_string())?;
+    let ty = infer_expr(ctx, obj)?.ok_or_else(|| "no value".to_string())?;
     if let UnaryOperator::Not = op {
         if ty == ctx.get_primitive(BOOL_TYPE) {
             Ok(Some(ty))
@@ -208,7 +208,7 @@ fn infer_compare<'b: 'a, 'a>(
     let right = &types[1..];
 
     for ((a, b), op) in left.iter().zip(right.iter()).zip(ops.iter()) {
-        let fun = comparison_name(op).ok_or("unsupported comparison".to_string())?;
+        let fun = comparison_name(op).ok_or_else(|| "unsupported comparison".to_string())?;
         let ty = resolve_call(ctx, Some(a.clone()), fun, &[b.clone()])?;
         if ty.is_none() || ty.unwrap() != boolean {
             return Err("comparison result must be boolean".into());
@@ -232,7 +232,7 @@ fn infer_call<'b: 'a, 'a>(
     let (obj, fun) = match &function.node {
         ExpressionType::Identifier { name } => (None, name),
         ExpressionType::Attribute { value, name } => (
-            Some(infer_expr(ctx, &value)?.ok_or("no value".to_string())?),
+            Some(infer_expr(ctx, &value)?.ok_or_else(|| "no value".to_string())?),
             name,
         ),
         _ => return Err("not supported".into()),
@@ -245,7 +245,7 @@ fn infer_subscript<'b: 'a, 'a>(
     a: &'b Expression,
     b: &'b Expression,
 ) -> ParserResult {
-    let a = infer_expr(ctx, a)?.ok_or("no value".to_string())?;
+    let a = infer_expr(ctx, a)?.ok_or_else(|| "no value".to_string())?;
     let t = if let ParametricType(LIST_TYPE, ls) = a.as_ref() {
         ls[0].clone()
     } else {
@@ -265,7 +265,7 @@ fn infer_subscript<'b: 'a, 'a>(
                     }
                 })
                 .collect();
-            let types = types?.ok_or("slice must have type".to_string())?;
+            let types = types?.ok_or_else(|| "slice must have type".to_string())?;
             if types.iter().all(|v| v == &int32) {
                 Ok(Some(a))
             } else {
@@ -273,7 +273,7 @@ fn infer_subscript<'b: 'a, 'a>(
             }
         }
         _ => {
-            let b = infer_expr(ctx, b)?.ok_or("no value".to_string())?;
+            let b = infer_expr(ctx, b)?.ok_or_else(|| "no value".to_string())?;
             if b == ctx.get_primitive(INT32_TYPE) {
                 Ok(Some(t))
             } else {
@@ -289,7 +289,7 @@ fn infer_if_expr<'b: 'a, 'a>(
     body: &'b Expression,
     orelse: &'b Expression,
 ) -> ParserResult {
-    let test = infer_expr(ctx, test)?.ok_or("no value".to_string())?;
+    let test = infer_expr(ctx, test)?.ok_or_else(|| "no value".to_string())?;
     if test != ctx.get_primitive(BOOL_TYPE) {
         return Err("test should be bool".into());
     }
@@ -346,7 +346,7 @@ fn infer_list_comprehension<'b: 'a, 'a>(
         return Err("async is not supported".into());
     }
 
-    let iter = infer_expr(ctx, &comprehension.iter)?.ok_or("no value".to_string())?;
+    let iter = infer_expr(ctx, &comprehension.iter)?.ok_or_else(|| "no value".to_string())?;
     if let ParametricType(LIST_TYPE, ls) = iter.as_ref() {
         ctx.with_scope(|ctx| {
             infer_simple_binding(ctx, &comprehension.target, ls[0].clone())?;
@@ -354,12 +354,12 @@ fn infer_list_comprehension<'b: 'a, 'a>(
             let boolean = ctx.get_primitive(BOOL_TYPE);
             for test in comprehension.ifs.iter() {
                 let result =
-                    infer_expr(ctx, test)?.ok_or("no value in test".to_string())?;
+                    infer_expr(ctx, test)?.ok_or_else(|| "no value in test".to_string())?;
                 if result != boolean {
                     return Err("test must be bool".into());
                 }
             }
-            let result = infer_expr(ctx, element)?.ok_or("no value")?;
+            let result = infer_expr(ctx, element)?.ok_or_else(|| "no value")?;
             Ok(Some(ParametricType(LIST_TYPE, vec![result]).into()))
         }).1
     } else {