CSY/reowolf Changeset - 68a065935a85 · Centrum Wiskunde & Informatica (CWI)

Changeset - 68a065935a85

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0 12 0

MH - 4 years ago 2021-05-21 20:33:08
contact@maxhenger.nl

prepare for casting expressions

12 files changed with 172 insertions and 47 deletions:

src/protocol/ast.rs

src/protocol/ast_printer.rs

src/protocol/eval/executor.rs

src/protocol/parser/depth_visitor.rs

src/protocol/parser/pass_definitions.rs

src/protocol/parser/pass_typing.rs

src/protocol/parser/pass_validation_linking.rs

src/protocol/parser/token_parsing.rs

src/protocol/parser/visitor.rs

src/protocol/tests/eval_silly.rs

src/protocol/tests/parser_inference.rs

src/protocol/tests/utils.rs

0 comments (0 inline, 0 general)

src/protocol/ast.rs

➞

Show inline comments

@@ @@ -133,48 +133,49 @@ define_new_ast_id!(ChannelStatementId, LocalStatementId); @@
 define_new_ast_id!(LabeledStatementId, StatementId, index(LabeledStatement, Statement::Labeled, statements), alloc(alloc_labeled_statement));
 define_new_ast_id!(IfStatementId, StatementId, index(IfStatement, Statement::If, statements), alloc(alloc_if_statement));
 define_new_ast_id!(EndIfStatementId, StatementId, index(EndIfStatement, Statement::EndIf, statements), alloc(alloc_end_if_statement));
 define_new_ast_id!(WhileStatementId, StatementId, index(WhileStatement, Statement::While, statements), alloc(alloc_while_statement));
 define_new_ast_id!(EndWhileStatementId, StatementId, index(EndWhileStatement, Statement::EndWhile, statements), alloc(alloc_end_while_statement));
 define_new_ast_id!(BreakStatementId, StatementId, index(BreakStatement, Statement::Break, statements), alloc(alloc_break_statement));
 define_new_ast_id!(ContinueStatementId, StatementId, index(ContinueStatement, Statement::Continue, statements), alloc(alloc_continue_statement));
 define_new_ast_id!(SynchronousStatementId, StatementId, index(SynchronousStatement, Statement::Synchronous, statements), alloc(alloc_synchronous_statement));
 define_new_ast_id!(EndSynchronousStatementId, StatementId, index(EndSynchronousStatement, Statement::EndSynchronous, statements), alloc(alloc_end_synchronous_statement));
 define_new_ast_id!(ReturnStatementId, StatementId, index(ReturnStatement, Statement::Return, statements), alloc(alloc_return_statement));
 define_new_ast_id!(GotoStatementId, StatementId, index(GotoStatement, Statement::Goto, statements), alloc(alloc_goto_statement));
 define_new_ast_id!(NewStatementId, StatementId, index(NewStatement, Statement::New, statements), alloc(alloc_new_statement));
 define_new_ast_id!(ExpressionStatementId, StatementId, index(ExpressionStatement, Statement::Expression, statements), alloc(alloc_expression_statement));
 define_aliased_ast_id!(ExpressionId, Id<Expression>, index(Expression, expressions));
 define_new_ast_id!(AssignmentExpressionId, ExpressionId, index(AssignmentExpression, Expression::Assignment, expressions), alloc(alloc_assignment_expression));
 define_new_ast_id!(BindingExpressionId, ExpressionId, index(BindingExpression, Expression::Binding, expressions), alloc(alloc_binding_expression));
 define_new_ast_id!(ConditionalExpressionId, ExpressionId, index(ConditionalExpression, Expression::Conditional, expressions), alloc(alloc_conditional_expression));
 define_new_ast_id!(BinaryExpressionId, ExpressionId, index(BinaryExpression, Expression::Binary, expressions), alloc(alloc_binary_expression));
 define_new_ast_id!(UnaryExpressionId, ExpressionId, index(UnaryExpression, Expression::Unary, expressions), alloc(alloc_unary_expression));
 define_new_ast_id!(IndexingExpressionId, ExpressionId, index(IndexingExpression, Expression::Indexing, expressions), alloc(alloc_indexing_expression));
 define_new_ast_id!(SlicingExpressionId, ExpressionId, index(SlicingExpression, Expression::Slicing, expressions), alloc(alloc_slicing_expression));
 define_new_ast_id!(SelectExpressionId, ExpressionId, index(SelectExpression, Expression::Select, expressions), alloc(alloc_select_expression));
 define_new_ast_id!(LiteralExpressionId, ExpressionId, index(LiteralExpression, Expression::Literal, expressions), alloc(alloc_literal_expression));
 define_new_ast_id!(CastExpressionId, ExpressionId, index(CastExpression, Expression::Cast, expressions), alloc(alloc_cast_expression));
 define_new_ast_id!(CallExpressionId, ExpressionId, index(CallExpression, Expression::Call, expressions), alloc(alloc_call_expression));
 define_new_ast_id!(VariableExpressionId, ExpressionId, index(VariableExpression, Expression::Variable, expressions), alloc(alloc_variable_expression));
 // TODO: @cleanup - pub qualifiers can be removed once done
 #[derive(Debug)]
 pub struct Heap {
     // Root arena, contains the entry point for different modules. Each root
     // contains lists of IDs that correspond to the other arenas.
     pub(crate) protocol_descriptions: Arena<Root>,
     // Contents of a file, these are the elements the `Root` elements refer to
     pragmas: Arena<Pragma>,
     pub(crate) imports: Arena<Import>,
     pub(crate) parser_types: Arena<ParserType>,
     pub(crate) variables: Arena<Variable>,
     pub(crate) definitions: Arena<Definition>,
     pub(crate) statements: Arena<Statement>,
     pub(crate) expressions: Arena<Expression>,
+}
 impl Heap {
     pub fn new() -> Heap {
         Heap {
             // string_alloc: StringAllocator::new(),
             protocol_descriptions: Arena::new(),
@@ @@ -1383,48 +1384,49 @@ pub enum ExpressionParent { @@
     ExpressionStmt(ExpressionStatementId),
     Expression(ExpressionId, u32) // index within expression (e.g LHS or RHS of expression)
+}
 impl ExpressionParent {
     pub fn is_new(&self) -> bool {
         match self {
             ExpressionParent::New(_) => true,
             _ => false,
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub enum Expression {
     Assignment(AssignmentExpression),
     Binding(BindingExpression),
     Conditional(ConditionalExpression),
     Binary(BinaryExpression),
     Unary(UnaryExpression),
     Indexing(IndexingExpression),
     Slicing(SlicingExpression),
     Select(SelectExpression),
     Literal(LiteralExpression),
     Cast(CastExpression),
     Call(CallExpression),
     Variable(VariableExpression),
+}
 impl Expression {
     pub fn as_assignment(&self) -> &AssignmentExpression {
         match self {
             Expression::Assignment(result) => result,
             _ => panic!("Unable to cast `Expression` to `AssignmentExpression`"),
+        }
+    }
     pub fn as_conditional(&self) -> &ConditionalExpression {
         match self {
             Expression::Conditional(result) => result,
             _ => panic!("Unable to cast `Expression` to `ConditionalExpression`"),
+        }
+    }
     pub fn as_binary(&self) -> &BinaryExpression {
         match self {
             Expression::Binary(result) => result,
             _ => panic!("Unable to cast `Expression` to `BinaryExpression`"),
+        }
+    }
     pub fn as_unary(&self) -> &UnaryExpression {
@@ @@ -1465,104 +1467,108 @@ impl Expression { @@
+    }
     pub fn as_variable(&self) -> &VariableExpression {
         match self {
             Expression::Variable(result) => result,
             _ => panic!("Unable to cast `Expression` to `VariableExpression`"),
+        }
+    }
     pub fn as_variable_mut(&mut self) -> &mut VariableExpression {
         match self {
             Expression::Variable(result) => result,
             _ => panic!("Unable to cast `Expression` to `VariableExpression`"),
+        }
+    }
     pub fn span(&self) -> InputSpan {
         match self {
             Expression::Assignment(expr) => expr.span,
             Expression::Binding(expr) => expr.span,
             Expression::Conditional(expr) => expr.span,
             Expression::Binary(expr) => expr.span,
             Expression::Unary(expr) => expr.span,
             Expression::Indexing(expr) => expr.span,
             Expression::Slicing(expr) => expr.span,
             Expression::Select(expr) => expr.span,
             Expression::Literal(expr) => expr.span,
             Expression::Cast(expr) => expr.span,
             Expression::Call(expr) => expr.span,
             Expression::Variable(expr) => expr.identifier.span,
+        }
+    }
     // TODO: @cleanup
     pub fn parent(&self) -> &ExpressionParent {
         match self {
             Expression::Assignment(expr) => &expr.parent,
             Expression::Binding(expr) => &expr.parent,
             Expression::Conditional(expr) => &expr.parent,
             Expression::Binary(expr) => &expr.parent,
             Expression::Unary(expr) => &expr.parent,
             Expression::Indexing(expr) => &expr.parent,
             Expression::Slicing(expr) => &expr.parent,
             Expression::Select(expr) => &expr.parent,
             Expression::Literal(expr) => &expr.parent,
             Expression::Cast(expr) => &expr.parent,
             Expression::Call(expr) => &expr.parent,
             Expression::Variable(expr) => &expr.parent,
+        }
+    }
     // TODO: @cleanup
     pub fn parent_expr_id(&self) -> Option<ExpressionId> {
         if let ExpressionParent::Expression(id, _) = self.parent() {
             Some(*id)
         } else {
             None
+        }
+    }
     // TODO: @cleanup
     pub fn set_parent(&mut self, parent: ExpressionParent) {
         match self {
             Expression::Assignment(expr) => expr.parent = parent,
             Expression::Binding(expr) => expr.parent = parent,
             Expression::Conditional(expr) => expr.parent = parent,
             Expression::Binary(expr) => expr.parent = parent,
             Expression::Unary(expr) => expr.parent = parent,
             Expression::Indexing(expr) => expr.parent = parent,
             Expression::Slicing(expr) => expr.parent = parent,
             Expression::Select(expr) => expr.parent = parent,
             Expression::Literal(expr) => expr.parent = parent,
             Expression::Cast(expr) => expr.parent = parent,
             Expression::Call(expr) => expr.parent = parent,
             Expression::Variable(expr) => expr.parent = parent,
+        }
+    }
     pub fn get_unique_id_in_definition(&self) -> i32 {
         match self {
             Expression::Assignment(expr) => expr.unique_id_in_definition,
             Expression::Binding(expr) => expr.unique_id_in_definition,
             Expression::Conditional(expr) => expr.unique_id_in_definition,
             Expression::Binary(expr) => expr.unique_id_in_definition,
             Expression::Unary(expr) => expr.unique_id_in_definition,
             Expression::Indexing(expr) => expr.unique_id_in_definition,
             Expression::Slicing(expr) => expr.unique_id_in_definition,
             Expression::Select(expr) => expr.unique_id_in_definition,
             Expression::Literal(expr) => expr.unique_id_in_definition,
             Expression::Cast(expr) => expr.unique_id_in_definition,
             Expression::Call(expr) => expr.unique_id_in_definition,
             Expression::Variable(expr) => expr.unique_id_in_definition,
+        }
+    }
+}
 #[derive(Debug, Clone, Copy)]
 pub enum AssignmentOperator {
     Set,
     Multiplied,
     Divided,
     Remained,
     Added,
     Subtracted,
     ShiftedLeft,
     ShiftedRight,
     BitwiseAnded,
     BitwiseXored,
     BitwiseOred,
+}
 #[derive(Debug, Clone)]
 pub struct AssignmentExpression {
     pub this: AssignmentExpressionId,
@@ @@ -1677,48 +1683,60 @@ pub struct IndexingExpression { @@
 pub struct SlicingExpression {
     pub this: SlicingExpressionId,
     // Parsing
     pub span: InputSpan, // from '[' to ']';
     pub subject: ExpressionId,
     pub from_index: ExpressionId,
     pub to_index: ExpressionId,
     // Validator/Linker
     pub parent: ExpressionParent,
     pub unique_id_in_definition: i32,
+}
 #[derive(Debug, Clone)]
 pub struct SelectExpression {
     pub this: SelectExpressionId,
     // Parsing
     pub span: InputSpan, // of the '.'
     pub subject: ExpressionId,
     pub field_name: Identifier,
     // Validator/Linker
     pub parent: ExpressionParent,
     pub unique_id_in_definition: i32,
+}
 #[derive(Debug, Clone)]
 pub struct CastExpression {
     pub this: CastExpressionId,
     // Parsing
     pub span: InputSpan, // of the "cast" keyword,
     pub to_type: ParserType,
     pub subject: ExpressionId,
     // Validator/linker
     pub parent: ExpressionParent,
     pub unique_id_in_definition: i32,
+}
 #[derive(Debug, Clone)]
 pub struct CallExpression {
     pub this: CallExpressionId,
     // Parsing
     pub span: InputSpan,
     pub parser_type: ParserType, // of the function call, not the return type
     pub method: Method,
     pub arguments: Vec<ExpressionId>,
     pub definition: DefinitionId,
     // Validator/Linker
     pub parent: ExpressionParent,
     pub unique_id_in_definition: i32,
+}
 #[derive(Debug, Clone, PartialEq, Eq)]
 pub enum Method {
     // Builtin
     Get,
     Put,
     Fires,
     Create,
     Length,
     Assert,
     UserFunction,

src/protocol/ast_printer.rs

➞

Show inline comments

@@ @@ -683,48 +683,51 @@ impl ASTWriter { @@
                         self.kv(indent3).with_s_key("ParserType")
                             .with_custom_val(|t| write_parser_type(t, heap, &data.parser_type));
                         self.kv(indent3).with_s_key("Definition").with_disp_val(&data.definition.index);
                         self.kv(indent3).with_s_key("VariantIdx").with_disp_val(&data.variant_idx);
                         for value in &data.values {
                             self.kv(indent3).with_s_key("Value");
                             self.write_expr(heap, *value, indent4);
+                        }
+                    }
                     Literal::Array(data) => {
                         val.with_s_val("Array");
                         let indent4 = indent3 + 1;
                         self.kv(indent3).with_s_key("Elements");
                         for expr_id in data {
                             self.write_expr(heap, *expr_id, indent4);
+                        }
+                    }
+                }
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
             },
             Expression::Cast(expr) => {
                 todo!("print casting expression")
+            }
             Expression::Call(expr) => {
                 self.kv(indent).with_id(PREFIX_CALL_EXPR_ID, expr.this.0.index)
                     .with_s_key("CallExpr");
                 let definition = &heap[expr.definition];
                 match definition {
                     Definition::Component(definition) => {
                         self.kv(indent2).with_s_key("BuiltIn").with_disp_val(&false);
                         self.kv(indent2).with_s_key("Variant").with_debug_val(&definition.variant);
                     },
                     Definition::Function(definition) => {
                         self.kv(indent2).with_s_key("BuiltIn").with_disp_val(&definition.builtin);
                         self.kv(indent2).with_s_key("Variant").with_s_val("Function");
                     },
                     _ => unreachable!()
+                }
                 self.kv(indent2).with_s_key("MethodName").with_identifier_val(definition.identifier());
                 self.kv(indent2).with_s_key("ParserType")
                     .with_custom_val(|t| write_parser_type(t, heap, &expr.parser_type));
                 // Arguments
                 self.kv(indent2).with_s_key("Arguments");
                 for arg_id in &expr.arguments {
                     self.write_expr(heap, *arg_id, indent3);

src/protocol/eval/executor.rs

➞

Show inline comments

@@ @@ -131,48 +131,51 @@ impl Frame { @@
                             for field in &literal.fields {
                                 if field.field_idx == want_field_idx {
                                     _num_pushed += 1;
                                     self.expr_stack.push_back(ExprInstruction::PushValToFront);
                                     self.serialize_expression(heap, field.value);
+                                }
+                            }
+                        }
                         debug_assert_eq!(_num_pushed, literal.fields.len())
                     },
                     Literal::Union(literal) => {
                         for value_expr_id in &literal.values {
                             self.expr_stack.push_back(ExprInstruction::PushValToFront);
                             self.serialize_expression(heap, *value_expr_id);
+                        }
                     },
                     Literal::Array(value_expr_ids) => {
                         for value_expr_id in value_expr_ids {
                             self.expr_stack.push_back(ExprInstruction::PushValToFront);
                             self.serialize_expression(heap, *value_expr_id);
+                        }
+                    }
+                }
             },
             Expression::Cast(_) => {
                 todo!("casting expression");
+            }
             Expression::Call(expr) => {
                 for arg_expr_id in &expr.arguments {
                     self.expr_stack.push_back(ExprInstruction::PushValToFront);
                     self.serialize_expression(heap, *arg_expr_id);
+                }
             },
             Expression::Variable(expr) => {
                 // No subexpressions
+            }
+        }
+    }
+}
 type EvalResult = Result<EvalContinuation, EvalError>;
 pub enum EvalContinuation {
     Stepping,
     Inconsistent,
     Terminal,
     SyncBlockStart,
     SyncBlockEnd,
     NewComponent(DefinitionId, i32, ValueGroup),
     BlockFires(Value),
     BlockGet(Value),
@@ @@ -467,48 +470,51 @@ impl Prompt { @@
                                     let heap_pos = transfer_expression_values_front_into_heap(
                                         cur_frame, &mut self.store, lit_value.fields.len()
                                     );
                                     Value::Struct(heap_pos)
+                                }
                                 Literal::Enum(lit_value) => {
                                     Value::Enum(lit_value.variant_idx as i64)
+                                }
                                 Literal::Union(lit_value) => {
                                     let heap_pos = transfer_expression_values_front_into_heap(
                                         cur_frame, &mut self.store, lit_value.values.len()
                                     );
                                     Value::Union(lit_value.variant_idx as i64, heap_pos)
+                                }
                                 Literal::Array(lit_value) => {
                                     let heap_pos = transfer_expression_values_front_into_heap(
                                         cur_frame, &mut self.store, lit_value.len()
                                     );
                                     Value::Array(heap_pos)
+                                }
                             };
                             cur_frame.expr_values.push_back(value);
                         },
                         Expression::Cast(_) => {
                             todo!("casting expression evaluation");
+                        }
                         Expression::Call(expr) => {
                             // Push a new frame. Note that all expressions have
                             // been pushed to the front, so they're in the order
                             // of the definition.
                             let num_args = expr.arguments.len();
                             // Determine stack boundaries
                             let cur_stack_boundary = self.store.cur_stack_boundary;
                             let new_stack_boundary = self.store.stack.len();
                             // Push new boundary and function arguments for new frame
                             self.store.stack.push(Value::PrevStackBoundary(cur_stack_boundary as isize));
                             for _ in 0..num_args {
                                 let argument = self.store.read_take_ownership(cur_frame.expr_values.pop_front().unwrap());
                                 self.store.stack.push(argument);
+                            }
                             // Determine the monomorph index of the function we're calling
                             let mono_data = types.get_procedure_expression_data(&cur_frame.definition, cur_frame.monomorph_idx);
                             let call_data = &mono_data.expr_data[expr.unique_id_in_definition as usize];
                             // Push the new frame
                             self.frames.push(Frame::new(heap, expr.definition, call_data.field_or_monomorph_idx));
                             self.store.cur_stack_boundary = new_stack_boundary;

src/protocol/parser/depth_visitor.rs

➞

Show inline comments

@@ @@ -145,48 +145,52 @@ pub(crate) trait Visitor: Sized { @@
+    }
     fn visit_binary_expression(&mut self, h: &mut Heap, expr: BinaryExpressionId) -> VisitorResult {
         recursive_binary_expression(self, h, expr)
+    }
     fn visit_unary_expression(&mut self, h: &mut Heap, expr: UnaryExpressionId) -> VisitorResult {
         recursive_unary_expression(self, h, expr)
+    }
     fn visit_indexing_expression(
         &mut self,
         h: &mut Heap,
         expr: IndexingExpressionId,
     ) -> VisitorResult {
         recursive_indexing_expression(self, h, expr)
+    }
     fn visit_slicing_expression(
         &mut self,
         h: &mut Heap,
         expr: SlicingExpressionId,
     ) -> VisitorResult {
         recursive_slicing_expression(self, h, expr)
+    }
     fn visit_select_expression(&mut self, h: &mut Heap, expr: SelectExpressionId) -> VisitorResult {
         recursive_select_expression(self, h, expr)
+    }
     fn visit_cast_expression(&mut self, h: &mut Heap, expr: CastExpressionId) -> VisitorResult {
         let subject = h[expr].subject;
         self.visit_expression(h, subject)
+    }
     fn visit_call_expression(&mut self, h: &mut Heap, expr: CallExpressionId) -> VisitorResult {
         recursive_call_expression(self, h, expr)
+    }
     fn visit_constant_expression(
         &mut self,
         _h: &mut Heap,
         _expr: LiteralExpressionId,
     ) -> VisitorResult {
         Ok(())
+    }
     fn visit_variable_expression(
         &mut self,
         _h: &mut Heap,
         _expr: VariableExpressionId,
     ) -> VisitorResult {
         Ok(())
+    }
+}
 fn recursive_call_expression_as_expression<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     call: CallExpressionId,
 ) -> VisitorResult {
@@ @@ -379,48 +383,49 @@ fn recursive_new_statement<T: Visitor>( @@
 fn recursive_expression_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: ExpressionStatementId,
 ) -> VisitorResult {
     this.visit_expression(h, h[stmt].expression)
+}
 fn recursive_expression<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     expr: ExpressionId,
 ) -> VisitorResult {
     match h[expr].clone() {
         Expression::Assignment(expr) => this.visit_assignment_expression(h, expr.this),
         Expression::Binding(expr) => this.visit_binding_expression(h, expr.this),
         Expression::Conditional(expr) => this.visit_conditional_expression(h, expr.this),
         Expression::Binary(expr) => this.visit_binary_expression(h, expr.this),
         Expression::Unary(expr) => this.visit_unary_expression(h, expr.this),
         Expression::Indexing(expr) => this.visit_indexing_expression(h, expr.this),
         Expression::Slicing(expr) => this.visit_slicing_expression(h, expr.this),
         Expression::Select(expr) => this.visit_select_expression(h, expr.this),
         Expression::Literal(expr) => this.visit_constant_expression(h, expr.this),
         Expression::Cast(expr) => this.visit_cast_expression(h, expr.this),
         Expression::Call(expr) => this.visit_call_expression(h, expr.this),
         Expression::Variable(expr) => this.visit_variable_expression(h, expr.this),
+    }
+}
 fn recursive_assignment_expression<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     expr: AssignmentExpressionId,
 ) -> VisitorResult {
     this.visit_expression(h, h[expr].left)?;
     this.visit_expression(h, h[expr].right)
+}
 fn recursive_binding_expression<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     expr: BindingExpressionId,
 ) -> VisitorResult {
     this.visit_expression(h, h[expr].left.upcast())?;
     this.visit_expression(h, h[expr].right)
+}
 fn recursive_conditional_expression<T: Visitor>(

src/protocol/parser/pass_definitions.rs

➞

Show inline comments

@@ @@ -683,49 +683,49 @@ impl PassDefinitions { @@
         debug_assert!(!call_id.is_invalid());
         Ok(ctx.heap.alloc_new_statement(|this| NewStatement{
             this,
             span: new_span,
             expression: call_id,
             next: StatementId::new_invalid(),
         }))
+    }
     fn consume_channel_statement(
         &mut self, module: &Module, iter: &mut TokenIter, ctx: &mut PassCtx
     ) -> Result<ChannelStatementId, ParseError> {
         // Consume channel specification
         let channel_span = consume_exact_ident(&module.source, iter, KW_STMT_CHANNEL)?;
         let channel_type = if Some(TokenKind::OpenAngle) == iter.next() {
             // Retrieve the type of the channel, we're cheating a bit here by
             // consuming the first '<' and setting the initial angle depth to 1
             // such that our final '>' will be consumed as well.
             iter.consume();
             let definition_id = self.cur_definition;
             let poly_vars = ctx.heap[definition_id].poly_vars();
             consume_parser_type(
                 &module.source, iter, &ctx.symbols, &ctx.heap,
-                &poly_vars, SymbolScope::Module(module.root_id), definition_id,
                 poly_vars, SymbolScope::Module(module.root_id), definition_id,
                 true, 1
             )?
         } else {
             // Assume inferred
             ParserType{ elements: vec![ParserTypeElement{
                 full_span: channel_span, // TODO: @Span fix
                 variant: ParserTypeVariant::Inferred
             }]}
         };
         let from_identifier = consume_ident_interned(&module.source, iter, ctx)?;
         consume_token(&module.source, iter, TokenKind::ArrowRight)?;
         let to_identifier = consume_ident_interned(&module.source, iter, ctx)?;
         consume_token(&module.source, iter, TokenKind::SemiColon)?;
         // Construct ports
         let from = ctx.heap.alloc_variable(|this| Variable{
             this,
             kind: VariableKind::Local,
             identifier: from_identifier,
             parser_type: channel_type.clone(),
             relative_pos_in_block: 0,
             unique_id_in_scope: -1,
         });
@@ @@ -1437,48 +1437,80 @@ impl PassDefinitions { @@
                             "unexpected type in expression, note that casting expressions are not yet implemented"
                         ))
+                    }
+                }
             } else {
                 // Check for builtin keywords or builtin functions
                 if ident_text == KW_LIT_NULL || ident_text == KW_LIT_TRUE || ident_text == KW_LIT_FALSE {
                     iter.consume();
                     // Parse builtin literal
                     let value = match ident_text {
                         KW_LIT_NULL => Literal::Null,
                         KW_LIT_TRUE => Literal::True,
                         KW_LIT_FALSE => Literal::False,
                         _ => unreachable!(),
                     };
                     ctx.heap.alloc_literal_expression(|this| LiteralExpression {
                         this,
                         span: ident_span,
                         value,
                         parent: ExpressionParent::None,
                         unique_id_in_definition: -1,
                     }).upcast()
                 } else if ident_text == KW_CAST {
                     // Casting expression
                     iter.consume();
                     let to_type = if Some(TokenKind::OpenAngle) == iter.next() {
                         iter.consume();
                         let definition_id = self.cur_definition;
                         let poly_vars = ctx.heap[definition_id].poly_vars();
                         consume_parser_type(
                             &module.source, iter, &ctx.symbols, &ctx.heap,
                             poly_vars, SymbolScope::Module(module.root_id), definition_id,
                             true, 1
                         )?
                     } else {
                         // Automatic casting with inferred target type
                         ParserType{ elements: vec![ParserTypeElement{
                             full_span: ident_span, // TODO: @Span fix
                             variant: ParserTypeVariant::Inferred,
                         }]}
                     };
                     consume_token(&module.source, iter, TokenKind::OpenParen)?;
                     let subject = self.consume_expression(module, iter, ctx)?;
                     consume_token(&module.source, iter, TokenKind::CloseParen)?;
                     ctx.heap.alloc_cast_expression(|this| CastExpression{
                         this,
                         span: ident_span,
                         to_type,
                         subject,
                         parent: ExpressionParent::None,
                         unique_id_in_definition: -1,
                     }).upcast()
                 } else {
                     // Not a builtin literal, but also not a known type. So we
                     // assume it is a variable expression. Although if we do,
                     // then if a programmer mistyped a struct/function name the
                     // error messages will be rather cryptic. For polymorphic
                     // arguments we can't really do anything at all (because it
                     // uses the '<' token). In the other cases we try to provide
                     // a better error message.
                     iter.consume();
                     let next = iter.next();
                     if Some(TokenKind::ColonColon) == next {
                         return Err(ParseError::new_error_str_at_span(&module.source, ident_span, "unknown identifier"));
                     } else if Some(TokenKind::OpenParen) == next {
                         return Err(ParseError::new_error_str_at_span(
                             &module.source, ident_span,
                             "unknown identifier, did you mistype a union variant's or a function's name?"
                         ));
                     } else if Some(TokenKind::OpenCurly) == next {
                         return Err(ParseError::new_error_str_at_span(
                             &module.source, ident_span,
                             "unknown identifier, did you mistype a struct type's name?"
                         ))
+                    }

src/protocol/parser/pass_typing.rs

➞

Show inline comments

@@ @@ -1296,61 +1296,73 @@ impl Visitor2 for PassTyping { @@
                 self.insert_initial_enum_polymorph_data(ctx, id);
             },
             Literal::Union(literal) => {
                 // May carry subexpressions and polymorphic arguments
                 // TODO: @performance
                 let expr_ids = literal.values.clone();
                 self.insert_initial_union_polymorph_data(ctx, id);
                 for expr_id in expr_ids {
                     self.visit_expr(ctx, expr_id)?;
+                }
             },
             Literal::Array(expressions) => {
                 // TODO: @performance
                 let expr_ids = expressions.clone();
                 for expr_id in expr_ids {
                     self.visit_expr(ctx, expr_id)?;
+                }
+            }
+        }
         self.progress_literal_expr(ctx, id)
+    }
     fn visit_cast_expr(&mut self, ctx: &mut Ctx, id: CastExpressionId) -> VisitorResult {
         let upcast_id = id.upcast();
         self.insert_initial_expr_inference_type(ctx, upcast_id)?;
         let cast_expr = &ctx.heap[id];
         let subject_expr_id = cast_expr.subject;
         self.visit_expr(ctx, subject_expr_id)?;
         self.progress_cast_expr(ctx, id)
+    }
     fn visit_call_expr(&mut self, ctx: &mut Ctx, id: CallExpressionId) -> VisitorResult {
         let upcast_id = id.upcast();
         self.insert_initial_expr_inference_type(ctx, upcast_id)?;
         self.insert_initial_call_polymorph_data(ctx, id);
         // By default we set the polymorph idx for calls to 0. If the call ends
         // up not being a polymorphic one, then we will select the default
         // expression types in the type table
         let call_expr = &ctx.heap[id];
         self.expr_types[call_expr.unique_id_in_definition as usize].field_or_monomorph_idx = 0;
         // Visit all arguments
         for arg_expr_id in call_expr.arguments.clone() {
+        for arg_expr_id in call_expr.arguments.clone() { // TODO: @Performance
             self.visit_expr(ctx, arg_expr_id)?;
+        }
         self.progress_call_expr(ctx, id)
+    }
     fn visit_variable_expr(&mut self, ctx: &mut Ctx, id: VariableExpressionId) -> VisitorResult {
         let upcast_id = id.upcast();
         self.insert_initial_expr_inference_type(ctx, upcast_id)?;
         let var_expr = &ctx.heap[id];
         debug_assert!(var_expr.declaration.is_some());
         let var_data = self.var_types.get_mut(var_expr.declaration.as_ref().unwrap()).unwrap();
         var_data.used_at.push(upcast_id);
         self.progress_variable_expr(ctx, id)
+    }
+}
 impl PassTyping {
     fn temp_get_display_name(&self, ctx: &Ctx, expr_id: ExpressionId) -> String {
         let expr_idx = ctx.heap[expr_id].get_unique_id_in_definition();
         let expr_type = &self.expr_types[expr_idx as usize].expr_type;
         expr_type.display_name(&ctx.heap)
@@ @@ -1519,48 +1531,52 @@ impl PassTyping { @@
             Expression::Binary(expr) => {
                 let id = expr.this;
                 self.progress_binary_expr(ctx, id)
             },
             Expression::Unary(expr) => {
                 let id = expr.this;
                 self.progress_unary_expr(ctx, id)
             },
             Expression::Indexing(expr) => {
                 let id = expr.this;
                 self.progress_indexing_expr(ctx, id)
             },
             Expression::Slicing(expr) => {
                 let id = expr.this;
                 self.progress_slicing_expr(ctx, id)
             },
             Expression::Select(expr) => {
                 let id = expr.this;
                 self.progress_select_expr(ctx, id)
             },
             Expression::Literal(expr) => {
                 let id = expr.this;
                 self.progress_literal_expr(ctx, id)
             },
             Expression::Cast(expr) => {
                 let id = expr.this;
                 self.progress_cast_expr(ctx, id)
             },
             Expression::Call(expr) => {
                 let id = expr.this;
                 self.progress_call_expr(ctx, id)
             },
             Expression::Variable(expr) => {
                 let id = expr.this;
                 self.progress_variable_expr(ctx, id)
+            }
+        }
+    }
     fn progress_assignment_expr(&mut self, ctx: &mut Ctx, id: AssignmentExpressionId) -> Result<(), ParseError> {
         use AssignmentOperator as AO;
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let arg1_expr_id = expr.left;
         let arg2_expr_id = expr.right;
         debug_log!("Assignment expr '{:?}': {}", expr.operation, upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Arg1 type: {}", self.temp_get_display_name(ctx, arg1_expr_id));
         debug_log!("   - Arg2 type: {}", self.temp_get_display_name(ctx, arg2_expr_id));
@@ @@ -2268,48 +2284,59 @@ impl PassTyping { @@
                     progress_expr = progress_expr || inner_expr_progress;
                     // Note that if the array type progressed the type of the arguments,
                     // then we should enqueue this progression function again
                     // TODO: @fix Make apply_equal_n accept a start idx as well
                     if arg_progress { self.queue_expr(ctx, upcast_id); }
+                }
                 debug_log!(" * After:");
                 debug_log!("   - Expr type [{}]: {}", progress_expr, self.temp_get_display_name(ctx, upcast_id));
                 progress_expr
             },
         };
         debug_log!(" * After:");
         debug_log!("   - Expr type: {}", self.temp_get_display_name(ctx, upcast_id));
         // TODO: FIX!!!!
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         Ok(())
+    }
     fn progress_cast_expr(&mut self, ctx: &mut Ctx, id: CastExpressionId) -> Result<(), ParseError> {
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let expr_idx = expr.unique_id_in_definition;
         // The cast expression acts like a blocker for two-way inference. The
         // only thing we can do is wait until both the input and the output
         // TODO: Continue here
         Ok(())
+    }
     // TODO: @cleanup, see how this can be cleaned up once I implement
     //  polymorphic struct/enum/union literals. These likely follow the same
     //  pattern as here.
     fn progress_call_expr(&mut self, ctx: &mut Ctx, id: CallExpressionId) -> Result<(), ParseError> {
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let expr_idx = expr.unique_id_in_definition;
         let extra_idx = self.expr_types[expr_idx as usize].extra_data_idx;
         debug_log!("Call expr '{}': {}", ctx.heap[expr.definition].identifier().value.as_str(), upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Expr type: {}", self.temp_get_display_name(ctx, upcast_id));
         debug_log!(" * During (inferring types from arguments and return type):");
         let extra = &mut self.extra_data[extra_idx as usize];
         // Check if we can make progress using the arguments and/or return types
         // while keeping track of the polyvars we've extended
         let mut poly_progress = HashSet::new();
         debug_assert_eq!(extra.embedded.len(), expr.arguments.len());
         for (call_arg_idx, arg_id) in expr.arguments.clone().into_iter().enumerate() {
             let arg_expr_idx = ctx.heap[arg_id].get_unique_id_in_definition();
             let signature_type: *mut _ = &mut extra.embedded[call_arg_idx];

src/protocol/parser/pass_validation_linking.rs

➞

Show inline comments

@@ @@ -706,48 +706,72 @@ impl Visitor2 for PassValidationLinking { @@
                     self.visit_expr(ctx, expr_id)?;
+                }
                 expr_section.forget();
             },
             Literal::Array(literal) => {
                 // Visit all expressions in the array
                 let upcast_id = id.upcast();
                 let expr_section = self.expression_buffer.start_section_initialized(literal);
                 for expr_idx in 0..expr_section.len() {
                     let expr_id = expr_section[expr_idx];
                     self.expr_parent = ExpressionParent::Expression(upcast_id, expr_idx as u32);
                     self.visit_expr(ctx, expr_id)?;
+                }
                 expr_section.forget();
+            }
+        }
         self.expr_parent = old_expr_parent;
         Ok(())
+    }
     fn visit_cast_expr(&mut self, ctx: &mut Ctx, id: CastExpressionId) -> VisitorResult {
         let cast_expr = &mut ctx.heap[id];
         if let Some(span) = self.must_be_assignable {
             return Err(ParseError::new_error_str_at_span(
                 &ctx.module.source, span, "cannot assign to the result from a cast expression"
             ))
+        }
         let upcast_id = id.upcast();
         let old_expr_parent = self.expr_parent;
         cast_expr.parent = old_expr_parent;
         cast_expr.unique_id_in_definition = self.next_expr_index;
         self.next_expr_index += 1;
         // Recurse into the thing that we're casting
         self.expr_parent = ExpressionParent::Expression(upcast_id, 0);
         let subject_id = cast_expr.subject;
         self.visit_expr(ctx, subject_id)?;
         self.expr_parent = old_expr_parent;
         Ok(())
+    }
     fn visit_call_expr(&mut self, ctx: &mut Ctx, id: CallExpressionId) -> VisitorResult {
         let call_expr = &mut ctx.heap[id];
         if let Some(span) = self.must_be_assignable {
             return Err(ParseError::new_error_str_at_span(
                 &ctx.module.source, span, "cannot assign to the result from a call expression"
             ))
+        }
         // Check whether the method is allowed to be called within the code's
         // context (in sync, definition type, etc.)
         let mut expected_wrapping_new_stmt = false;
         match &mut call_expr.method {
             Method::Get => {
                 if !self.def_type.is_primitive() {
                     return Err(ParseError::new_error_str_at_span(
                         &ctx.module.source, call_expr.span,
                         "a call to 'get' may only occur in primitive component definitions"
                     ));
+                }
                 if self.in_sync.is_none() {
                     return Err(ParseError::new_error_str_at_span(
                         &ctx.module.source, call_expr.span,
                         "a call to 'get' may only occur inside synchronous blocks"

src/protocol/parser/token_parsing.rs

➞

Show inline comments

@@ @@ -5,49 +5,50 @@ use crate::protocol::input_source::{ @@
     InputPosition as InputPosition,
     InputSpan,
     ParseError,
 };
 use super::tokens::*;
 use super::symbol_table::*;
 use super::{Module, PassCtx};
 // Keywords
 pub(crate) const KW_LET:       &'static [u8] = b"let";
 pub(crate) const KW_AS:        &'static [u8] = b"as";
 pub(crate) const KW_STRUCT:    &'static [u8] = b"struct";
 pub(crate) const KW_ENUM:      &'static [u8] = b"enum";
 pub(crate) const KW_UNION:     &'static [u8] = b"union";
 pub(crate) const KW_FUNCTION:  &'static [u8] = b"func";
 pub(crate) const KW_PRIMITIVE: &'static [u8] = b"primitive";
 pub(crate) const KW_COMPOSITE: &'static [u8] = b"composite";
 pub(crate) const KW_IMPORT:    &'static [u8] = b"import";
 // Keywords - literals
 pub(crate) const KW_LIT_TRUE:  &'static [u8] = b"true";
 pub(crate) const KW_LIT_FALSE: &'static [u8] = b"false";
 pub(crate) const KW_LIT_NULL:  &'static [u8] = b"null";
 // Keywords - functions
 // Keywords - function(like)s
 pub(crate) const KW_CAST:        &'static [u8] = b"cast";
 pub(crate) const KW_FUNC_GET:    &'static [u8] = b"get";
 pub(crate) const KW_FUNC_PUT:    &'static [u8] = b"put";
 pub(crate) const KW_FUNC_FIRES:  &'static [u8] = b"fires";
 pub(crate) const KW_FUNC_CREATE: &'static [u8] = b"create";
 pub(crate) const KW_FUNC_LENGTH: &'static [u8] = b"length";
 pub(crate) const KW_FUNC_ASSERT: &'static [u8] = b"assert";
 // Keywords - statements
 pub(crate) const KW_STMT_CHANNEL:  &'static [u8] = b"channel";
 pub(crate) const KW_STMT_IF:       &'static [u8] = b"if";
 pub(crate) const KW_STMT_ELSE:     &'static [u8] = b"else";
 pub(crate) const KW_STMT_WHILE:    &'static [u8] = b"while";
 pub(crate) const KW_STMT_BREAK:    &'static [u8] = b"break";
 pub(crate) const KW_STMT_CONTINUE: &'static [u8] = b"continue";
 pub(crate) const KW_STMT_GOTO:     &'static [u8] = b"goto";
 pub(crate) const KW_STMT_RETURN:   &'static [u8] = b"return";
 pub(crate) const KW_STMT_SYNC:     &'static [u8] = b"synchronous";
 pub(crate) const KW_STMT_NEW:      &'static [u8] = b"new";
 // Keywords - types
 // Since types are needed for returning diagnostic information to the user, the
 // string variants are put here as well.
 pub(crate) const KW_TYPE_IN_PORT_STR:  &'static str = "in";
 pub(crate) const KW_TYPE_OUT_PORT_STR: &'static str = "out";
@@ @@ -500,49 +501,49 @@ pub(crate) fn consume_ident_interned( @@
     let (value, span) = consume_ident(source, iter)?;
     let value = ctx.pool.intern(value);
     Ok(Identifier{ span, value })
+}
 fn is_reserved_definition_keyword(text: &[u8]) -> bool {
     match text {
         KW_STRUCT | KW_ENUM | KW_UNION | KW_FUNCTION | KW_PRIMITIVE | KW_COMPOSITE => true,
         _ => false,
+    }
+}
 fn is_reserved_statement_keyword(text: &[u8]) -> bool {
     match text {
         KW_IMPORT | KW_AS |
         KW_STMT_CHANNEL | KW_STMT_IF | KW_STMT_WHILE |
         KW_STMT_BREAK | KW_STMT_CONTINUE | KW_STMT_GOTO | KW_STMT_RETURN |
         KW_STMT_SYNC | KW_STMT_NEW => true,
         _ => false,
+    }
+}
 fn is_reserved_expression_keyword(text: &[u8]) -> bool {
     match text {
         KW_LET |
+        KW_LET | KW_CAST |
         KW_LIT_TRUE | KW_LIT_FALSE | KW_LIT_NULL |
         KW_FUNC_GET | KW_FUNC_PUT | KW_FUNC_FIRES | KW_FUNC_CREATE | KW_FUNC_ASSERT | KW_FUNC_LENGTH => true,
         _ => false,
+    }
+}
 fn is_reserved_type_keyword(text: &[u8]) -> bool {
     match text {
         KW_TYPE_IN_PORT | KW_TYPE_OUT_PORT | KW_TYPE_MESSAGE | KW_TYPE_BOOL |
         KW_TYPE_UINT8 | KW_TYPE_UINT16 | KW_TYPE_UINT32 | KW_TYPE_UINT64 |
         KW_TYPE_SINT8 | KW_TYPE_SINT16 | KW_TYPE_SINT32 | KW_TYPE_SINT64 |
         KW_TYPE_CHAR | KW_TYPE_STRING |
         KW_TYPE_INFERRED => true,
         _ => false,
+    }
+}
 fn is_reserved_keyword(text: &[u8]) -> bool {
     return
         is_reserved_definition_keyword(text) ||
         is_reserved_statement_keyword(text) ||
         is_reserved_expression_keyword(text) ||
         is_reserved_type_keyword(text);
+}

src/protocol/parser/visitor.rs

➞

Show inline comments

@@ @@ -184,47 +184,52 @@ pub(crate) trait Visitor2 { @@
             Expression::Binary(expr) => {
                 let this = expr.this;
                 self.visit_binary_expr(ctx, this)
+            }
             Expression::Unary(expr) => {
                 let this = expr.this;
                 self.visit_unary_expr(ctx, this)
+            }
             Expression::Indexing(expr) => {
                 let this = expr.this;
                 self.visit_indexing_expr(ctx, this)
+            }
             Expression::Slicing(expr) => {
                 let this = expr.this;
                 self.visit_slicing_expr(ctx, this)
+            }
             Expression::Select(expr) => {
                 let this = expr.this;
                 self.visit_select_expr(ctx, this)
+            }
             Expression::Literal(expr) => {
                 let this = expr.this;
                 self.visit_literal_expr(ctx, this)
+            }
             Expression::Cast(expr) => {
                 let this = expr.this;
                 self.visit_cast_expr(ctx, this)
+            }
             Expression::Call(expr) => {
                 let this = expr.this;
                 self.visit_call_expr(ctx, this)
+            }
             Expression::Variable(expr) => {
                 let this = expr.this;
                 self.visit_variable_expr(ctx, this)
+            }
+        }
+    }
     fn visit_assignment_expr(&mut self, _ctx: &mut Ctx, _id: AssignmentExpressionId) -> VisitorResult { Ok(()) }
     fn visit_binding_expr(&mut self, _ctx: &mut Ctx, _id: BindingExpressionId) -> VisitorResult { Ok(()) }
     fn visit_conditional_expr(&mut self, _ctx: &mut Ctx, _id: ConditionalExpressionId) -> VisitorResult { Ok(()) }
     fn visit_binary_expr(&mut self, _ctx: &mut Ctx, _id: BinaryExpressionId) -> VisitorResult { Ok(()) }
     fn visit_unary_expr(&mut self, _ctx: &mut Ctx, _id: UnaryExpressionId) -> VisitorResult { Ok(()) }
     fn visit_indexing_expr(&mut self, _ctx: &mut Ctx, _id: IndexingExpressionId) -> VisitorResult { Ok(()) }
     fn visit_slicing_expr(&mut self, _ctx: &mut Ctx, _id: SlicingExpressionId) -> VisitorResult { Ok(()) }
     fn visit_select_expr(&mut self, _ctx: &mut Ctx, _id: SelectExpressionId) -> VisitorResult { Ok(()) }
     fn visit_literal_expr(&mut self, _ctx: &mut Ctx, _id: LiteralExpressionId) -> VisitorResult { Ok(()) }
     fn visit_cast_expr(&mut self, _ctx: &mut Ctx, _id: CastExpressionId) -> VisitorResult { Ok(()) }
     fn visit_call_expr(&mut self, _ctx: &mut Ctx, _id: CallExpressionId) -> VisitorResult { Ok(()) }
     fn visit_variable_expr(&mut self, _ctx: &mut Ctx, _id: VariableExpressionId) -> VisitorResult { Ok(()) }
+}
@@ \ No newline at end of file @@

src/protocol/tests/eval_silly.rs

➞

Show inline comments

@@ @@ -166,57 +166,58 @@ fn test_struct_fields() { @@
             // Single depth modification
             auto original1 = make<u32>(5);
             auto modified1 = modify(original1, 2);
             auto success1 = original1.v == 5 && modified1.v == 2;
             // Multiple levels of modification
             auto original2 = make(make(make(make(true))));
             auto modified2 = modify(original2.v, make(make(false))); // strip one Nester level
             auto success2 = original2.v.v.v.v == true && modified2.v.v.v == false;
             return success1 && success2;
+        }
     ").for_function("foo", |f| {
         f.call_ok(Some(Value::Bool(true)));
     });
+}
 #[test]
 fn test_field_selection_polymorphism() {
     // Bit silly, but just to be sure
     Tester::new_single_source_expect_ok("struct field shuffles", "
         struct VecXYZ<T> { T x, T y, T z }
         struct VecYZX<T> { T y, T z, T x }
         struct VecZXY<T> { T z, T x, T y }
         func modify_x<T>(T input) -> T {
             input.x = 1337;
             return input;
+        }
         func foo() -> bool {
             auto xyz = VecXYZ<u16>{ x: 1, y: 2, z: 3 };
             auto yzx = VecYZX<u32>{ y: 2, z: 3, x: 1 };
     auto zxy = VecZXY<u64>{ x: 1, y: 2, z: 3 };
+            auto zxy = VecZXY<u64>{ x: 1, y: 2, z: 3 }; // different initialization order
             auto mod_xyz = modify_x(xyz);
             auto mod_yzx = modify_x(yzx);
             auto mod_zxy = modify_x(zxy);
             return
                 xyz.x == 1 && xyz.y == 2 && xyz.z == 3 &&
                 yzx.x == 1 && yzx.y == 2 && yzx.z == 3 &&
                 zxy.x == 1 && zxy.y == 2 && zxy.z == 3 &&
                 mod_xyz.x == 1337 && mod_xyz.y == 2 && mod_xyz.z == 3 &&
                 mod_yzx.x == 1337 && mod_yzx.y == 2 && mod_yzx.z == 3 &&
                 mod_zxy.x == 1337 && mod_zxy.y == 2 && mod_zxy.z == 3;
+        }
 ").for_function("foo", |f| {
         f.call_ok(Some(Value::Bool(true)));
     });
+}
 #[test]
 fn test_index_error() {
     Tester::new_single_source_expect_ok("indexing error", "
         func check_array(u32[] vals, u32 idx) -> u32 {
             return vals[idx];
+        }

src/protocol/tests/parser_inference.rs

➞

Show inline comments

@@ @@ -309,90 +309,90 @@ fn test_enum_inference() { @@
+}
 #[test]
 fn test_failed_variable_inference() {
     Tester::new_single_source_expect_err(
         "variable assignment mismatch",
+        "
         func call() -> u32 {
             u16 val16 = 0;
             u32 val32 = 0;
             auto a = val16;
             a = val32;
             return 0;
+        }
+        "
     ).error(|e| { e
         .assert_num(2)
         .assert_msg_has(0, "type 'u16'")
         .assert_msg_has(1, "type 'u32'");
     });
+}
 #[test]
 fn test_failed_polymorph_inference() {
     // Tester::new_single_source_expect_err(
     //     "function call inference mismatch",
     //     "
     //     func poly<T>(T a, T b) -> s32 { return 0; }
     //     func call() -> s32 {
     //         s8 first_arg = 5;
     //         s64 second_arg = 2;
     //         return poly(first_arg, second_arg);
     //     }
     //     "
     // ).error(|e| { e
     //     .assert_num(3)
     //     .assert_ctx_has(0, "poly(first_arg, second_arg)")
     //     .assert_occurs_at(0, "poly")
     //     .assert_msg_has(0, "Conflicting type for polymorphic variable 'T'")
     //     .assert_occurs_at(1, "second_arg")
     //     .assert_msg_has(1, "inferred it to 's64'")
     //     .assert_occurs_at(2, "first_arg")
     //     .assert_msg_has(2, "inferred it to 's8'");
     // });
     //
     // Tester::new_single_source_expect_err(
     //     "struct literal inference mismatch",
     //     "
     //     struct Pair<T>{ T first, T second }
     //     func call() -> s32 {
     //         s8 first_arg = 5;
     //         s64 second_arg = 2;
     //         auto pair = Pair{ first: first_arg, second: second_arg };
     //         return 3;
     //     }
     //     "
     // ).error(|e| { e
     //     .assert_num(3)
     //     .assert_ctx_has(0, "Pair{ first: first_arg, second: second_arg }")
     //     .assert_occurs_at(0, "Pair{")
     //     .assert_msg_has(0, "Conflicting type for polymorphic variable 'T'")
     //     .assert_occurs_at(1, "second_arg")
     //     .assert_msg_has(1, "inferred it to 's64'")
     //     .assert_occurs_at(2, "first_arg")
     //     .assert_msg_has(2, "inferred it to 's8'");
     // });
     Tester::new_single_source_expect_err(
         "function call inference mismatch",
+        "
         func poly<T>(T a, T b) -> s32 { return 0; }
         func call() -> s32 {
             s8 first_arg = 5;
             s64 second_arg = 2;
             return poly(first_arg, second_arg);
+        }
+        "
     ).error(|e| { e
         .assert_num(3)
         .assert_ctx_has(0, "poly(first_arg, second_arg)")
         .assert_occurs_at(0, "poly")
         .assert_msg_has(0, "Conflicting type for polymorphic variable 'T'")
         .assert_occurs_at(1, "second_arg")
         .assert_msg_has(1, "inferred it to 's64'")
         .assert_occurs_at(2, "first_arg")
         .assert_msg_has(2, "inferred it to 's8'");
     });
     Tester::new_single_source_expect_err(
         "struct literal inference mismatch",
+        "
         struct Pair<T>{ T first, T second }
         func call() -> s32 {
             s8 first_arg = 5;
             s64 second_arg = 2;
             auto pair = Pair{ first: first_arg, second: second_arg };
             return 3;
+        }
+        "
     ).error(|e| { e
         .assert_num(3)
         .assert_ctx_has(0, "Pair{ first: first_arg, second: second_arg }")
         .assert_occurs_at(0, "Pair{")
         .assert_msg_has(0, "Conflicting type for polymorphic variable 'T'")
         .assert_occurs_at(1, "second_arg")
         .assert_msg_has(1, "inferred it to 's64'")
         .assert_occurs_at(2, "first_arg")
         .assert_msg_has(2, "inferred it to 's8'");
     });
     // Cannot really test literal inference error, but this comes close
     Tester::new_single_source_expect_err(
         "enum literal inference mismatch",
+        "
         enum Uninteresting<T>{ Variant }
         func fix_t<T>(Uninteresting<T> arg) -> s32 { return 0; }
         func call() -> s32 {
             auto a = Uninteresting::Variant;
             fix_t<s8>(a);
             fix_t<s32>(a);
             return 4;
+        }
+        "
     ).error(|e| { e
         .assert_num(2)
         .assert_any_msg_has("type 'Uninteresting<s8>'")
         .assert_any_msg_has("type 'Uninteresting<s32>'");
     });
     Tester::new_single_source_expect_err(
         "field access inference mismatch",
+        "
         struct Holder<Shazam>{ Shazam a }

src/protocol/tests/utils.rs

➞

Show inline comments

             None
             .or_else(|| seek_expr_in_expr(heap, expr.subject, f))
             .or_else(|| seek_expr_in_expr(heap, expr.from_index, f))
             .or_else(|| seek_expr_in_expr(heap, expr.to_index, f))
         },
         Expression::Select(expr) => {
             seek_expr_in_expr(heap, expr.subject, f)
         },
         Expression::Literal(expr) => {
             if let Literal::Struct(lit) = &expr.value {
                 for field in &lit.fields {
                     if let Some(id) = seek_expr_in_expr(heap, field.value, f) {
                         return Some(id)
+                    }
+                }
             } else if let Literal::Array(elements) = &expr.value {
                 for element in elements {
                     if let Some(id) = seek_expr_in_expr(heap, *element, f) {
                         return Some(id)
+                    }
+                }
+            }
             None
         },
         Expression::Cast(expr) => {
             seek_expr_in_expr(heap, expr.subject, f)
+        }
         Expression::Call(expr) => {
             for arg in &expr.arguments {
                 if let Some(id) = seek_expr_in_expr(heap, *arg, f) {
                     return Some(id)
+                }
+            }
             None
         },
         Expression::Variable(_expr) => {
             None
+        }
+    }
+}
 fn seek_expr_in_stmt<F: Fn(&Expression) -> bool>(heap: &Heap, start: StatementId, f: &F) -> Option<ExpressionId> {
     let stmt = &heap[start];
     match stmt {
         Statement::Block(stmt) => {
             for stmt_id in &stmt.statements {
                 if let Some(id) = seek_expr_in_stmt(heap, *stmt_id, f) {
                     return Some(id)
+                }
+            }

0 comments (0 inline, 0 general)