CSY/reowolf Changeset - 6f859c43213c · Centrum Wiskunde & Informatica (CWI)

Changeset - 6f859c43213c

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0 8 0

MH - 4 years ago 2021-03-23 11:46:55
contact@maxhenger.nl

initial debugging of type inference

8 files changed with 227 insertions and 50 deletions:

src/protocol/ast.rs

src/protocol/ast_printer.rs

src/protocol/eval.rs

src/protocol/lexer.rs

src/protocol/parser/depth_visitor.rs

src/protocol/parser/type_resolver.rs

163

src/protocol/parser/visitor_linker.rs

src/runtime/tests.rs

0 comments (0 inline, 0 general)

src/protocol/ast.rs

➞

Show inline comments

@@ @@ -715,251 +715,258 @@ pub enum ParserTypeVariant { @@
     Long,
     String,
     // Literals (need to get concrete builtin type during typechecking)
     IntegerLiteral,
     Inferred,
     // Complex builtins
     Array(ParserTypeId), // array of a type
     Input(ParserTypeId), // typed input endpoint of a channel
     Output(ParserTypeId), // typed output endpoint of a channel
     Symbolic(SymbolicParserType), // symbolic type (definition or polyarg)
+}
 impl ParserTypeVariant {
     pub(crate) fn supports_polymorphic_args(&self) -> bool {
         use ParserTypeVariant::*;
         match self {
             Message | Bool | Byte | Short | Int | Long | String | IntegerLiteral | Inferred => false,
             _ => true
+        }
+    }
+}
 /// ParserType is a specification of a type during the parsing phase and initial
 /// linker/validator phase of the compilation process. These types may be
 /// (partially) inferred or represent literals (e.g. a integer whose bytesize is
 /// not yet determined).
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct ParserType {
     pub this: ParserTypeId,
     pub pos: InputPosition,
     pub variant: ParserTypeVariant,
+}
 /// SymbolicParserType is the specification of a symbolic type. During the
 /// parsing phase we will only store the identifier of the type. During the
 /// validation phase we will determine whether it refers to a user-defined type,
 /// or a polymorphic argument. After the validation phase it may still be the
 /// case that the resulting `variant` will not pass the typechecker.
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct SymbolicParserType {
     // Phase 1: parser
     pub identifier: NamespacedIdentifier,
     /// The user-specified polymorphic arguments. Zero-length implies that the
     /// user did not specify any of them, and they're either not needed or all
     /// need to be inferred. Otherwise the number of polymorphic arguments must
     /// match those of the corresponding definition
     pub poly_args: Vec<ParserTypeId>,
     // Phase 2: validation/linking (for types in function/component bodies) and
     //  type table construction (for embedded types of structs/unions)
     pub variant: Option<SymbolicParserTypeVariant>
+}
 /// Specifies whether the symbolic type points to an actual user-defined type,
 /// or whether it points to a polymorphic argument within the definition (e.g.
 /// a defined variable `T var` within a function `int func<T>()`
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub enum SymbolicParserTypeVariant {
     Definition(DefinitionId),
     // TODO: figure out if I need the DefinitionId here
     PolyArg(DefinitionId, usize), // index of polyarg in the definition
+}
 /// ConcreteType is the representation of a type after resolving symbolic types
 /// and performing type inference
 #[derive(Debug, Clone, Copy, serde::Serialize, serde::Deserialize)]
 pub enum ConcreteTypePart {
     // Special types (cannot be explicitly constructed by the programmer)
     Void,
     // Builtin types without nested types
     Message,
     Bool,
     Byte,
     Short,
     Int,
     Long,
     String,
     // Builtin types with one nested type
     Array,
     Slice,
     Input,
     Output,
     // User defined type with any number of nested types
     Instance(DefinitionId, usize),
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct ConcreteType {
     pub(crate) parts: Vec<ConcreteTypePart>
+}
 impl Default for ConcreteType {
     fn default() -> Self {
         Self{ parts: Vec::new() }
+    }
+}
 // TODO: Remove at some point
 #[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, serde::Deserialize)]
 pub enum PrimitiveType {
     Unassigned,
     Input,
     Output,
     Message,
     Boolean,
     Byte,
     Short,
     Int,
     Long,
     Symbolic(PrimitiveSymbolic)
+}
 // TODO: @cleanup, remove PartialEq implementations
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct PrimitiveSymbolic {
     // Phase 1: parser
     pub(crate) identifier: NamespacedIdentifier,
     // Phase 2: typing
     pub(crate) definition: Option<DefinitionId>
+}
 impl PartialEq for PrimitiveSymbolic {
     fn eq(&self, other: &Self) -> bool {
         self.identifier == other.identifier
+    }
+}
 impl Eq for PrimitiveSymbolic{}
 #[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, serde::Deserialize)]
 pub struct Type {
     pub primitive: PrimitiveType,
     pub array: bool,
+}
 #[allow(dead_code)]
 impl Type {
     pub const UNASSIGNED: Type = Type { primitive: PrimitiveType::Unassigned, array: false };
     pub const INPUT: Type = Type { primitive: PrimitiveType::Input, array: false };
     pub const OUTPUT: Type = Type { primitive: PrimitiveType::Output, array: false };
     pub const MESSAGE: Type = Type { primitive: PrimitiveType::Message, array: false };
     pub const BOOLEAN: Type = Type { primitive: PrimitiveType::Boolean, array: false };
     pub const BYTE: Type = Type { primitive: PrimitiveType::Byte, array: false };
     pub const SHORT: Type = Type { primitive: PrimitiveType::Short, array: false };
     pub const INT: Type = Type { primitive: PrimitiveType::Int, array: false };
     pub const LONG: Type = Type { primitive: PrimitiveType::Long, array: false };
     pub const INPUT_ARRAY: Type = Type { primitive: PrimitiveType::Input, array: true };
     pub const OUTPUT_ARRAY: Type = Type { primitive: PrimitiveType::Output, array: true };
     pub const MESSAGE_ARRAY: Type = Type { primitive: PrimitiveType::Message, array: true };
     pub const BOOLEAN_ARRAY: Type = Type { primitive: PrimitiveType::Boolean, array: true };
     pub const BYTE_ARRAY: Type = Type { primitive: PrimitiveType::Byte, array: true };
     pub const SHORT_ARRAY: Type = Type { primitive: PrimitiveType::Short, array: true };
     pub const INT_ARRAY: Type = Type { primitive: PrimitiveType::Int, array: true };
     pub const LONG_ARRAY: Type = Type { primitive: PrimitiveType::Long, array: true };
+}
 impl Display for Type {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         match &self.primitive {
             PrimitiveType::Unassigned => {
                 write!(f, "unassigned")?;
+            }
             PrimitiveType::Input => {
                 write!(f, "in")?;
+            }
             PrimitiveType::Output => {
                 write!(f, "out")?;
+            }
             PrimitiveType::Message => {
                 write!(f, "msg")?;
+            }
             PrimitiveType::Boolean => {
                 write!(f, "boolean")?;
+            }
             PrimitiveType::Byte => {
                 write!(f, "byte")?;
+            }
             PrimitiveType::Short => {
                 write!(f, "short")?;
+            }
             PrimitiveType::Int => {
                 write!(f, "int")?;
+            }
             PrimitiveType::Long => {
                 write!(f, "long")?;
+            }
             PrimitiveType::Symbolic(data) => {
                 // Type data is in ASCII range.
                 if let Some(id) = &data.definition {
                     write!(
                         f, "Symbolic({}, id: {})",
                         String::from_utf8_lossy(&data.identifier.value),
                         id.index
                     )?;
                 } else {
                     write!(
                         f, "Symbolic({}, id: Unresolved)",
                         String::from_utf8_lossy(&data.identifier.value)
                     )?;
+                }
+            }
+        }
         if self.array {
             write!(f, "[]")
         } else {
             Ok(())
+        }
+    }
+}
 type CharacterData = Vec<u8>;
 type IntegerData = i64;
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub enum Constant {
     Null, // message
     True,
     False,
     Character(CharacterData),
     Integer(IntegerData),
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub enum Method {
     Get,
     Put,
     Fires,
     Create,
     Symbolic(MethodSymbolic)
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct MethodSymbolic {
     pub(crate) identifier: NamespacedIdentifier,
     pub(crate) definition: Option<DefinitionId>
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub enum Field {
     Length,
     Symbolic(Identifier),
+}
 impl Field {
     pub fn is_length(&self) -> bool {
         match self {
             Field::Length => true,
             _ => false,
+        }
+    }
+}
 #[derive(Debug, Clone, Copy, serde::Serialize, serde::Deserialize)]
 pub enum Scope {
     Definition(DefinitionId),
     Regular(BlockStatementId),
     Synchronous((SynchronousStatementId, BlockStatementId)),
+}
@@ @@ -1528,193 +1535,192 @@ impl BlockStatement { @@
         let parent = self.parent_scope.unwrap();
         match parent {
             Scope::Definition(_) => {
                 // If the parent scope is a definition, then there is no
                 // parent block.
                 None
+            }
             Scope::Synchronous((parent, _)) => {
                 // It is always the case that when this function is called,
                 // the parent of a synchronous statement is a block statement:
                 // nested synchronous statements are flagged illegal,
                 // and that happens before resolving variables that
                 // creates the parent_scope references in the first place.
                 Some(h[parent].parent_scope(h).unwrap().to_block())
+            }
             Scope::Regular(parent) => {
                 // A variable scope is either a definition, sync, or block.
                 Some(parent)
+            }
+        }
+    }
     pub fn first(&self) -> StatementId {
         // It is an invariant (guaranteed by the lexer) that block statements have at least one stmt
         *self.statements.first().unwrap()
+    }
+}
 impl SyntaxElement for BlockStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 impl VariableScope for BlockStatement {
     fn parent_scope(&self, _h: &Heap) -> Option<Scope> {
         self.parent_scope.clone()
+    }
     fn get_variable(&self, h: &Heap, id: &Identifier) -> Option<VariableId> {
         for local_id in self.locals.iter() {
             let local = &h[*local_id];
             if local.identifier.value == id.value {
                 return Some(local_id.0);
+            }
+        }
         None
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub enum LocalStatement {
     Memory(MemoryStatement),
     Channel(ChannelStatement),
+}
 impl LocalStatement {
     pub fn this(&self) -> LocalStatementId {
         match self {
             LocalStatement::Memory(stmt) => stmt.this.upcast(),
             LocalStatement::Channel(stmt) => stmt.this.upcast(),
+        }
+    }
     pub fn as_memory(&self) -> &MemoryStatement {
         match self {
             LocalStatement::Memory(result) => result,
             _ => panic!("Unable to cast `LocalStatement` to `MemoryStatement`"),
+        }
+    }
     pub fn as_channel(&self) -> &ChannelStatement {
         match self {
             LocalStatement::Channel(result) => result,
             _ => panic!("Unable to cast `LocalStatement` to `ChannelStatement`"),
+        }
+    }
     pub fn next(&self) -> Option<StatementId> {
         match self {
             LocalStatement::Memory(stmt) => stmt.next,
             LocalStatement::Channel(stmt) => stmt.next,
+        }
+    }
+}
 impl SyntaxElement for LocalStatement {
     fn position(&self) -> InputPosition {
         match self {
             LocalStatement::Memory(stmt) => stmt.position(),
             LocalStatement::Channel(stmt) => stmt.position(),
+        }
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct MemoryStatement {
     pub this: MemoryStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub variable: LocalId,
     pub initial: ExpressionId,
     // Phase 2: linker
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for MemoryStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 /// ChannelStatement is the declaration of an input and output port associated
 /// with the same channel. Note that the polarity of the ports are from the
 /// point of view of the component. So an output port is something that a
 /// component uses to send data over (i.e. it is the "input end" of the
 /// channel), and vice versa.
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct ChannelStatement {
     pub this: ChannelStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub from: LocalId, // output
     pub to: LocalId,   // input
     // Phase 2: linker
     pub relative_pos_in_block: u32,
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for ChannelStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct SkipStatement {
     pub this: SkipStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     // Phase 2: linker
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for SkipStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct LabeledStatement {
     pub this: LabeledStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub label: Identifier,
     pub body: StatementId,
     // Phase 2: linker
     pub relative_pos_in_block: u32,
     pub in_sync: Option<SynchronousStatementId>,
+}
 impl SyntaxElement for LabeledStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct IfStatement {
     pub this: IfStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub test: ExpressionId,
     pub true_body: StatementId,
     pub false_body: StatementId,
     // Phase 2: linker
     pub end_if: Option<EndIfStatementId>,
+}
 impl SyntaxElement for IfStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct EndIfStatement {
     pub this: EndIfStatementId,
     // Phase 2: linker
     pub start_if: IfStatementId,
     pub position: InputPosition, // of corresponding if statement
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for EndIfStatement {
     fn position(&self) -> InputPosition {
         self.position
@@ @@ -1823,193 +1829,192 @@ impl VariableScope for SynchronousStatement { @@
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct EndSynchronousStatement {
     pub this: EndSynchronousStatementId,
     // Phase 2: linker
     pub position: InputPosition, // of corresponding sync statement
     pub start_sync: SynchronousStatementId,
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for EndSynchronousStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct ReturnStatement {
     pub this: ReturnStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub expression: ExpressionId,
+}
 impl SyntaxElement for ReturnStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct AssertStatement {
     pub this: AssertStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub expression: ExpressionId,
     // Phase 2: linker
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for AssertStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct GotoStatement {
     pub this: GotoStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub label: Identifier,
     // Phase 2: linker
     pub target: Option<LabeledStatementId>,
+}
 impl SyntaxElement for GotoStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct NewStatement {
     pub this: NewStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub expression: CallExpressionId,
     // Phase 2: linker
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for NewStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct ExpressionStatement {
     pub this: ExpressionStatementId,
     // Phase 1: parser
     pub position: InputPosition,
     pub expression: ExpressionId,
     // Phase 2: linker
     pub next: Option<StatementId>,
+}
 impl SyntaxElement for ExpressionStatement {
     fn position(&self) -> InputPosition {
         self.position
+    }
+}
 #[derive(Debug, PartialEq, Eq, Clone, Copy, serde::Serialize, serde::Deserialize)]
 pub enum ExpressionParent {
     None, // only set during initial parsing
     Memory(MemoryStatementId),
     If(IfStatementId),
     While(WhileStatementId),
     Return(ReturnStatementId),
     Assert(AssertStatementId),
     New(NewStatementId),
     ExpressionStmt(ExpressionStatementId),
     Expression(ExpressionId, u32) // index within expression (e.g LHS or RHS of expression)
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub enum Expression {
     Assignment(AssignmentExpression),
     Conditional(ConditionalExpression),
     Binary(BinaryExpression),
     Unary(UnaryExpression),
     Indexing(IndexingExpression),
     Slicing(SlicingExpression),
     Select(SelectExpression),
     Array(ArrayExpression),
     Constant(ConstantExpression),
     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 {
         match self {
             Expression::Unary(result) => result,
             _ => panic!("Unable to cast `Expression` to `UnaryExpression`"),
+        }
+    }
     pub fn as_indexing(&self) -> &IndexingExpression {
         match self {
             Expression::Indexing(result) => result,
             _ => panic!("Unable to cast `Expression` to `IndexingExpression`"),
+        }
+    }
     pub fn as_slicing(&self) -> &SlicingExpression {
         match self {
             Expression::Slicing(result) => result,
             _ => panic!("Unable to cast `Expression` to `SlicingExpression`"),
+        }
+    }
     pub fn as_select(&self) -> &SelectExpression {
         match self {
             Expression::Select(result) => result,
             _ => panic!("Unable to cast `Expression` to `SelectExpression`"),
+        }
+    }
     pub fn as_array(&self) -> &ArrayExpression {
         match self {
             Expression::Array(result) => result,
             _ => panic!("Unable to cast `Expression` to `ArrayExpression`"),
+        }
+    }
     pub fn as_constant(&self) -> &ConstantExpression {
         match self {
             Expression::Constant(result) => result,
             _ => panic!("Unable to cast `Expression` to `ConstantExpression`"),
+        }
+    }
     pub fn as_call(&self) -> &CallExpression {
         match self {
             Expression::Call(result) => result,
             _ => panic!("Unable to cast `Expression` to `CallExpression`"),
+        }
+    }
     pub fn as_call_mut(&mut self) -> &mut CallExpression {
         match self {
             Expression::Call(result) => result,
             _ => panic!("Unable to cast `Expression` to `CallExpression`"),
+        }
+    }
     pub fn as_variable(&self) -> &VariableExpression {
         match self {
             Expression::Variable(result) => result,
             _ => panic!("Unable to cast `Expression` to `VariableExpression`"),
+        }

src/protocol/ast_printer.rs

➞

Show inline comments

@@ @@ -268,194 +268,192 @@ impl ASTWriter { @@
     fn write_definition(&mut self, heap: &Heap, def_id: DefinitionId, indent: usize) {
         let indent2 = indent + 1;
         let indent3 = indent2 + 1;
         let indent4 = indent3 + 1;
         match &heap[def_id] {
             Definition::Struct(_) => todo!("implement Definition::Struct"),
             Definition::Enum(_) => todo!("implement Definition::Enum"),
             Definition::Function(def) => {
                 self.kv(indent).with_id(PREFIX_FUNCTION_ID, def.this.0.index)
                     .with_s_key("DefinitionFunction");
                 self.kv(indent2).with_s_key("Name").with_ascii_val(&def.identifier.value);
                 for poly_var_id in &def.poly_vars {
                     self.kv(indent3).with_s_key("PolyVar");
                     self.kv(indent4).with_s_key("Name").with_ascii_val(&poly_var_id.value);
+                }
                 self.kv(indent2).with_s_key("ReturnParserType").with_custom_val(|s| write_parser_type(s, heap, &heap[def.return_type]));
                 self.kv(indent2).with_s_key("Parameters");
                 for param_id in &def.parameters {
                     self.write_parameter(heap, *param_id, indent3);
+                }
                 self.kv(indent2).with_s_key("Body");
                 self.write_stmt(heap, def.body, indent3);
             },
             Definition::Component(def) => {
                 self.kv(indent).with_id(PREFIX_COMPONENT_ID,def.this.0.index)
                     .with_s_key("DefinitionComponent");
                 self.kv(indent2).with_s_key("Name").with_ascii_val(&def.identifier.value);
                 self.kv(indent2).with_s_key("Variant").with_debug_val(&def.variant);
                 self.kv(indent2).with_s_key("PolymorphicVariables");
                 for poly_var_id in &def.poly_vars {
                     self.kv(indent3).with_s_key("PolyVar");
                     self.kv(indent4).with_s_key("Name").with_ascii_val(&poly_var_id.value);
+                }
                 self.kv(indent2).with_s_key("Parameters");
                 for param_id in &def.parameters {
                     self.write_parameter(heap, *param_id, indent3)
+                }
                 self.kv(indent2).with_s_key("Body");
                 self.write_stmt(heap, def.body, indent3);
+            }
+        }
+    }
     fn write_parameter(&mut self, heap: &Heap, param_id: ParameterId, indent: usize) {
         let indent2 = indent + 1;
         let param = &heap[param_id];
         self.kv(indent).with_id(PREFIX_PARAMETER_ID, param_id.0.index)
             .with_s_key("Parameter");
         self.kv(indent2).with_s_key("Name").with_ascii_val(&param.identifier.value);
         self.kv(indent2).with_s_key("ParserType").with_custom_val(|w| write_parser_type(w, heap, &heap[param.parser_type]));
+    }
     fn write_stmt(&mut self, heap: &Heap, stmt_id: StatementId, indent: usize) {
         let stmt = &heap[stmt_id];
         let indent2 = indent + 1;
         let indent3 = indent2 + 1;
         match stmt {
             Statement::Block(stmt) => {
                 self.kv(indent).with_id(PREFIX_BLOCK_STMT_ID, stmt.this.0.index)
                     .with_s_key("Block");
                 for stmt_id in &stmt.statements {
                     self.write_stmt(heap, *stmt_id, indent2);
+                }
             },
             Statement::Local(stmt) => {
                 match stmt {
                     LocalStatement::Channel(stmt) => {
                         self.kv(indent).with_id(PREFIX_CHANNEL_STMT_ID, stmt.this.0.0.index)
                             .with_s_key("LocalChannel");
                         self.kv(indent2).with_s_key("From");
                         self.write_local(heap, stmt.from, indent3);
                         self.kv(indent2).with_s_key("To");
                         self.write_local(heap, stmt.to, indent3);
                         self.kv(indent2).with_s_key("Next")
                             .with_opt_disp_val(stmt.next.as_ref().map(|v| &v.index));
                     },
                     LocalStatement::Memory(stmt) => {
                         self.kv(indent).with_id(PREFIX_MEM_STMT_ID, stmt.this.0.0.index)
                             .with_s_key("LocalMemory");
                         self.kv(indent2).with_s_key("Variable");
                         self.write_local(heap, stmt.variable, indent3);
                         self.kv(indent2).with_s_key("initial");
                         self.write_expr(heap, stmt.initial, indent3);
                         self.kv(indent2).with_s_key("Next")
                             .with_opt_disp_val(stmt.next.as_ref().map(|v| &v.index));
+                    }
+                }
             },
             Statement::Skip(stmt) => {
                 self.kv(indent).with_id(PREFIX_SKIP_STMT_ID, stmt.this.0.index)
                     .with_s_key("Skip");
                 self.kv(indent2).with_s_key("Next")
                     .with_opt_disp_val(stmt.next.as_ref().map(|v| &v.index));
             },
             Statement::Labeled(stmt) => {
                 self.kv(indent).with_id(PREFIX_LABELED_STMT_ID, stmt.this.0.index)
                     .with_s_key("Labeled");
                 self.kv(indent2).with_s_key("Label").with_ascii_val(&stmt.label.value);
                 self.kv(indent2).with_s_key("Statement");
                 self.write_stmt(heap, stmt.body, indent3);
             },
             Statement::If(stmt) => {
                 self.kv(indent).with_id(PREFIX_IF_STMT_ID, stmt.this.0.index)
                     .with_s_key("If");
                 self.kv(indent2).with_s_key("EndIf")
                     .with_opt_disp_val(stmt.end_if.as_ref().map(|v| &v.0.index));
                 self.kv(indent2).with_s_key("Condition");
                 self.write_expr(heap, stmt.test, indent3);
                 self.kv(indent2).with_s_key("TrueBody");
                 self.write_stmt(heap, stmt.true_body, indent3);
                 self.kv(indent2).with_s_key("FalseBody");
                 self.write_stmt(heap, stmt.false_body, indent3);
             },
             Statement::EndIf(stmt) => {
                 self.kv(indent).with_id(PREFIX_ENDIF_STMT_ID, stmt.this.0.index)
                     .with_s_key("EndIf");
                 self.kv(indent2).with_s_key("StartIf").with_disp_val(&stmt.start_if.0.index);
                 self.kv(indent2).with_s_key("Next")
                     .with_opt_disp_val(stmt.next.as_ref().map(|v| &v.index));
             },
             Statement::While(stmt) => {
                 self.kv(indent).with_id(PREFIX_WHILE_STMT_ID, stmt.this.0.index)
                     .with_s_key("While");
                 self.kv(indent2).with_s_key("EndWhile")
                     .with_opt_disp_val(stmt.end_while.as_ref().map(|v| &v.0.index));
                 self.kv(indent2).with_s_key("InSync")
                     .with_opt_disp_val(stmt.in_sync.as_ref().map(|v| &v.0.index));
                 self.kv(indent2).with_s_key("Condition");
                 self.write_expr(heap, stmt.test, indent3);
                 self.kv(indent2).with_s_key("Body");
                 self.write_stmt(heap, stmt.body, indent3);
             },
             Statement::EndWhile(stmt) => {
                 self.kv(indent).with_id(PREFIX_ENDWHILE_STMT_ID, stmt.this.0.index)
                     .with_s_key("EndWhile");
                 self.kv(indent2).with_s_key("StartWhile").with_disp_val(&stmt.start_while.0.index);
                 self.kv(indent2).with_s_key("Next")
                     .with_opt_disp_val(stmt.next.as_ref().map(|v| &v.index));
             },
             Statement::Break(stmt) => {
                 self.kv(indent).with_id(PREFIX_BREAK_STMT_ID, stmt.this.0.index)
                     .with_s_key("Break");
                 self.kv(indent2).with_s_key("Label")
                     .with_opt_ascii_val(stmt.label.as_ref().map(|v| v.value.as_slice()));
                 self.kv(indent2).with_s_key("Target")
                     .with_opt_disp_val(stmt.target.as_ref().map(|v| &v.0.index));
             },
             Statement::Continue(stmt) => {
                 self.kv(indent).with_id(PREFIX_CONTINUE_STMT_ID, stmt.this.0.index)
                     .with_s_key("Continue");
                 self.kv(indent2).with_s_key("Label")
                     .with_opt_ascii_val(stmt.label.as_ref().map(|v| v.value.as_slice()));
                 self.kv(indent2).with_s_key("Target")
                     .with_opt_disp_val(stmt.target.as_ref().map(|v| &v.0.index));
             },
             Statement::Synchronous(stmt) => {
                 self.kv(indent).with_id(PREFIX_SYNC_STMT_ID, stmt.this.0.index)
                     .with_s_key("Synchronous");
                 self.kv(indent2).with_s_key("EndSync")
                     .with_opt_disp_val(stmt.end_sync.as_ref().map(|v| &v.0.index));
                 self.kv(indent2).with_s_key("Body");
                 self.write_stmt(heap, stmt.body, indent3);
             },
             Statement::EndSynchronous(stmt) => {
                 self.kv(indent).with_id(PREFIX_ENDSYNC_STMT_ID, stmt.this.0.index)
                     .with_s_key("EndSynchronous");
                 self.kv(indent2).with_s_key("StartSync").with_disp_val(&stmt.start_sync.0.index);
                 self.kv(indent2).with_s_key("Next")
                     .with_opt_disp_val(stmt.next.as_ref().map(|v| &v.index));
             },
             Statement::Return(stmt) => {
                 self.kv(indent).with_id(PREFIX_RETURN_STMT_ID, stmt.this.0.index)
                     .with_s_key("Return");
         PTV::Bool => { target.push_str("bool"); }
         PTV::Byte => { target.push_str("byte"); }
         PTV::Short => { target.push_str("short"); }
         PTV::Int => { target.push_str("int"); }
         PTV::Long => { target.push_str("long"); }
         PTV::String => { target.push_str("str"); }
         PTV::IntegerLiteral => { target.push_str("int_lit"); }
         PTV::Inferred => { target.push_str("auto"); }
         PTV::Symbolic(symbolic) => {
             target.push_str(&String::from_utf8_lossy(&symbolic.identifier.value));
             match symbolic.variant {
                 Some(SymbolicParserTypeVariant::PolyArg(def_id, idx)) => {
                     target.push_str(&format!("{{def: {}, idx: {}}}", def_id.index, idx));
                 },
                 Some(SymbolicParserTypeVariant::Definition(def_id)) => {
                     target.push_str(&format!("{{def: {}}}", def_id.index));
                 },
                 None => {
                     target.push_str("{None}");
+                }
+            }
             embedded.extend(&symbolic.poly_args);
+        }
     };
     if !embedded.is_empty() {
         target.push_str("<");
         for (idx, embedded_id) in embedded.into_iter().enumerate() {
             if idx != 0 { target.push_str(", "); }
             write_parser_type(target, heap, &heap[embedded_id]);
+        }
         target.push_str(">");
+    }
+}
 fn write_concrete_type(target: &mut String, heap: &Heap, t: &ConcreteType) {
     use ConcreteTypePart as CTP;
     fn write_concrete_part(target: &mut String, heap: &Heap, t: &ConcreteType, mut idx: usize) -> usize {
         if idx >= t.parts.len() {
             target.push_str("Programmer error: invalid concrete type tree");
             return idx;
+        }
         match &t.parts[idx] {
             CTP::Void => target.push_str("void"),
             CTP::Message => target.push_str("msg"),
             CTP::Bool => target.push_str("bool"),
             CTP::Byte => target.push_str("byte"),
             CTP::Short => target.push_str("short"),
             CTP::Int => target.push_str("int"),
             CTP::Long => target.push_str("long"),
             CTP::String => target.push_str("string"),
             CTP::Array => {
                 idx = write_concrete_part(target, heap, t, idx + 1);
                 target.push_str("[]");
             },
             CTP::Slice => {
                 idx = write_concrete_part(target, heap, t, idx + 1);
                 target.push_str("[..]");
+            }
             CTP::Input => {
                 target.push_str("in<");
                 idx = write_concrete_part(target, heap, t, idx + 1);
                 target.push('>');
             },
             CTP::Output => {
                 target.push_str("out<");
                 idx = write_concrete_part(target, heap, t, idx + 1);
                 target.push('>')
             },
             CTP::Instance(definition_id, num_embedded) => {
                 let identifier = heap[*definition_id].identifier();
                 target.push_str(&String::from_utf8_lossy(&identifier.value));
                 target.push('<');
                 for idx_embedded in 0..*num_embedded {
                     if idx_embedded != 0 {
                         target.push_str(", ");
+                    }
                     idx = write_concrete_part(target, heap, t, idx + 1);
+                }
                 target.push('>');
+            }
+        }
         idx + 1
+    }
     write_concrete_part(target, heap, t, 0);
+}
 fn write_expression_parent(target: &mut String, parent: &ExpressionParent) {
     use ExpressionParent as EP;
     *target = match parent {
         EP::None => String::from("None"),
         EP::Memory(id) => format!("MemoryStmt({})", id.0.0.index),
         EP::If(id) => format!("IfStmt({})", id.0.index),
         EP::While(id) => format!("WhileStmt({})", id.0.index),
         EP::Return(id) => format!("ReturnStmt({})", id.0.index),
         EP::Assert(id) => format!("AssertStmt({})", id.0.index),
         EP::New(id) => format!("NewStmt({})", id.0.index),
         EP::ExpressionStmt(id) => format!("ExprStmt({})", id.0.index),
         EP::Expression(id, idx) => format!("Expr({}, {})", id.index, idx)
     };
+}
@@ \ No newline at end of file @@

src/protocol/eval.rs

➞

Show inline comments

 use std::collections::HashMap;
 use std::fmt;
 use std::fmt::{Debug, Display, Formatter};
 use std::{i16, i32, i64, i8};
 use crate::common::*;
 use crate::protocol::ast::*;
 use crate::protocol::EvalContext;
 // const MAX_RECURSION: usize = 1024;
 const BYTE_MIN: i64 = i8::MIN as i64;
 const BYTE_MAX: i64 = i8::MAX as i64;
 const SHORT_MIN: i64 = i16::MIN as i64;
 const SHORT_MAX: i64 = i16::MAX as i64;
 const INT_MIN: i64 = i32::MIN as i64;
 const INT_MAX: i64 = i32::MAX as i64;
 const MESSAGE_MAX_LENGTH: i64 = SHORT_MAX;
 const ONE: Value = Value::Byte(ByteValue(1));
 // TODO: All goes one day anyway, so dirty typechecking hack
 trait ValueImpl {
     fn exact_type(&self) -> Type;
     fn is_type_compatible(&self, h: &Heap, t: &ParserType) -> bool {
         Self::is_type_compatible_hack(h, t)
+    }
     fn is_type_compatible_hack(h: &Heap, t: &ParserType) -> bool;
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub enum Value {
     Unassigned,
     Input(InputValue),
     Output(OutputValue),
     Message(MessageValue),
     Boolean(BooleanValue),
     Byte(ByteValue),
     Short(ShortValue),
     Int(IntValue),
     Long(LongValue),
     InputArray(InputArrayValue),
     OutputArray(OutputArrayValue),
     MessageArray(MessageArrayValue),
     BooleanArray(BooleanArrayValue),
     ByteArray(ByteArrayValue),
     ShortArray(ShortArrayValue),
     IntArray(IntArrayValue),
     LongArray(LongArrayValue),
+}
 impl Value {
     pub fn receive_message(buffer: &Payload) -> Value {
         Value::Message(MessageValue(Some(buffer.clone())))
+    }
     fn create_message(length: Value) -> Value {
         match length {
             Value::Byte(_) | Value::Short(_) | Value::Int(_) | Value::Long(_) => {
                 let length: i64 = i64::from(length);
                 if length < 0 || length > MESSAGE_MAX_LENGTH {
                     // Only messages within the expected length are allowed
                     Value::Message(MessageValue(None))
                 } else {
                     Value::Message(MessageValue(Some(Payload::new(length as usize))))
+                }
+            }
             _ => unimplemented!(),
+        }
+    }
     fn from_constant(constant: &Constant) -> Value {
         match constant {
             Constant::Null => Value::Message(MessageValue(None)),
             Constant::True => Value::Boolean(BooleanValue(true)),
             Constant::False => Value::Boolean(BooleanValue(false)),
             Constant::Integer(val) => {
                 // Convert raw ASCII data to UTF-8 string
                 let val = *val;
                 if val >= BYTE_MIN && val <= BYTE_MAX {
                     Value::Byte(ByteValue(val as i8))
                 } else if val >= SHORT_MIN && val <= SHORT_MAX {
                     Value::Short(ShortValue(val as i16))
                 } else if val >= INT_MIN && val <= INT_MAX {
                     Value::Int(IntValue(val as i32))
                 } else {
                     Value::Long(LongValue(val))
+                }
+            }
             Constant::Character(_data) => unimplemented!(),
+        }
+    }
     fn set(&mut self, index: &Value, value: &Value) -> Option<Value> {
         // The index must be of integer type, and non-negative
         let the_index: usize;
         match index {
             Value::Byte(_) | Value::Short(_) | Value::Int(_) | Value::Long(_) => {
                 let index = i64::from(index);
                 if index < 0 || index >= MESSAGE_MAX_LENGTH {
                     // It is inconsistent to update out of bounds
                     return None;
+                }
                 the_index = index.try_into().unwrap();
+            }
             _ => unreachable!(),
+        }
         // The subject must be either a message or an array
         // And the value and the subject must be compatible
         match (self, value) {
             (Value::Message(MessageValue(None)), _) => {
                 // It is inconsistent to update the null message
                 None
+            }
             (Value::Message(MessageValue(Some(payload))), Value::Byte(ByteValue(b))) => {
                 if *b < 0 {
                     // It is inconsistent to update with a negative value
                     return None;
+                }
                 if let Some(slot) = payload.as_mut_vec().get_mut(the_index) {
                     *slot = (*b).try_into().unwrap();
                     Some(value.clone())
                 } else {
                     // It is inconsistent to update out of bounds
                     None
+                }
+            }
             (Value::Message(MessageValue(Some(payload))), Value::Short(ShortValue(b))) => {
                 if *b < 0 || *b > BYTE_MAX as i16 {
                     // It is inconsistent to update with a negative value or a too large value
                     return None;
+                }
                 if let Some(slot) = payload.as_mut_vec().get_mut(the_index) {
@@ @@ -731,237 +732,240 @@ impl From<Value> for bool { @@
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<&Value> for bool {
     fn from(val: &Value) -> Self {
         match val {
             Value::Boolean(BooleanValue(b)) => *b,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<Value> for i8 {
     fn from(val: Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => b,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<&Value> for i8 {
     fn from(val: &Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => *b,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<Value> for i16 {
     fn from(val: Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => i16::from(b),
             Value::Short(ShortValue(s)) => s,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<&Value> for i16 {
     fn from(val: &Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => i16::from(*b),
             Value::Short(ShortValue(s)) => *s,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<Value> for i32 {
     fn from(val: Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => i32::from(b),
             Value::Short(ShortValue(s)) => i32::from(s),
             Value::Int(IntValue(i)) => i,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<&Value> for i32 {
     fn from(val: &Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => i32::from(*b),
             Value::Short(ShortValue(s)) => i32::from(*s),
             Value::Int(IntValue(i)) => *i,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<Value> for i64 {
     fn from(val: Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => i64::from(b),
             Value::Short(ShortValue(s)) => i64::from(s),
             Value::Int(IntValue(i)) => i64::from(i),
             Value::Long(LongValue(l)) => l,
             _ => unimplemented!(),
+        }
+    }
+}
 impl From<&Value> for i64 {
     fn from(val: &Value) -> Self {
         match val {
             Value::Byte(ByteValue(b)) => i64::from(*b),
             Value::Short(ShortValue(s)) => i64::from(*s),
             Value::Int(IntValue(i)) => i64::from(*i),
             Value::Long(LongValue(l)) => *l,
             _ => unimplemented!(),
+        }
+    }
+}
 impl ValueImpl for Value {
     fn exact_type(&self) -> Type {
         match self {
             Value::Unassigned => Type::UNASSIGNED,
             Value::Input(val) => val.exact_type(),
             Value::Output(val) => val.exact_type(),
             Value::Message(val) => val.exact_type(),
             Value::Boolean(val) => val.exact_type(),
             Value::Byte(val) => val.exact_type(),
             Value::Short(val) => val.exact_type(),
             Value::Int(val) => val.exact_type(),
             Value::Long(val) => val.exact_type(),
             Value::InputArray(val) => val.exact_type(),
             Value::OutputArray(val) => val.exact_type(),
             Value::MessageArray(val) => val.exact_type(),
             Value::BooleanArray(val) => val.exact_type(),
             Value::ByteArray(val) => val.exact_type(),
             Value::ShortArray(val) => val.exact_type(),
             Value::IntArray(val) => val.exact_type(),
             Value::LongArray(val) => val.exact_type(),
+        }
+    }
     fn is_type_compatible(&self, h: &Heap, t: &ParserType) -> bool {
         match self {
             Value::Unassigned => true,
             Value::Input(_) => InputValue::is_type_compatible_hack(h, t),
             Value::Output(_) => OutputValue::is_type_compatible_hack(h, t),
             Value::Message(_) => MessageValue::is_type_compatible_hack(h, t),
             Value::Boolean(_) => BooleanValue::is_type_compatible_hack(h, t),
             Value::Byte(_) => ByteValue::is_type_compatible_hack(h, t),
             Value::Short(_) => ShortValue::is_type_compatible_hack(h, t),
             Value::Int(_) => IntValue::is_type_compatible_hack(h, t),
             Value::Long(_) => LongValue::is_type_compatible_hack(h, t),
             Value::InputArray(_) => InputArrayValue::is_type_compatible_hack(h, t),
             Value::OutputArray(_) => OutputArrayValue::is_type_compatible_hack(h, t),
             Value::MessageArray(_) => MessageArrayValue::is_type_compatible_hack(h, t),
             Value::BooleanArray(_) => BooleanArrayValue::is_type_compatible_hack(h, t),
             Value::ByteArray(_) => ByteArrayValue::is_type_compatible_hack(h, t),
             Value::ShortArray(_) => ShortArrayValue::is_type_compatible_hack(h, t),
             Value::IntArray(_) => InputArrayValue::is_type_compatible_hack(h, t),
             Value::LongArray(_) => LongArrayValue::is_type_compatible_hack(h, t),
+        }
+    }
     fn is_type_compatible_hack(_h: &Heap, _t: &ParserType) -> bool { false }
+}
 impl Display for Value {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         let disp: &dyn Display;
         match self {
             Value::Unassigned => disp = &Type::UNASSIGNED,
             Value::Input(val) => disp = val,
             Value::Output(val) => disp = val,
             Value::Message(val) => disp = val,
             Value::Boolean(val) => disp = val,
             Value::Byte(val) => disp = val,
             Value::Short(val) => disp = val,
             Value::Int(val) => disp = val,
             Value::Long(val) => disp = val,
             Value::InputArray(val) => disp = val,
             Value::OutputArray(val) => disp = val,
             Value::MessageArray(val) => disp = val,
             Value::BooleanArray(val) => disp = val,
             Value::ByteArray(val) => disp = val,
             Value::ShortArray(val) => disp = val,
             Value::IntArray(val) => disp = val,
             Value::LongArray(val) => disp = val,
+        }
         disp.fmt(f)
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct InputValue(pub PortId);
 impl Display for InputValue {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         write!(f, "#in")
+    }
+}
 impl ValueImpl for InputValue {
     fn exact_type(&self) -> Type {
         Type::INPUT
+    }
     fn is_type_compatible_hack(_h: &Heap, t: &ParserType) -> bool {
         return if let ParserTypeVariant::Input(_) = t.variant { true } else { false }
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct OutputValue(pub PortId);
 impl Display for OutputValue {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         write!(f, "#out")
+    }
+}
 impl ValueImpl for OutputValue {
     fn exact_type(&self) -> Type {
         Type::OUTPUT
+    }
     fn is_type_compatible_hack(_h: &Heap, t: &ParserType) -> bool {
         return if let ParserTypeVariant::Output(_) = t.variant { true } else { false }
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct MessageValue(pub Option<Payload>);
 impl Display for MessageValue {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         match &self.0 {
             None => write!(f, "null"),
             Some(payload) => {
                 // format print up to 10 bytes
                 let mut slice = payload.as_slice();
                 if slice.len() > 10 {
                     slice = &slice[..10];
+                }
                 f.debug_list().entries(slice.iter().copied()).finish()
+            }
+        }
+    }
+}
 impl ValueImpl for MessageValue {
     fn exact_type(&self) -> Type {
         Type::MESSAGE
+    }
     fn is_type_compatible_hack(_h: &Heap, t: &ParserType) -> bool {
         return if let ParserTypeVariant::Message = t.variant { true } else { false };
+    }
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub struct BooleanValue(bool);
 impl Display for BooleanValue {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         write!(f, "{}", self.0)
+    }
+}
 impl ValueImpl for BooleanValue {
     fn exact_type(&self) -> Type {
@@ @@ -1501,196 +1505,194 @@ impl Store { @@
             Expression::Call(expr) => match &expr.method {
                 Method::Get => {
                     assert_eq!(1, expr.arguments.len());
                     let value = self.eval(h, ctx, expr.arguments[0])?;
                     match ctx.get(value.clone()) {
                         None => Err(EvalContinuation::BlockGet(value)),
                         Some(result) => Ok(result),
+                    }
+                }
                 Method::Put => {
                     assert_eq!(2, expr.arguments.len());
                     let port_value = self.eval(h, ctx, expr.arguments[0])?;
                     let msg_value = self.eval(h, ctx, expr.arguments[1])?;
                     println!("DEBUG: Handiling put({:?}, {:?})", port_value, msg_value);
                     if ctx.did_put(port_value.clone()) {
                         println!("DEBUG: Already put...");
                         // Return bogus, replacing this at some point anyway
                         Ok(Value::Message(MessageValue(None)))
                     } else {
                         println!("DEBUG: Did not yet put...");
                         Err(EvalContinuation::Put(port_value, msg_value))
+                    }
+                }
                 Method::Fires => {
                     assert_eq!(1, expr.arguments.len());
                     let value = self.eval(h, ctx, expr.arguments[0])?;
                     match ctx.fires(value.clone()) {
                         None => Err(EvalContinuation::BlockFires(value)),
                         Some(result) => Ok(result),
+                    }
+                }
                 Method::Create => {
                     assert_eq!(1, expr.arguments.len());
                     let length = self.eval(h, ctx, expr.arguments[0])?;
                     Ok(Value::create_message(length))
+                }
                 Method::Symbolic(_symbol) => unimplemented!(),
             },
             Expression::Variable(expr) => self.get(h, ctx, expr.this.upcast()),
+        }
+    }
+}
 type EvalResult = Result<Value, EvalContinuation>;
 pub enum EvalContinuation {
     Stepping,
     Inconsistent,
     Terminal,
     SyncBlockStart,
     SyncBlockEnd,
     NewComponent(DefinitionId, Vec<Value>),
     BlockFires(Value),
     BlockGet(Value),
     Put(Value, Value),
+}
 #[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]
 pub(crate) struct Prompt {
     definition: DefinitionId,
     store: Store,
     position: Option<StatementId>,
+}
 impl Prompt {
     pub fn new(h: &Heap, def: DefinitionId, args: &Vec<Value>) -> Self {
         let mut prompt =
             Prompt { definition: def, store: Store::new(), position: Some((&h[def]).body()) };
         prompt.set_arguments(h, args);
         prompt
+    }
     fn set_arguments(&mut self, h: &Heap, args: &Vec<Value>) {
         let def = &h[self.definition];
         let params = def.parameters();
         assert_eq!(params.len(), args.len());
         for (param, value) in params.iter().zip(args.iter()) {
             let hparam = &h[*param];
             let parser_type = &h[hparam.parser_type];
             assert!(value.is_type_compatible(h, parser_type));
             self.store.initialize(h, param.upcast(), value.clone());
+        }
+    }
     pub fn step(&mut self, h: &Heap, ctx: &mut EvalContext) -> EvalResult {
         if self.position.is_none() {
             return Err(EvalContinuation::Terminal);
+        }
         let stmt = &h[self.position.unwrap()];
         match stmt {
             Statement::Block(stmt) => {
                 // Continue to first statement
                 self.position = Some(stmt.first());
                 Err(EvalContinuation::Stepping)
+            }
             Statement::Local(stmt) => {
                 match stmt {
                     LocalStatement::Memory(stmt) => {
                         // Evaluate initial expression
                         let value = self.store.eval(h, ctx, stmt.initial)?;
                         // Update store
-                        self.store.initialize(h, stmt.variable.upcast(), value);
+                        self.store.initialize(h, stmt.variable.upcast(), Value::Unassigned);
+                    }
                     LocalStatement::Channel(stmt) => {
                         let [from, to] = ctx.new_channel();
                         // Store the values in the declared variables
                         self.store.initialize(h, stmt.from.upcast(), from);
                         self.store.initialize(h, stmt.to.upcast(), to);
+                    }
+                }
                 // Continue to next statement
                 self.position = stmt.next();
                 Err(EvalContinuation::Stepping)
+            }
             Statement::Skip(stmt) => {
                 // Continue to next statement
                 self.position = stmt.next;
                 Err(EvalContinuation::Stepping)
+            }
             Statement::Labeled(stmt) => {
                 // Continue to next statement
                 self.position = Some(stmt.body);
                 Err(EvalContinuation::Stepping)
+            }
             Statement::If(stmt) => {
                 // Evaluate test
                 let value = self.store.eval(h, ctx, stmt.test)?;
                 // Continue with either branch
                 if value.as_boolean().0 {
                     self.position = Some(stmt.true_body);
                 } else {
                     self.position = Some(stmt.false_body);
+                }
                 Err(EvalContinuation::Stepping)
+            }
             Statement::EndIf(stmt) => {
                 // Continue to next statement
                 self.position = stmt.next;
                 Err(EvalContinuation::Stepping)
+            }
             Statement::While(stmt) => {
                 // Evaluate test
                 let value = self.store.eval(h, ctx, stmt.test)?;
                 // Either continue with body, or go to next
                 if value.as_boolean().0 {
                     self.position = Some(stmt.body);
                 } else {
                     self.position = stmt.end_while.map(|x| x.upcast());
+                }
                 Err(EvalContinuation::Stepping)
+            }
             Statement::EndWhile(stmt) => {
                 // Continue to next statement
                 self.position = stmt.next;
                 Err(EvalContinuation::Stepping)
+            }
             Statement::Synchronous(stmt) => {
                 // Continue to next statement, and signal upward
                 self.position = Some(stmt.body);
                 Err(EvalContinuation::SyncBlockStart)
+            }
             Statement::EndSynchronous(stmt) => {
                 // Continue to next statement, and signal upward
                 self.position = stmt.next;
                 Err(EvalContinuation::SyncBlockEnd)
+            }
             Statement::Break(stmt) => {
                 // Continue to end of while
                 self.position = stmt.target.map(EndWhileStatementId::upcast);
                 Err(EvalContinuation::Stepping)
+            }
             Statement::Continue(stmt) => {
                 // Continue to beginning of while
                 self.position = stmt.target.map(WhileStatementId::upcast);
                 Err(EvalContinuation::Stepping)
+            }
             Statement::Assert(stmt) => {
                 // Evaluate expression
                 let value = self.store.eval(h, ctx, stmt.expression)?;
                 if value.as_boolean().0 {
                     // Continue to next statement
                     self.position = stmt.next;
                     Err(EvalContinuation::Stepping)
                 } else {
                     // Assertion failed: inconsistent
                     Err(EvalContinuation::Inconsistent)
+                }
+            }
             Statement::Return(stmt) => {
                 // Evaluate expression
                 let value = self.store.eval(h, ctx, stmt.expression)?;
                 // Done with evaluation
                 Ok(value)
+            }
             Statement::Goto(stmt) => {
                 // Continue to target
                 self.position = stmt.target.map(|x| x.upcast());
                 Err(EvalContinuation::Stepping)

src/protocol/lexer.rs

➞

Show inline comments

@@ @@ -562,193 +562,192 @@ impl Lexer<'_> { @@
         let backup_pos = self.source.pos();
         if !self.maybe_consume_type_spilled_without_pos_recovery() {
             self.source.seek(backup_pos);
             return false;
+        }
         return true;
+    }
     /// Attempts to consume polymorphic arguments without returning them. If it
     /// doesn't encounter well-formed polymorphic arguments, then the input
     /// position is left at a "random" position.
     fn maybe_consume_poly_args_spilled_without_pos_recovery(&mut self) -> bool {
         if let Some(b'<') = self.source.next() {
             self.source.consume();
             if self.consume_whitespace(false).is_err() { return false; }
             loop {
                 if !self.maybe_consume_type_spilled_without_pos_recovery() { return false; }
                 if self.consume_whitespace(false).is_err() { return false; }
                 let has_comma = self.source.next() == Some(b',');
                 if has_comma {
                     self.source.consume();
                     if self.consume_whitespace(false).is_err() { return false; }
+                }
                 if let Some(b'>') = self.source.next() {
                     self.source.consume();
                     break;
                 } else if !has_comma {
                     return false;
+                }
+            }
+        }
         return true;
+    }
     /// Consumes polymorphic arguments and its delimiters if specified. The
     /// input position may be at whitespace. If polyargs are present then the
     /// whitespace and the args are consumed and the input position will be
     /// placed after the polyarg list. If polyargs are not present then the
     /// input position will remain unmodified and an empty vector will be
     /// returned.
     ///
     /// Polymorphic arguments represent the specification of the parametric
     /// types of a polymorphic type: they specify the value of the polymorphic
     /// type's polymorphic variables.
     fn consume_polymorphic_args(&mut self, h: &mut Heap, allow_inference: bool) -> Result<Vec<ParserTypeId>, ParseError2> {
         let backup_pos = self.source.pos();
         self.consume_whitespace(false)?;
         if let Some(b'<') = self.source.next() {
             // Has polymorphic args, at least one type must be specified
             self.source.consume();
             self.consume_whitespace(false)?;
             let mut poly_args = Vec::new();
             loop {
                 // TODO: @cleanup, remove the no_more_types var
                 poly_args.push(self.consume_type2(h, allow_inference)?);
                 self.consume_whitespace(false)?;
                 let has_comma = self.source.next() == Some(b',');
                 if has_comma {
                     // We might not actually be getting more types when the
                     // comma is at the end of the line, and we get a closing
                     // angular bracket on the next line.
                     self.source.consume();
                     self.consume_whitespace(false)?;
+                }
                 if let Some(b'>') = self.source.next() {
                     self.source.consume();
                     break;
                 } else if !has_comma {
                     return Err(ParseError2::new_error(
                         &self.source, self.source.pos(),
                         "Expected the end of the polymorphic argument list"
                     ))
+                }
+            }
             Ok(poly_args)
         } else {
             // No polymorphic args
             self.source.seek(backup_pos);
             Ok(vec!())
+        }
+    }
     /// Consumes polymorphic variables. These are identifiers that are used
     /// within polymorphic types. The input position may be at whitespace. If
     /// polymorphic variables are present then the whitespace, wrapping
     /// delimiters and the polymorphic variables are consumed. Otherwise the
     /// input position will stay where it is. If no polymorphic variables are
     /// present then an empty vector will be returned.
     fn consume_polymorphic_vars(&mut self) -> Result<Vec<Identifier>, ParseError2> {
         let backup_pos = self.source.pos();
         self.consume_whitespace(false)?;
         if let Some(b'<') = self.source.next() {
             // Found the opening delimiter, we want at least one polyvar
             self.source.consume();
             self.consume_whitespace(false)?;
             let mut poly_vars = Vec::new();
             loop {
                 poly_vars.push(self.consume_identifier()?);
                 self.consume_whitespace(false)?;
                 let has_comma = self.source.next() == Some(b',');
                 if has_comma {
                     // We may get another variable
                     self.source.consume();
                     self.consume_whitespace(false)?;
+                }
                 if let Some(b'>') = self.source.next() {
                     self.source.consume();
                     break;
                 } else if !has_comma {
                     return Err(ParseError2::new_error(
                         &self.source, self.source.pos(),
                         "Expected the end of the polymorphic variable list"
                     ))
+                }
+            }
             Ok(poly_vars)
         } else {
             // No polymorphic args
             self.source.seek(backup_pos);
             Ok(vec!())
+        }
+    }
     // Parameters
     fn consume_parameter(&mut self, h: &mut Heap) -> Result<ParameterId, ParseError2> {
         let parser_type = self.consume_type2(h, false)?;
         self.consume_whitespace(true)?;
         let position = self.source.pos();
         let identifier = self.consume_identifier()?;
         let id =
             h.alloc_parameter(|this| Parameter { this, position, parser_type, identifier });
         Ok(id)
+    }
     fn consume_parameters(
         &mut self,
         h: &mut Heap,
         params: &mut Vec<ParameterId>,
     ) -> Result<(), ParseError2> {
         self.consume_string(b"(")?;
         self.consume_whitespace(false)?;
         if !self.has_string(b")") {
             while self.source.next().is_some() {
                 params.push(self.consume_parameter(h)?);
                 self.consume_whitespace(false)?;
                 if self.has_string(b")") {
                     break;
+                }
                 self.consume_string(b",")?;
                 self.consume_whitespace(false)?;
+            }
+        }
         self.consume_string(b")")?;
         Ok(())
+    }
     // ====================
     // Expressions
     // ====================
     fn consume_paren_expression(&mut self, h: &mut Heap) -> Result<ExpressionId, ParseError2> {
         self.consume_string(b"(")?;
         self.consume_whitespace(false)?;
         let result = self.consume_expression(h)?;
         self.consume_whitespace(false)?;
         self.consume_string(b")")?;
         Ok(result)
+    }
     fn consume_expression(&mut self, h: &mut Heap) -> Result<ExpressionId, ParseError2> {
         if self.level >= MAX_LEVEL {
             return Err(self.error_at_pos("Too deeply nested expression"));
+        }
         self.level += 1;
         let result = self.consume_assignment_expression(h);
         self.level -= 1;
         result
+    }
     fn consume_assignment_expression(&mut self, h: &mut Heap) -> Result<ExpressionId, ParseError2> {
         let result = self.consume_conditional_expression(h)?;
         self.consume_whitespace(false)?;
         if self.has_assignment_operator() {
             let position = self.source.pos();
@@ @@ -1542,310 +1541,346 @@ impl Lexer<'_> { @@
         // To prevent ambiguity with expression statements consisting only of an
         // identifier or a namespaced identifier, we look ahead and match on the
         // *single* colon that signals a labeled statement.
         let backup_pos = self.source.pos();
         let mut result = false;
         if self.consume_identifier_spilled().is_ok() {
             // next character is ':', second character is NOT ':'
             result = Some(b':') == self.source.next() && Some(b':') != self.source.lookahead(1)
+        }
         self.source.seek(backup_pos);
         return result;
+    }
     fn consume_statement_impl(&mut self, h: &mut Heap, wrap_in_block: bool) -> Result<StatementId, ParseError2> {
         // Parse and allocate statement
         let mut must_wrap = true;
         let mut stmt_id = if self.has_string(b"{") {
             must_wrap = false;
             self.consume_block_statement(h)?
         } else if self.has_keyword(b"skip") {
             must_wrap = false;
             self.consume_skip_statement(h)?.upcast()
         } else if self.has_keyword(b"if") {
             self.consume_if_statement(h)?.upcast()
         } else if self.has_keyword(b"while") {
             self.consume_while_statement(h)?.upcast()
         } else if self.has_keyword(b"break") {
             self.consume_break_statement(h)?.upcast()
         } else if self.has_keyword(b"continue") {
             self.consume_continue_statement(h)?.upcast()
         } else if self.has_keyword(b"synchronous") {
             self.consume_synchronous_statement(h)?.upcast()
         } else if self.has_keyword(b"return") {
             self.consume_return_statement(h)?.upcast()
         } else if self.has_keyword(b"assert") {
             self.consume_assert_statement(h)?.upcast()
         } else if self.has_keyword(b"goto") {
             self.consume_goto_statement(h)?.upcast()
         } else if self.has_keyword(b"new") {
             self.consume_new_statement(h)?.upcast()
         } else if self.has_label() {
             self.consume_labeled_statement(h)?.upcast()
         } else {
             self.consume_expression_statement(h)?.upcast()
         };
         // Wrap if desired and if needed
         if must_wrap && wrap_in_block {
             let position = h[stmt_id].position();
             let block_wrapper = h.alloc_block_statement(|this| BlockStatement{
                 this,
                 position,
                 statements: vec![stmt_id],
                 parent_scope: None,
                 relative_pos_in_parent: 0,
                 locals: Vec::new(),
                 labels: Vec::new()
             });
             stmt_id = block_wrapper.upcast();
+        }
         Ok(stmt_id)
+    }
     fn has_local_statement(&mut self) -> bool {
         /* To avoid ambiguity, we look ahead to find either the
         channel keyword that signals a variable declaration, or
         a type annotation followed by another identifier.
         Example:
           my_type[] x = {5}; // memory statement
           my_var[5] = x; // assignment expression, expression statement
         Note how both the local and the assignment
         start with arbitrary identifier followed by [. */
         if self.has_keyword(b"channel") {
             return true;
+        }
         if self.has_statement_keyword() {
             return false;
+        }
         let backup_pos = self.source.pos();
         let mut result = false;
         if self.maybe_consume_type_spilled_without_pos_recovery() {
             // We seem to have a valid type, do we now have an identifier?
             if self.consume_whitespace(true).is_ok() {
                 result = self.has_identifier();
+            }
+        }
         self.source.seek(backup_pos);
         return result;
+    }
     fn consume_block_statement(&mut self, h: &mut Heap) -> Result<StatementId, ParseError2> {
         let position = self.source.pos();
         let mut statements = Vec::new();
         self.consume_string(b"{")?;
         self.consume_whitespace(false)?;
         while self.has_local_statement() {
             statements.push(self.consume_local_statement(h)?.upcast());
             let (local_id, stmt_id) = self.consume_local_statement(h)?;
             statements.push(local_id.upcast());
             if let Some(stmt_id) = stmt_id {
                 statements.push(stmt_id.upcast());
+            }
             self.consume_whitespace(false)?;
+        }
         while !self.has_string(b"}") {
             statements.push(self.consume_statement(h, false)?);
             self.consume_whitespace(false)?;
+        }
         self.consume_string(b"}")?;
         if statements.is_empty() {
             Ok(h.alloc_skip_statement(|this| SkipStatement { this, position, next: None }).upcast())
         } else {
             Ok(h.alloc_block_statement(|this| BlockStatement {
                 this,
                 position,
                 statements,
                 parent_scope: None,
                 relative_pos_in_parent: 0,
                 locals: Vec::new(),
                 labels: Vec::new(),
             })
             .upcast())
+        }
+    }
     fn consume_local_statement(&mut self, h: &mut Heap) -> Result<LocalStatementId, ParseError2> {
+    fn consume_local_statement(&mut self, h: &mut Heap) -> Result<(LocalStatementId, Option<ExpressionStatementId>), ParseError2> {
         if self.has_keyword(b"channel") {
             Ok(self.consume_channel_statement(h)?.upcast())
             let local_id = self.consume_channel_statement(h)?.upcast();
             Ok((local_id, None))
         } else {
             Ok(self.consume_memory_statement(h)?.upcast())
             let (memory_id, stmt_id) = self.consume_memory_statement(h)?;
             Ok((memory_id.upcast(), Some(stmt_id)))
+        }
+    }
     fn consume_channel_statement(
         &mut self,
         h: &mut Heap,
     ) -> Result<ChannelStatementId, ParseError2> {
         // Consume channel statement and polymorphic argument if specified
         let position = self.source.pos();
         self.consume_keyword(b"channel")?;
         let poly_args = self.consume_polymorphic_args(h, true)?;
         let poly_arg_id = match poly_args.len() {
 => h.alloc_parser_type(|this| ParserType{
                 this, pos: position.clone(), variant: ParserTypeVariant::Inferred,
             }),
 => poly_args[0],
             _ => return Err(ParseError2::new_error(
                 &self.source, self.source.pos(),
                 "port construction using 'channel' accepts up to 1 polymorphic argument"
             ))
         };
         self.consume_whitespace(true)?;
         // Consume the output port
         let out_parser_type = h.alloc_parser_type(|this| ParserType{
             this, pos: position.clone(), variant: ParserTypeVariant::Output(poly_arg_id)
         });
         let out_identifier = self.consume_identifier()?;
         // Consume the "->" syntax
         self.consume_whitespace(false)?;
         self.consume_string(b"->")?;
         self.consume_whitespace(false)?;
         // Consume the input port
         // TODO: Unsure about this, both ports refer to the same ParserType, is this ok?
         let in_parser_type = h.alloc_parser_type(|this| ParserType{
             this, pos: position.clone(), variant: ParserTypeVariant::Input(poly_arg_id)
         });
         let in_identifier = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         let out_port = h.alloc_local(|this| Local {
             this,
             position,
             parser_type: out_parser_type,
             identifier: out_identifier,
             relative_pos_in_block: 0
         });
         let in_port = h.alloc_local(|this| Local {
             this,
             position,
             parser_type: in_parser_type,
             identifier: in_identifier,
             relative_pos_in_block: 0
         });
         Ok(h.alloc_channel_statement(|this| ChannelStatement {
             this,
             position,
             from: out_port,
             to: in_port,
             relative_pos_in_block: 0,
             next: None,
         }))
+    }
     fn consume_memory_statement(&mut self, h: &mut Heap) -> Result<MemoryStatementId, ParseError2> {
+    fn consume_memory_statement(&mut self, h: &mut Heap) -> Result<(MemoryStatementId, ExpressionStatementId), ParseError2> {
         let position = self.source.pos();
         let parser_type = self.consume_type2(h, true)?;
         self.consume_whitespace(true)?;
         let identifier = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         let assignment_position = self.source.pos();
         self.consume_string(b"=")?;
         self.consume_whitespace(false)?;
         let initial = self.consume_expression(h)?;
         let variable = h.alloc_local(|this| Local {
             this,
             position,
             parser_type,
             identifier,
+            identifier: identifier.clone(),
             relative_pos_in_block: 0
         });
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         Ok(h.alloc_memory_statement(|this| MemoryStatement {
         // Transform into the variable declaration, followed by an assignment
         let memory_stmt_id = h.alloc_memory_statement(|this| MemoryStatement {
             this,
             position,
             variable,
             initial,
             next: None,
         }))
         });
         let variable_expr_id = h.alloc_variable_expression(|this| VariableExpression{
             this,
             position: identifier.position.clone(),
             identifier: NamespacedIdentifier {
                 position: identifier.position.clone(),
                 num_namespaces: 1,
                 value: identifier.value.clone(),
             },
             declaration: None,
             parent: ExpressionParent::None,
             concrete_type: Default::default()
         });
         let assignment_expr_id = h.alloc_assignment_expression(|this| AssignmentExpression{
             this,
             position: assignment_position,
             left: variable_expr_id.upcast(),
             operation: AssignmentOperator::Set,
             right: initial,
             parent: ExpressionParent::None,
             concrete_type: Default::default()
         });
         let assignment_stmt_id = h.alloc_expression_statement(|this| ExpressionStatement{
             this,
             position,
             expression: assignment_expr_id.upcast(),
             next: None
         });
         Ok((memory_stmt_id, assignment_stmt_id))
+    }
     fn consume_labeled_statement(
         &mut self,
         h: &mut Heap,
     ) -> Result<LabeledStatementId, ParseError2> {
         let position = self.source.pos();
         let label = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         self.consume_string(b":")?;
         self.consume_whitespace(false)?;
         let body = self.consume_statement(h, false)?;
         Ok(h.alloc_labeled_statement(|this| LabeledStatement {
             this,
             position,
             label,
             body,
             relative_pos_in_block: 0,
             in_sync: None,
         }))
+    }
     fn consume_skip_statement(&mut self, h: &mut Heap) -> Result<SkipStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"skip")?;
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         Ok(h.alloc_skip_statement(|this| SkipStatement { this, position, next: None }))
+    }
     fn consume_if_statement(&mut self, h: &mut Heap) -> Result<IfStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"if")?;
         self.consume_whitespace(false)?;
         let test = self.consume_paren_expression(h)?;
         self.consume_whitespace(false)?;
         let true_body = self.consume_statement(h, true)?;
         self.consume_whitespace(false)?;
         let false_body = if self.has_keyword(b"else") {
             self.consume_keyword(b"else")?;
             self.consume_whitespace(false)?;
             self.consume_statement(h, true)?
         } else {
             h.alloc_skip_statement(|this| SkipStatement { this, position, next: None }).upcast()
         };
         Ok(h.alloc_if_statement(|this| IfStatement { this, position, test, true_body, false_body, end_if: None }))
+    }
     fn consume_while_statement(&mut self, h: &mut Heap) -> Result<WhileStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"while")?;
         self.consume_whitespace(false)?;
         let test = self.consume_paren_expression(h)?;
         self.consume_whitespace(false)?;
         let body = self.consume_statement(h, true)?;
         Ok(h.alloc_while_statement(|this| WhileStatement {
             this,
             position,
             test,
             body,
             end_while: None,
             in_sync: None,
         }))
+    }
     fn consume_break_statement(&mut self, h: &mut Heap) -> Result<BreakStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"break")?;
         self.consume_whitespace(false)?;
         let label;
         if self.has_identifier() {
             label = Some(self.consume_identifier()?);
             self.consume_whitespace(false)?;
         } else {
             label = None;
+        }
         self.consume_string(b";")?;
         Ok(h.alloc_break_statement(|this| BreakStatement { this, position, label, target: None }))
+    }
     fn consume_continue_statement(
         &mut self,
         h: &mut Heap,
     ) -> Result<ContinueStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"continue")?;
         self.consume_whitespace(false)?;
         let label;
         if self.has_identifier() {
             label = Some(self.consume_identifier()?);
             self.consume_whitespace(false)?;
         } else {
             label = None;
+        }
         self.consume_string(b";")?;
         Ok(h.alloc_continue_statement(|this| ContinueStatement {
             this,
             position,
             label,
             target: None,
         }))
+    }
@@ @@ -1872,396 +1907,401 @@ impl Lexer<'_> { @@
             end_sync: None,
             parent_scope: None,
         }))
+    }
     fn consume_return_statement(&mut self, h: &mut Heap) -> Result<ReturnStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"return")?;
         self.consume_whitespace(false)?;
         let expression = if self.has_string(b"(") {
             self.consume_paren_expression(h)
         } else {
             self.consume_expression(h)
         }?;
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         Ok(h.alloc_return_statement(|this| ReturnStatement { this, position, expression }))
+    }
     fn consume_assert_statement(&mut self, h: &mut Heap) -> Result<AssertStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"assert")?;
         self.consume_whitespace(false)?;
         let expression = if self.has_string(b"(") {
             self.consume_paren_expression(h)
         } else {
             self.consume_expression(h)
         }?;
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         Ok(h.alloc_assert_statement(|this| AssertStatement {
             this,
             position,
             expression,
             next: None,
         }))
+    }
     fn consume_goto_statement(&mut self, h: &mut Heap) -> Result<GotoStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"goto")?;
         self.consume_whitespace(false)?;
         let label = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         Ok(h.alloc_goto_statement(|this| GotoStatement { this, position, label, target: None }))
+    }
     fn consume_new_statement(&mut self, h: &mut Heap) -> Result<NewStatementId, ParseError2> {
         let position = self.source.pos();
         self.consume_keyword(b"new")?;
         self.consume_whitespace(false)?;
         let expression = self.consume_call_expression(h)?;
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         Ok(h.alloc_new_statement(|this| NewStatement { this, position, expression, next: None }))
+    }
     fn consume_expression_statement(
         &mut self,
         h: &mut Heap,
     ) -> Result<ExpressionStatementId, ParseError2> {
         let position = self.source.pos();
         let expression = self.consume_expression(h)?;
         self.consume_whitespace(false)?;
         self.consume_string(b";")?;
         Ok(h.alloc_expression_statement(|this| ExpressionStatement {
             this,
             position,
             expression,
             next: None,
         }))
+    }
     // ====================
     // Symbol definitions
     // ====================
     fn has_symbol_definition(&self) -> bool {
         self.has_keyword(b"composite")
             || self.has_keyword(b"primitive")
             || self.has_type_keyword()
             || self.has_identifier()
+    }
     fn consume_symbol_definition(&mut self, h: &mut Heap) -> Result<DefinitionId, ParseError2> {
         if self.has_keyword(b"struct") {
             Ok(self.consume_struct_definition(h)?.upcast())
         } else if self.has_keyword(b"enum") {
             Ok(self.consume_enum_definition(h)?.upcast())
         } else if self.has_keyword(b"composite") || self.has_keyword(b"primitive") {
             Ok(self.consume_component_definition(h)?.upcast())
         } else {
             Ok(self.consume_function_definition(h)?.upcast())
+        }
+    }
     fn consume_struct_definition(&mut self, h: &mut Heap) -> Result<StructId, ParseError2> {
         // Parse "struct" keyword, optional polyvars and its identifier
         let struct_pos = self.source.pos();
         self.consume_keyword(b"struct")?;
         self.consume_whitespace(true)?;
         let struct_ident = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         let poly_vars = self.consume_polymorphic_vars()?;
         self.consume_whitespace(false)?;
         // Parse struct fields
         self.consume_string(b"{")?;
         let mut next = self.source.next();
         let mut fields = Vec::new();
         while next.is_some() {
             let char = next.unwrap();
             if char == b'}' {
                 break;
+            }
             // Consume field definition
             self.consume_whitespace(false)?;
             let field_position = self.source.pos();
             let field_parser_type = self.consume_type2(h, false)?;
             self.consume_whitespace(true)?;
             let field_ident = self.consume_identifier()?;
             self.consume_whitespace(false)?;
             fields.push(StructFieldDefinition{
                 position: field_position,
                 field: field_ident,
                 parser_type: field_parser_type,
             });
             // If we have a comma, then we may or may not have another field
             // definition. Otherwise we expect the struct to be fully defined
             // and expect a closing brace
             next = self.source.next();
             if let Some(b',') = next {
                 self.source.consume();
                 self.consume_whitespace(false)?;
                 next = self.source.next();
             } else {
                 break;
+            }
+        }
         // End of struct definition, so we expect a closing brace
         self.consume_string(b"}")?;
         // Valid struct definition
         Ok(h.alloc_struct_definition(|this| StructDefinition{
             this,
             position: struct_pos,
             identifier: struct_ident,
             poly_vars,
             fields,
         }))
+    }
     fn consume_enum_definition(&mut self, h: &mut Heap) -> Result<EnumId, ParseError2> {
         // Parse "enum" keyword, optional polyvars and its identifier
         let enum_pos = self.source.pos();
         self.consume_keyword(b"enum")?;
         self.consume_whitespace(true)?;
         let enum_ident = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         let poly_vars = self.consume_polymorphic_vars()?;
         self.consume_whitespace(false)?;
         // Parse enum variants
         self.consume_string(b"{")?;
         let mut next = self.source.next();
         let mut variants = Vec::new();
         while next.is_some() {
             let char = next.unwrap();
             if char == b'}' {
                 break;
+            }
             // Consume variant identifier
             self.consume_whitespace(false)?;
             let variant_position = self.source.pos();
             let variant_ident = self.consume_identifier()?;
             self.consume_whitespace(false)?;
             // Consume variant (tag) value: may be nothing, in which case it is
             // assigned automatically, may be a constant integer, or an embedded
             // type as value, resulting in a tagged union
             next = self.source.next();
             let variant_value = if let Some(b',') = next {
                 EnumVariantValue::None
             } else if let Some(b'=') = next {
                 self.source.consume();
                 self.consume_whitespace(false)?;
                 if !self.has_integer() {
                     return Err(self.error_at_pos("expected integer"));
+                }
                 let variant_int = self.consume_integer()?;
                 self.consume_whitespace(false)?;
                 EnumVariantValue::Integer(variant_int)
             } else if let Some(b'(') = next {
                 self.source.consume();
                 self.consume_whitespace(false)?;
                 let variant_type = self.consume_type2(h, false)?;
                 self.consume_whitespace(false)?;
                 self.consume_string(b")")?;
                 self.consume_whitespace(false)?;
                 EnumVariantValue::Type(variant_type)
             } else {
                 return Err(self.error_at_pos("expected ',', '=', or '('"));
             };
             variants.push(EnumVariantDefinition{
                 position: variant_position,
                 identifier: variant_ident,
                 value: variant_value
             });
             // If we have a comma, then we may or may not have another variant,
             // otherwise we expect the enum is fully defined
             next = self.source.next();
             if let Some(b',') = next {
                 self.source.consume();
                 self.consume_whitespace(false)?;
                 next = self.source.next();
             } else {
                 break;
+            }
+        }
         self.consume_string(b"}")?;
         // An enum without variants is somewhat valid, but completely useless
         // within the language
         if variants.is_empty() {
             return Err(ParseError2::new_error(self.source, enum_pos, "enum definition without variants"));
+        }
         Ok(h.alloc_enum_definition(|this| EnumDefinition{
             this,
             position: enum_pos,
             identifier: enum_ident,
             poly_vars,
             variants,
         }))
+    }
     fn consume_component_definition(&mut self, h: &mut Heap) -> Result<ComponentId, ParseError2> {
         // TODO: Cleanup
         if self.has_keyword(b"composite") {
             Ok(self.consume_composite_definition(h)?)
         } else {
             Ok(self.consume_primitive_definition(h)?)
+        }
+    }
     fn consume_composite_definition(&mut self, h: &mut Heap) -> Result<ComponentId, ParseError2> {
         // Parse keyword, optional polyvars and the identifier
         let position = self.source.pos();
         self.consume_keyword(b"composite")?;
         self.consume_whitespace(true)?;
         let identifier = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         let poly_vars = self.consume_polymorphic_vars()?;
         self.consume_whitespace(false)?;
         // Consume parameters
         let mut parameters = Vec::new();
         self.consume_parameters(h, &mut parameters)?;
         self.consume_whitespace(false)?;
         // Parse body
         let body = self.consume_block_statement(h)?;
         Ok(h.alloc_component(|this| Component {
             this,
             variant: ComponentVariant::Composite,
             position,
             identifier,
             poly_vars,
             parameters,
             body
         }))
+    }
     fn consume_primitive_definition(&mut self, h: &mut Heap) -> Result<ComponentId, ParseError2> {
         // Consume keyword, optional polyvars and identifier
         let position = self.source.pos();
         self.consume_keyword(b"primitive")?;
         self.consume_whitespace(true)?;
         let identifier = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         let poly_vars = self.consume_polymorphic_vars()?;
         self.consume_whitespace(false)?;
         // Consume parameters
         let mut parameters = Vec::new();
         self.consume_parameters(h, &mut parameters)?;
         self.consume_whitespace(false)?;
         // Consume body
         let body = self.consume_block_statement(h)?;
         Ok(h.alloc_component(|this| Component {
             this,
             variant: ComponentVariant::Primitive,
             position,
             identifier,
             poly_vars,
             parameters,
             body
         }))
+    }
     fn consume_function_definition(&mut self, h: &mut Heap) -> Result<FunctionId, ParseError2> {
         // Consume return type, optional polyvars and identifier
         let position = self.source.pos();
         let return_type = self.consume_type2(h, false)?;
         self.consume_whitespace(true)?;
         let identifier = self.consume_identifier()?;
         self.consume_whitespace(false)?;
         let poly_vars = self.consume_polymorphic_vars()?;
         self.consume_whitespace(false)?;
         // Consume parameters
         let mut parameters = Vec::new();
         self.consume_parameters(h, &mut parameters)?;
         self.consume_whitespace(false)?;
         // Consume body
         let body = self.consume_block_statement(h)?;
         Ok(h.alloc_function(|this| Function {
             this,
             position,
             return_type,
             identifier,
             poly_vars,
             parameters,
             body,
         }))
+    }
     fn has_pragma(&self) -> bool {
         if let Some(c) = self.source.next() {
             c == b'#'
         } else {
             false
+        }
+    }
     fn consume_pragma(&mut self, h: &mut Heap) -> Result<PragmaId, ParseError2> {
         let position = self.source.pos();
         let next = self.source.next();
         if next != Some(b'#') {
             return Err(self.error_at_pos("Expected pragma"));
+        }
         self.source.consume();
         if !is_vchar(self.source.next()) {
             return Err(self.error_at_pos("Expected pragma"));
+        }
         if self.has_string(b"version") {
             self.consume_string(b"version")?;
             self.consume_whitespace(true)?;
             if !self.has_integer() {
                 return Err(self.error_at_pos("Expected integer constant"));
+            }
             let version = self.consume_integer()?;
             debug_assert!(version >= 0);
             return Ok(h.alloc_pragma(|this| Pragma::Version(PragmaVersion{
                 this, position, version: version as u64
             })))
         } else if self.has_string(b"module") {
             self.consume_string(b"module")?;
             self.consume_whitespace(true)?;
             if !self.has_identifier() {
                 return Err(self.error_at_pos("Expected identifier"));
+            }
             let mut value = Vec::new();
             let mut ident = self.consume_ident()?;
             value.append(&mut ident);
             while self.has_string(b".") {
                 self.consume_string(b".")?;
                 value.push(b'.');
                 ident = self.consume_ident()?;
                 value.append(&mut ident);
+            }
             return Ok(h.alloc_pragma(|this| Pragma::Module(PragmaModule{
                 this, position, value
             })));
         } else {
             return Err(self.error_at_pos("Unknown pragma"));
+        }
+    }
     fn has_import(&self) -> bool {
         self.has_keyword(b"import")
+    }
     fn consume_import(&mut self, h: &mut Heap) -> Result<ImportId, ParseError2> {
         // Parse the word "import" and the name of the module
         let position = self.source.pos();
         self.consume_keyword(b"import")?;
         self.consume_whitespace(true)?;
         let mut value = Vec::new();
         let mut ident = self.consume_ident()?;
         value.append(&mut ident);
         let mut last_ident_start = 0;
         while self.has_string(b".") {
             self.consume_string(b".")?;
             value.push(b'.');
             ident = self.consume_ident()?;
             last_ident_start = value.len();
             value.append(&mut ident);
+        }
         self.consume_whitespace(false)?;
         // Check for the potential aliasing or specific module imports

src/protocol/parser/depth_visitor.rs

➞

Show inline comments

 use crate::protocol::ast::*;
 use crate::protocol::inputsource::*;
 // The following indirection is needed due to a bug in the cbindgen tool.
 type Unit = ();
 pub(crate) type VisitorError = (InputPosition, String); // TODO: Revise when multi-file compiling is in place
 pub(crate) type VisitorResult = Result<Unit, VisitorError>;
 pub(crate) trait Visitor: Sized {
     fn visit_protocol_description(&mut self, h: &mut Heap, pd: RootId) -> VisitorResult {
         recursive_protocol_description(self, h, pd)
+    }
     fn visit_pragma(&mut self, _h: &mut Heap, _pragma: PragmaId) -> VisitorResult {
         Ok(())
+    }
     fn visit_import(&mut self, _h: &mut Heap, _import: ImportId) -> VisitorResult {
         Ok(())
+    }
     fn visit_symbol_definition(&mut self, h: &mut Heap, def: DefinitionId) -> VisitorResult {
         recursive_symbol_definition(self, h, def)
+    }
     fn visit_struct_definition(&mut self, _h: &mut Heap, _def: StructId) -> VisitorResult {
         Ok(())
+    }
     fn visit_enum_definition(&mut self, _h: &mut Heap, _def: EnumId) -> VisitorResult {
         Ok(())
+    }
     fn visit_component_definition(&mut self, h: &mut Heap, def: ComponentId) -> VisitorResult {
         recursive_component_definition(self, h, def)
+    }
     fn visit_composite_definition(&mut self, h: &mut Heap, def: ComponentId) -> VisitorResult {
         recursive_composite_definition(self, h, def)
+    }
     fn visit_primitive_definition(&mut self, h: &mut Heap, def: ComponentId) -> VisitorResult {
         recursive_primitive_definition(self, h, def)
+    }
     fn visit_function_definition(&mut self, h: &mut Heap, def: FunctionId) -> VisitorResult {
         recursive_function_definition(self, h, def)
+    }
     fn visit_variable_declaration(&mut self, h: &mut Heap, decl: VariableId) -> VisitorResult {
         recursive_variable_declaration(self, h, decl)
+    }
     fn visit_parameter_declaration(&mut self, _h: &mut Heap, _decl: ParameterId) -> VisitorResult {
         Ok(())
+    }
     fn visit_local_declaration(&mut self, _h: &mut Heap, _decl: LocalId) -> VisitorResult {
         Ok(())
+    }
     fn visit_statement(&mut self, h: &mut Heap, stmt: StatementId) -> VisitorResult {
         recursive_statement(self, h, stmt)
+    }
     fn visit_local_statement(&mut self, h: &mut Heap, stmt: LocalStatementId) -> VisitorResult {
         recursive_local_statement(self, h, stmt)
+    }
     fn visit_memory_statement(&mut self, h: &mut Heap, stmt: MemoryStatementId) -> VisitorResult {
-        recursive_memory_statement(self, h, stmt)
+        Ok(())
+    }
     fn visit_channel_statement(
         &mut self,
         _h: &mut Heap,
         _stmt: ChannelStatementId,
     ) -> VisitorResult {
         Ok(())
+    }
     fn visit_block_statement(&mut self, h: &mut Heap, stmt: BlockStatementId) -> VisitorResult {
         recursive_block_statement(self, h, stmt)
+    }
     fn visit_labeled_statement(&mut self, h: &mut Heap, stmt: LabeledStatementId) -> VisitorResult {
         recursive_labeled_statement(self, h, stmt)
+    }
     fn visit_skip_statement(&mut self, _h: &mut Heap, _stmt: SkipStatementId) -> VisitorResult {
         Ok(())
+    }
     fn visit_if_statement(&mut self, h: &mut Heap, stmt: IfStatementId) -> VisitorResult {
         recursive_if_statement(self, h, stmt)
+    }
     fn visit_end_if_statement(&mut self, _h: &mut Heap, _stmt: EndIfStatementId) -> VisitorResult {
         Ok(())
+    }
     fn visit_while_statement(&mut self, h: &mut Heap, stmt: WhileStatementId) -> VisitorResult {
         recursive_while_statement(self, h, stmt)
+    }
     fn visit_end_while_statement(&mut self, _h: &mut Heap, _stmt: EndWhileStatementId) -> VisitorResult {
         Ok(())
+    }
     fn visit_break_statement(&mut self, _h: &mut Heap, _stmt: BreakStatementId) -> VisitorResult {
         Ok(())
+    }
     fn visit_continue_statement(
         &mut self,
         _h: &mut Heap,
         _stmt: ContinueStatementId,
     ) -> VisitorResult {
         Ok(())
+    }
     fn visit_synchronous_statement(
         &mut self,
         h: &mut Heap,
         stmt: SynchronousStatementId,
     ) -> VisitorResult {
         recursive_synchronous_statement(self, h, stmt)
+    }
     fn visit_end_synchronous_statement(&mut self, _h: &mut Heap, _stmt: EndSynchronousStatementId) -> VisitorResult {
         Ok(())
+    }
     fn visit_return_statement(&mut self, h: &mut Heap, stmt: ReturnStatementId) -> VisitorResult {
         recursive_return_statement(self, h, stmt)
+    }
     fn visit_assert_statement(&mut self, h: &mut Heap, stmt: AssertStatementId) -> VisitorResult {
         recursive_assert_statement(self, h, stmt)
+    }
     fn visit_goto_statement(&mut self, _h: &mut Heap, _stmt: GotoStatementId) -> VisitorResult {
         Ok(())
+    }
     fn visit_new_statement(&mut self, h: &mut Heap, stmt: NewStatementId) -> VisitorResult {
         recursive_new_statement(self, h, stmt)
+    }
     fn visit_expression_statement(
         &mut self,
         h: &mut Heap,
         stmt: ExpressionStatementId,
     ) -> VisitorResult {
         recursive_expression_statement(self, h, stmt)
+    }
     fn visit_expression(&mut self, h: &mut Heap, expr: ExpressionId) -> VisitorResult {
         recursive_expression(self, h, expr)
+    }
     fn visit_assignment_expression(
         &mut self,
         h: &mut Heap,
         expr: AssignmentExpressionId,
     ) -> VisitorResult {
         recursive_assignment_expression(self, h, expr)
+    }
     fn visit_conditional_expression(
         &mut self,
         h: &mut Heap,
         expr: ConditionalExpressionId,
     ) -> VisitorResult {
         recursive_conditional_expression(self, h, expr)
+    }
     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,
@@ @@ -256,200 +256,192 @@ fn recursive_component_definition<T: Visitor>( @@
         ComponentVariant::Primitive => this.visit_primitive_definition(h, def),
         ComponentVariant::Composite => this.visit_composite_definition(h, def),
+    }
+}
 fn recursive_composite_definition<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     def: ComponentId,
 ) -> VisitorResult {
     for &param in h[def].parameters.clone().iter() {
         recursive_parameter_as_variable(this, h, param)?;
+    }
     this.visit_statement(h, h[def].body)
+}
 fn recursive_primitive_definition<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     def: ComponentId,
 ) -> VisitorResult {
     for &param in h[def].parameters.clone().iter() {
         recursive_parameter_as_variable(this, h, param)?;
+    }
     this.visit_statement(h, h[def].body)
+}
 fn recursive_function_definition<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     def: FunctionId,
 ) -> VisitorResult {
     for &param in h[def].parameters.clone().iter() {
         recursive_parameter_as_variable(this, h, param)?;
+    }
     this.visit_statement(h, h[def].body)
+}
 fn recursive_variable_declaration<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     decl: VariableId,
 ) -> VisitorResult {
     match h[decl].clone() {
         Variable::Parameter(decl) => this.visit_parameter_declaration(h, decl.this),
         Variable::Local(decl) => this.visit_local_declaration(h, decl.this),
+    }
+}
 fn recursive_statement<T: Visitor>(this: &mut T, h: &mut Heap, stmt: StatementId) -> VisitorResult {
     match h[stmt].clone() {
         Statement::Block(stmt) => this.visit_block_statement(h, stmt.this),
         Statement::Local(stmt) => this.visit_local_statement(h, stmt.this()),
         Statement::Skip(stmt) => this.visit_skip_statement(h, stmt.this),
         Statement::Labeled(stmt) => this.visit_labeled_statement(h, stmt.this),
         Statement::If(stmt) => this.visit_if_statement(h, stmt.this),
         Statement::While(stmt) => this.visit_while_statement(h, stmt.this),
         Statement::Break(stmt) => this.visit_break_statement(h, stmt.this),
         Statement::Continue(stmt) => this.visit_continue_statement(h, stmt.this),
         Statement::Synchronous(stmt) => this.visit_synchronous_statement(h, stmt.this),
         Statement::Return(stmt) => this.visit_return_statement(h, stmt.this),
         Statement::Assert(stmt) => this.visit_assert_statement(h, stmt.this),
         Statement::Goto(stmt) => this.visit_goto_statement(h, stmt.this),
         Statement::New(stmt) => this.visit_new_statement(h, stmt.this),
         Statement::Expression(stmt) => this.visit_expression_statement(h, stmt.this),
         Statement::EndSynchronous(stmt) => this.visit_end_synchronous_statement(h, stmt.this),
         Statement::EndWhile(stmt) => this.visit_end_while_statement(h, stmt.this),
         Statement::EndIf(stmt) => this.visit_end_if_statement(h, stmt.this),
+    }
+}
 fn recursive_block_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     block: BlockStatementId,
 ) -> VisitorResult {
     for &local in h[block].locals.clone().iter() {
         recursive_local_as_variable(this, h, local)?;
+    }
     for &stmt in h[block].statements.clone().iter() {
         this.visit_statement(h, stmt)?;
+    }
     Ok(())
+}
 fn recursive_local_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: LocalStatementId,
 ) -> VisitorResult {
     match h[stmt].clone() {
         LocalStatement::Channel(stmt) => this.visit_channel_statement(h, stmt.this),
         LocalStatement::Memory(stmt) => this.visit_memory_statement(h, stmt.this),
+    }
+}
 fn recursive_memory_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: MemoryStatementId,
 ) -> VisitorResult {
     this.visit_expression(h, h[stmt].initial)
+}
 fn recursive_labeled_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: LabeledStatementId,
 ) -> VisitorResult {
     this.visit_statement(h, h[stmt].body)
+}
 fn recursive_if_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: IfStatementId,
 ) -> VisitorResult {
     this.visit_expression(h, h[stmt].test)?;
     this.visit_statement(h, h[stmt].true_body)?;
     this.visit_statement(h, h[stmt].false_body)
+}
 fn recursive_while_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: WhileStatementId,
 ) -> VisitorResult {
     this.visit_expression(h, h[stmt].test)?;
     this.visit_statement(h, h[stmt].body)
+}
 fn recursive_synchronous_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: SynchronousStatementId,
 ) -> VisitorResult {
     // TODO: Check where this was used for
     // for &param in h[stmt].parameters.clone().iter() {
     //     recursive_parameter_as_variable(this, h, param)?;
     // }
     this.visit_statement(h, h[stmt].body)
+}
 fn recursive_return_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: ReturnStatementId,
 ) -> VisitorResult {
     this.visit_expression(h, h[stmt].expression)
+}
 fn recursive_assert_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: AssertStatementId,
 ) -> VisitorResult {
     this.visit_expression(h, h[stmt].expression)
+}
 fn recursive_new_statement<T: Visitor>(
     this: &mut T,
     h: &mut Heap,
     stmt: NewStatementId,
 ) -> VisitorResult {
     recursive_call_expression_as_expression(this, h, h[stmt].expression)
+}
 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::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::Array(expr) => this.visit_array_expression(h, expr.this),
         Expression::Constant(expr) => this.visit_constant_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 {

src/protocol/parser/type_resolver.rs

➞

Show inline comments

 /// type_resolver.rs
 ///
 /// Performs type inference and type checking
 ///
 /// TODO: Needs an optimization pass
 /// TODO: Needs a cleanup pass
 macro_rules! enabled_debug_print {
     (false, $name:literal, $format:literal) => {};
     (false, $name:literal, $format:literal, $($args:expr),*) => {};
     (true, $name:literal, $format:literal) => {
         println!("[{}] {}", $name, $format)
     };
     (true, $name:literal, $format:literal, $($args:expr),*) => {
         println!("[{}] {}", $name, format!($format, $($args),*))
     };
+}
 macro_rules! debug_log {
     ($format:literal) => {
         enabled_debug_print!(true, "types", $format);
     };
     ($format:literal, $($args:expr),*) => {
         enabled_debug_print!(true, "types", $format, $($args),*);
     };
+}
 use std::collections::{HashMap, HashSet, VecDeque};
 use crate::protocol::ast::*;
 use crate::protocol::inputsource::*;
 use super::type_table::*;
 use super::symbol_table::*;
 use super::visitor::{
     STMT_BUFFER_INIT_CAPACITY,
     EXPR_BUFFER_INIT_CAPACITY,
     Ctx,
     Visitor2,
     VisitorResult
 };
 use std::collections::hash_map::Entry;
 use crate::protocol::parser::type_resolver::InferenceTypePart::IntegerLike;
 const MESSAGE_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::Message ];
 const BOOL_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::Bool ];
 const NUMBERLIKE_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::NumberLike ];
 const INTEGERLIKE_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::IntegerLike ];
 const ARRAY_TEMPLATE: [InferenceTypePart; 2] = [ InferenceTypePart::Array, InferenceTypePart::Unknown ];
 const ARRAYLIKE_TEMPLATE: [InferenceTypePart; 2] = [ InferenceTypePart::ArrayLike, InferenceTypePart::Unknown ];
 const PORTLIKE_TEMPLATE: [InferenceTypePart; 2] = [ InferenceTypePart::PortLike, InferenceTypePart::Unknown ];
 /// TODO: @performance Turn into PartialOrd+Ord to simplify checks
 #[derive(Debug, Clone, Eq, PartialEq)]
 pub(crate) enum InferenceTypePart {
     // A marker with an identifier which we can use to seek subsections of the
     // inferred type
     Marker(usize),
     // Completely unknown type, needs to be inferred
     Unknown,
     // Partially known type, may be inferred to to be the appropriate related
     // type.
     // IndexLike,      // index into array/slice
     NumberLike,     // any kind of integer/float
     IntegerLike,    // any kind of integer
     ArrayLike,      // array or slice. Note that this must have a subtype
     PortLike,       // input or output port
     // Special types that cannot be instantiated by the user
     Void, // For builtin functions that do not return anything
     // Concrete types without subtypes
     Message,
     Bool,
     Byte,
     Short,
     Int,
     Long,
     String,
     // One subtype
     Array,
     Slice,
     Input,
     Output,
     // A user-defined type with any number of subtypes
     Instance(DefinitionId, usize)
+}
 impl InferenceTypePart {
     fn is_marker(&self) -> bool {
         if let InferenceTypePart::Marker(_) = self { true } else { false }
+    }
     /// Checks if the type is concrete, markers are interpreted as concrete
     /// types.
     fn is_concrete(&self) -> bool {
         use InferenceTypePart as ITP;
         match self {
             ITP::Unknown | ITP::NumberLike | ITP::IntegerLike |
             ITP::ArrayLike | ITP::PortLike => false,
             _ => true
+        }
+    }
     fn is_concrete_number(&self) -> bool {
         // TODO: @float
         use InferenceTypePart as ITP;
         match self {
             ITP::Byte | ITP::Short | ITP::Int | ITP::Long => true,
             _ => false,
+        }
+    }
     fn is_concrete_integer(&self) -> bool {
         use InferenceTypePart as ITP;
         match self {
             ITP::Byte | ITP::Short | ITP::Int | ITP::Long => true,
             _ => false,
+        }
+    }
     fn is_concrete_array_or_slice(&self) -> bool {
         use InferenceTypePart as ITP;
         match self {
             ITP::Array | ITP::Slice => true,
             _ => false,
@@ @@ -744,273 +764,279 @@ enum DefinitionType{ @@
     Function(FunctionId),
+}
 pub(crate) struct ResolveQueueElement {
     pub(crate) root_id: RootId,
     pub(crate) definition_id: DefinitionId,
     pub(crate) monomorph_types: Vec<ConcreteType>,
+}
 pub(crate) type ResolveQueue = Vec<ResolveQueueElement>;
 /// This particular visitor will recurse depth-first into the AST and ensures
 /// that all expressions have the appropriate types.
 pub(crate) struct TypeResolvingVisitor {
     // Current definition we're typechecking.
     definition_type: DefinitionType,
     poly_vars: Vec<ConcreteType>,
     // Buffers for iteration over substatements and subexpressions
     stmt_buffer: Vec<StatementId>,
     expr_buffer: Vec<ExpressionId>,
     // Mapping from parser type to inferred type. We attempt to continue to
     // specify these types until we're stuck or we've fully determined the type.
     var_types: HashMap<VariableId, VarData>,      // types of variables
     expr_types: HashMap<ExpressionId, InferenceType>,   // types of expressions
     extra_data: HashMap<ExpressionId, ExtraData>,       // data for function call inference
     // Keeping track of which expressions need to be reinferred because the
     // expressions they're linked to made progression on an associated type
     expr_queued: HashSet<ExpressionId>,
+}
 // TODO: @rename used for calls and struct literals, maybe union literals?
 struct ExtraData {
     /// Progression of polymorphic variables (if any)
     poly_vars: Vec<InferenceType>,
     /// Progression of types of call arguments or struct members
     embedded: Vec<InferenceType>,
     returned: InferenceType,
+}
 struct VarData {
     var_type: InferenceType,
     used_at: Vec<ExpressionId>,
+}
 impl TypeResolvingVisitor {
     pub(crate) fn new() -> Self {
         TypeResolvingVisitor{
             definition_type: DefinitionType::None,
             poly_vars: Vec::new(),
             stmt_buffer: Vec::with_capacity(STMT_BUFFER_INIT_CAPACITY),
             expr_buffer: Vec::with_capacity(EXPR_BUFFER_INIT_CAPACITY),
             var_types: HashMap::new(),
             expr_types: HashMap::new(),
             extra_data: HashMap::new(),
             expr_queued: HashSet::new(),
+        }
+    }
     // TODO: @cleanup Unsure about this, maybe a pattern will arise after
     //  a while.
     pub(crate) fn queue_module_definitions(ctx: &Ctx, queue: &mut ResolveQueue) {
         let root_id = ctx.module.root_id;
         let root = &ctx.heap.protocol_descriptions[root_id];
         for definition_id in &root.definitions {
             let definition = &ctx.heap[*definition_id];
             match definition {
                 Definition::Function(definition) => {
                     if definition.poly_vars.is_empty() {
                         queue.push(ResolveQueueElement{
                             root_id,
                             definition_id: *definition_id,
                             monomorph_types: Vec::new(),
                         })
+                    }
                 },
                 Definition::Component(definition) => {
                     if definition.poly_vars.is_empty() {
                         queue.push(ResolveQueueElement{
                             root_id,
                             definition_id: *definition_id,
                             monomorph_types: Vec::new(),
                         })
+                    }
                 },
                 Definition::Enum(_) | Definition::Struct(_) => {},
+            }
+        }
+    }
     pub(crate) fn handle_module_definition(
         &mut self, ctx: &mut Ctx, queue: &mut ResolveQueue, element: ResolveQueueElement
     ) -> VisitorResult {
         // Visit the definition
         debug_assert_eq!(ctx.module.root_id, element.root_id);
         self.reset();
         self.poly_vars.clear();
         self.poly_vars.extend(element.monomorph_types.iter().cloned());
         self.visit_definition(ctx, element.definition_id)?;
         // Keep resolving types
         self.resolve_types(ctx, queue)?;
         Ok(())
+    }
     fn reset(&mut self) {
         self.definition_type = DefinitionType::None;
         self.poly_vars.clear();
         self.stmt_buffer.clear();
         self.expr_buffer.clear();
         self.var_types.clear();
         self.expr_types.clear();
         self.extra_data.clear();
         self.expr_queued.clear();
+    }
+}
 impl Visitor2 for TypeResolvingVisitor {
     // Definitions
     fn visit_component_definition(&mut self, ctx: &mut Ctx, id: ComponentId) -> VisitorResult {
         self.reset();
         self.definition_type = DefinitionType::Component(id);
         let comp_def = &ctx.heap[id];
         debug_assert_eq!(comp_def.poly_vars.len(), self.poly_vars.len(), "component polyvars do not match imposed polyvars");
         debug_log!("{}", "-".repeat(80));
         debug_log!("Visiting component '{}': {}", &String::from_utf8_lossy(&comp_def.identifier.value), id.0.index);
         debug_log!("{}", "-".repeat(80));
         for param_id in comp_def.parameters.clone() {
             let param = &ctx.heap[param_id];
             let var_type = self.determine_inference_type_from_parser_type(ctx, param.parser_type, true);
             debug_assert!(var_type.is_done, "expected component arguments to be concrete types");
             self.var_types.insert(param_id.upcast(), VarData{ var_type, used_at: Vec::new() });
+        }
         let body_stmt_id = ctx.heap[id].body;
         self.visit_stmt(ctx, body_stmt_id)
+    }
     fn visit_function_definition(&mut self, ctx: &mut Ctx, id: FunctionId) -> VisitorResult {
         self.reset();
         self.definition_type = DefinitionType::Function(id);
         let func_def = &ctx.heap[id];
         debug_assert_eq!(func_def.poly_vars.len(), self.poly_vars.len(), "function polyvars do not match imposed polyvars");
         debug_log!("{}", "-".repeat(80));
         debug_log!("Visiting function '{}': {}", &String::from_utf8_lossy(&func_def.identifier.value), id.0.index);
         debug_log!("{}", "-".repeat(80));
         for param_id in func_def.parameters.clone() {
             let param = &ctx.heap[param_id];
             let var_type = self.determine_inference_type_from_parser_type(ctx, param.parser_type, true);
             debug_assert!(var_type.is_done, "expected function arguments to be concrete types");
             self.var_types.insert(param_id.upcast(), VarData{ var_type, used_at: Vec::new() });
+        }
         let body_stmt_id = ctx.heap[id].body;
         self.visit_stmt(ctx, body_stmt_id)
+    }
     // Statements
     fn visit_block_stmt(&mut self, ctx: &mut Ctx, id: BlockStatementId) -> VisitorResult {
         // Transfer statements for traversal
         let block = &ctx.heap[id];
         for stmt_id in block.statements.clone() {
             self.visit_stmt(ctx, stmt_id)?;
+        }
         Ok(())
+    }
     fn visit_local_memory_stmt(&mut self, ctx: &mut Ctx, id: MemoryStatementId) -> VisitorResult {
         let memory_stmt = &ctx.heap[id];
         let local = &ctx.heap[memory_stmt.variable];
         let var_type = self.determine_inference_type_from_parser_type(ctx, local.parser_type, true);
         self.var_types.insert(memory_stmt.variable.upcast(), VarData{ var_type, used_at: Vec::new() });
         let expr_id = memory_stmt.initial;
         self.visit_expr(ctx, expr_id)?;
         Ok(())
+    }
     fn visit_local_channel_stmt(&mut self, ctx: &mut Ctx, id: ChannelStatementId) -> VisitorResult {
         let channel_stmt = &ctx.heap[id];
         let from_local = &ctx.heap[channel_stmt.from];
         let from_var_type = self.determine_inference_type_from_parser_type(ctx, from_local.parser_type, true);
         self.var_types.insert(from_local.this.upcast(), VarData{ var_type: from_var_type, used_at: Vec::new() });
         let to_local = &ctx.heap[channel_stmt.to];
         let to_var_type = self.determine_inference_type_from_parser_type(ctx, to_local.parser_type, true);
         self.var_types.insert(to_local.this.upcast(), VarData{ var_type: to_var_type, used_at: Vec::new() });
         Ok(())
+    }
     fn visit_labeled_stmt(&mut self, ctx: &mut Ctx, id: LabeledStatementId) -> VisitorResult {
         let labeled_stmt = &ctx.heap[id];
         let substmt_id = labeled_stmt.body;
         self.visit_stmt(ctx, substmt_id)
+    }
     fn visit_if_stmt(&mut self, ctx: &mut Ctx, id: IfStatementId) -> VisitorResult {
         let if_stmt = &ctx.heap[id];
         let true_body_id = if_stmt.true_body;
         let false_body_id = if_stmt.false_body;
         let test_expr_id = if_stmt.test;
         self.visit_expr(ctx, test_expr_id)?;
         self.visit_stmt(ctx, true_body_id)?;
         self.visit_stmt(ctx, false_body_id)?;
         Ok(())
+    }
     fn visit_while_stmt(&mut self, ctx: &mut Ctx, id: WhileStatementId) -> VisitorResult {
         let while_stmt = &ctx.heap[id];
         let body_id = while_stmt.body;
         let test_expr_id = while_stmt.test;
         self.visit_expr(ctx, test_expr_id)?;
         self.visit_stmt(ctx, body_id)?;
         Ok(())
+    }
     fn visit_synchronous_stmt(&mut self, ctx: &mut Ctx, id: SynchronousStatementId) -> VisitorResult {
         let sync_stmt = &ctx.heap[id];
         let body_id = sync_stmt.body;
         self.visit_stmt(ctx, body_id)
+    }
     fn visit_return_stmt(&mut self, ctx: &mut Ctx, id: ReturnStatementId) -> VisitorResult {
         let return_stmt = &ctx.heap[id];
         let expr_id = return_stmt.expression;
         self.visit_expr(ctx, expr_id)
+    }
     fn visit_assert_stmt(&mut self, ctx: &mut Ctx, id: AssertStatementId) -> VisitorResult {
         let assert_stmt = &ctx.heap[id];
         let test_expr_id = assert_stmt.expression;
         self.visit_expr(ctx, test_expr_id)
+    }
     fn visit_new_stmt(&mut self, ctx: &mut Ctx, id: NewStatementId) -> VisitorResult {
         let new_stmt = &ctx.heap[id];
         let call_expr_id = new_stmt.expression;
         self.visit_call_expr(ctx, call_expr_id)
+    }
     fn visit_expr_stmt(&mut self, ctx: &mut Ctx, id: ExpressionStatementId) -> VisitorResult {
         let expr_stmt = &ctx.heap[id];
         let subexpr_id = expr_stmt.expression;
         self.visit_expr(ctx, subexpr_id)
+    }
     // Expressions
     fn visit_assignment_expr(&mut self, ctx: &mut Ctx, id: AssignmentExpressionId) -> VisitorResult {
         let upcast_id = id.upcast();
         self.insert_initial_expr_inference_type(ctx, upcast_id)?;
         let assign_expr = &ctx.heap[id];
         let left_expr_id = assign_expr.left;
         let right_expr_id = assign_expr.right;
         self.visit_expr(ctx, left_expr_id)?;
         self.visit_expr(ctx, right_expr_id)?;
@@ @@ -1092,786 +1118,905 @@ impl Visitor2 for TypeResolvingVisitor { @@
+    }
     fn visit_select_expr(&mut self, ctx: &mut Ctx, id: SelectExpressionId) -> VisitorResult {
         let upcast_id = id.upcast();
         self.insert_initial_expr_inference_type(ctx, upcast_id)?;
         let select_expr = &ctx.heap[id];
         let subject_expr_id = select_expr.subject;
         self.visit_expr(ctx, subject_expr_id)?;
         self.progress_select_expr(ctx, id)
+    }
     fn visit_array_expr(&mut self, ctx: &mut Ctx, id: ArrayExpressionId) -> VisitorResult {
         let upcast_id = id.upcast();
         self.insert_initial_expr_inference_type(ctx, upcast_id)?;
         let array_expr = &ctx.heap[id];
         // TODO: @performance
         for element_id in array_expr.elements.clone().into_iter() {
             self.visit_expr(ctx, element_id)?;
+        }
         self.progress_array_expr(ctx, id)
+    }
     fn visit_constant_expr(&mut self, ctx: &mut Ctx, id: ConstantExpressionId) -> VisitorResult {
         let upcast_id = id.upcast();
         self.insert_initial_expr_inference_type(ctx, upcast_id)?;
         self.progress_constant_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);
         // TODO: @performance
         let call_expr = &ctx.heap[id];
         for arg_expr_id in call_expr.arguments.clone() {
             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)
+    }
+}
 macro_rules! debug_assert_expr_ids_unique_and_known {
     // Base case for a single expression ID
     ($resolver:ident, $id:ident) => {
         if cfg!(debug_assertions) {
             $resolver.expr_types.contains_key(&$id);
+        }
     };
     // Base case for two expression IDs
     ($resolver:ident, $id1:ident, $id2:ident) => {
         debug_assert_ne!($id1, $id2);
         debug_assert_expr_ids_unique_and_known!($resolver, $id1);
         debug_assert_expr_ids_unique_and_known!($resolver, $id2);
     };
     // Generic case
     ($resolver:ident, $id1:ident, $id2:ident, $($tail:ident),+) => {
         debug_assert_ne!($id1, $id2);
         debug_assert_expr_ids_unique_and_known!($resolver, $id1);
         debug_assert_expr_ids_unique_and_known!($resolver, $id2, $($tail),+);
     };
+}
 macro_rules! debug_assert_ptrs_distinct {
     // Base case
     ($ptr1:ident, $ptr2:ident) => {
         debug_assert!(!std::ptr::eq($ptr1, $ptr2));
     };
     // Generic case
     ($ptr1:ident, $ptr2:ident, $($tail:ident),+) => {
         debug_assert_ptrs_distinct!($ptr1, $ptr2);
         debug_assert_ptrs_distinct!($ptr2, $($tail),+);
     };
+}
 impl TypeResolvingVisitor {
     fn resolve_types(&mut self, ctx: &mut Ctx, queue: &mut ResolveQueue) -> Result<(), ParseError2> {
         // Keep inferring until we can no longer make any progress
         println!("DEBUG: Resolve queue is {:?}", &self.expr_queued);
         while let Some(next_expr_id) = self.expr_queued.iter().next() {
             let next_expr_id = *next_expr_id;
             self.expr_queued.remove(&next_expr_id);
             self.progress_expr(ctx, next_expr_id)?;
+        }
         // Should have inferred everything
         for (expr_id, expr_type) in self.expr_types.iter() {
             if !expr_type.is_done {
                 let mut buffer = std::fs::File::create("type_debug.txt").unwrap();
                 use crate::protocol::ast_printer::ASTWriter;
                 let mut w = ASTWriter::new();
                 w.write_ast(&mut buffer, &ctx.heap);
                 // TODO: Auto-inference of integerlike types
                 let expr = &ctx.heap[*expr_id];
                 return Err(ParseError2::new_error(
                     &ctx.module.source, expr.position(),
                     &format!(
                         "Could not fully infer the type of this expression (got '{}')",
                         expr_type.display_name(&ctx.heap)
+                    )
                 ))
+            }
             let concrete_type = ctx.heap[*expr_id].get_type_mut();
             expr_type.write_concrete_type(concrete_type);
+        }
         // Check all things we need to monomorphize
         // TODO: Struct/enum/union monomorphization
         for (call_expr_id, extra_data) in self.extra_data.iter() {
             if extra_data.poly_vars.is_empty() { continue; }
             // We have a polymorph
             let mut monomorph_types = Vec::with_capacity(extra_data.poly_vars.len());
             for (poly_idx, poly_type) in extra_data.poly_vars.iter().enumerate() {
                 if !poly_type.is_done {
                     // TODO: Single clean function for function signatures and polyvars.
                     // TODO: Better error message
                     let expr = &ctx.heap[*call_expr_id];
                     return Err(ParseError2::new_error(
                         &ctx.module.source, expr.position(),
                         &format!(
                             "Could not fully infer the type of polymorphic variable {} of this expression (got '{}')",
                             poly_idx, poly_type.display_name(&ctx.heap)
+                        )
                     ))
+                }
                 let mut concrete_type = ConcreteType::default();
                 poly_type.write_concrete_type(&mut concrete_type);
                 monomorph_types.insert(poly_idx, concrete_type);
+            }
             // Resolve to call expression's definition
             let call_expr = if let Expression::Call(call_expr) = &ctx.heap[*call_expr_id] {
                 call_expr
             } else {
                 todo!("implement different kinds of polymorph expressions");
             };
             if let Method::Symbolic(symbolic) = &call_expr.method {
                 let definition_id = symbolic.definition.unwrap();
                 let root_id = ctx.types
                     .get_base_definition(&definition_id)
                     .unwrap()
                     .ast_root;
                 queue.push(ResolveQueueElement{
                     root_id,
                     definition_id,
                     monomorph_types,
                 })
+            }
+        }
         // Finally, if the currently resolved definition is a monomoprh, then we
         // add it to the type table
         if !self.poly_vars.is_empty() {
             let definition_id = match &self.definition_type {
                 DefinitionType::None => unreachable!(),
                 DefinitionType::Function(id) => id.upcast(),
                 DefinitionType::Component(id) => id.upcast(),
             };
             ctx.types.instantiate_monomorph(&definition_id, &self.poly_vars)
+        }
         Ok(())
+    }
     fn progress_expr(&mut self, ctx: &mut Ctx, id: ExpressionId) -> Result<(), ParseError2> {
         match &ctx.heap[id] {
             Expression::Assignment(expr) => {
                 let id = expr.this;
                 self.progress_assignment_expr(ctx, id)
             },
             Expression::Conditional(expr) => {
                 let id = expr.this;
                 self.progress_conditional_expr(ctx, id)
             },
             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::Array(expr) => {
                 let id = expr.this;
                 self.progress_array_expr(ctx, id)
             },
             Expression::Constant(expr) => {
                 let id = expr.this;
                 self.progress_constant_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<(), ParseError2> {
         use AssignmentOperator as AO;
         // TODO: Assignable check
         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.expr_types.get(&arg1_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Arg2 type: {}", self.expr_types.get(&arg2_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         let progress_base = match expr.operation {
             AO::Set =>
                 false,
             AO::Multiplied | AO::Divided | AO::Added | AO::Subtracted =>
                 self.apply_forced_constraint(ctx, upcast_id, &NUMBERLIKE_TEMPLATE)?,
             AO::Remained | AO::ShiftedLeft | AO::ShiftedRight |
             AO::BitwiseAnded | AO::BitwiseXored | AO::BitwiseOred =>
                 self.apply_forced_constraint(ctx, upcast_id, &INTEGERLIKE_TEMPLATE)?,
         };
         let (progress_expr, progress_arg1, progress_arg2) = self.apply_equal3_constraint(
             ctx, upcast_id, arg1_expr_id, arg2_expr_id, 0
         )?;
         debug_log!(" * After:");
         debug_log!("   - Arg1 type [{}]: {}", progress_arg1, self.expr_types.get(&arg1_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Arg2 type [{}]: {}", progress_arg2, self.expr_types.get(&arg2_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type [{}]: {}", progress_base || progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if progress_base || progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         if progress_arg1 { self.queue_expr(arg1_expr_id); }
         if progress_arg2 { self.queue_expr(arg2_expr_id); }
         Ok(())
+    }
     fn progress_conditional_expr(&mut self, ctx: &mut Ctx, id: ConditionalExpressionId) -> Result<(), ParseError2> {
         // Note: test expression type is already enforced
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let arg1_expr_id = expr.true_expression;
         let arg2_expr_id = expr.false_expression;
         debug_log!("Conditional expr: {}", upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Arg1 type: {}", self.expr_types.get(&arg1_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Arg2 type: {}", self.expr_types.get(&arg2_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         let (progress_expr, progress_arg1, progress_arg2) = self.apply_equal3_constraint(
             ctx, upcast_id, arg1_expr_id, arg2_expr_id, 0
         )?;
         debug_log!(" * After:");
         debug_log!("   - Arg1 type [{}]: {}", progress_arg1, self.expr_types.get(&arg1_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Arg2 type [{}]: {}", progress_arg2, self.expr_types.get(&arg2_expr_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type [{}]: {}", progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         if progress_arg1 { self.queue_expr(arg1_expr_id); }
         if progress_arg2 { self.queue_expr(arg2_expr_id); }
         Ok(())
+    }
     fn progress_binary_expr(&mut self, ctx: &mut Ctx, id: BinaryExpressionId) -> Result<(), ParseError2> {
         // Note: our expression type might be fixed by our parent, but we still
         // need to make sure it matches the type associated with our operation.
         use BinaryOperator as BO;
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let arg1_id = expr.left;
         let arg2_id = expr.right;
         debug_log!("Binary expr '{:?}': {}", expr.operation, upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Arg1 type: {}", self.expr_types.get(&arg1_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Arg2 type: {}", self.expr_types.get(&arg2_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         let (progress_expr, progress_arg1, progress_arg2) = match expr.operation {
             BO::Concatenate => {
                 // Arguments may be arrays/slices, output is always an array
                 let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &ARRAY_TEMPLATE)?;
                 let progress_arg1 = self.apply_forced_constraint(ctx, arg1_id, &ARRAYLIKE_TEMPLATE)?;
                 let progress_arg2 = self.apply_forced_constraint(ctx, arg2_id, &ARRAYLIKE_TEMPLATE)?;
                 // If they're all arraylike, then we want the subtype to match
                 let (subtype_expr, subtype_arg1, subtype_arg2) =
                     self.apply_equal3_constraint(ctx, upcast_id, arg1_id, arg2_id, 1)?;
                 (progress_expr || subtype_expr, progress_arg1 || subtype_arg1, progress_arg2 || subtype_arg2)
             },
             BO::LogicalOr | BO::LogicalAnd => {
                 // Forced boolean on all
                 let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &BOOL_TEMPLATE)?;
                 let progress_arg1 = self.apply_forced_constraint(ctx, arg1_id, &BOOL_TEMPLATE)?;
                 let progress_arg2 = self.apply_forced_constraint(ctx, arg2_id, &BOOL_TEMPLATE)?;
                 (progress_expr, progress_arg1, progress_arg2)
             },
             BO::BitwiseOr | BO::BitwiseXor | BO::BitwiseAnd | BO::Remainder | BO::ShiftLeft | BO::ShiftRight => {
                 // All equal of integer type
                 let progress_base = self.apply_forced_constraint(ctx, upcast_id, &INTEGERLIKE_TEMPLATE)?;
                 let (progress_expr, progress_arg1, progress_arg2) =
                     self.apply_equal3_constraint(ctx, upcast_id, arg1_id, arg2_id, 0)?;
                 (progress_base || progress_expr, progress_base || progress_arg1, progress_base || progress_arg2)
             },
-            BO::Equality | BO::Inequality | BO::LessThan | BO::GreaterThan | BO::LessThanEqual | BO::GreaterThanEqual => {
             BO::Equality | BO::Inequality => {
                 // Equal2 on args, forced boolean output
                 let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &BOOL_TEMPLATE)?;
                 let (progress_arg1, progress_arg2) =
                     self.apply_equal2_constraint(ctx, upcast_id, arg1_id, 0, arg2_id, 0)?;
                 (progress_expr, progress_arg1, progress_arg2)
             },
             BO::LessThan | BO::GreaterThan | BO::LessThanEqual | BO::GreaterThanEqual => {
                 // Equal2 on args with numberlike type, forced boolean output
                 let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &BOOL_TEMPLATE)?;
                 let progress_arg_base = self.apply_forced_constraint(ctx, arg1_id, &NUMBERLIKE_TEMPLATE)?;
                 let (progress_arg1, progress_arg2) =
                     self.apply_equal2_constraint(ctx, upcast_id, arg1_id, 0, arg2_id, 0)?;
                 (progress_expr, progress_arg_base || progress_arg1, progress_arg_base || progress_arg2)
             },
             BO::Add | BO::Subtract | BO::Multiply | BO::Divide => {
                 // All equal of number type
                 let progress_base = self.apply_forced_constraint(ctx, upcast_id, &NUMBERLIKE_TEMPLATE)?;
                 let (progress_expr, progress_arg1, progress_arg2) =
                     self.apply_equal3_constraint(ctx, upcast_id, arg1_id, arg2_id, 0)?;
                 (progress_base || progress_expr, progress_base || progress_arg1, progress_base || progress_arg2)
             },
         };
         debug_log!(" * After:");
         debug_log!("   - Arg1 type [{}]: {}", progress_arg1, self.expr_types.get(&arg1_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Arg2 type [{}]: {}", progress_arg2, self.expr_types.get(&arg2_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type [{}]: {}", progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         if progress_arg1 { self.queue_expr(arg1_id); }
         if progress_arg2 { self.queue_expr(arg2_id); }
         Ok(())
+    }
     fn progress_unary_expr(&mut self, ctx: &mut Ctx, id: UnaryExpressionId) -> Result<(), ParseError2> {
         use UnaryOperation as UO;
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let arg_id = expr.expression;
         debug_log!("Unary expr '{:?}': {}", expr.operation, upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Arg  type: {}", self.expr_types.get(&arg_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         let (progress_expr, progress_arg) = match expr.operation {
             UO::Positive | UO::Negative => {
                 // Equal types of numeric class
                 let progress_base = self.apply_forced_constraint(ctx, upcast_id, &NUMBERLIKE_TEMPLATE)?;
                 let (progress_expr, progress_arg) =
                     self.apply_equal2_constraint(ctx, upcast_id, upcast_id, 0, arg_id, 0)?;
                 (progress_base || progress_expr, progress_base || progress_arg)
             },
             UO::BitwiseNot | UO::PreIncrement | UO::PreDecrement | UO::PostIncrement | UO::PostDecrement => {
                 // Equal types of integer class
                 let progress_base = self.apply_forced_constraint(ctx, upcast_id, &INTEGERLIKE_TEMPLATE)?;
                 let (progress_expr, progress_arg) =
                     self.apply_equal2_constraint(ctx, upcast_id, upcast_id, 0, arg_id, 0)?;
                 (progress_base || progress_expr, progress_base || progress_arg)
             },
             UO::LogicalNot => {
                 // Both booleans
                 let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &BOOL_TEMPLATE)?;
                 let progress_arg = self.apply_forced_constraint(ctx, upcast_id, &BOOL_TEMPLATE)?;
                 (progress_expr, progress_arg)
+            }
         };
         debug_log!(" * After:");
         debug_log!("   - Arg  type [{}]: {}", progress_arg, self.expr_types.get(&arg_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr type [{}]: {}", progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         if progress_arg { self.queue_expr(arg_id); }
         Ok(())
+    }
     fn progress_indexing_expr(&mut self, ctx: &mut Ctx, id: IndexingExpressionId) -> Result<(), ParseError2> {
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let subject_id = expr.subject;
         let index_id = expr.index;
         debug_log!("Indexing expr: {}", upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Subject type: {}", self.expr_types.get(&subject_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Index   type: {}", self.expr_types.get(&index_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr    type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         // Make sure subject is arraylike and index is integerlike
         let progress_subject_base = self.apply_forced_constraint(ctx, subject_id, &ARRAYLIKE_TEMPLATE)?;
         let progress_index = self.apply_forced_constraint(ctx, index_id, &INTEGERLIKE_TEMPLATE)?;
         // Make sure if output is of T then subject is Array<T>
         let (progress_expr, progress_subject) =
             self.apply_equal2_constraint(ctx, upcast_id, upcast_id, 0, subject_id, 1)?;
         debug_log!(" * After:");
         debug_log!("   - Subject type [{}]: {}", progress_subject_base || progress_subject, self.expr_types.get(&subject_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Index   type [{}]: {}", progress_index, self.expr_types.get(&index_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr    type [{}]: {}", progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         if progress_subject_base || progress_subject { self.queue_expr(subject_id); }
         if progress_index { self.queue_expr(index_id); }
         Ok(())
+    }
     fn progress_slicing_expr(&mut self, ctx: &mut Ctx, id: SlicingExpressionId) -> Result<(), ParseError2> {
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let subject_id = expr.subject;
         let from_id = expr.from_index;
         let to_id = expr.to_index;
         debug_log!("Slicing expr: {}", upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Subject type: {}", self.expr_types.get(&subject_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - FromIdx type: {}", self.expr_types.get(&from_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - ToIdx   type: {}", self.expr_types.get(&to_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr    type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         // Make sure subject is arraylike and indices are of equal integerlike
         let progress_subject_base = self.apply_forced_constraint(ctx, subject_id, &ARRAYLIKE_TEMPLATE)?;
         let progress_idx_base = self.apply_forced_constraint(ctx, from_id, &INTEGERLIKE_TEMPLATE)?;
         let (progress_from, progress_to) = self.apply_equal2_constraint(ctx, upcast_id, from_id, 0, to_id, 0)?;
         // Make sure if output is of T then subject is Array<T>
         let (progress_expr, progress_subject) =
             self.apply_equal2_constraint(ctx, upcast_id, upcast_id, 0, subject_id, 1)?;
         debug_log!(" * After:");
         debug_log!("   - Subject type [{}]: {}", progress_subject_base || progress_subject, self.expr_types.get(&subject_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - FromIdx type [{}]: {}", progress_idx_base || progress_from, self.expr_types.get(&from_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - ToIdx   type [{}]: {}", progress_idx_base || progress_to, self.expr_types.get(&to_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr    type [{}]: {}", progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         if progress_subject_base || progress_subject { self.queue_expr(subject_id); }
         if progress_idx_base || progress_from { self.queue_expr(from_id); }
         if progress_idx_base || progress_to { self.queue_expr(to_id); }
         Ok(())
+    }
     fn progress_select_expr(&mut self, ctx: &mut Ctx, id: SelectExpressionId) -> Result<(), ParseError2> {
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let subject_id = expr.subject;
         debug_log!("Select expr: {}", upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Subject type: {}", self.expr_types.get(&subject_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr    type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         let (progress_subject, progress_expr) = match &expr.field {
             Field::Length => {
                 let progress_subject = self.apply_forced_constraint(ctx, subject_id, &ARRAYLIKE_TEMPLATE)?;
                 let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &INTEGERLIKE_TEMPLATE)?;
                 (progress_subject, progress_expr)
             },
             Field::Symbolic(_field) => {
                 todo!("implement select expr for symbolic fields");
+            }
         };
         debug_log!(" * After:");
         debug_log!("   - Subject type [{}]: {}", progress_subject, self.expr_types.get(&subject_id).unwrap().display_name(&ctx.heap));
         debug_log!("   - Expr    type [{}]: {}", progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if progress_subject { self.queue_expr(subject_id); }
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         Ok(())
+    }
     fn progress_array_expr(&mut self, ctx: &mut Ctx, id: ArrayExpressionId) -> Result<(), ParseError2> {
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let expr_elements = expr.elements.clone(); // TODO: @performance
         debug_log!("Array expr ({} elements): {}", expr_elements.len(), upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         // All elements should have an equal type
         let progress = self.apply_equal_n_constraint(ctx, upcast_id, &expr_elements)?;
         let mut any_progress = false;
         for (progress_arg, arg_id) in progress.iter().zip(expr_elements.iter()) {
             if *progress_arg {
                 any_progress = true;
                 self.queue_expr(*arg_id);
+            }
+        }
         // And the output should be an array of the element types
         let mut expr_progress = self.apply_forced_constraint(ctx, upcast_id, &ARRAY_TEMPLATE)?;
         if !expr_elements.is_empty() {
             let first_arg_id = expr_elements[0];
             let (inner_expr_progress, arg_progress) = self.apply_equal2_constraint(
                 ctx, upcast_id, upcast_id, 1, first_arg_id, 0
             )?;
             expr_progress = expr_progress || 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(upcast_id); }
+        }
         debug_log!(" * After:");
         debug_log!("   - Expr type [{}]: {}", expr_progress, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         if expr_progress { self.queue_expr_parent(ctx, upcast_id); }
         Ok(())
+    }
     fn progress_constant_expr(&mut self, ctx: &mut Ctx, id: ConstantExpressionId) -> Result<(), ParseError2> {
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let template = match &expr.value {
             Constant::Null => &MESSAGE_TEMPLATE,
             Constant::Integer(_) => &INTEGERLIKE_TEMPLATE,
             Constant::True | Constant::False => &BOOL_TEMPLATE,
             Constant::Character(_) => todo!("character literals")
         };
         let progress = self.apply_forced_constraint(ctx, upcast_id, template)?;
         if progress { self.queue_expr_parent(ctx, upcast_id); }
         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<(), ParseError2> {
         println!("DEBUG: Processing call {}", id.0.index);
         let upcast_id = id.upcast();
         let expr = &ctx.heap[id];
         let extra = self.extra_data.get_mut(&upcast_id).unwrap();
         debug_log!("Call expr '{}': {}", match &expr.method {
             Method::Create => String::from("create"),
             Method::Fires => String::from("fires"),
             Method::Get => String::from("get"),
             Method::Put => String::from("put"),
             Method::Symbolic(method) => String::from_utf8_lossy(&method.identifier.value).to_string()
         },upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         debug_log!(" * During (inferring types from arguments and return type):");
         // 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());
         let mut poly_infer_error = false;
         for (arg_idx, arg_id) in expr.arguments.clone().into_iter().enumerate() {
             let signature_type = &mut extra.embedded[arg_idx];
             let argument_type: *mut _ = self.expr_types.get_mut(&arg_id).unwrap();
             let (progress_sig, progress_arg) = Self::apply_equal2_constraint_types(
                 ctx, upcast_id, signature_type, 0, argument_type, 0
             )?;
-            println!("DEBUG Arg  {}: {} <--> {}", arg_idx, signature_type.display_name(&ctx.heap), unsafe{&*argument_type}.display_name(&ctx.heap));
+            debug_log!("   - Arg {} type | sig: {}, arg: {}", arg_idx, signature_type.display_name(&ctx.heap), unsafe{&*argument_type}.display_name(&ctx.heap));
             if progress_sig {
                 // Progressed signature, so also apply inference to the
                 // polymorph types using the markers
                 debug_assert!(signature_type.has_marker, "progress on signature argument type without markers");
                 for (poly_idx, poly_section) in signature_type.marker_iter() {
                     let polymorph_type = &mut extra.poly_vars[poly_idx];
                     match Self::apply_forced_constraint_types(
                         polymorph_type, 0, poly_section, 0
                     ) {
                         Ok(true) => { poly_progress.insert(poly_idx); },
                         Ok(false) => {},
                         Err(()) => { poly_infer_error = true; }
+                    }
                     println!("DEBUG Poly {}: {} <--> {}", poly_idx, polymorph_type.display_name(&ctx.heap), InferenceType::partial_display_name(&ctx.heap, poly_section));
                     debug_log!("   - Poly {} type | sig: {}, arg: {}", poly_idx, polymorph_type.display_name(&ctx.heap), InferenceType::partial_display_name(&ctx.heap, poly_section));
+                }
+            }
             if progress_arg {
                 // Progressed argument expression
                 self.expr_queued.insert(arg_id);
+            }
+        }
         // Do the same for the return type
         let signature_type = &mut extra.returned;
         let expr_type: *mut _ = self.expr_types.get_mut(&upcast_id).unwrap();
         let (progress_sig, progress_expr) = Self::apply_equal2_constraint_types(
             ctx, upcast_id, signature_type, 0, expr_type, 0
         )?;
-        println!("DEBUG Ret  {} <--> {}", signature_type.display_name(&ctx.heap), unsafe{&*expr_type}.display_name(&ctx.heap));
+        debug_log!("   - Ret type | sig: {}, arg: {}", signature_type.display_name(&ctx.heap), unsafe{&*expr_type}.display_name(&ctx.heap));
         if progress_sig {
             // As above: apply inference to polyargs as well
             debug_assert!(signature_type.has_marker, "progress on signature return type without markers");
             for (poly_idx, poly_section) in signature_type.marker_iter() {
                 let polymorph_type = &mut extra.poly_vars[poly_idx];
                 match Self::apply_forced_constraint_types(
                     polymorph_type, 0, poly_section, 0
                 ) {
                     Ok(true) => { poly_progress.insert(poly_idx); },
                     Ok(false) => {},
                     Err(()) => { poly_infer_error = true; }
+                }
-                println!("DEBUG Poly {}: {} <--> {}", poly_idx, polymorph_type.display_name(&ctx.heap), InferenceType::partial_display_name(&ctx.heap, poly_section));
+                debug_log!("   - Poly {} type | sig: {}, arg: {}", poly_idx, polymorph_type.display_name(&ctx.heap), InferenceType::partial_display_name(&ctx.heap, poly_section));
+            }
+        }
         if progress_expr {
             if let Some(parent_id) = ctx.heap[upcast_id].parent_expr_id() {
                 self.expr_queued.insert(parent_id);
+            }
+        }
         // If we had an error in the polymorphic variable's inference, then we
         // need to provide a human readable error: find a pair of inference
         // types in the arguments/return type that do not agree on the
         // polymorphic variable's type
         if poly_infer_error { return Err(self.construct_poly_arg_error(ctx, id)) }
         // If we did not have an error in the polymorph inference above, then
         // reapplying the polymorph type to each argument type and the return
         // type should always succeed.
         debug_log!(" * During (reinferring from progress polyvars):");
         // TODO: @performance If the algorithm is changed to be more "on demand
         //  argument re-evaluation", instead of "all-argument re-evaluation",
         //  then this is no longer true
         for poly_idx in poly_progress.into_iter() {
             // For each polymorphic argument: first extend the signature type,
             // then reapply the equal2 constraint to the expressions
             let poly_type = &extra.poly_vars[poly_idx];
             for (arg_idx, sig_type) in extra.embedded.iter_mut().enumerate() {
                 let mut seek_idx = 0;
                 let mut modified_sig = false;
                 while let Some((start_idx, end_idx)) = sig_type.find_subtree_idx_for_marker(poly_idx, seek_idx) {
                     let modified_at_marker = Self::apply_forced_constraint_types(
                         sig_type, start_idx, &poly_type.parts, 0
                     ).unwrap();
                     modified_sig = modified_sig || modified_at_marker;
                     seek_idx = end_idx;
+                }
                 if !modified_sig { continue; }
                 if !modified_sig {
                     debug_log!("   - Poly {} | Arg {} type | signature has not changed", poly_idx, arg_idx);
                     continue;
+                }
                 // Part of signature was modified, so update expression used as
                 // argument as well
                 let arg_expr_id = expr.arguments[arg_idx];
                 let arg_type: *mut _ = self.expr_types.get_mut(&arg_expr_id).unwrap();
                 let (progress_arg, _) = Self::apply_equal2_constraint_types(
                     ctx, arg_expr_id, arg_type, 0, sig_type, 0
                 ).expect("no inference error at argument type");
                 if progress_arg { self.expr_queued.insert(arg_expr_id); }
                 debug_log!("   - Poly {} | Arg {} type | sig: {}, arg: {}", poly_idx, arg_idx, sig_type.display_name(&ctx.heap), unsafe{&*arg_type}.display_name(&ctx.heap));
+            }
             // Again: do the same for the return type
             let sig_type = &mut extra.returned;
             let mut seek_idx = 0;
             let mut modified_sig = false;
             while let Some((start_idx, end_idx)) = sig_type.find_subtree_idx_for_marker(poly_idx, seek_idx) {
                 let modified_at_marker = Self::apply_forced_constraint_types(
                     sig_type, start_idx, &poly_type.parts, 0
                 ).unwrap();
                 modified_sig = modified_sig || modified_at_marker;
                 seek_idx = end_idx;
+            }
             if modified_sig {
                 let ret_type = self.expr_types.get_mut(&upcast_id).unwrap();
                 let (progress_ret, _) = Self::apply_equal2_constraint_types(
                     ctx, upcast_id, ret_type, 0, sig_type, 0
                 ).expect("no inference error at return type");
                 if progress_ret {
                     if let Some(parent_id) = ctx.heap[upcast_id].parent_expr_id() {
                         self.expr_queued.insert(parent_id);
+                    }
+                }
                 debug_log!("   - Poly {} | Ret type | sig: {}, arg: {}", poly_idx, sig_type.display_name(&ctx.heap), ret_type.display_name(&ctx.heap));
             } else {
                 debug_log!("   - Poly {} | Ret type | signature has not changed", poly_idx);
+            }
+        }
         debug_log!(" * After:");
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         Ok(())
+    }
     fn progress_variable_expr(&mut self, ctx: &mut Ctx, id: VariableExpressionId) -> Result<(), ParseError2> {
         let upcast_id = id.upcast();
         let var_expr = &ctx.heap[id];
         let var_id = var_expr.declaration.unwrap();
         debug_log!("Variable expr '{}': {}", &String::from_utf8_lossy(&ctx.heap[var_id].identifier().value), upcast_id.index);
         debug_log!(" * Before:");
         debug_log!("   - Var  type: {}", self.var_types.get(&var_id).unwrap().var_type.display_name(&ctx.heap));
         debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         // Retrieve shared variable type and expression type and apply inference
         let var_data = self.var_types.get_mut(&var_id).unwrap();
         let expr_type = self.expr_types.get_mut(&upcast_id).unwrap();
         let infer_res = unsafe{ InferenceType::infer_subtrees_for_both_types(
             &mut var_data.var_type as *mut _, 0, expr_type, 0
         ) };
         if infer_res == DualInferenceResult::Incompatible {
             let var_decl = &ctx.heap[var_id];
             return Err(ParseError2::new_error(
                 &ctx.module.source, var_decl.position(),
                 &format!(
                     "Conflicting types for this variable, previously assigned the type '{}'",
                     var_data.var_type.display_name(&ctx.heap)
+                )
             ).with_postfixed_info(
                 &ctx.module.source, var_expr.position,
                 &format!(
                     "But inferred to have incompatible type '{}' here",
                     expr_type.display_name(&ctx.heap)
+                )
             ))
+        }
         let progress_var = infer_res.modified_lhs();
         let progress_expr = infer_res.modified_rhs();
         if progress_var {
             for other_expr in var_data.used_at.iter() {
                 if *other_expr != upcast_id {
                     self.expr_queued.insert(*other_expr);
+                }
+            }
+        }
         if progress_expr { self.queue_expr_parent(ctx, upcast_id); }
         debug_log!(" * After:");
         debug_log!("   - Var  type [{}]: {}", progress_var, self.var_types.get(&var_id).unwrap().var_type.display_name(&ctx.heap));
         debug_log!("   - Expr type [{}]: {}", progress_expr, self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));
         Ok(())
+    }
     fn queue_expr_parent(&mut self, ctx: &Ctx, expr_id: ExpressionId) {
         if let ExpressionParent::Expression(parent_expr_id, _) = &ctx.heap[expr_id].parent() {
             self.expr_queued.insert(*parent_expr_id);
+        }
+    }
     fn queue_expr(&mut self, expr_id: ExpressionId) {
         self.expr_queued.insert(expr_id);
+    }
     /// Applies a forced type constraint: the type associated with the supplied
     /// expression will be molded into the provided "template". The template may
     /// be fully specified (e.g. a bool) or contain "inference" variables (e.g.
     /// an array of T)
     fn apply_forced_constraint(
         &mut self, ctx: &mut Ctx, expr_id: ExpressionId, template: &[InferenceTypePart]
     ) -> Result<bool, ParseError2> {
         debug_assert_expr_ids_unique_and_known!(self, expr_id);
         let expr_type = self.expr_types.get_mut(&expr_id).unwrap();
         match InferenceType::infer_subtree_for_single_type(expr_type, 0, template, 0) {
             SingleInferenceResult::Modified => Ok(true),
             SingleInferenceResult::Unmodified => Ok(false),
             SingleInferenceResult::Incompatible => Err(
                 self.construct_template_type_error(ctx, expr_id, template)
+            )
+        }
+    }
     fn apply_forced_constraint_types(
         to_infer: *mut InferenceType, to_infer_start_idx: usize,
         template: &[InferenceTypePart], template_start_idx: usize
     ) -> Result<bool, ()> {
         match InferenceType::infer_subtree_for_single_type(
             unsafe{ &mut *to_infer }, to_infer_start_idx,
             template, template_start_idx
         ) {
             SingleInferenceResult::Modified => Ok(true),
             SingleInferenceResult::Unmodified => Ok(false),
             SingleInferenceResult::Incompatible => Err(()),
+        }
+    }
     /// Applies a type constraint that expects the two provided types to be
     /// equal. We attempt to make progress in inferring the types. If the call
     /// is successful then the composition of all types are made equal.
     /// The "parent" `expr_id` is provided to construct errors.
     fn apply_equal2_constraint(
         &mut self, ctx: &Ctx, expr_id: ExpressionId,
         arg1_id: ExpressionId, arg1_start_idx: usize,
         arg2_id: ExpressionId, arg2_start_idx: usize
     ) -> Result<(bool, bool), ParseError2> {
         debug_assert_expr_ids_unique_and_known!(self, arg1_id, arg2_id);
         let arg1_type: *mut _ = self.expr_types.get_mut(&arg1_id).unwrap();
         let arg2_type: *mut _ = self.expr_types.get_mut(&arg2_id).unwrap();
         let infer_res = unsafe{ InferenceType::infer_subtrees_for_both_types(
             arg1_type, arg1_start_idx,
             arg2_type, arg2_start_idx
         ) };
         if infer_res == DualInferenceResult::Incompatible {
             return Err(self.construct_arg_type_error(ctx, expr_id, arg1_id, arg2_id));
+        }
         Ok((infer_res.modified_lhs(), infer_res.modified_rhs()))
+    }
     fn apply_equal2_constraint_types(
         ctx: &Ctx, expr_id: ExpressionId,
         type1: *mut InferenceType, type1_start_idx: usize,
         type2: *mut InferenceType, type2_start_idx: usize
     ) -> Result<(bool, bool), ParseError2> {
         debug_assert_ptrs_distinct!(type1, type2);
         let infer_res = unsafe {
             InferenceType::infer_subtrees_for_both_types(
                 type1, type1_start_idx,
                 type2, type2_start_idx
+            )
         };
         if infer_res == DualInferenceResult::Incompatible {
             return Err(ParseError2::new_error(
                 &ctx.module.source, ctx.heap[expr_id].position(),
                 "TODO: Write me, apply_equal2_constraint_types"
             ));
+        }
         Ok((infer_res.modified_lhs(), infer_res.modified_rhs()))
+    }
     /// Applies a type constraint that expects all three provided types to be
     /// equal. In case we can make progress in inferring the types then we
     /// attempt to do so. If the call is successful then the composition of all
     /// types is made equal.
@@ @@ -1903,252 +2048,251 @@ impl TypeResolvingVisitor { @@
         // If all types are compatible, but the second call caused the arg1_type
         // to be expanded, then we must also assign this to expr_type.
         let mut progress_expr = expr_res.modified_lhs();
         let mut progress_arg1 = expr_res.modified_rhs();
         let mut progress_arg2 = args_res.modified_rhs();
         if args_res.modified_lhs() {
             unsafe {
                 let end_idx = InferenceType::find_subtree_end_idx(&(*arg2_type).parts, start_idx);
                 let subtree = &((*arg2_type).parts[start_idx..end_idx]);
                 (*expr_type).replace_subtree(start_idx, subtree);
+            }
             progress_expr = true;
             progress_arg1 = true;
+        }
         Ok((progress_expr, progress_arg1, progress_arg2))
+    }
     // TODO: @optimize Since we only deal with a single type this might be done
     //  a lot more efficiently, methinks (disregarding the allocations here)
     fn apply_equal_n_constraint(
         &mut self, ctx: &Ctx, expr_id: ExpressionId, args: &[ExpressionId],
     ) -> Result<Vec<bool>, ParseError2> {
         // Early exit
         match args.len() {
 => return Ok(vec!()),         // nothing to progress
 => return Ok(vec![false]),    // only one type, so nothing to infer
             _ => {}
+        }
         let mut progress = Vec::new();
         progress.resize(args.len(), false);
         // Do pairwise inference, keep track of the last entry we made progress
         // on. Once done we need to update everything to the most-inferred type.
         let mut arg_iter = args.iter();
         let mut last_arg_id = *arg_iter.next().unwrap();
         let mut last_lhs_progressed = 0;
         let mut lhs_arg_idx = 0;
         while let Some(next_arg_id) = arg_iter.next() {
             let arg1_type: *mut _ = self.expr_types.get_mut(&last_arg_id).unwrap();
             let arg2_type: *mut _ = self.expr_types.get_mut(next_arg_id).unwrap();
             let res = unsafe {
                 InferenceType::infer_subtrees_for_both_types(arg1_type, 0, arg2_type, 0)
             };
             if res == DualInferenceResult::Incompatible {
                 return Err(self.construct_arg_type_error(ctx, expr_id, last_arg_id, *next_arg_id));
+            }
             if res.modified_lhs() {
                 // We re-inferred something on the left hand side, so everything
                 // up until now should be re-inferred.
                 progress[lhs_arg_idx] = true;
                 last_lhs_progressed = lhs_arg_idx;
+            }
             progress[lhs_arg_idx + 1] = res.modified_rhs();
             last_arg_id = *next_arg_id;
             lhs_arg_idx += 1;
+        }
         // Re-infer everything. Note that we do not need to re-infer the type
         // exactly at `last_lhs_progressed`, but only everything up to it.
         let last_type: *mut _ = self.expr_types.get_mut(args.last().unwrap()).unwrap();
         for arg_idx in 0..last_lhs_progressed {
             let arg_type: *mut _ = self.expr_types.get_mut(&args[arg_idx]).unwrap();
             unsafe{
                 (*arg_type).replace_subtree(0, &(*last_type).parts);
+            }
             progress[arg_idx] = true;
+        }
         Ok(progress)
+    }
     /// Determines the `InferenceType` for the expression based on the
     /// expression parent. Note that if the parent is another expression, we do
     /// not take special action, instead we let parent expressions fix the type
     /// of subexpressions before they have a chance to call this function.
     /// Hence: if the expression type is already set, this function doesn't do
     /// anything.
     fn insert_initial_expr_inference_type(
         &mut self, ctx: &mut Ctx, expr_id: ExpressionId
     ) -> Result<(), ParseError2> {
         use ExpressionParent as EP;
         use InferenceTypePart as ITP;
         let expr = &ctx.heap[expr_id];
         let inference_type = match expr.parent() {
             EP::None =>
                 // Should have been set by linker
                 unreachable!(),
-            EP::Memory(_) | EP::ExpressionStmt(_) | EP::Expression(_, _) =>
             EP::ExpressionStmt(_) | EP::Expression(_, _) =>
                 // Determined during type inference
                 InferenceType::new(false, false, vec![ITP::Unknown]),
             EP::If(_) | EP::While(_) | EP::Assert(_) =>
                 // Must be a boolean
                 InferenceType::new(false, true, vec![ITP::Bool]),
             EP::Return(_) =>
                 // Must match the return type of the function
                 if let DefinitionType::Function(func_id) = self.definition_type {
                     let return_parser_type_id = ctx.heap[func_id].return_type;
                     self.determine_inference_type_from_parser_type(ctx, return_parser_type_id, true)
                 } else {
                     // Cannot happen: definition always set upon body traversal
                     // and "return" calls in components are illegal.
                     unreachable!();
                 },
             EP::New(_) =>
                 // Must be a component call, which we assign a "Void" return
                 // type
                 InferenceType::new(false, true, vec![ITP::Void]),
         };
         match self.expr_types.entry(expr_id) {
             Entry::Vacant(vacant) => {
                 vacant.insert(inference_type);
             },
             Entry::Occupied(mut preexisting) => {
                 // We already have an entry, this happens if our parent fixed
                 // our type (e.g. we're used in a conditional expression's test)
                 // but we have a different type.
                 // TODO: Is this ever called? Seems like it can't
                 debug_assert!(false, "I am actually called, my ID is {}", expr_id.index);
                 let old_type = preexisting.get_mut();
                 if let SingleInferenceResult::Incompatible = InferenceType::infer_subtree_for_single_type(
                     old_type, 0, &inference_type.parts, 0
                 ) {
                     return Err(self.construct_expr_type_error(ctx, expr_id, expr_id))
+                }
+            }
+        }
         Ok(())
+    }
     fn insert_initial_call_polymorph_data(
         &mut self, ctx: &mut Ctx, call_id: CallExpressionId
     ) {
         use InferenceTypePart as ITP;
         // Note: the polymorph variables may be partially specified and may
         // contain references to the wrapping definition's (i.e. the proctype
         // we are currently visiting) polymorphic arguments.
         //
         // The arguments of the call may refer to polymorphic variables in the
         // definition of the function we're calling, not of the wrapping
         // definition. We insert markers in these inferred types to be able to
         // map them back and forth to the polymorphic arguments of the function
         // we are calling.
         let call = &ctx.heap[call_id];
         debug_assert!(!call.poly_args.is_empty());
         // Handle the polymorphic variables themselves
         let mut poly_vars = Vec::with_capacity(call.poly_args.len());
         for poly_arg_type_id in call.poly_args.clone() { // TODO: @performance
             poly_vars.push(self.determine_inference_type_from_parser_type(ctx, poly_arg_type_id, true));
+        }
         // Handle the arguments
         // TODO: @cleanup: Maybe factor this out for reuse in the validator/linker, should also
         //  make the code slightly more robust.
         let (embedded_types, return_type) = match &call.method {
             Method::Create => {
                 // Not polymorphic
                 unreachable!("insert initial polymorph data for builtin 'create()' call")
             },
             Method::Fires => {
                 // bool fires<T>(PortLike<T> arg)
+                (
                     vec![InferenceType::new(true, false, vec![ITP::PortLike, ITP::Marker(0), ITP::Unknown])],
                     InferenceType::new(false, true, vec![ITP::Bool])
+                )
             },
             Method::Get => {
                 // T get<T>(input<T> arg)
+                (
                     vec![InferenceType::new(true, false, vec![ITP::Input, ITP::Marker(0), ITP::Unknown])],
                     InferenceType::new(true, false, vec![ITP::Marker(0), ITP::Unknown])
+                )
             },
             Method::Put => {
                 // void Put<T>(output<T> port, T msg)
+                (
                     vec![
                         InferenceType::new(true, false, vec![ITP::Output, ITP::Marker(0), ITP::Unknown]),
                         InferenceType::new(true, false, vec![ITP::Marker(0), ITP::Unknown])
                     ],
                     InferenceType::new(false, true, vec![ITP::Void])
+                )
+            }
             Method::Symbolic(symbolic) => {
                 let definition = &ctx.heap[symbolic.definition.unwrap()];
                 match definition {
                     Definition::Component(definition) => {
                         let mut parameter_types = Vec::with_capacity(definition.parameters.len());
                         for param_id in definition.parameters.clone() {
                             let param = &ctx.heap[param_id];
                             let param_parser_type_id = param.parser_type;
                             parameter_types.push(self.determine_inference_type_from_parser_type(ctx, param_parser_type_id, false));
+                        }
                         (parameter_types, InferenceType::new(false, true, vec![InferenceTypePart::Void]))
                     },
                     Definition::Function(definition) => {
                         let mut parameter_types = Vec::with_capacity(definition.parameters.len());
                         for param_id in definition.parameters.clone() {
                             let param = &ctx.heap[param_id];
                             let param_parser_type_id = param.parser_type;
                             parameter_types.push(self.determine_inference_type_from_parser_type(ctx, param_parser_type_id, false));
+                        }
                         let return_type = self.determine_inference_type_from_parser_type(ctx, definition.return_type, false);
                         (parameter_types, return_type)
                     },
                     Definition::Struct(_) | Definition::Enum(_) => {
                         unreachable!("insert initial polymorph data for struct/enum");
+                    }
+                }
+            }
         };
         self.extra_data.insert(call_id.upcast(), ExtraData {
             poly_vars,
             embedded: embedded_types,
             returned: return_type
         });
+    }
     /// Determines the initial InferenceType from the provided ParserType. This
     /// may be called with two kinds of intentions:
     /// 1. To resolve a ParserType within the body of a function, or on
     ///     polymorphic arguments to calls/instantiations within that body. This
     ///     means that the polymorphic variables are known and can be replaced
     ///     with the monomorph we're instantiating.
     /// 2. To resolve a ParserType on a called function's definition or on
     ///     an instantiated datatype's members. This means that the polymorphic
     ///     arguments inside those ParserTypes refer to the polymorphic
     ///     variables in the called/instantiated type's definition.
     /// In the second case we place InferenceTypePart::Marker instances such
     /// that we can perform type inference on the polymorphic variables.
     fn determine_inference_type_from_parser_type(
         &mut self, ctx: &Ctx, parser_type_id: ParserTypeId,
         parser_type_in_body: bool
     ) -> InferenceType {
         use ParserTypeVariant as PTV;
         use InferenceTypePart as ITP;

src/protocol/parser/visitor_linker.rs

➞

Show inline comments

@@ @@ -127,195 +127,192 @@ impl ValidityAndLinkerVisitor { @@
 impl Visitor2 for ValidityAndLinkerVisitor {
     //--------------------------------------------------------------------------
     // Definition visitors
     //--------------------------------------------------------------------------
     fn visit_component_definition(&mut self, ctx: &mut Ctx, id: ComponentId) -> VisitorResult {
         self.reset_state();
         self.def_type = match &ctx.heap[id].variant {
             ComponentVariant::Primitive => DefinitionType::Primitive(id),
             ComponentVariant::Composite => DefinitionType::Composite(id),
         };
         self.cur_scope = Some(Scope::Definition(id.upcast()));
         self.expr_parent = ExpressionParent::None;
         // Visit types of parameters
         debug_assert!(self.parser_type_buffer.is_empty());
         let comp_def = &ctx.heap[id];
         self.parser_type_buffer.extend(
             comp_def.parameters
                 .iter()
                 .map(|id| ctx.heap[*id].parser_type)
         );
         let num_types = self.parser_type_buffer.len();
         for idx in 0..num_types {
             self.visit_parser_type(ctx, self.parser_type_buffer[idx])?;
+        }
         self.parser_type_buffer.clear();
         // Visit statements in component body
         let body_id = ctx.heap[id].body;
         self.performing_breadth_pass = true;
         self.visit_stmt(ctx, body_id)?;
         self.performing_breadth_pass = false;
         self.visit_stmt(ctx, body_id)?;
         self.check_post_definition_state();
         Ok(())
+    }
     fn visit_function_definition(&mut self, ctx: &mut Ctx, id: FunctionId) -> VisitorResult {
         self.reset_state();
         // Set internal statement indices
         self.def_type = DefinitionType::Function(id);
         self.cur_scope = Some(Scope::Definition(id.upcast()));
         self.expr_parent = ExpressionParent::None;
         // Visit types of parameters
         debug_assert!(self.parser_type_buffer.is_empty());
         let func_def = &ctx.heap[id];
         self.parser_type_buffer.extend(
             func_def.parameters
                 .iter()
                 .map(|id| ctx.heap[*id].parser_type)
         );
         self.parser_type_buffer.push(func_def.return_type);
         let num_types = self.parser_type_buffer.len();
         for idx in 0..num_types {
             self.visit_parser_type(ctx, self.parser_type_buffer[idx])?;
+        }
         self.parser_type_buffer.clear();
         // Visit statements in function body
         let body_id = ctx.heap[id].body;
         self.performing_breadth_pass = true;
         self.visit_stmt(ctx, body_id)?;
         self.performing_breadth_pass = false;
         self.visit_stmt(ctx, body_id)?;
         self.check_post_definition_state();
         Ok(())
+    }
     //--------------------------------------------------------------------------
     // Statement visitors
     //--------------------------------------------------------------------------
     fn visit_block_stmt(&mut self, ctx: &mut Ctx, id: BlockStatementId) -> VisitorResult {
         self.visit_block_stmt_with_hint(ctx, id, None)
+    }
     fn visit_local_memory_stmt(&mut self, ctx: &mut Ctx, id: MemoryStatementId) -> VisitorResult {
         if self.performing_breadth_pass {
             let variable_id = ctx.heap[id].variable;
             self.checked_local_add(ctx, self.relative_pos_in_block, variable_id)?;
         } else {
             let variable_id = ctx.heap[id].variable;
             let parser_type_id = ctx.heap[variable_id].parser_type;
             self.visit_parser_type(ctx, parser_type_id)?;
             debug_assert_eq!(self.expr_parent, ExpressionParent::None);
             self.expr_parent = ExpressionParent::Memory(id);
             self.visit_expr(ctx, ctx.heap[id].initial)?;
             self.expr_parent = ExpressionParent::None;
+        }
         Ok(())
+    }
     fn visit_local_channel_stmt(&mut self, ctx: &mut Ctx, id: ChannelStatementId) -> VisitorResult {
         if self.performing_breadth_pass {
             let (from_id, to_id) = {
                 let stmt = &ctx.heap[id];
                 (stmt.from, stmt.to)
             };
             self.checked_local_add(ctx, self.relative_pos_in_block, from_id)?;
             self.checked_local_add(ctx, self.relative_pos_in_block, to_id)?;
         } else {
             let chan_stmt = &ctx.heap[id];
             let from_type_id = ctx.heap[chan_stmt.from].parser_type;
             let to_type_id = ctx.heap[chan_stmt.to].parser_type;
             self.visit_parser_type(ctx, from_type_id)?;
             self.visit_parser_type(ctx, to_type_id)?;
+        }
         Ok(())
+    }
     fn visit_labeled_stmt(&mut self, ctx: &mut Ctx, id: LabeledStatementId) -> VisitorResult {
         if self.performing_breadth_pass {
             // Add label to block lookup
             self.checked_label_add(ctx, id)?;
             // Modify labeled statement itself
             let labeled = &mut ctx.heap[id];
             labeled.relative_pos_in_block = self.relative_pos_in_block;
             labeled.in_sync = self.in_sync.clone();
+        }
         let body_id = ctx.heap[id].body;
         self.visit_stmt(ctx, body_id)?;
         Ok(())
+    }
     fn visit_if_stmt(&mut self, ctx: &mut Ctx, id: IfStatementId) -> VisitorResult {
         if self.performing_breadth_pass {
             let position = ctx.heap[id].position;
             let end_if_id = ctx.heap.alloc_end_if_statement(|this| {
                 EndIfStatement {
                     this,
                     start_if: id,
                     position,
                     next: None,
+                }
             });
             let stmt = &mut ctx.heap[id];
             stmt.end_if = Some(end_if_id);
             self.insert_buffer.push((self.relative_pos_in_block + 1, end_if_id.upcast()));
         } else {
             // Traverse expression and bodies
             let (test_id, true_id, false_id) = {
                 let stmt = &ctx.heap[id];
                 (stmt.test, stmt.true_body, stmt.false_body)
             };
             debug_assert_eq!(self.expr_parent, ExpressionParent::None);
             self.expr_parent = ExpressionParent::If(id);
             self.visit_expr(ctx, test_id)?;
             self.expr_parent = ExpressionParent::None;
             self.visit_stmt(ctx, true_id)?;
             self.visit_stmt(ctx, false_id)?;
+        }
         Ok(())
+    }
     fn visit_while_stmt(&mut self, ctx: &mut Ctx, id: WhileStatementId) -> VisitorResult {
         if self.performing_breadth_pass {
             let position = ctx.heap[id].position;
             let end_while_id = ctx.heap.alloc_end_while_statement(|this| {
                 EndWhileStatement {
                     this,
                     start_while: id,
                     position,
                     next: None,
+                }
             });
             let stmt = &mut ctx.heap[id];
             stmt.end_while = Some(end_while_id);
             stmt.in_sync = self.in_sync.clone();
             self.insert_buffer.push((self.relative_pos_in_block + 1, end_while_id.upcast()));
         } else {
             let (test_id, body_id) = {
                 let stmt = &ctx.heap[id];
                 (stmt.test, stmt.body)
             };
             let old_while = self.in_while.replace(id);

src/runtime/tests.rs

➞

Show inline comments

@@ @@ -1304,149 +1304,149 @@ fn for_msg_byte() { @@
     c.add_component(b"for_msg_byte", &[p0]).unwrap();
     c.connect(None).unwrap();
     for expecting in 0u8..8 {
         c.get(g0).unwrap();
         c.sync(None).unwrap();
         assert_eq!(&[expecting], c.gotten(g0).unwrap().as_slice());
+    }
     c.sync(None).unwrap();
+}
 #[test]
 fn eq_causality() {
     let test_log_path = Path::new("./logs/eq_causality");
     let pdl = b"
     primitive eq(in a, in b, out c) {
         msg ma = null;
         msg mb = null;
         while(true) synchronous {
             if(fires(a)) {
                 // b and c also fire!
                 // left first!
                 ma = get(a);
                 put(c, ma);
                 mb = get(b);
                 assert(ma == mb);
+            }
+        }
+    }
     ";
     let pd = reowolf::ProtocolDescription::parse(pdl).unwrap();
     let mut c = file_logged_configured_connector(0, test_log_path, Arc::new(pd));
     /*
     [native]p0-->g0[eq]p1--.
                  g1        |
                  ^---------`
     */
     let [p0, g0] = c.new_port_pair();
     let [p1, g1] = c.new_port_pair();
     c.add_component(b"eq", &[g0, g1, p1]).unwrap();
     /*
                   V--------.
                  g2        |
     [native]p2-->g3[eq]p3--`
     */
     let [p2, g2] = c.new_port_pair();
     let [p3, g3] = c.new_port_pair();
     c.add_component(b"eq", &[g3, g2, p3]).unwrap();
     c.connect(None).unwrap();
     for _ in 0..4 {
         // everything is fine with LEFT FIRST
         c.put(p0, TEST_MSG.clone()).unwrap();
         c.sync(MS100).unwrap();
         // no solution when left is NOT FIRST
         c.put(p2, TEST_MSG.clone()).unwrap();
         c.sync(MS100).unwrap_err();
+    }
+}
 #[test]
 fn eq_no_causality() {
     let test_log_path = Path::new("./logs/eq_no_causality");
     let pdl = b"
     composite eq(in<msg> a, in<msg> b, out<msg> c) {
         channel leftfirsto -> leftfirsti;
         new eqinner(a, b, c, leftfirsto, leftfirsti);
+    }
     primitive eqinner(in<msg> a, in<msg> b, out<msg> c, out<msg> leftfirsto, in<msg> leftfirsti) {
         msg ma = null;
         msg mb = null;
         while(true) synchronous {
             if(fires(a)) {
                 // b and c also fire!
                 if(fires(leftfirsti)) {
                     // left first! DO USE DUMMY
                     ma = get(a);
                     put(c, ma);
                     mb = get(b);
                     // using dummy!
                     put(leftfirsto, ma);
                     get(leftfirsti);
                 } else {
                     // right first! DON'T USE DUMMY
                     mb = get(b);
                     put(c, mb);
                     ma = get(a);
+                }
                 assert(ma == mb);
+            }
+        }
+    }
-    T some_function<T>(msg a, msg b) {
+    T some_function<T>(int a, int b) {
         T something = a;
         return something;
+    }
     primitive quick_test(in<int> a, in<int> b) {
         // msg ma = null;
         auto test1 = 0;
         auto test2 = 0;
         auto ma = some_function(test1, test2);
         while(true) synchronous {
             if (fires(a)) {
                 ma = get(a);
+            }
             if (fires(b)) {
                 ma = get(b);
+            }
             if (fires(a) && fires(b)) {
                 ma = get(a) + get(b);
+            }
+        }
+    }
     ";
     let pd = reowolf::ProtocolDescription::parse(pdl).unwrap();
     let mut c = file_logged_configured_connector(0, test_log_path, Arc::new(pd));
     /*
     [native]p0-->g0[eq]p1--.
                  g1        |
                  ^---------`
     */
     let [p0, g0] = c.new_port_pair();
     let [p1, g1] = c.new_port_pair();
     c.add_component(b"eq", &[g0, g1, p1]).unwrap();
     /*
                   V--------.
                  g2        |
     [native]p2-->g3[eq]p3--`
     */
     let [p2, g2] = c.new_port_pair();
     let [p3, g3] = c.new_port_pair();
     c.add_component(b"eq", &[g3, g2, p3]).unwrap();
     c.connect(None).unwrap();
     for _ in 0..32 {
         // ok when they send
         c.put(p0, TEST_MSG.clone()).unwrap();
         c.put(p2, TEST_MSG.clone()).unwrap();
         c.sync(SEC1).unwrap();
         // ok when they don't
         c.sync(SEC1).unwrap();
+    }
+}

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