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8 Commits

Author SHA1 Message Date
Greg Shuflin
4c99be700f Fix failing test 2021-12-16 10:49:46 -08:00
Greg Shuflin
2247d9b58e Add failing test 2021-12-16 02:43:16 -08:00
Greg Shuflin
dcec8be307 Note about lookup_name_in_scope 2021-12-16 02:35:58 -08:00
Greg Shuflin
934a390f2d Walk impl block 2021-12-16 02:34:18 -08:00
Greg Shuflin
8e8be1b449 A couple simplifications 2021-12-11 18:38:23 -08:00
Greg Shuflin
5bfd79669e Rename environment -> memory 2021-12-11 04:14:26 -08:00
Greg Shuflin
d913443e97 WIP evaluating self in method call 2021-12-09 03:46:13 -08:00
Greg Shuflin
b5ec8116a2 handle impl block 2021-12-08 02:53:41 -08:00
14 changed files with 280 additions and 101 deletions

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@ -18,6 +18,7 @@ use crate::{
derivative::Derivative, derivative::Derivative,
identifier::{define_id_kind, Id}, identifier::{define_id_kind, Id},
parsing::Location, parsing::Location,
util::delim_wrapped,
}; };
define_id_kind!(ASTItem); define_id_kind!(ASTItem);
@ -40,12 +41,12 @@ impl fmt::Display for AST {
#[derive(Derivative, Debug, Clone)] #[derive(Derivative, Debug, Clone)]
#[derivative(PartialEq)] #[derivative(PartialEq)]
pub struct Statement { pub struct Statement<K> {
#[derivative(PartialEq = "ignore")] #[derivative(PartialEq = "ignore")]
pub id: ItemId, pub id: ItemId,
#[derivative(PartialEq = "ignore")] #[derivative(PartialEq = "ignore")]
pub location: Location, pub location: Location,
pub kind: StatementKind, pub kind: K,
} }
#[derive(Debug, PartialEq, Clone)] #[derive(Debug, PartialEq, Clone)]
@ -65,23 +66,23 @@ pub enum FlowControl {
#[derive(Debug, Clone, PartialEq, Default)] #[derive(Debug, Clone, PartialEq, Default)]
pub struct Block { pub struct Block {
pub statements: Vec<Statement>, pub statements: Vec<Statement<StatementKind>>,
} }
impl From<Vec<Statement>> for Block { impl From<Vec<Statement<StatementKind>>> for Block {
fn from(statements: Vec<Statement>) -> Self { fn from(statements: Vec<Statement<StatementKind>>) -> Self {
Self { statements } Self { statements }
} }
} }
impl From<Statement> for Block { impl From<Statement<StatementKind>> for Block {
fn from(statement: Statement) -> Self { fn from(statement: Statement<StatementKind>) -> Self {
Self { statements: vec![statement] } Self { statements: vec![statement] }
} }
} }
impl AsRef<[Statement]> for Block { impl AsRef<[Statement<StatementKind>]> for Block {
fn as_ref(&self) -> &[Statement] { fn as_ref(&self) -> &[Statement<StatementKind>] {
self.statements.as_ref() self.statements.as_ref()
} }
} }
@ -123,15 +124,41 @@ pub struct FormalParam {
pub enum Declaration { pub enum Declaration {
FuncSig(Signature), FuncSig(Signature),
FuncDecl(Signature, Block), FuncDecl(Signature, Block),
TypeDecl { name: TypeSingletonName, body: TypeBody, mutable: bool }, TypeDecl {
name: TypeSingletonName,
body: TypeBody,
mutable: bool,
},
//TODO TypeAlias `original` needs to be a more complex type definition //TODO TypeAlias `original` needs to be a more complex type definition
TypeAlias { alias: Rc<String>, original: Rc<String> }, TypeAlias {
Binding { name: Rc<String>, constant: bool, type_anno: Option<TypeIdentifier>, expr: Expression }, alias: Rc<String>,
Impl { type_name: TypeIdentifier, interface_name: Option<TypeSingletonName>, block: Vec<Declaration> }, original: Rc<String>,
Interface { name: Rc<String>, signatures: Vec<Signature> }, },
Binding {
name: Rc<String>,
constant: bool,
type_anno: Option<TypeIdentifier>,
expr: Expression,
},
Impl {
type_name: TypeIdentifier,
interface_name: Option<TypeSingletonName>,
block: Vec<Statement<Declaration>>,
},
Interface {
name: Rc<String>,
signatures: Vec<Signature>,
},
//TODO need to limit the types of statements that can be annotated //TODO need to limit the types of statements that can be annotated
Annotation { name: Rc<String>, arguments: Vec<Expression>, inner: Box<Statement> }, Annotation {
Module { name: Rc<String>, items: Block }, name: Rc<String>,
arguments: Vec<Expression>,
inner: Box<Statement<StatementKind>>,
},
Module {
name: Rc<String>,
items: Block,
},
} }
#[derive(Debug, PartialEq, Clone)] #[derive(Debug, PartialEq, Clone)]
@ -192,6 +219,22 @@ pub enum TypeIdentifier {
Singleton(TypeSingletonName), Singleton(TypeSingletonName),
} }
impl fmt::Display for TypeIdentifier {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self {
TypeIdentifier::Tuple(items) =>
write!(f, "{}", delim_wrapped('(', ')', items.iter().map(|item| item.to_string()))),
TypeIdentifier::Singleton(tsn) => {
write!(f, "{}", tsn.name)?;
if !tsn.params.is_empty() {
write!(f, "{}", delim_wrapped('<', '>', tsn.params.iter().map(|item| item.to_string())))?;
}
Ok(())
}
}
}
}
#[derive(Debug, PartialEq, Clone)] #[derive(Debug, PartialEq, Clone)]
pub struct TypeSingletonName { pub struct TypeSingletonName {
pub name: Rc<String>, pub name: Rc<String>,

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@ -29,7 +29,7 @@ pub(super) fn render_ast(ast: &AST) -> String {
buf buf
} }
fn render_statement(stmt: &Statement, indent: usize, buf: &mut String) { fn render_statement(stmt: &Statement<StatementKind>, indent: usize, buf: &mut String) {
use StatementKind::*; use StatementKind::*;
do_indent(indent, buf); do_indent(indent, buf);
match stmt.kind { match stmt.kind {

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@ -163,7 +163,7 @@ pub fn block(input: Span) -> ParseResult<Block> {
context("block", map(block_template(many1(statement_delimiter), statement), |items| items.into()))(input) context("block", map(block_template(many1(statement_delimiter), statement), |items| items.into()))(input)
} }
fn statement(input: Span) -> ParseResult<Statement> { fn statement(input: Span) -> ParseResult<Statement<StatementKind>> {
let (input, pos) = position(input)?; let (input, pos) = position(input)?;
let location = pos.location_offset().into(); let location = pos.location_offset().into();
let id = fresh_id(&input); let id = fresh_id(&input);
@ -243,8 +243,16 @@ fn implementation(input: Span) -> ParseResult<Declaration> {
))(input) ))(input)
} }
fn decl_block(input: Span) -> ParseResult<Vec<Declaration>> { fn decl_block(input: Span) -> ParseResult<Vec<Statement<Declaration>>> {
block_template(many1(statement_delimiter), func_decl)(input) context("decl-block", block_template(many1(statement_delimiter), func_decl_statement))(input)
}
fn func_decl_statement(input: Span) -> ParseResult<Statement<Declaration>> {
let (input, pos) = position(input)?;
let location = pos.location_offset().into();
let id = fresh_id(&input);
let (rest, kind) = context("decl-statement", func_decl)(input)?;
Ok((rest, Statement { id, location, kind }))
} }
fn interface(input: Span) -> ParseResult<Declaration> { fn interface(input: Span) -> ParseResult<Declaration> {

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@ -38,10 +38,10 @@ peg::parser! {
"{" __ items:(statement(parser) ** delimiter()) delimiter()? __ "}" { items.into() } / "{" __ items:(statement(parser) ** delimiter()) delimiter()? __ "}" { items.into() } /
"{" __ stmt:statement(parser) __ "}" { vec![stmt].into() } "{" __ stmt:statement(parser) __ "}" { vec![stmt].into() }
rule block_item(parser: &mut Parser) -> Statement = rule block_item(parser: &mut Parser) -> Statement<StatementKind> =
_ stmt:statement(parser) _ delimiter()+ { stmt } _ stmt:statement(parser) _ delimiter()+ { stmt }
rule statement(parser: &mut Parser) -> Statement = rule statement(parser: &mut Parser) -> Statement<StatementKind> =
_ pos:position!() kind:statement_kind(parser) _ { Statement { id: parser.fresh(), location: pos.into(), kind } } _ pos:position!() kind:statement_kind(parser) _ { Statement { id: parser.fresh(), location: pos.into(), kind } }
rule statement_kind(parser: &mut Parser) -> StatementKind = rule statement_kind(parser: &mut Parser) -> StatementKind =
@ -100,8 +100,11 @@ peg::parser! {
Declaration::Impl { type_name, interface_name: None, block } Declaration::Impl { type_name, interface_name: None, block }
} }
rule decl_block(parser: &mut Parser) -> Vec<Declaration> = rule decl_block(parser: &mut Parser) -> Vec<Statement<Declaration>> =
"{" __ decls:(func_declaration(parser) ** (delimiter()+)) delimiter()? __ "}" { decls } "{" __ decls:(func_declaration_stmt(parser) ** (delimiter()+)) delimiter()? __ "}" { decls }
rule func_declaration_stmt(parser: &mut Parser) -> Statement<Declaration> =
pos:position!() decl:func_declaration(parser) { Statement { id: parser.fresh(), location: pos.into(), kind: decl } }
rule interface(parser: &mut Parser) -> Declaration = rule interface(parser: &mut Parser) -> Declaration =
"interface" _ name:identifier() _ signatures:signature_block(parser) { Declaration::Interface { name: rc_string(name), signatures } } "interface" _ name:identifier() _ signatures:signature_block(parser) { Declaration::Interface { name: rc_string(name), signatures } }

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@ -21,11 +21,11 @@ fn strlit(s: &str) -> ExpressionKind {
ExpressionKind::StringLiteral { s: Rc::new(s.to_string()), prefix: None } ExpressionKind::StringLiteral { s: Rc::new(s.to_string()), prefix: None }
} }
fn stmt(kind: StatementKind) -> Statement { fn stmt<K>(kind: K) -> Statement<K> {
Statement { location: Location::default(), id: ItemId::default(), kind } Statement { location: Location::default(), id: ItemId::default(), kind }
} }
fn exst(kind: ExpressionKind) -> Statement { fn exst(kind: ExpressionKind) -> Statement<StatementKind> {
Statement { Statement {
location: Location::default(), location: Location::default(),
id: ItemId::default(), id: ItemId::default(),
@ -33,7 +33,7 @@ fn exst(kind: ExpressionKind) -> Statement {
} }
} }
fn decl(declaration: Declaration) -> Statement { fn decl(declaration: Declaration) -> Statement<StatementKind> {
Statement { Statement {
location: Location::default(), location: Location::default(),
id: ItemId::default(), id: ItemId::default(),
@ -41,7 +41,7 @@ fn decl(declaration: Declaration) -> Statement {
} }
} }
fn fn_decl(sig: Signature, stmts: Block) -> Statement { fn fn_decl(sig: Signature, stmts: Block) -> Statement<StatementKind> {
Statement { Statement {
kind: StatementKind::Declaration(Declaration::FuncDecl(sig, stmts)), kind: StatementKind::Declaration(Declaration::FuncDecl(sig, stmts)),
location: Default::default(), location: Default::default(),
@ -992,14 +992,14 @@ fn impls() {
use Declaration::{FuncDecl, Impl}; use Declaration::{FuncDecl, Impl};
let block = vec![ let block = vec![
FuncDecl( stmt(FuncDecl(
Signature { name: rc("yolo"), operator: false, params: vec![], type_anno: None }, Signature { name: rc("yolo"), operator: false, params: vec![], type_anno: None },
vec![].into(), vec![].into(),
), )),
FuncDecl( stmt(FuncDecl(
Signature { name: rc("swagg"), operator: false, params: vec![], type_anno: None }, Signature { name: rc("swagg"), operator: false, params: vec![], type_anno: None },
vec![].into(), vec![].into(),
), )),
]; ];
assert_ast!( assert_ast!(

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@ -51,9 +51,8 @@ impl<'a, 'b> Reducer<'a, 'b> {
.. ..
}) => { }) => {
let symbol = self.symbol_table.lookup_symbol(item_id).unwrap(); let symbol = self.symbol_table.lookup_symbol(item_id).unwrap();
let def_id = symbol.def_id();
entrypoint.push(Statement::Binding { entrypoint.push(Statement::Binding {
id: def_id, id: symbol.def_id(),
constant: *constant, constant: *constant,
expr: self.expression(expr), expr: self.expression(expr),
}); });
@ -65,7 +64,7 @@ impl<'a, 'b> Reducer<'a, 'b> {
ReducedIR { functions: self.functions, entrypoint } ReducedIR { functions: self.functions, entrypoint }
} }
fn top_level_definition(&mut self, statement: &ast::Statement) { fn top_level_definition(&mut self, statement: &ast::Statement<ast::StatementKind>) {
let ast::Statement { id: item_id, kind, .. } = statement; let ast::Statement { id: item_id, kind, .. } = statement;
match kind { match kind {
ast::StatementKind::Expression(_expr) => { ast::StatementKind::Expression(_expr) => {
@ -85,7 +84,10 @@ impl<'a, 'b> Reducer<'a, 'b> {
} }
} }
fn function_internal_statement(&mut self, statement: &ast::Statement) -> Option<Statement> { fn function_internal_statement(
&mut self,
statement: &ast::Statement<ast::StatementKind>,
) -> Option<Statement> {
let ast::Statement { id: item_id, kind, .. } = statement; let ast::Statement { id: item_id, kind, .. } = statement;
match kind { match kind {
ast::StatementKind::Expression(expr) => Some(Statement::Expression(self.expression(expr))), ast::StatementKind::Expression(expr) => Some(Statement::Expression(self.expression(expr))),
@ -96,8 +98,11 @@ impl<'a, 'b> Reducer<'a, 'b> {
} }
ast::Declaration::Binding { constant, expr, .. } => { ast::Declaration::Binding { constant, expr, .. } => {
let symbol = self.symbol_table.lookup_symbol(item_id).unwrap(); let symbol = self.symbol_table.lookup_symbol(item_id).unwrap();
let def_id = symbol.def_id(); Some(Statement::Binding {
Some(Statement::Binding { id: def_id, constant: *constant, expr: self.expression(expr) }) id: symbol.def_id(),
constant: *constant,
expr: self.expression(expr),
})
} }
_ => None, _ => None,
}, },
@ -115,16 +120,15 @@ impl<'a, 'b> Reducer<'a, 'b> {
fn insert_function_definition(&mut self, item_id: &ast::ItemId, statements: &ast::Block) { fn insert_function_definition(&mut self, item_id: &ast::ItemId, statements: &ast::Block) {
let symbol = self.symbol_table.lookup_symbol(item_id).unwrap(); let symbol = self.symbol_table.lookup_symbol(item_id).unwrap();
let def_id = symbol.def_id();
let function_def = FunctionDefinition { body: self.function_internal_block(statements) }; let function_def = FunctionDefinition { body: self.function_internal_block(statements) };
self.functions.insert(def_id, function_def); self.functions.insert(symbol.def_id(), function_def);
} }
fn expression(&mut self, expr: &ast::Expression) -> Expression { fn expression(&mut self, expr: &ast::Expression) -> Expression {
use crate::ast::ExpressionKind::*; use crate::ast::ExpressionKind::*;
match &expr.kind { match &expr.kind {
SelfValue => panic!(), SelfValue => Expression::Lookup(Lookup::SelfParam),
NatLiteral(n) => Expression::Literal(Literal::Nat(*n)), NatLiteral(n) => Expression::Literal(Literal::Nat(*n)),
FloatLiteral(f) => Expression::Literal(Literal::Float(*f)), FloatLiteral(f) => Expression::Literal(Literal::Float(*f)),
//TODO implement handling string literal prefixes //TODO implement handling string literal prefixes
@ -133,10 +137,19 @@ impl<'a, 'b> Reducer<'a, 'b> {
BinExp(binop, lhs, rhs) => self.binop(binop, lhs, rhs), BinExp(binop, lhs, rhs) => self.binop(binop, lhs, rhs),
PrefixExp(op, arg) => self.prefix(op, arg), PrefixExp(op, arg) => self.prefix(op, arg),
Value(qualified_name) => self.value(qualified_name), Value(qualified_name) => self.value(qualified_name),
Call { f, arguments } => Expression::Call { Call { f, arguments } => {
f: Box::new(self.expression(f)), let f = self.expression(f);
args: arguments.iter().map(|arg| self.invocation_argument(arg)).collect(), let args = arguments.iter().map(|arg| self.invocation_argument(arg)).collect();
}, //TODO need to have full type availability at this point to do this method lookup
//correctly
if let Expression::Access { name, expr } = f {
let def_id = unimplemented!();
let method = Expression::Lookup(Lookup::Function(def_id));
Expression::CallMethod { f: Box::new(method), args, self_expr: expr }
} else {
Expression::Call { f: Box::new(f), args }
}
}
TupleLiteral(exprs) => Expression::Tuple(exprs.iter().map(|e| self.expression(e)).collect()), TupleLiteral(exprs) => Expression::Tuple(exprs.iter().map(|e| self.expression(e)).collect()),
IfExpression { discriminator, body } => IfExpression { discriminator, body } =>
self.reduce_if_expression(discriminator.as_ref().map(|x| x.as_ref()), body), self.reduce_if_expression(discriminator.as_ref().map(|x| x.as_ref()), body),

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@ -57,6 +57,7 @@ pub enum Expression {
Access { name: String, expr: Box<Expression> }, Access { name: String, expr: Box<Expression> },
Callable(Callable), Callable(Callable),
Call { f: Box<Expression>, args: Vec<Expression> }, Call { f: Box<Expression>, args: Vec<Expression> },
CallMethod { f: Box<Expression>, args: Vec<Expression>, self_expr: Box<Expression> },
Conditional { cond: Box<Expression>, then_clause: Vec<Statement>, else_clause: Vec<Statement> }, Conditional { cond: Box<Expression>, then_clause: Vec<Statement>, else_clause: Vec<Statement> },
CaseMatch { cond: Box<Expression>, alternatives: Vec<Alternative> }, CaseMatch { cond: Box<Expression>, alternatives: Vec<Alternative> },
Loop { cond: Box<Expression>, statements: Vec<Statement> }, Loop { cond: Box<Expression>, statements: Vec<Statement> },
@ -90,6 +91,7 @@ pub enum Lookup {
GlobalVar(DefId), GlobalVar(DefId),
Function(DefId), Function(DefId),
Param(u8), Param(u8),
SelfParam,
} }
#[derive(Debug, Clone, PartialEq)] #[derive(Debug, Clone, PartialEq)]

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@ -35,6 +35,7 @@ pub enum SymbolError {
DuplicateRecord { type_fqsn: Fqsn, location: Location, record: String, member: String }, DuplicateRecord { type_fqsn: Fqsn, location: Location, record: String, member: String },
UnknownAnnotation { name: String }, UnknownAnnotation { name: String },
BadAnnotation { name: String, msg: String }, BadAnnotation { name: String, msg: String },
BadImplBlockEntry,
} }
#[allow(dead_code)] #[allow(dead_code)]

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@ -1,5 +1,6 @@
use std::{ use std::{
collections::{hash_map::Entry, HashMap, HashSet}, collections::{hash_map::Entry, HashMap, HashSet},
rc::Rc,
str::FromStr, str::FromStr,
}; };
@ -38,7 +39,7 @@ impl<'a> SymbolTablePopulator<'a> {
fn add_from_scope( fn add_from_scope(
&mut self, &mut self,
statements: &[Statement], statements: &[Statement<StatementKind>],
scope_stack: &mut Vec<ScopeSegment>, scope_stack: &mut Vec<ScopeSegment>,
function_scope: bool, function_scope: bool,
) -> Vec<SymbolError> { ) -> Vec<SymbolError> {
@ -75,11 +76,33 @@ impl<'a> SymbolTablePopulator<'a> {
self.add_type_members(name, body, mutable, location, type_fqsn) self.add_type_members(name, body, mutable, location, type_fqsn)
} }
/* Declaration::Impl { type_name, interface_name, block } => {
Declaration::Impl { type_name, body, .. } => { let mut errors = vec![];
let new_scope = ScopeSegment::Name(Rc::new(format!("<impl-block>{}", type_name)));
scope_stack.push(new_scope);
}, for decl_stmt in block.iter() {
*/ let Statement { id, kind, location } = decl_stmt;
let location = *location;
match kind {
decl @ Declaration::FuncDecl(signature, body) => {
let output =
self.add_single_declaration(id, decl, location, scope_stack, true);
if let Err(e) = output {
errors.push(e);
};
let new_scope = ScopeSegment::Name(signature.name.clone());
scope_stack.push(new_scope);
let output = self.add_from_scope(body.as_ref(), scope_stack, true);
scope_stack.pop();
errors.extend(output.into_iter());
}
_other => errors.push(SymbolError::BadImplBlockEntry),
};
}
scope_stack.pop();
errors
}
_ => vec![], _ => vec![],
}; };
errors.extend(recursive_errs.into_iter()); errors.extend(recursive_errs.into_iter());
@ -98,7 +121,22 @@ impl<'a> SymbolTablePopulator<'a> {
function_scope: bool, function_scope: bool,
) -> Result<(), SymbolError> { ) -> Result<(), SymbolError> {
match kind { match kind {
StatementKind::Declaration(Declaration::FuncSig(signature)) => { StatementKind::Declaration(decl) =>
self.add_single_declaration(id, decl, location, scope_stack, function_scope),
_ => return Ok(()),
}
}
fn add_single_declaration(
&mut self,
id: &ItemId,
decl: &Declaration,
location: Location,
scope_stack: &[ScopeSegment],
function_scope: bool,
) -> Result<(), SymbolError> {
match decl {
Declaration::FuncSig(signature) => {
let fq_function = Fqsn::from_scope_stack(scope_stack, signature.name.clone()); let fq_function = Fqsn::from_scope_stack(scope_stack, signature.name.clone());
self.table self.table
.fq_names .fq_names
@ -109,7 +147,7 @@ impl<'a> SymbolTablePopulator<'a> {
self.add_symbol(id, fq_function, SymbolSpec::Func { method: None }); self.add_symbol(id, fq_function, SymbolSpec::Func { method: None });
} }
StatementKind::Declaration(Declaration::FuncDecl(signature, ..)) => { Declaration::FuncDecl(signature, ..) => {
let fn_name = &signature.name; let fn_name = &signature.name;
let fq_function = Fqsn::from_scope_stack(scope_stack, fn_name.clone()); let fq_function = Fqsn::from_scope_stack(scope_stack, fn_name.clone());
self.table self.table
@ -121,11 +159,13 @@ impl<'a> SymbolTablePopulator<'a> {
self.add_symbol(id, fq_function, SymbolSpec::Func { method: None }); self.add_symbol(id, fq_function, SymbolSpec::Func { method: None });
} }
StatementKind::Declaration(Declaration::TypeDecl { name, .. }) => { Declaration::TypeDecl { name, .. } => {
let fq_type = Fqsn::from_scope_stack(scope_stack, name.name.clone()); let fq_type = Fqsn::from_scope_stack(scope_stack, name.name.clone());
self.table.types.register(fq_type, NameSpec { location, kind: TypeKind::Constructor })?; self.table.types.register(fq_type, NameSpec { location, kind: TypeKind::Constructor })?;
} }
StatementKind::Declaration(Declaration::Binding { name, .. }) => { //TODO handle type aliases
Declaration::TypeAlias { .. } => (),
Declaration::Binding { name, .. } => {
let fq_binding = Fqsn::from_scope_stack(scope_stack, name.clone()); let fq_binding = Fqsn::from_scope_stack(scope_stack, name.clone());
self.table self.table
.fq_names .fq_names
@ -134,11 +174,14 @@ impl<'a> SymbolTablePopulator<'a> {
self.add_symbol(id, fq_binding, SymbolSpec::GlobalBinding); self.add_symbol(id, fq_binding, SymbolSpec::GlobalBinding);
} }
} }
StatementKind::Declaration(Declaration::Module { name, .. }) => { //TODO implement interfaces
Declaration::Interface { .. } => (),
Declaration::Impl { .. } => (),
Declaration::Module { name, .. } => {
let fq_module = Fqsn::from_scope_stack(scope_stack, name.clone()); let fq_module = Fqsn::from_scope_stack(scope_stack, name.clone());
self.table.fq_names.register(fq_module, NameSpec { location, kind: NameKind::Module })?; self.table.fq_names.register(fq_module, NameSpec { location, kind: NameKind::Module })?;
} }
StatementKind::Declaration(Declaration::Annotation { name, arguments, inner }) => { Declaration::Annotation { name, arguments, inner } => {
let inner = inner.as_ref(); let inner = inner.as_ref();
self.add_single_statement( self.add_single_statement(
&inner.id, &inner.id,
@ -149,7 +192,6 @@ impl<'a> SymbolTablePopulator<'a> {
)?; )?;
self.process_annotation(name.as_ref(), arguments.as_slice(), scope_stack, inner)?; self.process_annotation(name.as_ref(), arguments.as_slice(), scope_stack, inner)?;
} }
_ => (),
} }
Ok(()) Ok(())
} }
@ -159,7 +201,7 @@ impl<'a> SymbolTablePopulator<'a> {
name: &str, name: &str,
arguments: &[Expression], arguments: &[Expression],
scope_stack: &[ScopeSegment], scope_stack: &[ScopeSegment],
inner: &Statement, inner: &Statement<StatementKind>,
) -> Result<(), SymbolError> { ) -> Result<(), SymbolError> {
if name == "register_builtin" { if name == "register_builtin" {
if let Statement { if let Statement {

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@ -15,19 +15,20 @@ enum NameType {
Import(Fqsn), Import(Fqsn),
} }
type LexScope<'a> = ScopeStack<'a, Rc<String>, NameType, ScopeType>;
#[derive(Debug)] #[derive(Debug)]
enum ScopeType { enum ScopeType {
Function { name: Rc<String> }, Function { name: Rc<String> },
Lambda, Lambda,
PatternMatch, PatternMatch,
ImplBlock,
//TODO add some notion of a let-like scope? //TODO add some notion of a let-like scope?
} }
pub struct ScopeResolver<'a> { pub struct ScopeResolver<'a> {
symbol_table: &'a mut super::SymbolTable, symbol_table: &'a mut super::SymbolTable,
//TODO maybe this shouldn't be a scope stack, b/c the recursion behavior comes from multiple lexical_scopes: LexScope<'a>,
//instances of ScopeResolver
lexical_scopes: ScopeStack<'a, Rc<String>, NameType, ScopeType>,
} }
impl<'a> ScopeResolver<'a> { impl<'a> ScopeResolver<'a> {
@ -43,6 +44,7 @@ impl<'a> ScopeResolver<'a> {
/// This method correctly modifies the id_to_def table (ItemId) to have the appropriate /// This method correctly modifies the id_to_def table (ItemId) to have the appropriate
/// mappings. /// mappings.
fn lookup_name_in_scope(&mut self, name: &QualifiedName) { fn lookup_name_in_scope(&mut self, name: &QualifiedName) {
//TODO this method badly needs attention
let QualifiedName { id, components } = name; let QualifiedName { id, components } = name;
let local_name = components.first().unwrap().clone(); let local_name = components.first().unwrap().clone();
@ -138,6 +140,8 @@ impl<'a> ASTVisitor for ScopeResolver<'a> {
let param_names = signature.params.iter().map(|param| param.name.clone()); let param_names = signature.params.iter().map(|param| param.name.clone());
//TODO I'm 90% sure this is right, until I get to closures //TODO I'm 90% sure this is right, until I get to closures
//let mut new_scope = self.lexical_scopes.new_scope(Some(ScopeType::Function { name: signature.name.clone() })); //let mut new_scope = self.lexical_scopes.new_scope(Some(ScopeType::Function { name: signature.name.clone() }));
//TODO this will recurse unwantedly into scopes; need to pop an outer function
//scope off first before going into a non-closure scope
let mut new_scope = let mut new_scope =
ScopeStack::new(Some(ScopeType::Function { name: signature.name.clone() })); ScopeStack::new(Some(ScopeType::Function { name: signature.name.clone() }));
@ -162,6 +166,15 @@ impl<'a> ASTVisitor for ScopeResolver<'a> {
} }
Recursion::Continue Recursion::Continue
} }
Declaration::Impl { block, .. } => {
let mut new_scope = ScopeStack::new(Some(ScopeType::ImplBlock));
let mut new_resolver =
ScopeResolver { symbol_table: self.symbol_table, lexical_scopes: new_scope };
for stmt in block.iter() {
walk_declaration(&mut new_resolver, &stmt.kind, &stmt.id);
}
Recursion::Stop
}
_ => Recursion::Continue, _ => Recursion::Continue,
} }
} }

View File

@ -271,9 +271,27 @@ fn duplicate_struct_members() {
); );
} }
/*
#[test] #[test]
fn methods() { fn method_definition_added_to_symbol_table() {
let source = r#"
type Foo = { x: Int, y: Int }
impl Foo {
fn hella() {
let a = 50
self.x + a
}
}
"#;
let (symbols, _) = add_symbols(source);
symbols.debug();
assert!(symbols.fq_names.table.get(&make_fqsn(&["<impl-block>Foo", "hella"])).is_some());
assert!(symbols.fq_names.table.get(&make_fqsn(&["<impl-block>Foo", "hella", "a"])).is_some());
}
#[test]
fn duplicate_method_definitions_detected() {
let source = r#" let source = r#"
type Foo = { x: Int, y: Int } type Foo = { x: Int, y: Int }
@ -282,10 +300,15 @@ impl Foo {
fn hella() { fn hella() {
self.x + 50 self.x + 50
} }
fn hella() {
self.x + 40
}
} }
"#; "#;
let (symbols, _) = add_symbols(source); let (_symbols, output) = add_symbols(source);
symbols.debug(); let errs = output.unwrap_err();
assert!(symbols.fq_names.table.get(&make_fqsn(&["hella"])).is_some()); assert_matches!(&errs[..], [
SymbolError::DuplicateName { prev_name: pn1, ..},
] if pn1 == &Fqsn::from_strs(&["<impl-block>Foo", "hella"]));
} }
*/

View File

@ -38,7 +38,7 @@ impl<'a, 'b> Evaluator<'a, 'b> {
let mut acc = vec![]; let mut acc = vec![];
for (def_id, function) in reduced.functions.into_iter() { for (def_id, function) in reduced.functions.into_iter() {
let mem = (&def_id).into(); let mem = (&def_id).into();
self.state.environments.insert(mem, MemoryValue::Function(function)); self.state.memory.insert(mem, MemoryValue::Function(function));
} }
for statement in reduced.entrypoint.into_iter() { for statement in reduced.entrypoint.into_iter() {
@ -78,7 +78,7 @@ impl<'a, 'b> Evaluator<'a, 'b> {
match stmt { match stmt {
Statement::Binding { ref id, expr, constant: _ } => { Statement::Binding { ref id, expr, constant: _ } => {
let evaluated = self.expression(expr)?; let evaluated = self.expression(expr)?;
self.state.environments.insert(id.into(), evaluated.into()); self.state.memory.insert(id.into(), evaluated.into());
Ok(StatementOutput::Nothing) Ok(StatementOutput::Nothing)
} }
Statement::Expression(expr) => { Statement::Expression(expr) => {
@ -119,7 +119,7 @@ impl<'a, 'b> Evaluator<'a, 'b> {
Expression::Lookup(kind) => match kind { Expression::Lookup(kind) => match kind {
Lookup::Function(ref id) => { Lookup::Function(ref id) => {
let mem = id.into(); let mem = id.into();
match self.state.environments.lookup(&mem) { match self.state.memory.lookup(&mem) {
// This just checks that the function exists in "memory" by ID, we don't // This just checks that the function exists in "memory" by ID, we don't
// actually retrieve it until `apply_function()` // actually retrieve it until `apply_function()`
Some(MemoryValue::Function(_)) => Primitive::Callable(Callable::UserDefined(*id)), Some(MemoryValue::Function(_)) => Primitive::Callable(Callable::UserDefined(*id)),
@ -128,14 +128,21 @@ impl<'a, 'b> Evaluator<'a, 'b> {
} }
Lookup::Param(n) => { Lookup::Param(n) => {
let mem = n.into(); let mem = n.into();
match self.state.environments.lookup(&mem) { match self.state.memory.lookup(&mem) {
Some(MemoryValue::Primitive(prim)) => prim.clone(), Some(MemoryValue::Primitive(prim)) => prim.clone(),
e => return Err(format!("Param lookup error, got {:?}", e).into()), e => return Err(format!("Param lookup error, got {:?}", e).into()),
} }
} }
Lookup::SelfParam => {
let mem = Memory::self_param();
match self.state.memory.lookup(&mem) {
Some(MemoryValue::Primitive(prim)) => prim.clone(),
e => return Err(format!("SelfParam lookup error, got {:?}", e).into()),
}
}
Lookup::LocalVar(ref id) | Lookup::GlobalVar(ref id) => { Lookup::LocalVar(ref id) | Lookup::GlobalVar(ref id) => {
let mem = id.into(); let mem = id.into();
match self.state.environments.lookup(&mem) { match self.state.memory.lookup(&mem) {
Some(MemoryValue::Primitive(expr)) => expr.clone(), Some(MemoryValue::Primitive(expr)) => expr.clone(),
_ => _ =>
return Err( return Err(
@ -148,10 +155,12 @@ impl<'a, 'b> Evaluator<'a, 'b> {
let mem = lval.into(); let mem = lval.into();
let evaluated = self.expression(rval)?; let evaluated = self.expression(rval)?;
println!("Inserting {:?} into {:?}", evaluated, mem); println!("Inserting {:?} into {:?}", evaluated, mem);
self.state.environments.insert(mem, MemoryValue::Primitive(evaluated)); self.state.memory.insert(mem, MemoryValue::Primitive(evaluated));
Primitive::unit() Primitive::unit()
} }
Expression::Call { box f, args } => self.call_expression(f, args)?, Expression::Call { box f, args } => self.call_expression(f, args, None)?,
Expression::CallMethod { box f, args, box self_expr } =>
self.call_expression(f, args, Some(self_expr))?,
Expression::Callable(Callable::DataConstructor { type_id, tag }) => { Expression::Callable(Callable::DataConstructor { type_id, tag }) => {
let arity = self.type_context.lookup_variant_arity(&type_id, tag).unwrap(); let arity = self.type_context.lookup_variant_arity(&type_id, tag).unwrap();
if arity == 0 { if arity == 0 {
@ -302,9 +311,9 @@ impl<'a, 'b> Evaluator<'a, 'b> {
let cond = self.expression(cond)?; let cond = self.expression(cond)?;
for alt in alternatives.into_iter() { for alt in alternatives.into_iter() {
let mut new_scope = self.state.environments.new_scope(None); let mut new_scope = self.state.memory.new_scope(None);
if matches(&cond, &alt.pattern, &mut new_scope) { if matches(&cond, &alt.pattern, &mut new_scope) {
let mut new_state = State { environments: new_scope }; let mut new_state = State { memory: new_scope };
let mut evaluator = Evaluator::new(&mut new_state, self.type_context); let mut evaluator = Evaluator::new(&mut new_state, self.type_context);
let output = evaluator.block(alt.item); let output = evaluator.block(alt.item);
self.early_returning = evaluator.early_returning; self.early_returning = evaluator.early_returning;
@ -314,7 +323,13 @@ impl<'a, 'b> Evaluator<'a, 'b> {
Err("No valid match in match expression".into()) Err("No valid match in match expression".into())
} }
fn call_expression(&mut self, f: Expression, args: Vec<Expression>) -> EvalResult<Primitive> { //TODO need to do something with self_expr to make method invocations actually work
fn call_expression(
&mut self,
f: Expression,
args: Vec<Expression>,
self_expr: Option<Expression>,
) -> EvalResult<Primitive> {
let func = match self.expression(f)? { let func = match self.expression(f)? {
Primitive::Callable(func) => func, Primitive::Callable(func) => func,
other => return Err(format!("Trying to call non-function value: {:?}", other).into()), other => return Err(format!("Trying to call non-function value: {:?}", other).into()),
@ -323,10 +338,10 @@ impl<'a, 'b> Evaluator<'a, 'b> {
Callable::Builtin(builtin) => self.apply_builtin(builtin, args), Callable::Builtin(builtin) => self.apply_builtin(builtin, args),
Callable::UserDefined(def_id) => { Callable::UserDefined(def_id) => {
let mem = (&def_id).into(); let mem = (&def_id).into();
match self.state.environments.lookup(&mem) { match self.state.memory.lookup(&mem) {
Some(MemoryValue::Function(FunctionDefinition { body })) => { Some(MemoryValue::Function(FunctionDefinition { body })) => {
let body = body.clone(); //TODO ideally this clone would not happen let body = body.clone(); //TODO ideally this clone would not happen
self.apply_function(body, args) self.apply_function(body, args, self_expr)
} }
e => Err(format!("Error looking up function with id {}: {:?}", def_id, e).into()), e => Err(format!("Error looking up function with id {}: {:?}", def_id, e).into()),
} }
@ -340,7 +355,7 @@ impl<'a, 'b> Evaluator<'a, 'b> {
) )
.into()); .into());
} }
self.apply_function(body, args) self.apply_function(body, args, None)
} }
Callable::DataConstructor { type_id, tag } => { Callable::DataConstructor { type_id, tag } => {
let arity = self.type_context.lookup_variant_arity(&type_id, tag).unwrap(); let arity = self.type_context.lookup_variant_arity(&type_id, tag).unwrap();
@ -469,21 +484,30 @@ impl<'a, 'b> Evaluator<'a, 'b> {
}) })
} }
fn apply_function(&mut self, body: Vec<Statement>, args: Vec<Expression>) -> EvalResult<Primitive> { fn apply_function(
&mut self,
body: Vec<Statement>,
args: Vec<Expression>,
self_expr: Option<Expression>,
) -> EvalResult<Primitive> {
let self_expr = if let Some(expr) = self_expr { Some(self.expression(expr)?) } else { None };
let mut evaluated_args: Vec<Primitive> = vec![]; let mut evaluated_args: Vec<Primitive> = vec![];
for arg in args.into_iter() { for arg in args.into_iter() {
evaluated_args.push(self.expression(arg)?); evaluated_args.push(self.expression(arg)?);
} }
let mut frame_state = State { environments: self.state.environments.new_scope(None) }; let mut frame_state = State { memory: self.state.memory.new_scope(None) };
let mut evaluator = Evaluator::new(&mut frame_state, self.type_context); let mut evaluator = Evaluator::new(&mut frame_state, self.type_context);
if let Some(evaled) = self_expr {
let mem = Memory::self_param();
evaluator.state.memory.insert(mem, MemoryValue::Primitive(evaled));
}
for (n, evaled) in evaluated_args.into_iter().enumerate() { for (n, evaled) in evaluated_args.into_iter().enumerate() {
let n = n as u8; let n = n as u8;
let mem = n.into(); let mem = n.into();
evaluator.state.environments.insert(mem, MemoryValue::Primitive(evaled)); evaluator.state.memory.insert(mem, MemoryValue::Primitive(evaled));
} }
evaluator.block(body) evaluator.block(body)
} }
} }

View File

@ -4,7 +4,7 @@ use crate::{
reduced_ir::{Callable, Expression, FunctionDefinition, Literal, ReducedIR}, reduced_ir::{Callable, Expression, FunctionDefinition, Literal, ReducedIR},
symbol_table::DefId, symbol_table::DefId,
type_inference::{TypeContext, TypeId}, type_inference::{TypeContext, TypeId},
util::ScopeStack, util::{delim_wrapped, ScopeStack},
}; };
mod evaluator; mod evaluator;
@ -14,7 +14,7 @@ type EvalResult<T> = Result<T, RuntimeError>;
#[derive(Debug)] #[derive(Debug)]
pub struct State<'a> { pub struct State<'a> {
environments: ScopeStack<'a, Memory, MemoryValue>, memory: ScopeStack<'a, Memory, MemoryValue>,
} }
//TODO - eh, I dunno, maybe it doesn't matter exactly how memory works in the tree-walking //TODO - eh, I dunno, maybe it doesn't matter exactly how memory works in the tree-walking
@ -24,6 +24,12 @@ enum Memory {
Index(u32), Index(u32),
} }
impl Memory {
fn self_param() -> Self {
Memory::Index(3_999_999)
}
}
// This is for function param lookups, and is a hack // This is for function param lookups, and is a hack
impl From<u8> for Memory { impl From<u8> for Memory {
fn from(n: u8) -> Self { fn from(n: u8) -> Self {
@ -61,19 +67,6 @@ impl RuntimeError {
} }
} }
fn delim_wrapped(lhs: char, rhs: char, terms: impl Iterator<Item = String>) -> String {
let mut buf = String::new();
write!(buf, "{}", lhs).unwrap();
for term in terms.map(Some).intersperse(None) {
match term {
Some(e) => write!(buf, "{}", e).unwrap(),
None => write!(buf, ", ").unwrap(),
};
}
write!(buf, "{}", rhs).unwrap();
buf
}
/// Anything that can be stored in memory; that is, a function definition, or a fully-evaluated /// Anything that can be stored in memory; that is, a function definition, or a fully-evaluated
/// program value. /// program value.
#[derive(Debug)] #[derive(Debug)]
@ -165,7 +158,7 @@ impl From<Literal> for Primitive {
impl<'a> State<'a> { impl<'a> State<'a> {
pub fn new() -> Self { pub fn new() -> Self {
Self { environments: ScopeStack::new(Some("global".to_string())) } Self { memory: ScopeStack::new(Some("global".to_string())) }
} }
pub fn evaluate( pub fn evaluate(

View File

@ -1,4 +1,18 @@
use std::{cmp::Eq, collections::HashMap, hash::Hash}; use std::{cmp::Eq, collections::HashMap, fmt::Write, hash::Hash};
/// Utility function for printing a comma-delimited list of things
pub(crate) fn delim_wrapped(lhs: char, rhs: char, terms: impl Iterator<Item = String>) -> String {
let mut buf = String::new();
write!(buf, "{}", lhs).unwrap();
for term in terms.map(Some).intersperse(None) {
match term {
Some(e) => write!(buf, "{}", e).unwrap(),
None => write!(buf, ", ").unwrap(),
};
}
write!(buf, "{}", rhs).unwrap();
buf
}
#[derive(Default, Debug)] #[derive(Default, Debug)]
pub struct ScopeStack<'a, T: 'a, V: 'a, N = String> pub struct ScopeStack<'a, T: 'a, V: 'a, N = String>