add import statement

ltcc: map all outputted bytecode such that absolute addresses become relative to the file

typing: rename scope to super_scope
This commit is contained in:
Michael Sippel 2024-10-21 12:00:13 +02:00
parent a948b53d9a
commit 4bc7fd1788
Signed by: senvas
GPG key ID: F96CF119C34B64A6
6 changed files with 122 additions and 46 deletions

View file

@ -7,4 +7,5 @@ edition = "2021"
laddertypes = { path = "../../lib-laddertypes", features = ["pretty"] }
tisc = { path = "../../lib-tisc" }
serde = { version = "1.0", features = ["derive"] }
iterate-text = "0.0.1"
tiny-ansi = "0.1.0"

View file

@ -12,6 +12,9 @@ use {
#[derive(Clone, Debug)]
pub enum Statement {
Import {
path: String,
},
Assignment {
name_region: InputRegionTag,
var_id: String,

View file

@ -225,6 +225,28 @@ where It: Iterator<Item = (InputRegionTag, Result<LTIRToken, LexError>)>
val_expr,
})
}
"import" => {
let region = region.clone();
tokens.next();
let tok = tokens.next();
if let Some((path_region, path_token)) = tok {
match path_token {
Ok(LTIRToken::DoubleQuote(path_str)) => {
let _ = parse_expect(tokens, LTIRToken::StatementSep)?;
Ok(Statement::Import {
path: path_str
})
}
_ => {
Err((path_region, ParseError::UnexpectedToken))
}
}
} else {
Err((region, ParseError::UnexpectedEnd))
}
}
"return" => {
tokens.next();
let expr = parse_expr(super_scope, tokens)?;

View file

@ -85,6 +85,8 @@ impl ProcedureCompiler {
pub fn compile_statement(mut self, statement: &Statement) -> Self {
match statement {
Statement::Import { path } => {
}
Statement::Assignment { name_region, var_id, val_expr } => {
self = self.compile_expr(val_expr, true);

View file

@ -38,24 +38,24 @@ impl LTExpr {
}
}
pub fn infer_type(&self, scope: &Arc<RwLock<Scope>>) -> TypeTag
pub fn infer_type(&self, super_scope: &Arc<RwLock<Scope>>) -> TypeTag
{
match self {
LTExpr::WordLiteral{ region, val } => {
Ok(scope.write().unwrap().parse(
"_2^64 ~ machine.UInt64 ~ machine.Word"
Ok(super_scope.write().unwrap().parse(
"machine.Int64 ~ machine.Word"
).unwrap())
}
LTExpr::StringLiteral{ region, value } => {
Ok(scope.write().unwrap().parse(
Ok(super_scope.write().unwrap().parse(
"<Seq Char ~ Unicode ~ _2^32 ~ _2^64 ~ machine.UInt64>
~ <TermArray 0 machine.UInt64 ~ machine.Word>"
).unwrap())
}
LTExpr::Symbol { region, typ, symbol } => {
let mut s = scope.write().unwrap();
let mut s = super_scope.write().unwrap();
if let Some(sdef) = s.get(symbol) {
Ok(sdef.get_type(&mut *s))
} else {
@ -65,7 +65,7 @@ impl LTExpr {
}
LTExpr::Ascend { region, typ, expr } => {
let expr_type = expr.infer_type( scope )?;
let expr_type = expr.infer_type( super_scope )?;
let sub_type = typ.clone();
/*
@ -89,7 +89,7 @@ impl LTExpr {
}
LTExpr::Descend { region, typ, expr } => {
let expr_type = expr.infer_type(scope)?;
let expr_type = expr.infer_type(super_scope)?;
let super_type = typ.clone();
if let Ok(i) = expr_type.is_syntactic_subtype_of(&super_type) {
@ -127,11 +127,11 @@ impl LTExpr {
}
LTExpr::Application{ region, typ, head, body } => {
let mut head_type = head.infer_type(scope)?;
let mut head_type = head.infer_type(super_scope)?;
let mut args = body.into_iter();
let mut result_type = head_type;
let mut sugared_result_type = result_type.sugar(&mut *scope.write().unwrap());
let mut sugared_result_type = result_type.sugar(&mut *super_scope.write().unwrap());
let mut errors = Vec::new();
@ -141,10 +141,10 @@ impl LTExpr {
for (argi, expected_arg_type) in f_types.iter().enumerate() {
if let Some(arg) = args.next() {
let expected_arg_type = expected_arg_type.clone().desugar(&mut *scope.write().unwrap());
let expected_arg_type = expected_arg_type.clone().desugar(&mut *super_scope.write().unwrap());
// check subtype
let received_arg_type = arg.infer_type(scope)?;
let received_arg_type = arg.infer_type(super_scope)?;
if ! received_arg_type.is_syntactic_subtype_of(&expected_arg_type).is_ok() {
errors.push(TypeError{
region: arg.get_region(),
@ -166,7 +166,7 @@ impl LTExpr {
return
if errors.len() == 0 {
result_type = sugared_result_type.desugar(&mut *scope.write().unwrap());
result_type = sugared_result_type.desugar(&mut *super_scope.write().unwrap());
Ok(result_type)
} else {
Err(errors)
@ -183,7 +183,7 @@ impl LTExpr {
}
if errors.len() == 0 {
result_type = sugared_result_type.desugar(&mut *scope.write().unwrap());
result_type = sugared_result_type.desugar(&mut *super_scope.write().unwrap());
Ok(result_type)
} else {
Err(errors)
@ -191,13 +191,13 @@ impl LTExpr {
}
LTExpr::Branch { region, condition, if_expr, else_expr } => {
let received_cond_type = condition.infer_type(scope)?;
let expected_cond_type = scope.write().unwrap().parse("Bool ~ machine.Word").unwrap();
let received_cond_type = condition.infer_type(super_scope)?;
let expected_cond_type = super_scope.write().unwrap().parse("Bool ~ machine.Word").unwrap();
if received_cond_type.is_syntactic_subtype_of(&expected_cond_type).is_ok() {
let if_expr_type = if_expr.infer_type(scope)?;
let else_expr_type = else_expr.infer_type(scope)?;
let if_expr_type = if_expr.infer_type(super_scope)?;
let else_expr_type = else_expr.infer_type(super_scope)?;
if if_expr_type.is_syntactic_subtype_of(&else_expr_type).is_ok() {
Ok(else_expr_type)
@ -223,14 +223,14 @@ impl LTExpr {
}
}
LTExpr::WhileLoop { region, condition, body } => {
let received_cond_type = condition.infer_type(scope)?;
let expected_cond_type = scope.write().unwrap().parse("Bool ~ machine.Word").unwrap();
let received_cond_type = condition.infer_type(super_scope)?;
let expected_cond_type = super_scope.write().unwrap().parse("Bool ~ machine.Word").unwrap();
if received_cond_type.is_syntactic_subtype_of(&expected_cond_type).is_ok() {
let body_type = body.infer_type(scope)?;
let body_type = body_type.sugar(&mut scope.clone());
let body_type = body.infer_type(super_scope)?;
let body_type = body_type.sugar(&mut super_scope.clone());
let loop_type = laddertypes::SugaredTypeTerm::Seq(vec![ body_type ]);
Ok(loop_type.desugar(&mut scope.clone()))
Ok(loop_type.desugar(&mut super_scope.clone()))
} else {
return Err(vec![ TypeError{
region: condition.get_region(),
@ -250,7 +250,6 @@ impl LTExpr {
LTExpr::ExportBlock{ region:_, scope:_, statements:_ } => true,
_ => false
};
eprintln!(" .. in block (export={}) ", enable_export);
for s in statements {
match s.infer_type(scope, enable_export) {
@ -266,6 +265,11 @@ impl LTExpr {
}
}
let export = scope.read().unwrap().export();
super_scope.write().unwrap().import(
export
);
Ok(
if types.len() == 1 { types.pop().unwrap() }
else { laddertypes::SugaredTypeTerm::Struct(types) }
@ -279,6 +283,45 @@ impl LTExpr {
impl Statement {
pub fn infer_type(&self, scope: &Arc<RwLock<Scope>>, enable_export: bool) -> Result< Option<laddertypes::SugaredTypeTerm> , Vec<TypeError> > {
match self {
Statement::Import { path } => {
/*
* 1. load file
* 2. parse
* 3. infer types
* 3. import symbols
*/
let iter_chars = iterate_text::file::characters::IterateFileCharacters::new(path.clone());
/* compile source file
*/
let mut lexer = crate::lexer::LTIRLexer::from( iter_chars.peekable() );
let mut program_tokens =
lexer
.filter(|tok| match tok {
(_, Ok(crate::lexer::LTIRToken::Comment(_))) => false,
_ => true
})
.peekable();
let mut scope = scope.clone();
match crate::parser::parse_expr( &mut scope, &mut program_tokens ) {
Ok( mut ast ) => {
match ast.infer_type(&scope) {
Ok(mut t) => {
}
Err(type_err) =>{
eprintln!("In {} : Type Error", path);
}
}
}
Err( parse_err ) => {
eprintln!("In {} : Parse Error", path);
}
}
Ok(None)
}
Statement::LetAssign{ name_region, typ, var_id, val_expr } => {
let typ = val_expr.infer_type( scope )?;
@ -304,7 +347,6 @@ impl Statement {
}
_ => {
let id = scope.write().unwrap().declare_var(var_id.clone(), typ);
eprintln!("TYPING declare var ({}) = {}, export ={}", var_id, id, enable_export);
Ok(None)
}
}
@ -314,8 +356,8 @@ impl Statement {
let t = expr.infer_type(scope)?;
let symb = expr.export_symbols();
eprintln!("expr statement: import symbols from expr {:?}", symb);
scope.write().unwrap().import( symb );
// eprintln!("expr statement: import symbols from expr {:?}", symb);
// scope.write().unwrap().import( symb );
if t != laddertypes::TypeTerm::App(vec![]) {
let st = t.sugar(&mut scope.clone());

View file

@ -54,12 +54,11 @@ fn main() {
.into_iter()
.filter_map(|(symbol, def)| match def {
ltcore::symbols::SymbolDef::StaticRef { typ, link_addr, export } => {
eprintln!("runtime export static REF {}", export);
if export {
if let Some(addr)= link_addr {
if let Some(addr)= runtime_linker.get_link_addr(&symbol) {
Some((symbol, addr))
} else {
Some((symbol.clone(), runtime_linker.get_link_addr(&symbol).unwrap_or(-1)))
None
}
} else {
None
@ -168,18 +167,6 @@ fn main() {
}
eprintln!("{} {}\n{}", "Compiled".green(), path.bold(), "---------------".green());
for (name, def) in exports.iter() {
eprintln!("export {}:", name.yellow().bold());
let mut t = def.get_type(&mut main_scope);
t = t.normalize();
t = t.param_normalize();
let mut tc = main_scope.clone();
eprintln!( "{}", t.sugar(&mut tc).pretty(&tc,0) );
}
main_scope.write().unwrap().import(
exports
);
/* link assembly-program to symbols
*/
@ -212,10 +199,10 @@ fn main() {
.filter_map(|(symbol, def)| match def {
ltcore::symbols::SymbolDef::StaticRef { typ, link_addr, export } => {
if export {
if let Some(addr)= link_addr {
if let Some(addr) = linker.get_link_addr(&symbol) {
Some((symbol.clone(), addr))
} else {
Some((symbol.clone(), linker.get_link_addr(&symbol).unwrap_or(-1)))
None
}
} else {
None
@ -229,9 +216,12 @@ fn main() {
Some(( symbol, w ))
}
tisc::LinkAddr::Relative{ symbol: b, offset } => {
let addr = linker.get_link_addr(&b).unwrap_or(-1);
if let Some(addr) = linker.get_link_addr(&b) {
// eprintln!("relative symbol {} -> {}({})+{}", symbol, b, addr, offset);
Some((symbol, addr + offset ))
} else {
None
}
}
}
} else {
@ -243,6 +233,22 @@ fn main() {
.collect(),
code: linker.link_partial().expect("Link error:")
.into_iter()
.map(|w| match w {
tisc::assembler::AssemblyWord::Symbol(
tisc::LinkAddr::Absolute(a)
) => {
tisc::assembler::AssemblyWord::Symbol(
tisc::LinkAddr::Relative{
symbol: args.output.clone().into(),
offset: a
}
)
},
w => w
})
.collect()
};
let mut output = std::io::BufWriter::new(