#![feature(trace_macros)] #![feature(slice_patterns, box_patterns, box_syntax)] #![feature(proc_macro)] extern crate itertools; #[macro_use] extern crate lazy_static; #[macro_use] extern crate maplit; #[macro_use] extern crate schala_repl; #[macro_use] extern crate schala_codegen; use std::cell::RefCell; use std::rc::Rc; use itertools::Itertools; use schala_repl::{ProgrammingLanguageInterface, EvalOptions, TraceArtifact, UnfinishedComputation, FinishedComputation}; macro_rules! bx { ($e:expr) => { Box::new($e) } } mod util; mod builtin; mod tokenizing; mod ast; mod parsing; mod symbol_table; mod typechecking; mod reduced_ast; mod eval; //trace_macros!(true); #[derive(ProgrammingLanguageInterface)] #[LanguageName = "Schala"] #[SourceFileExtension = "schala"] #[PipelineSteps(tokenizing, parsing(compact,expanded,trace), symbol_table, typechecking, ast_reducing, eval)] pub struct Schala { state: eval::State<'static>, symbol_table: Rc>, type_context: typechecking::TypeContext<'static>, } impl Schala { fn new_blank_env() -> Schala { let symbols = Rc::new(RefCell::new(symbol_table::SymbolTable::new())); Schala { symbol_table: symbols.clone(), type_context: typechecking::TypeContext::new(symbols.clone()), state: eval::State::new(symbols), } } pub fn new() -> Schala { let prelude = r#" type Option = Some(T) | None "#; let mut s = Schala::new_blank_env(); s.execute_pipeline(prelude, &EvalOptions::default()); s } } fn tokenizing(_handle: &mut Schala, input: &str, comp: Option<&mut UnfinishedComputation>) -> Result, String> { let tokens = tokenizing::tokenize(input); comp.map(|comp| { let token_string = tokens.iter().map(|t| format!("{:?}", t.token_type, t.offset.0, t.offset.1)).join(", "); comp.add_artifact(TraceArtifact::new("tokens", token_string)); }); let errors: Vec = tokens.iter().filter_map(|t| t.get_error()).collect(); if errors.len() == 0 { Ok(tokens) } else { Err(format!("{:?}", errors)) } } fn parsing(_handle: &mut Schala, input: Vec, comp: Option<&mut UnfinishedComputation>) -> Result { let (ast, trace) = parsing::parse(input); comp.map(|comp| { //TODO need to control which of these debug stages get added let opt = comp.cur_debug_options.get(0).map(|s| s.clone()); match opt { None => comp.add_artifact(TraceArtifact::new("ast", format!("{:?}", ast))), Some(ref s) if s == "compact" => comp.add_artifact(TraceArtifact::new("ast", format!("{:?}", ast))), Some(ref s) if s == "expanded" => comp.add_artifact(TraceArtifact::new("ast", format!("{:#?}", ast))), Some(ref s) if s == "trace" => comp.add_artifact(TraceArtifact::new_parse_trace(trace)), Some(ref x) => println!("Bad parsing debug option: {}", x), }; }); ast.map_err(|err| err.msg) } fn symbol_table(handle: &mut Schala, input: ast::AST, comp: Option<&mut UnfinishedComputation>) -> Result { let add = handle.symbol_table.borrow_mut().add_top_level_symbols(&input); match add { Ok(()) => { let artifact = TraceArtifact::new("symbol_table", handle.symbol_table.borrow().debug_symbol_table()); comp.map(|comp| comp.add_artifact(artifact)); Ok(input) }, Err(msg) => Err(msg) } } fn typechecking(handle: &mut Schala, input: ast::AST, comp: Option<&mut UnfinishedComputation>) -> Result { match handle.type_context.type_check_ast(&input) { Ok(ty) => { comp.map(|c| { c.add_artifact(TraceArtifact::new("type_table", format!("{}", handle.type_context.debug_types()))); c.add_artifact(TraceArtifact::new("type_check", format!("{:?}", ty))); }); Ok(input) }, Err(msg) => { comp.map(|comp| { comp.add_artifact(TraceArtifact::new("type_table", format!("{}", handle.type_context.debug_types()))); comp.add_artifact(TraceArtifact::new("type_check", format!("Type error: {:?}", msg))); }); Ok(input) } } } fn ast_reducing(handle: &mut Schala, input: ast::AST, comp: Option<&mut UnfinishedComputation>) -> Result { let ref symbol_table = handle.symbol_table.borrow(); let output = input.reduce(symbol_table); comp.map(|comp| comp.add_artifact(TraceArtifact::new("ast_reducing", format!("{:?}", output)))); Ok(output) } fn eval(handle: &mut Schala, input: reduced_ast::ReducedAST, comp: Option<&mut UnfinishedComputation>) -> Result { comp.map(|comp| comp.add_artifact(TraceArtifact::new("value_state", handle.state.debug_print()))); let evaluation_outputs = handle.state.evaluate(input, true); let text_output: Result, String> = evaluation_outputs .into_iter() .collect(); let eval_output: Result = text_output .map(|v| { v.into_iter().intersperse(format!("\n")).collect() }); eval_output }