//! Module that defines the public compilation API of [`Engine`]. use crate::parser::ParseState; use crate::{Engine, EvalAltResult, Identifier, ParseError, Position, Scope, AST}; #[cfg(feature = "no_std")] use std::prelude::v1::*; #[cfg(not(feature = "no_object"))] use crate::Map; impl Engine { /// Compile a string into an [`AST`], which can be used later for evaluation. /// /// # Example /// /// ``` /// # fn main() -> Result<(), Box> { /// use rhai::Engine; /// /// let engine = Engine::new(); /// /// // Compile a script to an AST and store it for later evaluation /// let ast = engine.compile("40 + 2")?; /// /// for _ in 0..42 { /// assert_eq!(engine.eval_ast::(&ast)?, 42); /// } /// # Ok(()) /// # } /// ``` #[inline(always)] pub fn compile(&self, script: &str) -> Result { self.compile_with_scope(&Scope::new(), script) } /// Compile a string into an [`AST`] using own scope, which can be used later for evaluation. /// /// ## Constants Propagation /// /// If not [`OptimizationLevel::None`][crate::OptimizationLevel::None], constants defined within /// the scope are propagated throughout the script _including_ functions. This allows functions /// to be optimized based on dynamic global constants. /// /// # Example /// /// ``` /// # fn main() -> Result<(), Box> { /// # #[cfg(not(feature = "no_optimize"))] /// # { /// use rhai::{Engine, Scope, OptimizationLevel}; /// /// let mut engine = Engine::new(); /// /// // Create initialized scope /// let mut scope = Scope::new(); /// scope.push_constant("x", 42_i64); // 'x' is a constant /// /// // Compile a script to an AST and store it for later evaluation. /// // Notice that `Full` optimization is on, so constants are folded /// // into function calls and operators. /// let ast = engine.compile_with_scope(&mut scope, /// "if x > 40 { x } else { 0 }" // all 'x' are replaced with 42 /// )?; /// /// // Normally this would have failed because no scope is passed into the 'eval_ast' /// // call and so the variable 'x' does not exist. Here, it passes because the script /// // has been optimized and all references to 'x' are already gone. /// assert_eq!(engine.eval_ast::(&ast)?, 42); /// # } /// # Ok(()) /// # } /// ``` #[inline(always)] pub fn compile_with_scope(&self, scope: &Scope, script: &str) -> Result { self.compile_scripts_with_scope(scope, &[script]) } /// Compile a string into an [`AST`] using own scope, which can be used later for evaluation, /// embedding all imported modules. /// /// Not available under `no_module`. /// /// Modules referred by `import` statements containing literal string paths are eagerly resolved /// via the current [module resolver][crate::ModuleResolver] and embedded into the resultant /// [`AST`]. When it is evaluated later, `import` statement directly recall pre-resolved /// [modules][crate::Module] and the resolution process is not performed again. #[cfg(not(feature = "no_module"))] pub fn compile_into_self_contained( &self, scope: &Scope, script: &str, ) -> Result> { use crate::{ ast::{ASTNode, Expr, Stmt}, func::native::shared_take_or_clone, module::resolvers::StaticModuleResolver, }; use std::collections::BTreeSet; fn collect_imports( ast: &AST, resolver: &StaticModuleResolver, imports: &mut BTreeSet, ) { ast.walk( &mut |path| match path.last().expect("contains current node") { // Collect all `import` statements with a string constant path ASTNode::Stmt(Stmt::Import(Expr::StringConstant(s, _), _, _)) if !resolver.contains_path(s) && !imports.contains(s.as_str()) => { imports.insert(s.clone().into()); true } _ => true, }, ); } let mut ast = self.compile_scripts_with_scope(scope, &[script])?; if let Some(ref module_resolver) = self.module_resolver { let mut resolver = StaticModuleResolver::new(); let mut imports = BTreeSet::new(); collect_imports(&ast, &resolver, &mut imports); if !imports.is_empty() { while let Some(path) = imports.iter().next() { let path = path.clone(); match module_resolver.resolve_ast(self, None, &path, Position::NONE) { Some(Ok(module_ast)) => { collect_imports(&module_ast, &resolver, &mut imports) } Some(err) => return err, None => (), } let module = module_resolver.resolve(self, None, &path, Position::NONE)?; let module = shared_take_or_clone(module); imports.remove(&path); resolver.insert(path, module); } ast.set_resolver(resolver); } } Ok(ast) } /// When passed a list of strings, first join the strings into one large script, and then /// compile them into an [`AST`] using own scope, which can be used later for evaluation. /// /// The scope is useful for passing constants into the script for optimization when using /// [`OptimizationLevel::Full`][crate::OptimizationLevel::Full]. /// /// ## Note /// /// All strings are simply parsed one after another with nothing inserted in between, not even a /// newline or space. /// /// ## Constants Propagation /// /// If not [`OptimizationLevel::None`][crate::OptimizationLevel::None], constants defined within /// the scope are propagated throughout the script _including_ functions. This allows functions /// to be optimized based on dynamic global constants. /// /// # Example /// /// ``` /// # fn main() -> Result<(), Box> { /// # #[cfg(not(feature = "no_optimize"))] /// # { /// use rhai::{Engine, Scope, OptimizationLevel}; /// /// let mut engine = Engine::new(); /// /// // Create initialized scope /// let mut scope = Scope::new(); /// scope.push_constant("x", 42_i64); // 'x' is a constant /// /// // Compile a script made up of script segments to an AST and store it for later evaluation. /// // Notice that `Full` optimization is on, so constants are folded /// // into function calls and operators. /// let ast = engine.compile_scripts_with_scope(&mut scope, &[ /// "if x > 40", // all 'x' are replaced with 42 /// "{ x } el", /// "se { 0 }" // segments do not need to be valid scripts! /// ])?; /// /// // Normally this would have failed because no scope is passed into the 'eval_ast' /// // call and so the variable 'x' does not exist. Here, it passes because the script /// // has been optimized and all references to 'x' are already gone. /// assert_eq!(engine.eval_ast::(&ast)?, 42); /// # } /// # Ok(()) /// # } /// ``` #[inline(always)] pub fn compile_scripts_with_scope( &self, scope: &Scope, scripts: &[&str], ) -> Result { self.compile_with_scope_and_optimization_level( scope, scripts, #[cfg(not(feature = "no_optimize"))] self.optimization_level, ) } /// Join a list of strings and compile into an [`AST`] using own scope at a specific optimization level. /// /// ## Constants Propagation /// /// If not [`OptimizationLevel::None`], constants defined within the scope are propagated /// throughout the script _including_ functions. This allows functions to be optimized based on /// dynamic global constants. #[inline] pub(crate) fn compile_with_scope_and_optimization_level( &self, scope: &Scope, scripts: &[&str], #[cfg(not(feature = "no_optimize"))] optimization_level: crate::OptimizationLevel, ) -> Result { let (stream, tokenizer_control) = self.lex_raw(scripts, self.token_mapper.as_ref().map(Box::as_ref)); let mut state = ParseState::new(self, tokenizer_control); self.parse( &mut stream.peekable(), &mut state, scope, #[cfg(not(feature = "no_optimize"))] optimization_level, ) } /// Compile a string containing an expression into an [`AST`], /// which can be used later for evaluation. /// /// # Example /// /// ``` /// # fn main() -> Result<(), Box> { /// use rhai::Engine; /// /// let engine = Engine::new(); /// /// // Compile a script to an AST and store it for later evaluation /// let ast = engine.compile_expression("40 + 2")?; /// /// for _ in 0..42 { /// assert_eq!(engine.eval_ast::(&ast)?, 42); /// } /// # Ok(()) /// # } /// ``` #[inline(always)] pub fn compile_expression(&self, script: &str) -> Result { self.compile_expression_with_scope(&Scope::new(), script) } /// Compile a string containing an expression into an [`AST`] using own scope, /// which can be used later for evaluation. /// /// # Example /// /// ``` /// # fn main() -> Result<(), Box> { /// # #[cfg(not(feature = "no_optimize"))] /// # { /// use rhai::{Engine, Scope, OptimizationLevel}; /// /// let mut engine = Engine::new(); /// /// // Create initialized scope /// let mut scope = Scope::new(); /// scope.push_constant("x", 10_i64); // 'x' is a constant /// /// // Compile a script to an AST and store it for later evaluation. /// // Notice that `Full` optimization is on, so constants are folded /// // into function calls and operators. /// let ast = engine.compile_expression_with_scope(&mut scope, /// "2 + (x + x) * 2" // all 'x' are replaced with 10 /// )?; /// /// // Normally this would have failed because no scope is passed into the 'eval_ast' /// // call and so the variable 'x' does not exist. Here, it passes because the script /// // has been optimized and all references to 'x' are already gone. /// assert_eq!(engine.eval_ast::(&ast)?, 42); /// # } /// # Ok(()) /// # } /// ``` #[inline] pub fn compile_expression_with_scope( &self, scope: &Scope, script: &str, ) -> Result { let scripts = [script]; let (stream, tokenizer_control) = self.lex_raw(&scripts, self.token_mapper.as_ref().map(Box::as_ref)); let mut peekable = stream.peekable(); let mut state = ParseState::new(self, tokenizer_control); self.parse_global_expr( &mut peekable, &mut state, scope, #[cfg(not(feature = "no_optimize"))] self.optimization_level, ) } /// Parse a JSON string into an [object map][`Map`]. /// This is a light-weight alternative to using, say, /// [`serde_json`](https://crates.io/crates/serde_json) to deserialize the JSON. /// /// Not available under `no_object`. /// /// The JSON string must be an object hash. It cannot be a simple scalar value. /// /// Set `has_null` to `true` in order to map `null` values to `()`. /// Setting it to `false` will cause an [`ErrorVariableNotFound`][EvalAltResult::ErrorVariableNotFound] error during parsing. /// /// # JSON With Sub-Objects /// /// This method assumes no sub-objects in the JSON string. That is because the syntax /// of a JSON sub-object (or object hash), `{ .. }`, is different from Rhai's syntax, `#{ .. }`. /// Parsing a JSON string with sub-objects will cause a syntax error. /// /// If it is certain that the character `{` never appears in any text string within the JSON object, /// which is a valid assumption for many use cases, then globally replace `{` with `#{` before calling this method. /// /// # Example /// /// ``` /// # fn main() -> Result<(), Box> { /// use rhai::{Engine, Map}; /// /// let engine = Engine::new(); /// /// let map = engine.parse_json( /// r#"{"a":123, "b":42, "c":{"x":false, "y":true}, "d":null}"# /// .replace("{", "#{").as_str(), /// true)?; /// /// assert_eq!(map.len(), 4); /// assert_eq!(map["a"].as_int().expect("a should exist"), 123); /// assert_eq!(map["b"].as_int().expect("b should exist"), 42); /// assert!(map["d"].is::<()>()); /// /// let c = map["c"].read_lock::().expect("c should exist"); /// assert_eq!(c["x"].as_bool().expect("x should be bool"), false); /// # Ok(()) /// # } /// ``` #[cfg(not(feature = "no_object"))] #[inline(always)] pub fn parse_json( &self, json: impl AsRef, has_null: bool, ) -> Result> { use crate::tokenizer::Token; fn parse_json_inner( engine: &Engine, json: &str, has_null: bool, ) -> Result> { let mut scope = Scope::new(); let json_text = json.trim_start(); let scripts = if json_text.starts_with(Token::MapStart.literal_syntax()) { [json_text, ""] } else if json_text.starts_with(Token::LeftBrace.literal_syntax()) { ["#", json_text] } else { return Err(crate::ParseErrorType::MissingToken( Token::LeftBrace.syntax().into(), "to start a JSON object hash".into(), ) .into_err(Position::new(1, (json.len() - json_text.len() + 1) as u16)) .into()); }; let (stream, tokenizer_control) = engine.lex_raw( &scripts, if has_null { Some(&|token, _, _| { match token { // If `null` is present, make sure `null` is treated as a variable Token::Reserved(s) if &*s == "null" => Token::Identifier(s), _ => token, } }) } else { None }, ); let mut state = ParseState::new(engine, tokenizer_control); let ast = engine.parse_global_expr( &mut stream.peekable(), &mut state, &scope, #[cfg(not(feature = "no_optimize"))] crate::OptimizationLevel::None, )?; if has_null { scope.push_constant("null", ()); } engine.eval_ast_with_scope(&mut scope, &ast) } parse_json_inner(self, json.as_ref(), has_null) } }