//! Main module defining the script evaluation [`Engine`]. use crate::ast::{Expr, FnCallExpr, Ident, ReturnType, Stmt}; use crate::dynamic::{map_std_type_name, AccessMode, Union, Variant}; use crate::fn_call::run_builtin_op_assignment; use crate::fn_native::{ CallableFunction, IteratorFn, OnDebugCallback, OnPrintCallback, OnProgressCallback, OnVarCallback, }; use crate::module::NamespaceRef; use crate::optimize::OptimizationLevel; use crate::packages::{Package, StandardPackage}; use crate::r#unsafe::unsafe_cast_var_name_to_lifetime; use crate::stdlib::{ any::{type_name, TypeId}, borrow::Cow, boxed::Box, collections::{HashMap, HashSet}, fmt, format, hash::{Hash, Hasher}, iter::{empty, once, FromIterator}, num::{NonZeroU64, NonZeroU8, NonZeroUsize}, ops::DerefMut, string::{String, ToString}, }; use crate::syntax::CustomSyntax; use crate::utils::{get_hasher, StraightHasherBuilder}; use crate::{ calc_native_fn_hash, Dynamic, EvalAltResult, FnPtr, ImmutableString, Module, Position, Scope, Shared, StaticVec, }; #[cfg(not(feature = "no_index"))] use crate::Array; #[cfg(not(feature = "no_index"))] pub const TYPICAL_ARRAY_SIZE: usize = 8; // Small arrays are typical #[cfg(not(feature = "no_object"))] use crate::Map; #[cfg(not(feature = "no_object"))] pub const TYPICAL_MAP_SIZE: usize = 8; // Small maps are typical /// _(INTERNALS)_ A stack of imported [modules][Module]. /// Exported under the `internals` feature only. /// /// # Volatile Data Structure /// /// This type is volatile and may change. // // # Implementation Notes // // We cannot use Cow here because `eval` may load a [module][Module] and // the module name will live beyond the AST of the eval script text. // The best we can do is a shared reference. #[derive(Debug, Clone, Default)] pub struct Imports(StaticVec<(ImmutableString, Shared)>); impl Imports { /// Get the length of this stack of imported [modules][Module]. #[inline(always)] pub fn len(&self) -> usize { self.0.len() } /// Is this stack of imported [modules][Module] empty? #[inline(always)] pub fn is_empty(&self) -> bool { self.0.is_empty() } /// Get the imported [modules][Module] at a particular index. #[inline(always)] pub fn get(&self, index: usize) -> Option> { self.0.get(index).map(|(_, m)| m).cloned() } /// Get the index of an imported [modules][Module] by name. #[inline(always)] pub fn find(&self, name: &str) -> Option { self.0 .iter() .enumerate() .rev() .find(|(_, (key, _))| key.as_str() == name) .map(|(index, _)| index) } /// Push an imported [modules][Module] onto the stack. #[inline(always)] pub fn push(&mut self, name: impl Into, module: impl Into>) { self.0.push((name.into(), module.into())); } /// Truncate the stack of imported [modules][Module] to a particular length. #[inline(always)] pub fn truncate(&mut self, size: usize) { self.0.truncate(size); } /// Get an iterator to this stack of imported [modules][Module] in reverse order. #[allow(dead_code)] #[inline(always)] pub fn iter(&self) -> impl Iterator { self.0 .iter() .rev() .map(|(name, module)| (name.as_str(), module.as_ref())) } /// Get an iterator to this stack of imported [modules][Module] in reverse order. #[allow(dead_code)] #[inline(always)] pub(crate) fn iter_raw(&self) -> impl Iterator)> { self.0.iter().rev().map(|(n, m)| (n, m)) } /// Get a consuming iterator to this stack of imported [modules][Module] in reverse order. #[inline(always)] pub fn into_iter(self) -> impl Iterator)> { self.0.into_iter().rev() } /// Add a stream of imported [modules][Module]. #[inline(always)] pub fn extend(&mut self, stream: impl Iterator)>) { self.0.extend(stream) } /// Does the specified function hash key exist in this stack of imported [modules][Module]? #[allow(dead_code)] #[inline(always)] pub fn contains_fn(&self, hash: NonZeroU64) -> bool { self.0.iter().any(|(_, m)| m.contains_qualified_fn(hash)) } /// Get specified function via its hash key. #[inline(always)] pub fn get_fn( &self, hash: NonZeroU64, ) -> Option<(&CallableFunction, Option<&ImmutableString>)> { self.0 .iter() .rev() .find_map(|(_, m)| m.get_qualified_fn(hash).map(|f| (f, m.id_raw()))) } /// Does the specified [`TypeId`][std::any::TypeId] iterator exist in this stack of /// imported [modules][Module]? #[allow(dead_code)] #[inline(always)] pub fn contains_iter(&self, id: TypeId) -> bool { self.0.iter().any(|(_, m)| m.contains_qualified_iter(id)) } /// Get the specified [`TypeId`][std::any::TypeId] iterator. #[inline(always)] pub fn get_iter(&self, id: TypeId) -> Option { self.0 .iter() .rev() .find_map(|(_, m)| m.get_qualified_iter(id)) } } impl<'a, T: IntoIterator)>> From for Imports { #[inline(always)] fn from(value: T) -> Self { Self( value .into_iter() .map(|(k, v)| (k.clone(), v.clone())) .collect(), ) } } impl FromIterator<(ImmutableString, Shared)> for Imports { #[inline(always)] fn from_iter)>>(iter: T) -> Self { Self(iter.into_iter().collect()) } } #[cfg(not(feature = "unchecked"))] #[cfg(debug_assertions)] #[cfg(not(feature = "no_function"))] pub const MAX_CALL_STACK_DEPTH: usize = 8; #[cfg(not(feature = "unchecked"))] #[cfg(debug_assertions)] pub const MAX_EXPR_DEPTH: usize = 32; #[cfg(not(feature = "unchecked"))] #[cfg(not(feature = "no_function"))] #[cfg(debug_assertions)] pub const MAX_FUNCTION_EXPR_DEPTH: usize = 16; #[cfg(not(feature = "unchecked"))] #[cfg(not(debug_assertions))] #[cfg(not(feature = "no_function"))] pub const MAX_CALL_STACK_DEPTH: usize = 128; #[cfg(not(feature = "unchecked"))] #[cfg(not(debug_assertions))] pub const MAX_EXPR_DEPTH: usize = 128; #[cfg(not(feature = "unchecked"))] #[cfg(not(feature = "no_function"))] #[cfg(not(debug_assertions))] pub const MAX_FUNCTION_EXPR_DEPTH: usize = 32; pub const KEYWORD_PRINT: &str = "print"; pub const KEYWORD_DEBUG: &str = "debug"; pub const KEYWORD_TYPE_OF: &str = "type_of"; pub const KEYWORD_EVAL: &str = "eval"; pub const KEYWORD_FN_PTR: &str = "Fn"; pub const KEYWORD_FN_PTR_CALL: &str = "call"; pub const KEYWORD_FN_PTR_CURRY: &str = "curry"; #[cfg(not(feature = "no_closure"))] pub const KEYWORD_IS_SHARED: &str = "is_shared"; pub const KEYWORD_IS_DEF_VAR: &str = "is_def_var"; pub const KEYWORD_THIS: &str = "this"; #[cfg(not(feature = "no_object"))] pub const FN_GET: &str = "get$"; #[cfg(not(feature = "no_object"))] pub const FN_SET: &str = "set$"; #[cfg(not(feature = "no_index"))] pub const FN_IDX_GET: &str = "index$get$"; #[cfg(not(feature = "no_index"))] pub const FN_IDX_SET: &str = "index$set$"; #[cfg(not(feature = "no_function"))] pub const FN_ANONYMOUS: &str = "anon$"; #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] pub const OP_EQUALS: &str = "=="; /// Method of chaining. #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] #[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)] pub enum ChainType { /// Not a chaining type. NonChaining, /// Indexing. Index, /// Dotting. Dot, } /// Value of a chaining argument. #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] #[derive(Debug, Clone, Hash)] pub enum ChainArgument { /// Dot-property access. Property, /// Arguments to a dot-function call. FnCallArgs(StaticVec), /// Index value. IndexValue(Dynamic), } #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] impl ChainArgument { /// Return the `Dynamic` value. /// /// # Panics /// /// Panics if not `ChainArgument::IndexValue`. #[inline(always)] #[cfg(not(feature = "no_index"))] pub fn as_index_value(self) -> Dynamic { match self { Self::Property | Self::FnCallArgs(_) => panic!("expecting ChainArgument::IndexValue"), Self::IndexValue(value) => value, } } /// Return the `StaticVec` value. /// /// # Panics /// /// Panics if not `ChainArgument::FnCallArgs`. #[inline(always)] #[cfg(not(feature = "no_object"))] pub fn as_fn_call_args(self) -> StaticVec { match self { Self::Property | Self::IndexValue(_) => panic!("expecting ChainArgument::FnCallArgs"), Self::FnCallArgs(value) => value, } } } #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] impl From> for ChainArgument { #[inline(always)] fn from(value: StaticVec) -> Self { Self::FnCallArgs(value) } } #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] impl From for ChainArgument { #[inline(always)] fn from(value: Dynamic) -> Self { Self::IndexValue(value) } } /// A type that encapsulates a mutation target for an expression with side effects. #[derive(Debug)] pub enum Target<'a> { /// The target is a mutable reference to a `Dynamic` value somewhere. Ref(&'a mut Dynamic), /// The target is a mutable reference to a Shared `Dynamic` value. /// It holds both the access guard and the original shared value. #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] LockGuard((crate::dynamic::DynamicWriteLock<'a, Dynamic>, Dynamic)), /// The target is a temporary `Dynamic` value (i.e. the mutation can cause no side effects). Value(Dynamic), /// The target is a character inside a String. /// This is necessary because directly pointing to a char inside a String is impossible. #[cfg(not(feature = "no_index"))] StringChar(&'a mut Dynamic, usize, Dynamic), } impl<'a> Target<'a> { /// Is the `Target` a reference pointing to other data? #[allow(dead_code)] #[inline(always)] pub fn is_ref(&self) -> bool { match self { Self::Ref(_) => true, #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Self::LockGuard(_) => true, Self::Value(_) => false, #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, _) => false, } } /// Is the `Target` an owned value? #[allow(dead_code)] #[inline(always)] pub fn is_value(&self) -> bool { match self { Self::Ref(_) => false, #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Self::LockGuard(_) => false, Self::Value(_) => true, #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, _) => false, } } /// Is the `Target` a shared value? #[allow(dead_code)] #[inline(always)] pub fn is_shared(&self) -> bool { match self { Self::Ref(r) => r.is_shared(), #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Self::LockGuard(_) => true, Self::Value(r) => r.is_shared(), #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, _) => false, } } /// Is the `Target` a specific type? #[allow(dead_code)] #[inline(always)] pub fn is(&self) -> bool { match self { Target::Ref(r) => r.is::(), #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Target::LockGuard((r, _)) => r.is::(), Target::Value(r) => r.is::(), #[cfg(not(feature = "no_index"))] Target::StringChar(_, _, _) => TypeId::of::() == TypeId::of::(), } } /// Get the value of the `Target` as a `Dynamic`, cloning a referenced value if necessary. #[inline(always)] pub fn take_or_clone(self) -> Dynamic { match self { Self::Ref(r) => r.clone(), // Referenced value is cloned #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Self::LockGuard((_, orig)) => orig, // Original value is simply taken Self::Value(v) => v, // Owned value is simply taken #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, ch) => ch, // Character is taken } } /// Take a `&mut Dynamic` reference from the `Target`. #[inline(always)] pub fn take_ref(self) -> Option<&'a mut Dynamic> { match self { Self::Ref(r) => Some(r), _ => None, } } /// Convert a shared or reference `Target` into a target with an owned value. #[inline(always)] pub fn into_owned(self) -> Target<'static> { self.take_or_clone().into() } /// Propagate a changed value back to the original source. /// This has no effect except for string indexing. #[cfg(not(feature = "no_object"))] #[inline(always)] pub fn propagate_changed_value(&mut self) { match self { Self::Ref(_) | Self::Value(_) => (), #[cfg(not(feature = "no_closure"))] Self::LockGuard(_) => (), #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, ch) => { let char_value = ch.clone(); self.set_value(char_value, Position::NONE).unwrap(); } } } /// Update the value of the `Target`. #[cfg(any(not(feature = "no_object"), not(feature = "no_index")))] pub fn set_value(&mut self, new_val: Dynamic, pos: Position) -> Result<(), Box> { match self { Self::Ref(r) => **r = new_val, #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Self::LockGuard((r, _)) => **r = new_val, Self::Value(_) => panic!("cannot update a value"), #[cfg(not(feature = "no_index"))] Self::StringChar(string, index, _) if string.is::() => { let mut s = string.write_lock::().unwrap(); // Replace the character at the specified index position let new_ch = new_val.as_char().map_err(|err| { Box::new(EvalAltResult::ErrorMismatchDataType( err.to_string(), "char".to_string(), pos, )) })?; let mut chars = s.chars().collect::>(); // See if changed - if so, update the String if chars[*index] != new_ch { chars[*index] = new_ch; *s = chars.iter().collect::().into(); } } #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, _) => unreachable!(), } Ok(()) } } impl<'a> From<&'a mut Dynamic> for Target<'a> { #[inline(always)] fn from(value: &'a mut Dynamic) -> Self { #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] if value.is_shared() { // Cloning is cheap for a shared value let container = value.clone(); return Self::LockGuard((value.write_lock::().unwrap(), container)); } Self::Ref(value) } } impl AsRef for Target<'_> { #[inline(always)] fn as_ref(&self) -> &Dynamic { match self { Self::Ref(r) => *r, #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Self::LockGuard((r, _)) => &**r, Self::Value(ref r) => r, #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, ref r) => r, } } } impl AsMut for Target<'_> { #[inline(always)] fn as_mut(&mut self) -> &mut Dynamic { match self { Self::Ref(r) => *r, #[cfg(not(feature = "no_closure"))] #[cfg(not(feature = "no_object"))] Self::LockGuard((r, _)) => r.deref_mut(), Self::Value(ref mut r) => r, #[cfg(not(feature = "no_index"))] Self::StringChar(_, _, ref mut r) => r, } } } impl> From for Target<'_> { #[inline(always)] fn from(value: T) -> Self { Self::Value(value.into()) } } /// _(INTERNALS)_ A type that holds all the current states of the [`Engine`]. /// Exported under the `internals` feature only. /// /// # Volatile Data Structure /// /// This type is volatile and may change. #[derive(Debug, Clone, Default)] pub struct State { /// Source of the current context. pub source: Option, /// Normally, access to variables are parsed with a relative offset into the scope to avoid a lookup. /// In some situation, e.g. after running an `eval` statement, subsequent offsets become mis-aligned. /// When that happens, this flag is turned on to force a scope lookup by name. pub always_search: bool, /// Level of the current scope. The global (root) level is zero, a new block /// (or function call) is one level higher, and so on. pub scope_level: usize, /// Number of operations performed. pub operations: u64, /// Number of modules loaded. pub modules: usize, /// Embedded module resolver. #[cfg(not(feature = "no_module"))] pub resolver: Option>, /// Functions resolution cache. fn_resolution_caches: StaticVec< HashMap< NonZeroU64, Option<(CallableFunction, Option)>, StraightHasherBuilder, >, >, } impl State { /// Is the state currently at global (root) level? #[inline(always)] pub fn is_global(&self) -> bool { self.scope_level == 0 } /// Get the current functions resolution cache. pub fn fn_resolution_cache( &self, ) -> Option< &HashMap< NonZeroU64, Option<(CallableFunction, Option)>, StraightHasherBuilder, >, > { self.fn_resolution_caches.last() } /// Get a mutable reference to the current functions resolution cache. pub fn fn_resolution_cache_mut( &mut self, ) -> &mut HashMap< NonZeroU64, Option<(CallableFunction, Option)>, StraightHasherBuilder, > { if self.fn_resolution_caches.is_empty() { self.fn_resolution_caches .push(HashMap::with_capacity_and_hasher(16, StraightHasherBuilder)); } self.fn_resolution_caches.last_mut().unwrap() } /// Push an empty functions resolution cache onto the stack and make it current. pub fn push_fn_resolution_cache(&mut self) { self.fn_resolution_caches.push(Default::default()); } /// Remove the current functions resolution cache and make the last one current. pub fn pop_fn_resolution_cache(&mut self) { self.fn_resolution_caches.pop(); } /// Clear the current functions resolution cache. /// /// # Panics /// /// Panics if there is no current functions resolution cache. pub fn clear_fn_resolution_cache(&mut self) { self.fn_resolution_caches.last_mut().unwrap().clear(); } } /// _(INTERNALS)_ A type containing all the limits imposed by the [`Engine`]. /// Exported under the `internals` feature only. /// /// # Volatile Data Structure /// /// This type is volatile and may change. #[cfg(not(feature = "unchecked"))] #[derive(Debug, Clone, Eq, PartialEq, Hash)] pub struct Limits { /// Maximum levels of call-stack to prevent infinite recursion. /// /// Set to zero to effectively disable function calls. /// /// Not available under `no_function`. #[cfg(not(feature = "no_function"))] pub max_call_stack_depth: usize, /// Maximum depth of statements/expressions at global level. pub max_expr_depth: Option, /// Maximum depth of statements/expressions in functions. /// /// Not available under `no_function`. #[cfg(not(feature = "no_function"))] pub max_function_expr_depth: Option, /// Maximum number of operations allowed to run. pub max_operations: Option, /// Maximum number of [modules][Module] allowed to load. /// /// Set to zero to effectively disable loading any [module][Module]. /// /// Not available under `no_module`. #[cfg(not(feature = "no_module"))] pub max_modules: usize, /// Maximum length of a [string][ImmutableString]. pub max_string_size: Option, /// Maximum length of an [array][Array]. /// /// Not available under `no_index`. #[cfg(not(feature = "no_index"))] pub max_array_size: Option, /// Maximum number of properties in an [object map][Map]. /// /// Not available under `no_object`. #[cfg(not(feature = "no_object"))] pub max_map_size: Option, } /// Context of a script evaluation process. #[derive(Debug)] pub struct EvalContext<'e, 'x, 'px: 'x, 'a, 's, 'm, 'pm: 'm, 't, 'pt: 't> { pub(crate) engine: &'e Engine, pub(crate) scope: &'x mut Scope<'px>, pub(crate) mods: &'a mut Imports, pub(crate) state: &'s mut State, pub(crate) lib: &'m [&'pm Module], pub(crate) this_ptr: &'t mut Option<&'pt mut Dynamic>, pub(crate) level: usize, } impl<'e, 'x, 'px, 'a, 's, 'm, 'pm, 't, 'pt> EvalContext<'e, 'x, 'px, 'a, 's, 'm, 'pm, 't, 'pt> { /// The current [`Engine`]. #[inline(always)] pub fn engine(&self) -> &Engine { self.engine } /// The current source. #[inline(always)] pub fn source(&self) -> Option<&str> { self.state.source.as_ref().map(|s| s.as_str()) } /// The current [`Scope`]. #[inline(always)] pub fn scope(&self) -> &Scope { self.scope } /// Mutable reference to the current [`Scope`]. #[inline(always)] pub fn scope_mut(&mut self) -> &mut &'x mut Scope<'px> { &mut self.scope } /// Get an iterator over the current set of modules imported via `import` statements. #[cfg(not(feature = "no_module"))] #[inline(always)] pub fn iter_imports(&self) -> impl Iterator { self.mods.iter() } /// _(INTERNALS)_ The current set of modules imported via `import` statements. /// Available under the `internals` feature only. #[cfg(feature = "internals")] #[cfg(not(feature = "no_module"))] #[inline(always)] pub fn imports(&self) -> &Imports { self.mods } /// Get an iterator over the namespaces containing definition of all script-defined functions. #[inline(always)] pub fn iter_namespaces(&self) -> impl Iterator { self.lib.iter().cloned() } /// _(INTERNALS)_ The current set of namespaces containing definitions of all script-defined functions. /// Available under the `internals` feature only. #[cfg(feature = "internals")] #[inline(always)] pub fn namespaces(&self) -> &[&Module] { self.lib } /// The current bound `this` pointer, if any. #[inline(always)] pub fn this_ptr(&self) -> Option<&Dynamic> { self.this_ptr.as_ref().map(|v| &**v) } /// The current nesting level of function calls. #[inline(always)] pub fn call_level(&self) -> usize { self.level } } /// Rhai main scripting engine. /// /// # Thread Safety /// /// [`Engine`] is re-entrant. /// /// Currently, [`Engine`] is neither [`Send`] nor [`Sync`]. /// Use the `sync` feature to make it [`Send`] `+` [`Sync`]. /// /// # Example /// /// ``` /// # fn main() -> Result<(), Box> { /// use rhai::Engine; /// /// let engine = Engine::new(); /// /// let result = engine.eval::("40 + 2")?; /// /// println!("Answer: {}", result); // prints 42 /// # Ok(()) /// # } /// ``` pub struct Engine { /// A unique ID identifying this scripting [`Engine`]. pub id: String, /// A module containing all functions directly loaded into the Engine. pub(crate) global_namespace: Module, /// A collection of all modules loaded into the global namespace of the Engine. pub(crate) global_modules: StaticVec>, /// A collection of all sub-modules directly loaded into the Engine. pub(crate) global_sub_modules: HashMap>, /// A module resolution service. #[cfg(not(feature = "no_module"))] pub(crate) module_resolver: Box, /// A hashmap mapping type names to pretty-print names. pub(crate) type_names: HashMap, /// A hashset containing symbols to disable. pub(crate) disabled_symbols: HashSet, /// A hashmap containing custom keywords and precedence to recognize. pub(crate) custom_keywords: HashMap>, /// Custom syntax. pub(crate) custom_syntax: HashMap, /// Callback closure for resolving variable access. pub(crate) resolve_var: Option, /// Callback closure for implementing the `print` command. pub(crate) print: OnPrintCallback, /// Callback closure for implementing the `debug` command. pub(crate) debug: OnDebugCallback, /// Callback closure for progress reporting. pub(crate) progress: Option, /// Optimize the AST after compilation. pub(crate) optimization_level: OptimizationLevel, /// Max limits. #[cfg(not(feature = "unchecked"))] pub(crate) limits: Limits, /// Disable doc-comments? pub(crate) disable_doc_comments: bool, } impl fmt::Debug for Engine { #[inline(always)] fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { if !self.id.is_empty() { write!(f, "Engine({})", self.id) } else { f.write_str("Engine") } } } impl Default for Engine { #[inline(always)] fn default() -> Self { Self::new() } } /// Make getter function #[cfg(not(feature = "no_object"))] #[inline(always)] pub fn make_getter(id: &str) -> String { format!("{}{}", FN_GET, id) } /// Make setter function #[cfg(not(feature = "no_object"))] #[inline(always)] pub fn make_setter(id: &str) -> String { format!("{}{}", FN_SET, id) } /// Is this function an anonymous function? #[cfg(not(feature = "no_function"))] #[inline(always)] pub fn is_anonymous_fn(fn_name: &str) -> bool { fn_name.starts_with(FN_ANONYMOUS) } /// Print to stdout #[inline(always)] fn default_print(_s: &str) { #[cfg(not(feature = "no_std"))] #[cfg(not(target_arch = "wasm32"))] println!("{}", _s); } /// Debug to stdout #[inline(always)] fn default_debug(_s: &str, _source: Option<&str>, _pos: Position) { #[cfg(not(feature = "no_std"))] #[cfg(not(target_arch = "wasm32"))] if let Some(source) = _source { println!("{} @ {:?} | {}", source, _pos, _s); } else { println!("{:?} | {}", _pos, _s); } } /// Search for a module within an imports stack. /// [`Position`] in [`EvalAltResult`] is [`None`][Position::None] and must be set afterwards. pub fn search_imports( mods: &Imports, state: &mut State, namespace: &NamespaceRef, ) -> Result, Box> { let Ident { name: root, pos } = &namespace[0]; // Qualified - check if the root module is directly indexed let index = if state.always_search { None } else { namespace.index() }; Ok(if let Some(index) = index { let offset = mods.len() - index.get(); mods.get(offset).expect("invalid index in Imports") } else { mods.find(root) .map(|n| mods.get(n).expect("invalid index in Imports")) .ok_or_else(|| EvalAltResult::ErrorModuleNotFound(root.to_string(), *pos))? }) } impl Engine { /// Create a new [`Engine`] #[inline] pub fn new() -> Self { // Create the new scripting Engine let mut engine = Self { id: Default::default(), global_namespace: Default::default(), global_modules: Default::default(), global_sub_modules: Default::default(), #[cfg(not(feature = "no_module"))] #[cfg(not(feature = "no_std"))] #[cfg(not(target_arch = "wasm32"))] module_resolver: Box::new(crate::module::resolvers::FileModuleResolver::new()), #[cfg(not(feature = "no_module"))] #[cfg(any(feature = "no_std", target_arch = "wasm32",))] module_resolver: Box::new(crate::module::resolvers::DummyModuleResolver::new()), type_names: Default::default(), disabled_symbols: Default::default(), custom_keywords: Default::default(), custom_syntax: Default::default(), // variable resolver resolve_var: None, // default print/debug implementations print: Box::new(default_print), debug: Box::new(default_debug), // progress callback progress: None, // optimization level optimization_level: if cfg!(feature = "no_optimize") { OptimizationLevel::None } else { OptimizationLevel::Simple }, #[cfg(not(feature = "unchecked"))] limits: Limits { #[cfg(not(feature = "no_function"))] max_call_stack_depth: MAX_CALL_STACK_DEPTH, max_expr_depth: NonZeroUsize::new(MAX_EXPR_DEPTH), #[cfg(not(feature = "no_function"))] max_function_expr_depth: NonZeroUsize::new(MAX_FUNCTION_EXPR_DEPTH), max_operations: None, #[cfg(not(feature = "no_module"))] max_modules: usize::MAX, max_string_size: None, #[cfg(not(feature = "no_index"))] max_array_size: None, #[cfg(not(feature = "no_object"))] max_map_size: None, }, disable_doc_comments: false, }; engine.register_global_module(StandardPackage::new().as_shared_module()); engine } /// Create a new [`Engine`] with minimal built-in functions. /// /// Use [`register_global_module`][Engine::register_global_module] to add packages of functions. #[inline] pub fn new_raw() -> Self { Self { id: Default::default(), global_namespace: Default::default(), global_modules: Default::default(), global_sub_modules: Default::default(), #[cfg(not(feature = "no_module"))] module_resolver: Box::new(crate::module::resolvers::DummyModuleResolver::new()), type_names: Default::default(), disabled_symbols: Default::default(), custom_keywords: Default::default(), custom_syntax: Default::default(), resolve_var: None, print: Box::new(|_| {}), debug: Box::new(|_, _, _| {}), progress: None, optimization_level: if cfg!(feature = "no_optimize") { OptimizationLevel::None } else { OptimizationLevel::Simple }, #[cfg(not(feature = "unchecked"))] limits: Limits { #[cfg(not(feature = "no_function"))] max_call_stack_depth: MAX_CALL_STACK_DEPTH, max_expr_depth: NonZeroUsize::new(MAX_EXPR_DEPTH), #[cfg(not(feature = "no_function"))] max_function_expr_depth: NonZeroUsize::new(MAX_FUNCTION_EXPR_DEPTH), max_operations: None, #[cfg(not(feature = "no_module"))] max_modules: usize::MAX, max_string_size: None, #[cfg(not(feature = "no_index"))] max_array_size: None, #[cfg(not(feature = "no_object"))] max_map_size: None, }, disable_doc_comments: false, } } /// Search for a variable within the scope or within imports, /// depending on whether the variable name is namespace-qualified. pub(crate) fn search_namespace<'s>( &self, scope: &'s mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &'s mut Option<&mut Dynamic>, expr: &Expr, ) -> Result<(Target<'s>, Position), Box> { match expr { Expr::Variable(v) => match v.as_ref() { // Qualified variable (_, Some((hash_var, modules)), Ident { name, pos }) => { let module = search_imports(mods, state, modules)?; let target = module.get_qualified_var(*hash_var).map_err(|mut err| { match *err { EvalAltResult::ErrorVariableNotFound(ref mut err_name, _) => { *err_name = format!("{}{}", modules, name); } _ => (), } err.fill_position(*pos) })?; // Module variables are constant let mut target = target.clone(); target.set_access_mode(AccessMode::ReadOnly); Ok((target.into(), *pos)) } // Normal variable access _ => self.search_scope_only(scope, mods, state, lib, this_ptr, expr), }, _ => unreachable!("Expr::Variable expected, but gets {:?}", expr), } } /// Search for a variable within the scope pub(crate) fn search_scope_only<'s>( &self, scope: &'s mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &'s mut Option<&mut Dynamic>, expr: &Expr, ) -> Result<(Target<'s>, Position), Box> { let (index, _, Ident { name, pos }) = match expr { Expr::Variable(v) => v.as_ref(), _ => unreachable!("Expr::Variable expected, but gets {:?}", expr), }; // Check if the variable is `this` if name.as_str() == KEYWORD_THIS { if let Some(val) = this_ptr { return Ok(((*val).into(), *pos)); } else { return EvalAltResult::ErrorUnboundThis(*pos).into(); } } // Check if it is directly indexed let index = if state.always_search { &None } else { index }; // Check the variable resolver, if any if let Some(ref resolve_var) = self.resolve_var { let index = index.map(NonZeroUsize::get).unwrap_or(0); let context = EvalContext { engine: self, scope, mods, state, lib, this_ptr, level: 0, }; if let Some(mut result) = resolve_var(name, index, &context).map_err(|err| err.fill_position(*pos))? { result.set_access_mode(AccessMode::ReadOnly); return Ok((result.into(), *pos)); } } let index = if let Some(index) = index { scope.len() - index.get() } else { // Find the variable in the scope scope .get_index(name) .ok_or_else(|| EvalAltResult::ErrorVariableNotFound(name.to_string(), *pos))? .0 }; let val = scope.get_mut_by_index(index); // Check for data race - probably not necessary because the only place it should conflict is // in a method call when the object variable is also used as a parameter. // if cfg!(not(feature = "no_closure")) && val.is_locked() { // return EvalAltResult::ErrorDataRace(name.into(), *pos).into(); // } Ok((val.into(), *pos)) } /// Chain-evaluate a dot/index chain. /// [`Position`] in [`EvalAltResult`] is [`None`][Position::None] and must be set afterwards. #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] fn eval_dot_index_chain_helper( &self, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &mut Option<&mut Dynamic>, target: &mut Target, rhs: &Expr, idx_values: &mut StaticVec, chain_type: ChainType, level: usize, new_val: Option<(Dynamic, Position)>, ) -> Result<(Dynamic, bool), Box> { if chain_type == ChainType::NonChaining { unreachable!("should not be ChainType::NonChaining"); } let is_ref = target.is_ref(); let next_chain = match rhs { Expr::Index(_, _) => ChainType::Index, Expr::Dot(_, _) => ChainType::Dot, _ => ChainType::NonChaining, }; // Pop the last index value let idx_val = idx_values.pop().unwrap(); let target_val = target.as_mut(); match chain_type { #[cfg(not(feature = "no_index"))] ChainType::Index => { let pos = rhs.position(); match rhs { // xxx[idx].expr... | xxx[idx][expr]... Expr::Dot(x, x_pos) | Expr::Index(x, x_pos) => { let idx_pos = x.lhs.position(); let idx_val = idx_val.as_index_value(); let obj_ptr = &mut self.get_indexed_mut( mods, state, lib, target_val, idx_val, idx_pos, false, is_ref, true, level, )?; self.eval_dot_index_chain_helper( mods, state, lib, this_ptr, obj_ptr, &x.rhs, idx_values, next_chain, level, new_val, ) .map_err(|err| err.fill_position(*x_pos)) } // xxx[rhs] = new_val _ if new_val.is_some() => { let idx_val = idx_val.as_index_value(); let mut idx_val2 = idx_val.clone(); // `call_setter` is introduced to bypass double mutable borrowing of target let _call_setter = match self.get_indexed_mut( mods, state, lib, target_val, idx_val, pos, true, is_ref, false, level, ) { // Indexed value is a reference - update directly Ok(ref mut obj_ptr) => { let (new_val, new_val_pos) = new_val.unwrap(); obj_ptr.set_value(new_val, new_val_pos)?; None } Err(err) => match *err { // No index getter - try to call an index setter #[cfg(not(feature = "no_index"))] EvalAltResult::ErrorIndexingType(_, _) => Some(new_val.unwrap()), // Any other error - return err => return Err(Box::new(err)), }, }; #[cfg(not(feature = "no_index"))] if let Some(mut new_val) = _call_setter { let val_type_name = target_val.type_name(); let args = &mut [target_val, &mut idx_val2, &mut new_val.0]; self.exec_fn_call( mods, state, lib, FN_IDX_SET, None, args, is_ref, true, false, new_val.1, None, None, level, ) .map_err(|err| match *err { EvalAltResult::ErrorFunctionNotFound(fn_sig, _) if fn_sig.ends_with("]=") => { EvalAltResult::ErrorIndexingType( self.map_type_name(val_type_name).into(), Position::NONE, ) } err => err, })?; } Ok((Dynamic::UNIT, true)) } // xxx[rhs] _ => { let idx_val = idx_val.as_index_value(); self.get_indexed_mut( mods, state, lib, target_val, idx_val, pos, false, is_ref, true, level, ) .map(|v| (v.take_or_clone(), false)) } } } #[cfg(not(feature = "no_object"))] ChainType::Dot => { match rhs { // xxx.fn_name(arg_expr_list) Expr::FnCall(x, pos) if x.namespace.is_none() && new_val.is_none() => { let FnCallExpr { name, hash_script: hash, def_value, .. } = x.as_ref(); let def_value = def_value.as_ref(); let args = idx_val.as_fn_call_args(); self.make_method_call( mods, state, lib, name, *hash, target, args, def_value, false, *pos, level, ) } // xxx.fn_name(...) = ??? Expr::FnCall(_, _) if new_val.is_some() => { unreachable!("method call cannot be assigned to") } // xxx.module::fn_name(...) - syntax error Expr::FnCall(_, _) => { unreachable!("function call in dot chain should not be namespace-qualified") } // {xxx:map}.id = ??? Expr::Property(x) if target_val.is::() && new_val.is_some() => { let Ident { name, pos } = &x.2; let index = name.clone().into(); let mut val = self.get_indexed_mut( mods, state, lib, target_val, index, *pos, true, is_ref, false, level, )?; let (new_val, new_val_pos) = new_val.unwrap(); val.set_value(new_val, new_val_pos)?; Ok((Default::default(), true)) } // {xxx:map}.id Expr::Property(x) if target_val.is::() => { let Ident { name, pos } = &x.2; let index = name.clone().into(); let val = self.get_indexed_mut( mods, state, lib, target_val, index, *pos, false, is_ref, false, level, )?; Ok((val.take_or_clone(), false)) } // xxx.id = ??? Expr::Property(x) if new_val.is_some() => { let (_, setter, Ident { pos, .. }) = x.as_ref(); let mut new_val = new_val; let mut args = [target_val, &mut new_val.as_mut().unwrap().0]; self.exec_fn_call( mods, state, lib, setter, None, &mut args, is_ref, true, false, *pos, None, None, level, ) .map(|(v, _)| (v, true)) } // xxx.id Expr::Property(x) => { let (getter, _, Ident { pos, .. }) = x.as_ref(); let mut args = [target_val]; self.exec_fn_call( mods, state, lib, getter, None, &mut args, is_ref, true, false, *pos, None, None, level, ) .map(|(v, _)| (v, false)) } // {xxx:map}.sub_lhs[expr] | {xxx:map}.sub_lhs.expr Expr::Index(x, x_pos) | Expr::Dot(x, x_pos) if target_val.is::() => { let mut val = match &x.lhs { Expr::Property(p) => { let Ident { name, pos } = &p.2; let index = name.clone().into(); self.get_indexed_mut( mods, state, lib, target_val, index, *pos, false, is_ref, true, level, )? } // {xxx:map}.fn_name(arg_expr_list)[expr] | {xxx:map}.fn_name(arg_expr_list).expr Expr::FnCall(x, pos) if x.namespace.is_none() => { let FnCallExpr { name, hash_script: hash, def_value, .. } = x.as_ref(); let def_value = def_value.as_ref(); let args = idx_val.as_fn_call_args(); let (val, _) = self.make_method_call( mods, state, lib, name, *hash, target, args, def_value, false, *pos, level, )?; val.into() } // {xxx:map}.module::fn_name(...) - syntax error Expr::FnCall(_, _) => unreachable!( "function call in dot chain should not be namespace-qualified" ), // Others - syntax error expr => unreachable!("invalid dot expression: {:?}", expr), }; self.eval_dot_index_chain_helper( mods, state, lib, this_ptr, &mut val, &x.rhs, idx_values, next_chain, level, new_val, ) .map_err(|err| err.fill_position(*x_pos)) } // xxx.sub_lhs[expr] | xxx.sub_lhs.expr Expr::Index(x, x_pos) | Expr::Dot(x, x_pos) => { match &x.lhs { // xxx.prop[expr] | xxx.prop.expr Expr::Property(p) => { let (getter, setter, Ident { pos, .. }) = p.as_ref(); let arg_values = &mut [target_val, &mut Default::default()]; let args = &mut arg_values[..1]; let (mut val, updated) = self.exec_fn_call( mods, state, lib, getter, None, args, is_ref, true, false, *pos, None, None, level, )?; let val = &mut val; let (result, may_be_changed) = self .eval_dot_index_chain_helper( mods, state, lib, this_ptr, &mut val.into(), &x.rhs, idx_values, next_chain, level, new_val, ) .map_err(|err| err.fill_position(*x_pos))?; // Feed the value back via a setter just in case it has been updated if updated || may_be_changed { // Re-use args because the first &mut parameter will not be consumed arg_values[1] = val; self.exec_fn_call( mods, state, lib, setter, None, arg_values, is_ref, true, false, *pos, None, None, level, ) .or_else( |err| match *err { // If there is no setter, no need to feed it back because // the property is read-only EvalAltResult::ErrorDotExpr(_, _) => { Ok((Dynamic::UNIT, false)) } _ => Err(err), }, )?; } Ok((result, may_be_changed)) } // xxx.fn_name(arg_expr_list)[expr] | xxx.fn_name(arg_expr_list).expr Expr::FnCall(f, pos) if f.namespace.is_none() => { let FnCallExpr { name, hash_script: hash, def_value, .. } = f.as_ref(); let def_value = def_value.as_ref(); let args = idx_val.as_fn_call_args(); let (mut val, _) = self.make_method_call( mods, state, lib, name, *hash, target, args, def_value, false, *pos, level, )?; let val = &mut val; let target = &mut val.into(); self.eval_dot_index_chain_helper( mods, state, lib, this_ptr, target, &x.rhs, idx_values, next_chain, level, new_val, ) .map_err(|err| err.fill_position(*pos)) } // xxx.module::fn_name(...) - syntax error Expr::FnCall(_, _) => unreachable!( "function call in dot chain should not be namespace-qualified" ), // Others - syntax error expr => unreachable!("invalid dot expression: {:?}", expr), } } // Syntax error _ => EvalAltResult::ErrorDotExpr("".into(), rhs.position()).into(), } } chain_type => unreachable!("invalid ChainType: {:?}", chain_type), } } /// Evaluate a dot/index chain. #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] fn eval_dot_index_chain( &self, scope: &mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &mut Option<&mut Dynamic>, expr: &Expr, level: usize, new_val: Option<(Dynamic, Position)>, ) -> Result> { let (crate::ast::BinaryExpr { lhs, rhs }, chain_type, op_pos) = match expr { Expr::Index(x, pos) => (x.as_ref(), ChainType::Index, *pos), Expr::Dot(x, pos) => (x.as_ref(), ChainType::Dot, *pos), _ => unreachable!("index or dot chain expected, but gets {:?}", expr), }; let idx_values = &mut Default::default(); self.eval_indexed_chain( scope, mods, state, lib, this_ptr, rhs, chain_type, idx_values, 0, level, )?; match lhs { // id.??? or id[???] Expr::Variable(x) => { let Ident { name: var_name, pos: var_pos, } = &x.2; self.inc_operations(state, *var_pos)?; let (target, pos) = self.search_namespace(scope, mods, state, lib, this_ptr, lhs)?; // Constants cannot be modified if target.as_ref().is_read_only() && new_val.is_some() { return EvalAltResult::ErrorAssignmentToConstant(var_name.to_string(), pos) .into(); } let obj_ptr = &mut target.into(); self.eval_dot_index_chain_helper( mods, state, lib, &mut None, obj_ptr, rhs, idx_values, chain_type, level, new_val, ) .map(|(v, _)| v) .map_err(|err| err.fill_position(op_pos)) } // {expr}.??? = ??? or {expr}[???] = ??? _ if new_val.is_some() => unreachable!("cannot assign to an expression"), // {expr}.??? or {expr}[???] expr => { let val = self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)?; let obj_ptr = &mut val.into(); self.eval_dot_index_chain_helper( mods, state, lib, this_ptr, obj_ptr, rhs, idx_values, chain_type, level, new_val, ) .map(|(v, _)| v) .map_err(|err| err.fill_position(op_pos)) } } } /// Evaluate a chain of indexes and store the results in a [`StaticVec`]. /// [`StaticVec`] is used to avoid an allocation in the overwhelming cases of /// just a few levels of indexing. #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] fn eval_indexed_chain( &self, scope: &mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &mut Option<&mut Dynamic>, expr: &Expr, parent_chain_type: ChainType, idx_values: &mut StaticVec, size: usize, level: usize, ) -> Result<(), Box> { self.inc_operations(state, expr.position())?; match expr { Expr::FnCall(x, _) if parent_chain_type == ChainType::Dot && x.namespace.is_none() => { let arg_values = x .args .iter() .map(|arg_expr| { self.eval_expr(scope, mods, state, lib, this_ptr, arg_expr, level) }) .collect::, _>>()?; idx_values.push(arg_values.into()); } Expr::FnCall(_, _) if parent_chain_type == ChainType::Dot => { unreachable!("function call in dot chain should not be namespace-qualified") } Expr::Property(_) if parent_chain_type == ChainType::Dot => { idx_values.push(ChainArgument::Property) } Expr::Property(_) => unreachable!("unexpected Expr::Property for indexing"), Expr::Index(x, _) | Expr::Dot(x, _) => { let crate::ast::BinaryExpr { lhs, rhs, .. } = x.as_ref(); // Evaluate in left-to-right order let lhs_val = match lhs { Expr::Property(_) if parent_chain_type == ChainType::Dot => { ChainArgument::Property } Expr::Property(_) => unreachable!("unexpected Expr::Property for indexing"), Expr::FnCall(x, _) if parent_chain_type == ChainType::Dot && x.namespace.is_none() => { x.args .iter() .map(|arg_expr| { self.eval_expr(scope, mods, state, lib, this_ptr, arg_expr, level) }) .collect::, _>>()? .into() } Expr::FnCall(_, _) if parent_chain_type == ChainType::Dot => { unreachable!("function call in dot chain should not be namespace-qualified") } _ => self .eval_expr(scope, mods, state, lib, this_ptr, lhs, level)? .into(), }; // Push in reverse order let chain_type = match expr { Expr::Index(_, _) => ChainType::Index, Expr::Dot(_, _) => ChainType::Dot, _ => unreachable!("index or dot chain expected, but gets {:?}", expr), }; self.eval_indexed_chain( scope, mods, state, lib, this_ptr, rhs, chain_type, idx_values, size, level, )?; idx_values.push(lhs_val); } _ => idx_values.push( self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)? .into(), ), } Ok(()) } /// Get the value at the indexed position of a base type. /// [`Position`] in [`EvalAltResult`] may be None and should be set afterwards. #[cfg(any(not(feature = "no_index"), not(feature = "no_object")))] fn get_indexed_mut<'t>( &self, _mods: &mut Imports, state: &mut State, _lib: &[&Module], target: &'t mut Dynamic, idx: Dynamic, idx_pos: Position, _create: bool, _is_ref: bool, _indexers: bool, _level: usize, ) -> Result, Box> { self.inc_operations(state, Position::NONE)?; match target { #[cfg(not(feature = "no_index"))] Dynamic(Union::Array(arr, _)) => { // val_array[idx] let index = idx .as_int() .map_err(|err| self.make_type_mismatch_err::(err, idx_pos))?; let arr_len = arr.len(); if index >= 0 { arr.get_mut(index as usize) .map(Target::from) .ok_or_else(|| { EvalAltResult::ErrorArrayBounds(arr_len, index, idx_pos).into() }) } else { EvalAltResult::ErrorArrayBounds(arr_len, index, idx_pos).into() } } #[cfg(not(feature = "no_object"))] Dynamic(Union::Map(map, _)) => { // val_map[idx] Ok(if _create { let index = idx.take_immutable_string().map_err(|err| { self.make_type_mismatch_err::(err, idx_pos) })?; map.entry(index).or_insert_with(Default::default).into() } else { let index = idx.read_lock::().ok_or_else(|| { self.make_type_mismatch_err::("", idx_pos) })?; map.get_mut(&*index) .map(Target::from) .unwrap_or_else(|| Target::from(())) }) } #[cfg(not(feature = "no_index"))] Dynamic(Union::Str(s, _)) => { // val_string[idx] let chars_len = s.chars().count(); let index = idx .as_int() .map_err(|err| self.make_type_mismatch_err::(err, idx_pos))?; if index >= 0 { let offset = index as usize; let ch = s.chars().nth(offset).ok_or_else(|| { EvalAltResult::ErrorStringBounds(chars_len, index, idx_pos) })?; Ok(Target::StringChar(target, offset, ch.into())) } else { EvalAltResult::ErrorStringBounds(chars_len, index, idx_pos).into() } } #[cfg(not(feature = "no_index"))] _ if _indexers => { let type_name = target.type_name(); let mut idx = idx; let args = &mut [target, &mut idx]; self.exec_fn_call( _mods, state, _lib, FN_IDX_GET, None, args, _is_ref, true, false, idx_pos, None, None, _level, ) .map(|(v, _)| v.into()) .map_err(|err| match *err { EvalAltResult::ErrorFunctionNotFound(fn_sig, _) if fn_sig.ends_with(']') => { Box::new(EvalAltResult::ErrorIndexingType( type_name.into(), Position::NONE, )) } _ => err, }) } _ => EvalAltResult::ErrorIndexingType( self.map_type_name(target.type_name()).into(), Position::NONE, ) .into(), } } // Evaluate an 'in' expression. fn eval_in_expr( &self, scope: &mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &mut Option<&mut Dynamic>, lhs: &Expr, rhs: &Expr, level: usize, ) -> Result> { self.inc_operations(state, rhs.position())?; let lhs_value = self.eval_expr(scope, mods, state, lib, this_ptr, lhs, level)?; let rhs_value = self.eval_expr(scope, mods, state, lib, this_ptr, rhs, level)?; match rhs_value { #[cfg(not(feature = "no_index"))] Dynamic(Union::Array(mut rhs_value, _)) => { // Call the `==` operator to compare each value let def_value = Some(false.into()); let def_value = def_value.as_ref(); for value in rhs_value.iter_mut() { let args = &mut [&mut lhs_value.clone(), value]; // Qualifiers (none) + function name + number of arguments + argument `TypeId`'s. let hash_fn = calc_native_fn_hash(empty(), OP_EQUALS, args.iter().map(|a| a.type_id())) .unwrap(); let pos = rhs.position(); if self .call_native_fn( mods, state, lib, OP_EQUALS, hash_fn, args, false, false, pos, def_value, )? .0 .as_bool() .unwrap_or(false) { return Ok(true.into()); } } Ok(false.into()) } #[cfg(not(feature = "no_object"))] Dynamic(Union::Map(rhs_value, _)) => match lhs_value { // Only allows string or char Dynamic(Union::Str(s, _)) => Ok(rhs_value.contains_key(&s).into()), Dynamic(Union::Char(c, _)) => Ok(rhs_value.contains_key(&c.to_string()).into()), _ => EvalAltResult::ErrorInExpr(lhs.position()).into(), }, Dynamic(Union::Str(rhs_value, _)) => match lhs_value { // Only allows string or char Dynamic(Union::Str(s, _)) => Ok(rhs_value.contains(s.as_str()).into()), Dynamic(Union::Char(c, _)) => Ok(rhs_value.contains(c).into()), _ => EvalAltResult::ErrorInExpr(lhs.position()).into(), }, _ => EvalAltResult::ErrorInExpr(rhs.position()).into(), } } /// Evaluate an expression. pub(crate) fn eval_expr( &self, scope: &mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &mut Option<&mut Dynamic>, expr: &Expr, level: usize, ) -> Result> { self.inc_operations(state, expr.position())?; let result = match expr { Expr::DynamicConstant(x, _) => Ok(x.as_ref().clone()), Expr::IntegerConstant(x, _) => Ok((*x).into()), #[cfg(not(feature = "no_float"))] Expr::FloatConstant(x, _) => Ok((*x).into()), Expr::StringConstant(x, _) => Ok(x.clone().into()), Expr::CharConstant(x, _) => Ok((*x).into()), Expr::FnPointer(x, _) => Ok(FnPtr::new_unchecked(x.clone(), Default::default()).into()), Expr::Variable(x) if (x.2).name == KEYWORD_THIS => this_ptr .as_deref() .cloned() .ok_or_else(|| EvalAltResult::ErrorUnboundThis((x.2).pos).into()), Expr::Variable(_) => self .search_namespace(scope, mods, state, lib, this_ptr, expr) .map(|(val, _)| val.take_or_clone()), // Statement block Expr::Stmt(x, _) => { self.eval_stmt_block(scope, mods, state, lib, this_ptr, x.as_ref(), true, level) } // lhs[idx_expr] #[cfg(not(feature = "no_index"))] Expr::Index(_, _) => { self.eval_dot_index_chain(scope, mods, state, lib, this_ptr, expr, level, None) } // lhs.dot_rhs #[cfg(not(feature = "no_object"))] Expr::Dot(_, _) => { self.eval_dot_index_chain(scope, mods, state, lib, this_ptr, expr, level, None) } #[cfg(not(feature = "no_index"))] Expr::Array(x, _) => { let mut arr = Array::with_capacity(crate::stdlib::cmp::max(TYPICAL_ARRAY_SIZE, x.len())); for item in x.as_ref() { arr.push(self.eval_expr(scope, mods, state, lib, this_ptr, item, level)?); } Ok(Dynamic(Union::Array(Box::new(arr), AccessMode::ReadWrite))) } #[cfg(not(feature = "no_object"))] Expr::Map(x, _) => { let mut map = Map::with_capacity(crate::stdlib::cmp::max(TYPICAL_MAP_SIZE, x.len())); for (Ident { name: key, .. }, expr) in x.as_ref() { map.insert( key.clone(), self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)?, ); } Ok(Dynamic(Union::Map(Box::new(map), AccessMode::ReadWrite))) } // Normal function call Expr::FnCall(x, pos) if x.namespace.is_none() => { let FnCallExpr { name, capture: cap_scope, hash_script: hash, args, def_value, .. } = x.as_ref(); let def_value = def_value.as_ref(); self.make_function_call( scope, mods, state, lib, this_ptr, name, args, def_value, *hash, false, *pos, *cap_scope, level, ) } // Namespace-qualified function call Expr::FnCall(x, pos) if x.namespace.is_some() => { let FnCallExpr { name, namespace, hash_script, args, def_value, .. } = x.as_ref(); let namespace = namespace.as_ref(); let hash = hash_script.unwrap(); let def_value = def_value.as_ref(); self.make_qualified_function_call( scope, mods, state, lib, this_ptr, namespace, name, args, def_value, hash, *pos, level, ) } Expr::In(x, _) => { self.eval_in_expr(scope, mods, state, lib, this_ptr, &x.lhs, &x.rhs, level) } Expr::And(x, _) => { Ok((self .eval_expr(scope, mods, state, lib, this_ptr, &x.lhs, level)? .as_bool() .map_err(|err| self.make_type_mismatch_err::(err, x.lhs.position()))? && // Short-circuit using && self .eval_expr(scope, mods, state, lib, this_ptr, &x.rhs, level)? .as_bool() .map_err(|err| self.make_type_mismatch_err::(err, x.rhs.position()))?) .into()) } Expr::Or(x, _) => { Ok((self .eval_expr(scope, mods, state, lib, this_ptr, &x.lhs, level)? .as_bool() .map_err(|err| self.make_type_mismatch_err::(err, x.lhs.position()))? || // Short-circuit using || self .eval_expr(scope, mods, state, lib, this_ptr, &x.rhs, level)? .as_bool() .map_err(|err| self.make_type_mismatch_err::(err, x.rhs.position()))?) .into()) } Expr::BoolConstant(x, _) => Ok((*x).into()), Expr::Unit(_) => Ok(Dynamic::UNIT), Expr::Custom(custom, _) => { let expressions = custom .keywords .iter() .map(Into::into) .collect::>(); let custom_def = self .custom_syntax .get(custom.tokens.first().unwrap()) .unwrap(); let mut context = EvalContext { engine: self, scope, mods, state, lib, this_ptr, level, }; (custom_def.func)(&mut context, &expressions) } _ => unreachable!("expression cannot be evaluated: {:?}", expr), }; self.check_data_size(result, expr.position()) } /// Evaluate a statements block. pub(crate) fn eval_stmt_block<'a>( &self, scope: &mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &mut Option<&mut Dynamic>, statements: impl IntoIterator, restore: bool, level: usize, ) -> Result> { let mut _has_imports = false; let prev_always_search = state.always_search; let prev_scope_len = scope.len(); let prev_mods_len = mods.len(); if restore { state.scope_level += 1; } let result = statements.into_iter().try_fold(Dynamic::UNIT, |_, stmt| { #[cfg(not(feature = "no_module"))] match stmt { Stmt::Import(_, _, _) => { // When imports list is modified, clear the functions lookup cache if _has_imports { state.clear_fn_resolution_cache(); } else if restore { state.push_fn_resolution_cache(); _has_imports = true; } } _ => (), } self.eval_stmt(scope, mods, state, lib, this_ptr, stmt, level) }); if restore { scope.rewind(prev_scope_len); if _has_imports { // If imports list is modified, pop the functions lookup cache state.pop_fn_resolution_cache(); } mods.truncate(prev_mods_len); state.scope_level -= 1; // The impact of new local variables goes away at the end of a block // because any new variables introduced will go out of scope state.always_search = prev_always_search; } result } /// Evaluate a statement. /// /// # Safety /// /// This method uses some unsafe code, mainly for avoiding cloning of local variable names via /// direct lifetime casting. pub(crate) fn eval_stmt( &self, scope: &mut Scope, mods: &mut Imports, state: &mut State, lib: &[&Module], this_ptr: &mut Option<&mut Dynamic>, stmt: &Stmt, level: usize, ) -> Result> { self.inc_operations(state, stmt.position())?; let result = match stmt { // No-op Stmt::Noop(_) => Ok(Dynamic::UNIT), // Expression as statement Stmt::Expr(expr) => self.eval_expr(scope, mods, state, lib, this_ptr, expr, level), // var op= rhs Stmt::Assignment(x, op_pos) if x.0.get_variable_access(false).is_some() => { let (lhs_expr, op, rhs_expr) = x.as_ref(); let mut rhs_val = self .eval_expr(scope, mods, state, lib, this_ptr, rhs_expr, level)? .flatten(); let (mut lhs_ptr, pos) = self.search_namespace(scope, mods, state, lib, this_ptr, lhs_expr)?; if !lhs_ptr.is_ref() { return EvalAltResult::ErrorAssignmentToConstant( lhs_expr.get_variable_access(false).unwrap().to_string(), pos, ) .into(); } self.inc_operations(state, pos)?; if lhs_ptr.as_ref().is_read_only() { // Assignment to constant variable Err(Box::new(EvalAltResult::ErrorAssignmentToConstant( lhs_expr.get_variable_access(false).unwrap().to_string(), pos, ))) } else if op.is_empty() { // Normal assignment if cfg!(not(feature = "no_closure")) && lhs_ptr.is_shared() { *lhs_ptr.as_mut().write_lock::().unwrap() = rhs_val; } else { *lhs_ptr.as_mut() = rhs_val; } Ok(Dynamic::UNIT) } else { // Op-assignment - in order of precedence: // 1) Native registered overriding function // 2) Built-in implementation // 3) Map to `var = var op rhs` // Qualifiers (none) + function name + number of arguments + argument `TypeId`'s. let arg_types = once(lhs_ptr.as_mut().type_id()).chain(once(rhs_val.type_id())); let hash_fn = calc_native_fn_hash(empty(), op, arg_types).unwrap(); match self .global_namespace .get_fn(hash_fn, false) .map(|f| (f, None)) .or_else(|| { self.global_modules .iter() .find_map(|m| m.get_fn(hash_fn, false).map(|f| (f, m.id_raw()))) }) .or_else(|| mods.get_fn(hash_fn)) { // op= function registered as method Some((func, source)) if func.is_method() => { let mut lock_guard; let lhs_ptr_inner; if cfg!(not(feature = "no_closure")) && lhs_ptr.is_shared() { lock_guard = lhs_ptr.as_mut().write_lock::().unwrap(); lhs_ptr_inner = lock_guard.deref_mut(); } else { lhs_ptr_inner = lhs_ptr.as_mut(); } let args = &mut [lhs_ptr_inner, &mut rhs_val]; // Overriding exact implementation let source = source.or_else(|| state.source.as_ref()).map(|s| s.as_str()); if func.is_plugin_fn() { func.get_plugin_fn() .call((self, op.as_ref(), source, &*mods, lib).into(), args)?; } else { func.get_native_fn()( (self, op.as_ref(), source, &*mods, lib).into(), args, )?; } } // Built-in op-assignment function _ if run_builtin_op_assignment(op, lhs_ptr.as_mut(), &rhs_val)? .is_some() => {} // Not built-in: expand to `var = var op rhs` _ => { let op = &op[..op.len() - 1]; // extract operator without = // Clone the LHS value let args = &mut [&mut lhs_ptr.as_mut().clone(), &mut rhs_val]; // Run function let (value, _) = self.exec_fn_call( mods, state, lib, op, None, args, false, false, false, *op_pos, None, None, level, )?; let value = value.flatten(); if cfg!(not(feature = "no_closure")) && lhs_ptr.is_shared() { *lhs_ptr.as_mut().write_lock::().unwrap() = value; } else { *lhs_ptr.as_mut() = value; } } } Ok(Dynamic::UNIT) } } // lhs op= rhs Stmt::Assignment(x, op_pos) => { let (lhs_expr, op, rhs_expr) = x.as_ref(); let mut rhs_val = self.eval_expr(scope, mods, state, lib, this_ptr, rhs_expr, level)?; let _new_val = if op.is_empty() { // Normal assignment Some((rhs_val, rhs_expr.position())) } else { // Op-assignment - always map to `lhs = lhs op rhs` let op = &op[..op.len() - 1]; // extract operator without = let args = &mut [ &mut self.eval_expr(scope, mods, state, lib, this_ptr, lhs_expr, level)?, &mut rhs_val, ]; Some( self.exec_fn_call( mods, state, lib, op, None, args, false, false, false, *op_pos, None, None, level, ) .map(|(v, _)| (v, rhs_expr.position()))?, ) }; // Must be either `var[index] op= val` or `var.prop op= val` match lhs_expr { // name op= rhs (handled above) Expr::Variable(_) => { unreachable!("Expr::Variable case should already been handled") } // idx_lhs[idx_expr] op= rhs #[cfg(not(feature = "no_index"))] Expr::Index(_, _) => { self.eval_dot_index_chain( scope, mods, state, lib, this_ptr, lhs_expr, level, _new_val, )?; Ok(Dynamic::UNIT) } // dot_lhs.dot_rhs op= rhs #[cfg(not(feature = "no_object"))] Expr::Dot(_, _) => { self.eval_dot_index_chain( scope, mods, state, lib, this_ptr, lhs_expr, level, _new_val, )?; Ok(Dynamic::UNIT) } _ => unreachable!("cannot assign to expression: {:?}", lhs_expr), } } // Block scope Stmt::Block(statements, _) => { self.eval_stmt_block(scope, mods, state, lib, this_ptr, statements, true, level) } // If statement Stmt::If(expr, x, _) => { let (if_block, else_block) = x.as_ref(); self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)? .as_bool() .map_err(|err| self.make_type_mismatch_err::(err, expr.position())) .and_then(|guard_val| { if guard_val { self.eval_stmt(scope, mods, state, lib, this_ptr, if_block, level) } else if let Some(stmt) = else_block { self.eval_stmt(scope, mods, state, lib, this_ptr, stmt, level) } else { Ok(Dynamic::UNIT) } }) } // Switch statement Stmt::Switch(match_expr, x, _) => { let (table, def_stmt) = x.as_ref(); let hasher = &mut get_hasher(); self.eval_expr(scope, mods, state, lib, this_ptr, match_expr, level)? .hash(hasher); let hash = hasher.finish(); if let Some(stmt) = table.get(&hash) { self.eval_stmt(scope, mods, state, lib, this_ptr, stmt, level) } else if let Some(def_stmt) = def_stmt { self.eval_stmt(scope, mods, state, lib, this_ptr, def_stmt, level) } else { Ok(Dynamic::UNIT) } } // While loop Stmt::While(expr, body, _) => loop { match self .eval_expr(scope, mods, state, lib, this_ptr, expr, level)? .as_bool() { Ok(true) => { match self.eval_stmt(scope, mods, state, lib, this_ptr, body, level) { Ok(_) => (), Err(err) => match *err { EvalAltResult::LoopBreak(false, _) => (), EvalAltResult::LoopBreak(true, _) => return Ok(Dynamic::UNIT), _ => return Err(err), }, } } Ok(false) => return Ok(Dynamic::UNIT), Err(err) => { return Err(self.make_type_mismatch_err::(err, expr.position())) } } }, // Do loop Stmt::Do(body, expr, is_while, _) => loop { match self.eval_stmt(scope, mods, state, lib, this_ptr, body, level) { Ok(_) => (), Err(err) => match *err { EvalAltResult::LoopBreak(false, _) => continue, EvalAltResult::LoopBreak(true, _) => return Ok(Dynamic::UNIT), _ => return Err(err), }, } match self .eval_expr(scope, mods, state, lib, this_ptr, expr, level)? .as_bool() { Ok(true) if !*is_while => return Ok(Dynamic::UNIT), Ok(false) if *is_while => return Ok(Dynamic::UNIT), Ok(_) => (), Err(err) => { return Err(self.make_type_mismatch_err::(err, expr.position())) } } }, // For loop Stmt::For(expr, x, _) => { let (name, stmt) = x.as_ref(); let iter_obj = self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)?; let iter_type = iter_obj.type_id(); let func = self .global_namespace .get_iter(iter_type) .or_else(|| { self.global_modules .iter() .find_map(|m| m.get_iter(iter_type)) }) .or_else(|| mods.get_iter(iter_type)); if let Some(func) = func { // Add the loop variable let var_name: Cow<'_, str> = if state.is_global() { name.clone().into() } else { unsafe_cast_var_name_to_lifetime(name).into() }; scope.push(var_name, ()); let index = scope.len() - 1; state.scope_level += 1; for iter_value in func(iter_obj) { let loop_var = scope.get_mut_by_index(index); let value = iter_value.flatten(); if cfg!(not(feature = "no_closure")) && loop_var.is_shared() { *loop_var.write_lock().unwrap() = value; } else { *loop_var = value; } self.inc_operations(state, stmt.position())?; match self.eval_stmt(scope, mods, state, lib, this_ptr, stmt, level) { Ok(_) => (), Err(err) => match *err { EvalAltResult::LoopBreak(false, _) => (), EvalAltResult::LoopBreak(true, _) => break, _ => return Err(err), }, } } state.scope_level -= 1; scope.rewind(scope.len() - 1); Ok(Dynamic::UNIT) } else { EvalAltResult::ErrorFor(expr.position()).into() } } // Continue statement Stmt::Continue(pos) => EvalAltResult::LoopBreak(false, *pos).into(), // Break statement Stmt::Break(pos) => EvalAltResult::LoopBreak(true, *pos).into(), // Try/Catch statement Stmt::TryCatch(x, _, _) => { let (try_body, err_var, catch_body) = x.as_ref(); let result = self .eval_stmt(scope, mods, state, lib, this_ptr, try_body, level) .map(|_| Dynamic::UNIT); match result { Ok(_) => result, Err(err) if err.is_pseudo_error() => Err(err), Err(err) if !err.is_catchable() => Err(err), Err(mut err) => { let value = match *err { EvalAltResult::ErrorRuntime(ref x, _) => x.clone(), _ => { err.set_position(Position::NONE); err.to_string().into() } }; let orig_scope_len = scope.len(); state.scope_level += 1; if let Some(Ident { name, .. }) = err_var { scope.push(unsafe_cast_var_name_to_lifetime(&name), value); } let result = self.eval_stmt(scope, mods, state, lib, this_ptr, catch_body, level); state.scope_level -= 1; scope.rewind(orig_scope_len); match result { Ok(_) => Ok(Dynamic::UNIT), Err(result_err) => match *result_err { // Re-throw exception EvalAltResult::ErrorRuntime(Dynamic(Union::Unit(_, _)), pos) => { err.set_position(pos); Err(err) } _ => Err(result_err), }, } } } } // Return value Stmt::Return((ReturnType::Return, pos), Some(expr), _) => EvalAltResult::Return( self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)?, *pos, ) .into(), // Empty return Stmt::Return((ReturnType::Return, pos), None, _) => { EvalAltResult::Return(Default::default(), *pos).into() } // Throw value Stmt::Return((ReturnType::Exception, pos), Some(expr), _) => { let val = self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)?; EvalAltResult::ErrorRuntime(val, *pos).into() } // Empty throw Stmt::Return((ReturnType::Exception, pos), None, _) => { EvalAltResult::ErrorRuntime(Dynamic::UNIT, *pos).into() } // Let/const statement Stmt::Let(var_def, expr, export, _) | Stmt::Const(var_def, expr, export, _) => { let entry_type = match stmt { Stmt::Let(_, _, _, _) => AccessMode::ReadWrite, Stmt::Const(_, _, _, _) => AccessMode::ReadOnly, _ => unreachable!("should be Stmt::Let or Stmt::Const, but gets {:?}", stmt), }; let val = if let Some(expr) = expr { self.eval_expr(scope, mods, state, lib, this_ptr, expr, level)? .flatten() } else { Dynamic::UNIT }; let (var_name, _alias): (Cow<'_, str>, _) = if state.is_global() { ( var_def.name.to_string().into(), if *export { Some(var_def.name.clone()) } else { None }, ) } else if *export { unreachable!("exported variable not on global level"); } else { (unsafe_cast_var_name_to_lifetime(&var_def.name).into(), None) }; scope.push_dynamic_value(var_name, entry_type, val); #[cfg(not(feature = "no_module"))] if let Some(alias) = _alias { scope.add_entry_alias(scope.len() - 1, alias); } Ok(Dynamic::UNIT) } // Import statement #[cfg(not(feature = "no_module"))] Stmt::Import(expr, alias, _pos) => { // Guard against too many modules #[cfg(not(feature = "unchecked"))] if state.modules >= self.max_modules() { return EvalAltResult::ErrorTooManyModules(*_pos).into(); } if let Some(path) = self .eval_expr(scope, mods, state, lib, this_ptr, &expr, level)? .try_cast::() { use crate::ModuleResolver; let expr_pos = expr.position(); let module = state .resolver .as_ref() .and_then(|r| match r.resolve(self, &path, expr_pos) { Ok(m) => return Some(Ok(m)), Err(err) => match *err { EvalAltResult::ErrorModuleNotFound(_, _) => None, _ => return Some(Err(err)), }, }) .unwrap_or_else(|| self.module_resolver.resolve(self, &path, expr_pos))?; if let Some(name_def) = alias { if !module.is_indexed() { // Index the module (making a clone copy if necessary) if it is not indexed let mut module = crate::fn_native::shared_take_or_clone(module); module.build_index(); mods.push(name_def.name.clone(), module); } else { mods.push(name_def.name.clone(), module); } } state.modules += 1; Ok(Dynamic::UNIT) } else { Err(self.make_type_mismatch_err::("", expr.position())) } } // Export statement #[cfg(not(feature = "no_module"))] Stmt::Export(list, _) => { for (Ident { name, pos: id_pos }, rename) in list.iter() { // Mark scope variables as public if let Some(index) = scope.get_index(name).map(|(i, _)| i) { let alias = rename.as_ref().map(|x| &x.name).unwrap_or_else(|| name); scope.add_entry_alias(index, alias.clone()); } else { return EvalAltResult::ErrorVariableNotFound(name.to_string(), *id_pos) .into(); } } Ok(Dynamic::UNIT) } // Share statement #[cfg(not(feature = "no_closure"))] Stmt::Share(x) => { if let Some((index, _)) = scope.get_index(&x.name) { let val = scope.get_mut_by_index(index); if !val.is_shared() { // Replace the variable with a shared value. *val = crate::stdlib::mem::take(val).into_shared(); } } Ok(Dynamic::UNIT) } }; self.check_data_size(result, stmt.position()) } /// Check a result to ensure that the data size is within allowable limit. /// [`Position`] in [`EvalAltResult`] may be None and should be set afterwards. #[cfg(feature = "unchecked")] #[inline(always)] fn check_data_size( &self, result: Result>, _pos: Position, ) -> Result> { result } /// Check a result to ensure that the data size is within allowable limit. #[cfg(not(feature = "unchecked"))] fn check_data_size( &self, result: Result>, pos: Position, ) -> Result> { // Simply return all errors if result.is_err() { return result; } // If no data size limits, just return let mut has_limit = self.limits.max_string_size.is_some(); #[cfg(not(feature = "no_index"))] { has_limit = has_limit || self.limits.max_array_size.is_some(); } #[cfg(not(feature = "no_object"))] { has_limit = has_limit || self.limits.max_map_size.is_some(); } if !has_limit { return result; } // Recursively calculate the size of a value (especially `Array` and `Map`) fn calc_size(value: &Dynamic) -> (usize, usize, usize) { match value { #[cfg(not(feature = "no_index"))] Dynamic(Union::Array(arr, _)) => { let mut arrays = 0; let mut maps = 0; arr.iter().for_each(|value| match value { Dynamic(Union::Array(_, _)) => { let (a, m, _) = calc_size(value); arrays += a; maps += m; } #[cfg(not(feature = "no_object"))] Dynamic(Union::Map(_, _)) => { let (a, m, _) = calc_size(value); arrays += a; maps += m; } _ => arrays += 1, }); (arrays, maps, 0) } #[cfg(not(feature = "no_object"))] Dynamic(Union::Map(map, _)) => { let mut arrays = 0; let mut maps = 0; map.values().for_each(|value| match value { #[cfg(not(feature = "no_index"))] Dynamic(Union::Array(_, _)) => { let (a, m, _) = calc_size(value); arrays += a; maps += m; } Dynamic(Union::Map(_, _)) => { let (a, m, _) = calc_size(value); arrays += a; maps += m; } _ => maps += 1, }); (arrays, maps, 0) } Dynamic(Union::Str(s, _)) => (0, 0, s.len()), _ => (0, 0, 0), } } let (_arr, _map, s) = calc_size(result.as_ref().unwrap()); if s > self .limits .max_string_size .map_or(usize::MAX, NonZeroUsize::get) { return EvalAltResult::ErrorDataTooLarge("Length of string".to_string(), pos).into(); } #[cfg(not(feature = "no_index"))] if _arr > self .limits .max_array_size .map_or(usize::MAX, NonZeroUsize::get) { return EvalAltResult::ErrorDataTooLarge("Size of array".to_string(), pos).into(); } #[cfg(not(feature = "no_object"))] if _map > self .limits .max_map_size .map_or(usize::MAX, NonZeroUsize::get) { return EvalAltResult::ErrorDataTooLarge("Size of object map".to_string(), pos).into(); } result } /// Check if the number of operations stay within limit. #[inline] pub(crate) fn inc_operations( &self, state: &mut State, pos: Position, ) -> Result<(), Box> { state.operations += 1; #[cfg(not(feature = "unchecked"))] // Guard against too many operations if self.max_operations() > 0 && state.operations > self.max_operations() { return EvalAltResult::ErrorTooManyOperations(pos).into(); } // Report progress - only in steps if let Some(progress) = &self.progress { if let Some(token) = progress(state.operations) { // Terminate script if progress returns a termination token return EvalAltResult::ErrorTerminated(token, pos).into(); } } Ok(()) } /// Map a type_name into a pretty-print name #[inline(always)] pub(crate) fn map_type_name<'a>(&'a self, name: &'a str) -> &'a str { self.type_names .get(name) .map(String::as_str) .unwrap_or_else(|| map_std_type_name(name)) } /// Make a `Box<`[`EvalAltResult`][EvalAltResult::ErrorMismatchDataType]`>`. #[inline(always)] pub(crate) fn make_type_mismatch_err(&self, typ: &str, pos: Position) -> Box { EvalAltResult::ErrorMismatchDataType( typ.into(), self.map_type_name(type_name::()).into(), pos, ) .into() } }