const std = @import("std"); const logger = @import("logger.zig"); const JSXRuntime = @import("options.zig").JSX.Runtime; const Runtime = @import("runtime.zig").Runtime; usingnamespace @import("global.zig"); usingnamespace @import("ast/base.zig"); const ImportRecord = @import("import_record.zig").ImportRecord; const allocators = @import("allocators.zig"); const _hash_map = @import("hash_map.zig"); const StringHashMap = _hash_map.StringHashMap; const AutoHashMap = _hash_map.AutoHashMap; pub fn NewBaseStore(comptime Union: anytype, comptime count: usize) type { var max_size = 0; var max_align = 1; for (Union) |kind| { max_size = std.math.max(@sizeOf(kind), max_size); max_align = if (@sizeOf(kind) == 0) max_align else std.math.max(@alignOf(kind), max_align); } const UnionValueType = [max_size]u8; const MaxAlign = max_align; return struct { const Allocator = std.mem.Allocator; const Self = @This(); const Block = struct { items: [count]UnionValueType align(MaxAlign) = undefined, used: usize = 0, allocator: *std.mem.Allocator, pub inline fn isFull(block: *const Block) bool { return block.used >= block.items.len; } pub fn append(block: *Block, value: anytype) *UnionValueType { std.debug.assert(block.used < count); const index = block.used; std.mem.copy(u8, &block.items[index], value); block.used += 1; return &block.items[index]; } }; block: Block, overflow_ptrs: [4096 * 3]*Block = undefined, overflow: []*Block = &([_]*Block{}), overflow_used: usize = 0, allocator: *Allocator, pub threadlocal var instance: Self = undefined; pub threadlocal var _self: *Self = undefined; pub fn reset() void { _self.block.used = 0; for (_self.overflow[0.._self.overflow_used]) |b| { b.used = 0; } _self.overflow_used = 0; } pub fn init(allocator: *std.mem.Allocator) *Self { instance = Self{ .allocator = allocator, .block = Block{ .allocator = allocator }, }; _self = &instance; return _self; } pub fn append(comptime ValueType: type, value: ValueType) *ValueType { return _self._append(ValueType, value); } fn _append(self: *Self, comptime ValueType: type, value: ValueType) *ValueType { if (!self.block.isFull()) { var ptr = self.block.append(std.mem.asBytes(&value)); var aligned_slice = @alignCast(@alignOf(ValueType), ptr); return @ptrCast( *ValueType, aligned_slice, ); } if (self.overflow_used >= self.overflow.len or self.overflow[self.overflow_used].isFull()) { var slice = self.allocator.alloc(Block, 2) catch unreachable; for (slice) |*block| { block.allocator = self.allocator; block.used = 0; block.items = undefined; self.overflow_ptrs[self.overflow.len] = block; self.overflow = self.overflow_ptrs[0 .. self.overflow.len + 1]; } } var block = self.overflow[self.overflow_used]; var ptr = block.append(std.mem.asBytes(&value)); if (block.isFull()) { self.overflow_used += 1; } var aligned_slice = @alignCast(@alignOf(ValueType), ptr); return @ptrCast( *ValueType, aligned_slice, ); } }; } // There are three types. // 1. Expr (expression) // 2. Stmt (statement) // 3. Binding // Q: "What's the difference between an expression and a statement?" // A: > Expression: Something which evaluates to a value. Example: 1+2/x // > Statement: A line of code which does something. Example: GOTO 100 // > https://stackoverflow.com/questions/19132/expression-versus-statement/19224#19224 // Expr, Binding, and Stmt each wrap a Data: // Data is where the actual data where the node lives. // There are four possible versions of this structure: // [ ] 1. *Expr, *Stmt, *Binding // [ ] 1a. *Expr, *Stmt, *Binding something something dynamic dispatch // [ ] 2. *Data // [x] 3. Data.(*) (The union value in Data is a pointer) // I chose #3 mostly for code simplification -- sometimes, the data is modified in-place. // But also it uses the least memory. // Since Data is a union, the size in bytes of Data is the max of all types // So with #1 or #2, if S.Function consumes 768 bits, that means Data must be >= 768 bits // Which means "true" in code now takes up over 768 bits, probably more than what v8 spends // Instead, this approach means Data is the size of a pointer. // It's not really clear which approach is best without benchmarking it. // The downside with this approach is potentially worse memory locality, since the data for the node is somewhere else. // But it could also be better memory locality due to smaller in-memory size (more likely to hit the cache) // only benchmarks will provide an answer! // But we must have pointers somewhere in here because can't have types that contain themselves pub const BindingNodeIndex = Binding; pub const StmtNodeIndex = Stmt; pub const ExprNodeIndex = Expr; pub const ExprNodeList = []Expr; pub const StmtNodeList = []Stmt; pub const BindingNodeList = []Binding; pub const ImportItemStatus = enum(u2) { none, // The linker doesn't report import/export mismatch errors generated, // The printer will replace this import with "undefined" missing, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub const AssignTarget = enum(u2) { none, replace, // "a = b" update, // "a += b" pub fn jsonStringify(self: *const @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub const LocRef = struct { loc: logger.Loc, ref: ?Ref }; pub const Flags = struct { pub const JSXElement = packed struct { is_key_before_rest: bool = false, }; pub const Property = packed struct { is_computed: bool = false, is_method: bool = false, is_static: bool = false, was_shorthand: bool = false, is_spread: bool = false, const None = Flags.Property{}; }; pub const Function = packed struct { is_async: bool = false, is_generator: bool = false, has_rest_arg: bool = false, has_if_scope: bool = false, is_forward_declaration: bool = false, // This is true if the function is a method is_unique_formal_parameters: bool = false, // Only applicable to function statements. is_export: bool = false, // Used for Hot Module Reloading's wrapper function // "iife" stands for "immediately invoked function expression" print_as_iife: bool = false, const None = Flags.Function{}; }; }; pub const Binding = struct { loc: logger.Loc, data: B, const Serializable = struct { @"type": Tag, object: string, value: B, loc: logger.Loc, }; pub fn jsonStringify(self: *const @This(), options: anytype, writer: anytype) !void { return try std.json.stringify(Serializable{ .@"type" = std.meta.activeTag(self.data), .object = "binding", .value = self.data, .loc = self.loc }, options, writer); } pub fn ToExpr(comptime expr_type: type, comptime func_type: anytype) type { const ExprType = expr_type; return struct { context: *ExprType, allocator: *std.mem.Allocator, pub const Context = @This(); pub fn wrapIdentifier(ctx: *const Context, loc: logger.Loc, ref: Ref) Expr { return func_type(ctx.context, loc, ref); } pub fn init(context: *ExprType) Context { return Context{ .context = context, .allocator = context.allocator }; } }; } pub fn toExpr(binding: *const Binding, wrapper: anytype) Expr { var loc = binding.loc; switch (binding.data) { .b_missing => { return Expr.alloc(wrapper.allocator, E.Missing{}, loc); }, .b_identifier => |b| { return wrapper.wrapIdentifier(loc, b.ref); }, .b_array => |b| { var exprs = wrapper.allocator.alloc(Expr, b.items.len) catch unreachable; var i: usize = 0; while (i < exprs.len) : (i += 1) { const item = b.items[i]; exprs[i] = convert: { const expr = toExpr(&item.binding, wrapper); if (b.has_spread and i == exprs.len - 1) { break :convert Expr.alloc(wrapper.allocator, E.Spread{ .value = expr }, expr.loc); } else if (item.default_value) |default| { break :convert Expr.assign(expr, default, wrapper.allocator); } else { break :convert expr; } }; } return Expr.alloc(wrapper.allocator, E.Array{ .items = exprs, .is_single_line = b.is_single_line }, loc); }, .b_object => |b| { var properties = wrapper.allocator.alloc(G.Property, b.properties.len) catch unreachable; var i: usize = 0; while (i < properties.len) : (i += 1) { const item = b.properties[i]; properties[i] = G.Property{ .flags = item.flags, .kind = if (item.flags.is_spread) G.Property.Kind.spread else G.Property.Kind.normal, .value = toExpr(&item.value, wrapper), .initializer = item.default_value, }; } return Expr.alloc(wrapper.allocator, E.Object{ .properties = properties, .is_single_line = b.is_single_line }, loc); }, else => { Global.panic("Interanl error", .{}); }, } } pub const Tag = enum(u5) { b_identifier, b_array, b_property, b_object, b_missing, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub var icount: usize = 0; pub fn init(t: anytype, loc: logger.Loc) Binding { icount += 1; switch (@TypeOf(t)) { *B.Identifier => { return Binding{ .loc = loc, .data = B{ .b_identifier = t } }; }, *B.Array => { return Binding{ .loc = loc, .data = B{ .b_array = t } }; }, *B.Property => { return Binding{ .loc = loc, .data = B{ .b_property = t } }; }, *B.Object => { return Binding{ .loc = loc, .data = B{ .b_object = t } }; }, *B.Missing => { return Binding{ .loc = loc, .data = B{ .b_missing = t } }; }, else => { @compileError("Invalid type passed to Binding.init"); }, } } pub fn alloc(allocator: *std.mem.Allocator, t: anytype, loc: logger.Loc) Binding { icount += 1; switch (@TypeOf(t)) { B.Identifier => { var data = allocator.create(B.Identifier) catch unreachable; data.* = t; return Binding{ .loc = loc, .data = B{ .b_identifier = data } }; }, B.Array => { var data = allocator.create(B.Array) catch unreachable; data.* = t; return Binding{ .loc = loc, .data = B{ .b_array = data } }; }, B.Property => { var data = allocator.create(B.Property) catch unreachable; data.* = t; return Binding{ .loc = loc, .data = B{ .b_property = data } }; }, B.Object => { var data = allocator.create(B.Object) catch unreachable; data.* = t; return Binding{ .loc = loc, .data = B{ .b_object = data } }; }, B.Missing => { return Binding{ .loc = loc, .data = B{ .b_missing = .{} } }; }, else => { @compileError("Invalid type passed to Binding.alloc"); }, } } }; pub const B = union(Binding.Tag) { b_identifier: *B.Identifier, b_array: *B.Array, b_property: *B.Property, b_object: *B.Object, b_missing: B.Missing, pub const Identifier = struct { ref: Ref, }; pub const Property = struct { flags: Flags.Property = Flags.Property.None, key: ExprNodeIndex, value: BindingNodeIndex, default_value: ?ExprNodeIndex = null, }; pub const Object = struct { properties: []Property, is_single_line: bool = false }; pub const Array = struct { items: []ArrayBinding, has_spread: bool = false, is_single_line: bool = false, }; pub const Missing = struct {}; }; pub const ClauseItem = struct { alias: string, alias_loc: logger.Loc, name: LocRef, // This is the original name of the symbol stored in "Name". It's needed for // "SExportClause" statements such as this: // // export {foo as bar} from 'path' // // In this case both "foo" and "bar" are aliases because it's a re-export. // We need to preserve both aliases in case the symbol is renamed. In this // example, "foo" is "OriginalName" and "bar" is "Alias". original_name: string, }; pub const G = struct { pub const Decl = struct { binding: BindingNodeIndex, value: ?ExprNodeIndex = null, }; pub const NamespaceAlias = struct { namespace_ref: Ref, alias: string, }; pub const ExportStarAlias = struct { loc: logger.Loc, // Although this alias name starts off as being the same as the statement's // namespace symbol, it may diverge if the namespace symbol name is minified. // The original alias name is preserved here to avoid this scenario. original_name: string, }; pub const Class = struct { class_keyword: logger.Range = logger.Range.None, ts_decorators: ExprNodeList = &([_]Expr{}), class_name: ?LocRef = null, extends: ?ExprNodeIndex = null, body_loc: logger.Loc = logger.Loc.Empty, properties: []Property = &([_]Property{}), }; // invalid shadowing if left as Comment pub const Comment = struct { loc: logger.Loc, text: string }; pub const Property = struct { ts_decorators: ExprNodeList = &([_]ExprNodeIndex{}), // Key is optional for spread key: ?ExprNodeIndex = null, // This is omitted for class fields value: ?ExprNodeIndex = null, // This is used when parsing a pattern that uses default values: // // [a = 1] = []; // ({a = 1} = {}); // // It's also used for class fields: // // class Foo { a = 1 } // initializer: ?ExprNodeIndex = null, kind: Kind = Kind.normal, flags: Flags.Property = Flags.Property.None, pub const Kind = enum(u2) { normal, get, set, spread, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; }; pub const FnBody = struct { loc: logger.Loc, stmts: StmtNodeList, }; pub const Fn = struct { name: ?LocRef, open_parens_loc: logger.Loc, args: []Arg = &([_]Arg{}), // This was originally nullable, but doing so I believe caused a miscompilation // Specifically, the body was always null. body: FnBody = FnBody{ .loc = logger.Loc.Empty, .stmts = &([_]StmtNodeIndex{}) }, arguments_ref: ?Ref = null, flags: Flags.Function = Flags.Function.None, }; pub const Arg = struct { ts_decorators: ExprNodeList = &([_]Expr{}), binding: BindingNodeIndex, default: ?ExprNodeIndex = null, // "constructor(public x: boolean) {}" is_typescript_ctor_field: bool = false, }; }; pub const Symbol = struct { // This is the name that came from the parser. Printed names may be renamed // during minification or to avoid name collisions. Do not use the original // name during printing. original_name: string, // This is used for symbols that represent items in the import clause of an // ES6 import statement. These should always be referenced by EImportIdentifier // instead of an EIdentifier. When this is present, the expression should // be printed as a property access off the namespace instead of as a bare // identifier. // // For correctness, this must be stored on the symbol instead of indirectly // associated with the Ref for the symbol somehow. In ES6 "flat bundling" // mode, re-exported symbols are collapsed using MergeSymbols() and renamed // symbols from other files that end up at this symbol must be able to tell // if it has a namespace alias. namespace_alias: ?G.NamespaceAlias = null, // Used by the parser for single pass parsing. link: ?Ref = null, // An estimate of the number of uses of this symbol. This is used to detect // whether a symbol is used or not. For example, TypeScript imports that are // unused must be removed because they are probably type-only imports. This // is an estimate and may not be completely accurate due to oversights in the // code. But it should always be non-zero when the symbol is used. use_count_estimate: u32 = 0, // This is for generating cross-chunk imports and exports for code splitting. chunk_index: ?u32 = null, // This is used for minification. Symbols that are declared in sibling scopes // can share a name. A good heuristic (from Google Closure Compiler) is to // assign names to symbols from sibling scopes in declaration order. That way // local variable names are reused in each global function like this, which // improves gzip compression: // // function x(a, b) { ... } // function y(a, b, c) { ... } // // The parser fills this in for symbols inside nested scopes. There are three // slot namespaces: regular symbols, label symbols, and private symbols. nested_scope_slot: ?u32 = null, kind: Kind = Kind.other, // Certain symbols must not be renamed or minified. For example, the // "arguments" variable is declared by the runtime for every function. // Renaming can also break any identifier used inside a "with" statement. must_not_be_renamed: bool = false, // We automatically generate import items for property accesses off of // namespace imports. This lets us remove the expensive namespace imports // while bundling in many cases, replacing them with a cheap import item // instead: // // import * as ns from 'path' // ns.foo() // // That can often be replaced by this, which avoids needing the namespace: // // import {foo} from 'path' // foo() // // However, if the import is actually missing then we don't want to report a // compile-time error like we do for real import items. This status lets us // avoid this. We also need to be able to replace such import items with // undefined, which this status is also used for. import_item_status: ImportItemStatus = ImportItemStatus.none, // Sometimes we lower private symbols even if they are supported. For example, // consider the following TypeScript code: // // class Foo { // #foo = 123 // bar = this.#foo // } // // If "useDefineForClassFields: false" is set in "tsconfig.json", then "bar" // must use assignment semantics instead of define semantics. We can compile // that to this code: // // class Foo { // constructor() { // this.#foo = 123; // this.bar = this.#foo; // } // #foo; // } // // However, we can't do the same for static fields: // // class Foo { // static #foo = 123 // static bar = this.#foo // } // // Compiling these static fields to something like this would be invalid: // // class Foo { // static #foo; // } // Foo.#foo = 123; // Foo.bar = Foo.#foo; // // Thus "#foo" must be lowered even though it's supported. Another case is // when we're converting top-level class declarations to class expressions // to avoid the TDZ and the class shadowing symbol is referenced within the // class body: // // class Foo { // static #foo = Foo // } // // This cannot be converted into something like this: // // var Foo = class { // static #foo; // }; // Foo.#foo = Foo; // private_symbol_must_be_lowered: bool = false, pub const Kind = enum { // An unbound symbol is one that isn't declared in the file it's referenced // in. For example, using "window" without declaring it will be unbound. unbound, // This has special merging behavior. You're allowed to re-declare these // symbols more than once in the same scope. These symbols are also hoisted // out of the scope they are declared in to the closest containing function // or module scope. These are the symbols with this kind: // // - Function arguments // - Function statements // - Variables declared using "var" // hoisted, hoisted_function, // There's a weird special case where catch variables declared using a simple // identifier (i.e. not a binding pattern) block hoisted variables instead of // becoming an error: // // var e = 0; // try { throw 1 } catch (e) { // print(e) // 1 // var e = 2 // print(e) // 2 // } // print(e) // 0 (since the hoisting stops at the catch block boundary) // // However, other forms are still a syntax error: // // try {} catch (e) { let e } // try {} catch ({e}) { var e } // // This symbol is for handling this weird special case. catch_identifier, // Generator and async functions are not hoisted, but still have special // properties such as being able to overwrite previous functions with the // same name generator_or_async_function, // This is the special "arguments" variable inside functions arguments, // Classes can merge with TypeScript namespaces. class, // A class-private identifier (i.e. "#foo"). private_field, private_method, private_get, private_set, private_get_set_pair, private_static_field, private_static_method, private_static_get, private_static_set, private_static_get_set_pair, // Labels are in their own namespace label, // TypeScript enums can merge with TypeScript namespaces and other TypeScript // enums. ts_enum, // TypeScript namespaces can merge with classes, functions, TypeScript enums, // and other TypeScript namespaces. ts_namespace, // In TypeScript, imports are allowed to silently collide with symbols within // the module. Presumably this is because the imports may be type-only. import, // Assigning to a "const" symbol will throw a TypeError at runtime cconst, // This annotates all other symbols that don't have special behavior. other, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub const Use = struct { count_estimate: u32 = 0, }; pub const Map = struct { // This could be represented as a "map[Ref]Symbol" but a two-level array was // more efficient in profiles. This appears to be because it doesn't involve // a hash. This representation also makes it trivial to quickly merge symbol // maps from multiple files together. Each file only generates symbols in a // single inner array, so you can join the maps together by just make a // single outer array containing all of the inner arrays. See the comment on // "Ref" for more detail. symbols_for_source: [][]Symbol, pub fn get(self: *Map, ref: Ref) ?*Symbol { if (Ref.isSourceIndexNull(ref.source_index)) { return null; } return &self.symbols_for_source[ref.source_index][ref.inner_index]; } pub fn init(sourceCount: usize, allocator: *std.mem.Allocator) !Map { var symbols_for_source: [][]Symbol = try allocator.alloc([]Symbol, sourceCount); return Map{ .symbols_for_source = symbols_for_source }; } pub fn initList(list: [][]Symbol) Map { return Map{ .symbols_for_source = list }; } pub fn follow(symbols: *Map, ref: Ref) Ref { if (symbols.get(ref)) |symbol| { const link = symbol.link orelse return ref; if (!link.eql(ref)) { symbol.link = ref; } return symbol.link orelse unreachable; } else { return ref; } } }; pub inline fn isKindPrivate(kind: Symbol.Kind) bool { return @enumToInt(kind) >= @enumToInt(Symbol.Kind.private_field) and @enumToInt(kind) <= @enumToInt(Symbol.Kind.private_static_get_set_pair); } pub inline fn isKindHoisted(kind: Symbol.Kind) bool { return @enumToInt(kind) == @enumToInt(Symbol.Kind.hoisted) or @enumToInt(kind) == @enumToInt(Symbol.Kind.hoisted_function); } pub inline fn isHoisted(self: *const Symbol) bool { return Symbol.isKindHoisted(self.kind); } pub inline fn isKindHoistedOrFunction(kind: Symbol.Kind) bool { return isKindHoisted(kind) or kind == Symbol.Kind.generator_or_async_function; } pub inline fn isKindFunction(kind: Symbol.Kind) bool { return kind == Symbol.Kind.hoisted_function or kind == Symbol.Kind.generator_or_async_function; } pub fn isReactComponentishName(symbol: *const Symbol) bool { switch (symbol.kind) { .hoisted, .hoisted_function, .cconst, .class, .other => { return switch (symbol.original_name[0]) { 'A'...'Z' => true, else => false, }; }, else => { return false; }, } } }; pub const OptionalChain = enum(u2) { // "a?.b" start, // "a?.b.c" => ".c" is OptionalChainContinue // "(a?.b).c" => ".c" is OptionalChain null ccontinue, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub const E = struct { pub const Array = struct { items: ExprNodeList, comma_after_spread: ?logger.Loc = null, is_single_line: bool = false, is_parenthesized: bool = false, }; pub const Unary = struct { op: Op.Code, value: ExprNodeIndex, }; pub const Binary = struct { left: ExprNodeIndex, right: ExprNodeIndex, op: Op.Code, }; pub const Boolean = packed struct { value: bool }; pub const Super = struct {}; pub const Null = struct {}; pub const This = struct {}; pub const Undefined = struct {}; pub const New = struct { target: ExprNodeIndex, args: ExprNodeList, // True if there is a comment containing "@__PURE__" or "#__PURE__" preceding // this call expression. See the comment inside ECall for more details. can_be_unwrapped_if_unused: bool = false, }; pub const NewTarget = struct {}; pub const ImportMeta = struct {}; pub const Call = struct { // Node: target: ExprNodeIndex, args: ExprNodeList = &([_]ExprNodeIndex{}), optional_chain: ?OptionalChain = null, is_direct_eval: bool = false, // True if there is a comment containing "@__PURE__" or "#__PURE__" preceding // this call expression. This is an annotation used for tree shaking, and // means that the call can be removed if it's unused. It does not mean the // call is pure (e.g. it may still return something different if called twice). // // Note that the arguments are not considered to be part of the call. If the // call itself is removed due to this annotation, the arguments must remain // if they have side effects. can_be_unwrapped_if_unused: bool = false, // Used when printing to generate the source prop on the fly was_jsx_element: bool = false, pub fn hasSameFlagsAs(a: *Call, b: *Call) bool { return (a.optional_chain == b.optional_chain and a.is_direct_eval == b.is_direct_eval and a.can_be_unwrapped_if_unused == b.can_be_unwrapped_if_unused); } }; pub const Dot = struct { // target is Node target: ExprNodeIndex, name: string, name_loc: logger.Loc, optional_chain: ?OptionalChain = null, // If true, this property access is known to be free of side-effects. That // means it can be removed if the resulting value isn't used. can_be_removed_if_unused: bool = false, // If true, this property access is a function that, when called, can be // unwrapped if the resulting value is unused. Unwrapping means discarding // the call target but keeping any arguments with side effects. call_can_be_unwrapped_if_unused: bool = false, pub fn hasSameFlagsAs(a: *Dot, b: *Dot) bool { return (a.optional_chain == b.optional_chain and a.is_direct_eval == b.is_direct_eval and a.can_be_unwrapped_if_unused == b.can_be_unwrapped_if_unused and a.call_can_be_unwrapped_if_unused == b.call_can_be_unwrapped_if_unused); } }; pub const Index = struct { index: ExprNodeIndex, target: ExprNodeIndex, optional_chain: ?OptionalChain = null, pub fn hasSameFlagsAs(a: *Index, b: *Index) bool { return (a.optional_chain == b.optional_chain); } }; pub const Arrow = struct { args: []G.Arg, body: G.FnBody, is_async: bool = false, has_rest_arg: bool = false, prefer_expr: bool = false, // Use shorthand if true and "Body" is a single return statement }; pub const Function = struct { func: G.Fn }; pub const Identifier = packed struct { ref: Ref = Ref.None, // If we're inside a "with" statement, this identifier may be a property // access. In that case it would be incorrect to remove this identifier since // the property access may be a getter or setter with side effects. must_keep_due_to_with_stmt: bool = false, // If true, this identifier is known to not have a side effect (i.e. to not // throw an exception) when referenced. If false, this identifier may or may // not have side effects when referenced. This is used to allow the removal // of known globals such as "Object" if they aren't used. can_be_removed_if_unused: bool = false, // If true, this identifier represents a function that, when called, can be // unwrapped if the resulting value is unused. Unwrapping means discarding // the call target but keeping any arguments with side effects. call_can_be_unwrapped_if_unused: bool = false, }; // This is similar to an EIdentifier but it represents a reference to an ES6 // import item. // // Depending on how the code is linked, the file containing this EImportIdentifier // may or may not be in the same module group as the file it was imported from. // // If it's the same module group than we can just merge the import item symbol // with the corresponding symbol that was imported, effectively renaming them // to be the same thing and statically binding them together. // // But if it's a different module group, then the import must be dynamically // evaluated using a property access off the corresponding namespace symbol, // which represents the result of a require() call. // // It's stored as a separate type so it's not easy to confuse with a plain // identifier. For example, it'd be bad if code trying to convert "{x: x}" into // "{x}" shorthand syntax wasn't aware that the "x" in this case is actually // "{x: importedNamespace.x}". This separate type forces code to opt-in to // doing this instead of opt-out. pub const ImportIdentifier = packed struct { ref: Ref, // If true, this was originally an identifier expression such as "foo". If // false, this could potentially have been a member access expression such // as "ns.foo" off of an imported namespace object. was_originally_identifier: bool = false, }; // This is similar to EIdentifier but it represents class-private fields and // methods. It can be used where computed properties can be used, such as // EIndex and Property. pub const PrivateIdentifier = struct { ref: Ref, }; /// In development mode, the new JSX transform has a few special props /// - `React.jsxDEV(type, arguments, key, isStaticChildren, source, self)` /// - `arguments`: /// ```{ ...props, children: children, }``` /// - `source`: https://github.com/babel/babel/blob/ef87648f3f05ccc393f89dea7d4c7c57abf398ce/packages/babel-plugin-transform-react-jsx-source/src/index.js#L24-L48 /// ```{ /// fileName: string | null, /// columnNumber: number | null, /// lineNumber: number | null, /// }``` /// - `children`: /// - multiple children? the function is React.jsxsDEV, "jsxs" instead of "jsx" /// - one child? the function is React.jsxDEV, /// - no children? the function is React.jsxDEV and children is an empty array. /// `isStaticChildren`: https://github.com/facebook/react/blob/4ca62cac45c288878d2532e5056981d177f9fdac/packages/react/src/jsx/ReactJSXElementValidator.js#L369-L384 /// This flag means children is an array of JSX Elements literals. /// The documentation on this is sparse, but it appears that /// React just calls Object.freeze on the children array. /// Object.freeze, historically, is quite a bit slower[0] than just not doing that. /// Given that...I am choosing to always pass "false" to this. /// This also skips extra state that we'd need to track. /// If React Fast Refresh ends up using this later, then we can revisit this decision. /// [0]: https://github.com/automerge/automerge/issues/177 pub const JSXElement = struct { /// null represents a fragment tag: ?ExprNodeIndex = null, /// props properties: []G.Property = &([_]G.Property{}), /// element children children: ExprNodeList = &([_]ExprNodeIndex{}), /// key is the key prop like key: ?ExprNodeIndex = null, flags: Flags.JSXElement = Flags.JSXElement{}, pub const SpecialProp = enum { __self, // old react transform used this as a prop __source, key, any, pub const Map = std.ComptimeStringMap(SpecialProp, .{ .{ "__self", .__self }, .{ "__source", .__source }, .{ "key", .key }, }); }; }; pub const Missing = struct { pub fn jsonStringify(self: *const @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(null, opts, o); } }; pub const Number = struct { value: f64, pub fn jsonStringify(self: *const Number, opts: anytype, o: anytype) !void { return try std.json.stringify(self.value, opts, o); } }; pub const BigInt = struct { value: string, pub fn jsonStringify(self: *const @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(self.value, opts, o); } }; pub const Object = struct { properties: []G.Property = &[_]G.Property{}, comma_after_spread: ?logger.Loc = null, is_single_line: bool = false, is_parenthesized: bool = false, }; pub const Spread = struct { value: ExprNodeIndex }; pub const String = struct { value: JavascriptString = &([_]u16{}), utf8: string = &([_]u8{}), prefer_template: bool = false, pub fn clone(str: *const String, allocator: *std.mem.Allocator) !String { if (str.isUTF8()) { return String{ .utf8 = try allocator.dupe(u8, str.utf8), .prefer_template = str.prefer_template, }; } else { return String{ .value = try allocator.dupe(u16, str.value), .prefer_template = str.prefer_template, }; } } pub inline fn isUTF8(s: *const String) bool { return s.utf8.len > 0; } pub inline fn isBlank(s: *const String) bool { return std.math.max(s.utf8.len, s.value.len) == 0; } pub inline fn isPresent(s: *const String) bool { return std.math.max(s.utf8.len, s.value.len) > 0; } pub fn eql(s: *const String, comptime _t: type, other: anytype) bool { if (s.isUTF8()) { switch (_t) { @This() => { if (other.isUTF8()) { return strings.eql(s.utf8, other.utf8); } else { return strings.utf16EqlString(other.value, s.utf8); } }, string => { return strings.eql(s.utf8, other); }, JavascriptString => { return strings.utf16EqlString(other, s.utf8); }, else => { @compileError("Invalid type"); }, } } else { switch (_t) { @This() => { if (other.isUTF8()) { return strings.utf16EqlString(s.value, other.utf8); } else { return std.mem.eql(u16, other.value, s.value); } }, string => { return strings.utf16EqlString(s.value, other); }, JavascriptString => { return std.mem.eql(u16, other.value, s.value); }, else => { @compileError("Invalid type"); }, } } } pub fn string(s: *const String, allocator: *std.mem.Allocator) !string { if (s.isUTF8()) { return s.utf8; } else { return strings.toUTF8Alloc(allocator, s.value); } } pub fn jsonStringify(s: *const String, options: anytype, writer: anytype) !void { var buf = [_]u8{0} ** 4096; var i: usize = 0; for (s.value) |char| { buf[i] = @intCast(u8, char); i += 1; if (i >= 4096) { break; } } return try std.json.stringify(buf[0..i], options, writer); } }; // value is in the Node pub const TemplatePart = struct { value: ExprNodeIndex, tail_loc: logger.Loc, tail: E.String, }; pub const Template = struct { tag: ?ExprNodeIndex = null, head: E.String, parts: []TemplatePart = &([_]TemplatePart{}), }; pub const RegExp = struct { value: string, pub fn jsonStringify(self: *const RegExp, opts: anytype, o: anytype) !void { return try std.json.stringify(self.value, opts, o); } }; pub const Class = G.Class; pub const Await = struct { value: ExprNodeIndex, }; pub const Yield = struct { value: ?ExprNodeIndex = null, is_star: bool = false, }; pub const If = struct { test_: ExprNodeIndex, yes: ExprNodeIndex, no: ExprNodeIndex, }; pub const Require = packed struct { import_record_index: u32 = 0, }; pub const RequireOrRequireResolve = struct { import_record_index: u32 = 0, }; pub const Import = struct { expr: ExprNodeIndex, import_record_index: u32, // Comments inside "import()" expressions have special meaning for Webpack. // Preserving comments inside these expressions makes it possible to use // esbuild as a TypeScript-to-JavaScript frontend for Webpack to improve // performance. We intentionally do not interpret these comments in esbuild // because esbuild is not Webpack. But we do preserve them since doing so is // harmless, easy to maintain, and useful to people. See the Webpack docs for // more info: https://webpack.js.org/api/module-methods/#magic-comments. // TODO: leading_interior_comments: []G.Comment = &([_]G.Comment{}), }; }; pub const Stmt = struct { loc: logger.Loc, data: Data, const Serializable = struct { @"type": Tag, object: string, value: Data, loc: logger.Loc, }; pub fn jsonStringify(self: *const Stmt, options: anytype, writer: anytype) !void { return try std.json.stringify(Serializable{ .@"type" = std.meta.activeTag(self.data), .object = "stmt", .value = self.data, .loc = self.loc }, options, writer); } pub fn isTypeScript(self: *Stmt) bool { return @as(Stmt.Tag, self.data) == .s_type_script; } pub fn empty() Stmt { return Stmt.init(Stmt.None, logger.Loc.Empty); } var None = S.Empty{}; pub inline fn getBlock(self: *const @This()) *S.Block { return self.data.s_block; } pub inline fn getBreak(self: *const @This()) *S.Break { return self.data.s_break; } pub inline fn getClass(self: *const @This()) *S.Class { return self.data.s_class; } pub inline fn getComment(self: *const @This()) *S.Comment { return self.data.s_comment; } pub inline fn getContinue(self: *const @This()) *S.Continue { return self.data.s_continue; } pub inline fn getDebugger(self: *const @This()) S.Debugger { return S.Debugger{}; } pub inline fn getDirective(self: *const @This()) *S.Directive { return self.data.s_directive; } pub inline fn getDoWhile(self: *const @This()) *S.DoWhile { return self.data.s_do_while; } pub inline fn getEmpty(self: *const @This()) S.Empty { return S.Empty{}; } pub inline fn getEnum(self: *const @This()) *S.Enum { return self.data.s_enum; } pub inline fn getExportClause(self: *const @This()) *S.ExportClause { return self.data.s_export_clause; } pub inline fn getExportDefault(self: *const @This()) *S.ExportDefault { return self.data.s_export_default; } pub inline fn getExportEquals(self: *const @This()) *S.ExportEquals { return self.data.s_export_equals; } pub inline fn getExportFrom(self: *const @This()) *S.ExportFrom { return self.data.s_export_from; } pub inline fn getExportStar(self: *const @This()) *S.ExportStar { return self.data.s_export_star; } pub inline fn getExpr(self: *const @This()) *S.SExpr { return self.data.s_expr; } pub inline fn getForIn(self: *const @This()) *S.ForIn { return self.data.s_for_in; } pub inline fn getForOf(self: *const @This()) *S.ForOf { return self.data.s_for_of; } pub inline fn getFor(self: *const @This()) *S.For { return self.data.s_for; } pub inline fn getFunction(self: *const @This()) *S.Function { return self.data.s_function; } pub inline fn getIf(self: *const @This()) *S.If { return self.data.s_if; } pub inline fn getImport(self: *const @This()) *S.Import { return self.data.s_import; } pub inline fn getLabel(self: *const @This()) *S.Label { return self.data.s_label; } pub inline fn getLazyExport(self: *const @This()) *S.LazyExport { return self.data.s_lazy_export; } pub inline fn getLocal(self: *const @This()) *S.Local { return self.data.s_local; } pub inline fn getNamespace(self: *const @This()) *S.Namespace { return self.data.s_namespace; } pub inline fn getReturn(self: *const @This()) *S.Return { return self.data.s_return; } pub inline fn getSwitch(self: *const @This()) *S.Switch { return self.data.s_switch; } pub inline fn getThrow(self: *const @This()) *S.Throw { return self.data.s_throw; } pub inline fn getTry(self: *const @This()) *S.Try { return self.data.s_try; } pub inline fn getTypeScript(self: *const @This()) S.TypeScript { return S.TypeScript{}; } pub inline fn getWhile(self: *const @This()) *S.While { return self.data.s_while; } pub inline fn getWith(self: *const @This()) *S.With { return self.data.s_with; } pub var icount: usize = 0; pub fn init(origData: anytype, loc: logger.Loc) Stmt { icount += 1; if (@typeInfo(@TypeOf(origData)) != .Pointer and @TypeOf(origData) != S.Empty) { @compileError("Stmt.init needs a pointer."); } if (@TypeOf(origData) == S.Empty) { return Stmt{ .loc = loc, .data = Data{ .s_empty = S.Empty{} } }; } switch (@TypeOf(origData.*)) { S.Block => { return Stmt.comptime_init("s_block", S.Block, origData, loc); }, S.Break => { return Stmt.comptime_init("s_break", S.Break, origData, loc); }, S.Class => { return Stmt.comptime_init("s_class", S.Class, origData, loc); }, S.Comment => { return Stmt.comptime_init("s_comment", S.Comment, origData, loc); }, S.Continue => { return Stmt.comptime_init("s_continue", S.Continue, origData, loc); }, S.Debugger => { return Stmt.comptime_init("s_debugger", S.Debugger, origData, loc); }, S.Directive => { return Stmt.comptime_init("s_directive", S.Directive, origData, loc); }, S.DoWhile => { return Stmt.comptime_init("s_do_while", S.DoWhile, origData, loc); }, S.Empty => { return Stmt.comptime_init("s_empty", S.Empty, origData, loc); }, S.Enum => { return Stmt.comptime_init("s_enum", S.Enum, origData, loc); }, S.ExportClause => { return Stmt.comptime_init("s_export_clause", S.ExportClause, origData, loc); }, S.ExportDefault => { return Stmt.comptime_init("s_export_default", S.ExportDefault, origData, loc); }, S.ExportEquals => { return Stmt.comptime_init("s_export_equals", S.ExportEquals, origData, loc); }, S.ExportFrom => { return Stmt.comptime_init("s_export_from", S.ExportFrom, origData, loc); }, S.ExportStar => { return Stmt.comptime_init("s_export_star", S.ExportStar, origData, loc); }, S.SExpr => { return Stmt.comptime_init("s_expr", S.SExpr, origData, loc); }, S.ForIn => { return Stmt.comptime_init("s_for_in", S.ForIn, origData, loc); }, S.ForOf => { return Stmt.comptime_init("s_for_of", S.ForOf, origData, loc); }, S.For => { return Stmt.comptime_init("s_for", S.For, origData, loc); }, S.Function => { return Stmt.comptime_init("s_function", S.Function, origData, loc); }, S.If => { return Stmt.comptime_init("s_if", S.If, origData, loc); }, S.Import => { return Stmt.comptime_init("s_import", S.Import, origData, loc); }, S.Label => { return Stmt.comptime_init("s_label", S.Label, origData, loc); }, S.LazyExport => { return Stmt.comptime_init("s_lazy_export", S.LazyExport, origData, loc); }, S.Local => { return Stmt.comptime_init("s_local", S.Local, origData, loc); }, S.Namespace => { return Stmt.comptime_init("s_namespace", S.Namespace, origData, loc); }, S.Return => { return Stmt.comptime_init("s_return", S.Return, origData, loc); }, S.Switch => { return Stmt.comptime_init("s_switch", S.Switch, origData, loc); }, S.Throw => { return Stmt.comptime_init("s_throw", S.Throw, origData, loc); }, S.Try => { return Stmt.comptime_init("s_try", S.Try, origData, loc); }, S.TypeScript => { return Stmt.comptime_init("s_type_script", S.TypeScript, origData, loc); }, S.While => { return Stmt.comptime_init("s_while", S.While, origData, loc); }, S.With => { return Stmt.comptime_init("s_with", S.With, origData, loc); }, else => { @compileError("Invalid type in Stmt.init"); }, } } inline fn comptime_alloc(allocator: *std.mem.Allocator, comptime tag_name: string, comptime typename: type, origData: anytype, loc: logger.Loc) Stmt { return Stmt{ .loc = loc, .data = @unionInit(Data, tag_name, Data.Store.append(typename, origData)) }; } inline fn comptime_init(comptime tag_name: string, comptime typename: type, origData: anytype, loc: logger.Loc) Stmt { return Stmt{ .loc = loc, .data = @unionInit(Data, tag_name, origData) }; } pub fn alloc(allocator: *std.mem.Allocator, origData: anytype, loc: logger.Loc) Stmt { icount += 1; switch (@TypeOf(origData)) { S.Block => { return Stmt.comptime_alloc(allocator, "s_block", S.Block, origData, loc); }, S.Break => { return Stmt.comptime_alloc(allocator, "s_break", S.Break, origData, loc); }, S.Class => { return Stmt.comptime_alloc(allocator, "s_class", S.Class, origData, loc); }, S.Comment => { return Stmt.comptime_alloc(allocator, "s_comment", S.Comment, origData, loc); }, S.Continue => { return Stmt.comptime_alloc(allocator, "s_continue", S.Continue, origData, loc); }, S.Debugger => { return Stmt{ .loc = loc, .data = .{ .s_debugger = origData } }; }, S.Directive => { return Stmt.comptime_alloc(allocator, "s_directive", S.Directive, origData, loc); }, S.DoWhile => { return Stmt.comptime_alloc(allocator, "s_do_while", S.DoWhile, origData, loc); }, S.Empty => { return Stmt{ .loc = loc, .data = Data{ .s_empty = S.Empty{} } }; }, S.Enum => { return Stmt.comptime_alloc(allocator, "s_enum", S.Enum, origData, loc); }, S.ExportClause => { return Stmt.comptime_alloc(allocator, "s_export_clause", S.ExportClause, origData, loc); }, S.ExportDefault => { return Stmt.comptime_alloc(allocator, "s_export_default", S.ExportDefault, origData, loc); }, S.ExportEquals => { return Stmt.comptime_alloc(allocator, "s_export_equals", S.ExportEquals, origData, loc); }, S.ExportFrom => { return Stmt.comptime_alloc(allocator, "s_export_from", S.ExportFrom, origData, loc); }, S.ExportStar => { return Stmt.comptime_alloc(allocator, "s_export_star", S.ExportStar, origData, loc); }, S.SExpr => { return Stmt.comptime_alloc(allocator, "s_expr", S.SExpr, origData, loc); }, S.ForIn => { return Stmt.comptime_alloc(allocator, "s_for_in", S.ForIn, origData, loc); }, S.ForOf => { return Stmt.comptime_alloc(allocator, "s_for_of", S.ForOf, origData, loc); }, S.For => { return Stmt.comptime_alloc(allocator, "s_for", S.For, origData, loc); }, S.Function => { return Stmt.comptime_alloc(allocator, "s_function", S.Function, origData, loc); }, S.If => { return Stmt.comptime_alloc(allocator, "s_if", S.If, origData, loc); }, S.Import => { return Stmt.comptime_alloc(allocator, "s_import", S.Import, origData, loc); }, S.Label => { return Stmt.comptime_alloc(allocator, "s_label", S.Label, origData, loc); }, S.LazyExport => { return Stmt.comptime_alloc(allocator, "s_lazy_export", S.LazyExport, origData, loc); }, S.Local => { return Stmt.comptime_alloc(allocator, "s_local", S.Local, origData, loc); }, S.Namespace => { return Stmt.comptime_alloc(allocator, "s_namespace", S.Namespace, origData, loc); }, S.Return => { return Stmt.comptime_alloc(allocator, "s_return", S.Return, origData, loc); }, S.Switch => { return Stmt.comptime_alloc(allocator, "s_switch", S.Switch, origData, loc); }, S.Throw => { return Stmt.comptime_alloc(allocator, "s_throw", S.Throw, origData, loc); }, S.Try => { return Stmt.comptime_alloc(allocator, "s_try", S.Try, origData, loc); }, S.TypeScript => { return Stmt{ .loc = loc, .data = Data{ .s_type_script = S.TypeScript{} } }; }, S.While => { return Stmt.comptime_alloc(allocator, "s_while", S.While, origData, loc); }, S.With => { return Stmt.comptime_alloc(allocator, "s_with", S.With, origData, loc); }, else => { @compileError("Invalid type in Stmt.init"); }, } } pub const Tag = enum(u6) { s_block, s_break, s_class, s_comment, s_continue, s_debugger, s_directive, s_do_while, s_empty, s_enum, s_export_clause, s_export_default, s_export_equals, s_export_from, s_export_star, s_expr, s_for_in, s_for_of, s_for, s_function, s_if, s_import, s_label, s_lazy_export, s_local, s_namespace, s_return, s_switch, s_throw, s_try, s_type_script, s_while, s_with, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } pub fn isExportLike(tag: Tag) bool { return switch (tag) { .s_export_clause, .s_export_default, .s_export_equals, .s_export_from, .s_export_star, .s_empty => true, else => false, }; } }; pub const Data = union(Tag) { s_block: *S.Block, s_break: *S.Break, s_class: *S.Class, s_comment: *S.Comment, s_continue: *S.Continue, s_directive: *S.Directive, s_do_while: *S.DoWhile, s_enum: *S.Enum, s_export_clause: *S.ExportClause, s_export_default: *S.ExportDefault, s_export_equals: *S.ExportEquals, s_export_from: *S.ExportFrom, s_export_star: *S.ExportStar, s_expr: *S.SExpr, s_for_in: *S.ForIn, s_for_of: *S.ForOf, s_for: *S.For, s_function: *S.Function, s_if: *S.If, s_import: *S.Import, s_label: *S.Label, s_lazy_export: *S.LazyExport, s_local: *S.Local, s_namespace: *S.Namespace, s_return: *S.Return, s_switch: *S.Switch, s_throw: *S.Throw, s_try: *S.Try, s_while: *S.While, s_with: *S.With, s_type_script: S.TypeScript, s_empty: S.Empty, // special case, its a zero value type s_debugger: S.Debugger, pub const Store = struct { const Union = [_]type{ S.Block, S.Break, S.Class, S.Comment, S.Continue, S.Directive, S.DoWhile, S.Enum, S.ExportClause, S.ExportDefault, S.ExportEquals, S.ExportFrom, S.ExportStar, S.SExpr, S.ForIn, S.ForOf, S.For, S.Function, S.If, S.Import, S.Label, S.LazyExport, S.Local, S.Namespace, S.Return, S.Switch, S.Throw, S.Try, S.TypeScript, S.While, S.With, }; pub const All = NewBaseStore(Union, 128); threadlocal var has_inited = false; pub fn create(allocator: *std.mem.Allocator) void { if (has_inited) { return; } has_inited = true; _ = All.init(allocator); } pub fn reset() void { All.reset(); } pub fn append(comptime ValueType: type, value: anytype) *ValueType { return All.append(ValueType, value); } }; pub inline fn set(data: *Data, value: anytype) void { const ValueType = @TypeOf(value); if (@typeInfo(ValueType) == .Pointer) { data.setValue(@TypeOf(value.*), value.*); } else { data.setValue(@TypeOf(value), value); } } pub inline fn setValue(data: *Data, comptime ValueType: type, value: ValueType) void { switch (comptime ValueType) { S.Block => { data.s_block = Block.append(value); }, S.Break => { data.s_break = Break.append(value); }, S.Class => { data.s_class = Class.append(value); }, S.Comment => { data.s_comment = Comment.append(value); }, S.Continue => { data.s_continue = Continue.append(value); }, S.Debugger => { data.s_debugger = Debugger.append(value); }, S.Directive => { data.s_directive = Directive.append(value); }, S.DoWhile => { data.s_do_while = DoWhile.append(value); }, S.Empty => { data.s_empty = Empty.append(value); }, S.Enum => { data.s_enum = Enum.append(value); }, S.ExportClause => { data.s_export_clause = ExportClause.append(value); }, S.ExportDefault => { data.s_export_default = ExportDefault.append(value); }, S.ExportEquals => { data.s_export_equals = ExportEquals.append(value); }, S.ExportFrom => { data.s_export_from = ExportFrom.append(value); }, S.ExportStar => { data.s_export_star = ExportStar.append(value); }, S.SExpr => { data.s_s_expr = SExpr.append(value); }, S.ForIn => { data.s_for_in = ForIn.append(value); }, S.ForOf => { data.s_for_of = ForOf.append(value); }, S.For => { data.s_for = For.append(value); }, S.Function => { data.s_function = Function.append(value); }, S.If => { data.s_if = If.append(value); }, S.Import => { data.s_import = Import.append(value); }, S.Label => { data.s_label = Label.append(value); }, S.LazyExport => { data.s_lazy_export = LazyExport.append(value); }, S.Local => { data.s_local = Local.append(value); }, S.Namespace => { data.s_namespace = Namespace.append(value); }, S.Return => { data.s_return = Return.append(value); }, S.Switch => { data.s_switch = Switch.append(value); }, S.Throw => { data.s_throw = Throw.append(value); }, S.Try => { data.s_try = Try.append(value); }, S.TypeScript => { data.s_type_script = value; }, S.While => { data.s_while = While.append(value); }, S.With => { data.s_with = With.append(value); }, else => { @compileError("Invalid type passed to Stmt.Data.set " ++ @typeName(ValueType)); }, } } }; pub fn caresAboutScope(self: *Stmt) bool { return switch (self.data) { .s_block, .s_empty, .s_debugger, .s_expr, .s_if, .s_for, .s_for_in, .s_for_of, .s_do_while, .s_while, .s_with, .s_try, .s_switch, .s_return, .s_throw, .s_break, .s_continue, .s_directive => { return false; }, .s_local => |local| { return local.kind != Kind.k_var; }, else => { return true; }, }; } }; pub const Expr = struct { loc: logger.Loc, data: Data, pub fn toEmpty(expr: *Expr) Expr { return Expr{ .data = .{ .e_missing = E.Missing{} }, .loc = expr.loc }; } pub fn isEmpty(expr: *Expr) bool { return std.meta.activeTag(expr.data) == .e_missing; } pub const Query = struct { expr: Expr, loc: logger.Loc }; pub fn getArray(exp: *const Expr) *E.Array { return exp.data.e_array; } pub fn getUnary(exp: *const Expr) *E.Unary { return exp.data.e_unary; } pub fn getBinary(exp: *const Expr) *E.Binary { return exp.data.e_binary; } pub fn getThis(exp: *const Expr) *E.This { return E.This{}; } pub fn getClass(exp: *const Expr) *E.Class { return exp.data.e_class; } pub fn getBoolean(exp: *const Expr) *E.Boolean { return exp.data.e_boolean; } pub fn getSuper(exp: *const Expr) *E.Super { return exp.data.e_super; } pub fn getNull(exp: *const Expr) *E.Null { return exp.data.e_null; } pub fn getUndefined(exp: *const Expr) *E.Undefined { return exp.data.e_undefined; } pub fn getNew(exp: *const Expr) *E.New { return exp.data.e_new; } pub fn getNewTarget(exp: *const Expr) *E.NewTarget { return &E.NewTarget{}; } pub fn getFunction(exp: *const Expr) *E.Function { return exp.data.e_function; } pub fn getCall(exp: *const Expr) *E.Call { return exp.data.e_call; } pub fn getDot(exp: *const Expr) *E.Dot { return exp.data.e_dot; } pub fn getIndex(exp: *const Expr) *E.Index { return exp.data.e_index; } pub fn getArrow(exp: *const Expr) *E.Arrow { return exp.data.e_arrow; } pub fn getIdentifier(exp: *const Expr) *E.Identifier { return exp.data.e_identifier; } pub fn getImportIdentifier(exp: *const Expr) *E.ImportIdentifier { return exp.data.e_import_identifier; } pub fn getPrivateIdentifier(exp: *const Expr) *E.PrivateIdentifier { return exp.data.e_private_identifier; } pub fn getJsxElement(exp: *const Expr) *E.JSXElement { return exp.data.e_jsx_element; } pub fn getMissing(exp: *const Expr) *E.Missing { return exp.data.e_missing; } pub fn getNumber(exp: *const Expr) E.Number { return exp.data.e_number; } pub fn getBigInt(exp: *const Expr) E.BigInt { return exp.data.e_big_int; } pub fn getObject(exp: *const Expr) *E.Object { return exp.data.e_object; } pub fn getSpread(exp: *const Expr) *E.Spread { return exp.data.e_spread; } pub fn getString(exp: *const Expr) E.String { return exp.data.e_string; } pub fn getTemplatePart(exp: *const Expr) *E.TemplatePart { return exp.data.e_template_part; } pub fn getTemplate(exp: *const Expr) *E.Template { return exp.data.e_template; } pub fn getRegExp(exp: *const Expr) *E.RegExp { return exp.data.e_reg_exp; } pub fn getAwait(exp: *const Expr) *E.Await { return exp.data.e_await; } pub fn getYield(exp: *const Expr) *E.Yield { return exp.data.e_yield; } pub fn getIf(exp: *const Expr) *E.If { return exp.data.e_if; } pub fn getRequire(exp: *const Expr) *E.Require { return exp.data.e_require; } pub fn getRequireOrRequireResolve(exp: *const Expr) *E.RequireOrRequireResolve { return exp.data.e_require_or_require_resolve; } pub fn getImport(exp: *const Expr) *E.Import { return exp.data.e_import; } pub fn asProperty(expr: *const Expr, name: string) ?Query { if (std.meta.activeTag(expr.data) != .e_object) return null; const obj = expr.data.e_object; if (@ptrToInt(obj.properties.ptr) == 0) return null; for (obj.properties) |prop| { const value = prop.value orelse continue; const key = prop.key orelse continue; if (std.meta.activeTag(key.data) != .e_string) continue; const key_str = key.data.e_string; if (key_str.eql(string, name)) { return Query{ .expr = value, .loc = key.loc }; } } return null; } pub const ArrayIterator = struct { array: *const E.Array, index: u32, pub fn next(this: *ArrayIterator) ?Expr { if (this.index >= this.array.items.len) { return null; } defer this.index += 1; return this.array.items[this.index]; } }; pub fn asArray(expr: *const Expr) ?ArrayIterator { if (std.meta.activeTag(expr.data) != .e_array) return null; const array = expr.data.e_array; if (array.items.len == 0 or @ptrToInt(array.items.ptr) == 0) return null; return ArrayIterator{ .array = array, .index = 0 }; } pub fn asString(expr: *const Expr, allocator: *std.mem.Allocator) ?string { if (std.meta.activeTag(expr.data) != .e_string) return null; const key_str = expr.data.e_string; return if (key_str.isUTF8()) key_str.utf8 else key_str.string(allocator) catch null; } pub fn asBool( expr: *const Expr, ) ?bool { if (std.meta.activeTag(expr.data) != .e_boolean) return null; return expr.data.e_boolean.value; } pub const EFlags = enum { none, ts_decorator }; const Serializable = struct { @"type": Tag, object: string, value: Data, loc: logger.Loc, }; pub fn isMissing(a: *const Expr) bool { return std.meta.activeTag(a.data) == Expr.Tag.e_missing; } // The goal of this function is to "rotate" the AST if it's possible to use the // left-associative property of the operator to avoid unnecessary parentheses. // // When using this, make absolutely sure that the operator is actually // associative. For example, the "-" operator is not associative for // floating-point numbers. pub fn joinWithLeftAssociativeOp( op: Op.Code, a: Expr, b: Expr, allocator: *std.mem.Allocator, ) Expr { // "(a, b) op c" => "a, b op c" switch (a.data) { .e_binary => |comma| { if (comma.op == .bin_comma) { comma.right = joinWithLeftAssociativeOp(op, comma.right, b, allocator); } }, else => {}, } // "a op (b op c)" => "(a op b) op c" // "a op (b op (c op d))" => "((a op b) op c) op d" switch (b.data) { .e_binary => |binary| { if (binary.op == op) { return joinWithLeftAssociativeOp( op, joinWithLeftAssociativeOp(op, a, binary.left, allocator), binary.right, allocator, ); } }, else => {}, } // "a op b" => "a op b" // "(a op b) op c" => "(a op b) op c" return Expr.alloc(allocator, E.Binary{ .op = op, .left = a, .right = b }, a.loc); } pub fn joinWithComma(a: Expr, b: Expr, allocator: *std.mem.Allocator) Expr { if (a.isMissing()) { return b; } if (b.isMissing()) { return a; } return Expr.alloc(allocator, E.Binary{ .op = .bin_comma, .left = a, .right = b }, a.loc); } pub fn joinAllWithComma(all: []Expr, allocator: *std.mem.Allocator) Expr { std.debug.assert(all.len > 0); switch (all.len) { 1 => { return all[0]; }, 2 => { return Expr.joinWithComma(all[0], all[1], allocator); }, else => { var i: usize = 1; var expr = all[0]; while (i < all.len) : (i += 1) { expr = Expr.joinWithComma(expr, all[i], allocator); } return expr; }, } } pub fn joinAllWithCommaCallback(all: []Expr, comptime Context: type, ctx: Context, callback: (fn (ctx: anytype, expr: anytype) ?Expr), allocator: *std.mem.Allocator) ?Expr { std.debug.assert(all.len > 0); switch (all.len) { 1 => { return callback(ctx, all[0]); }, 2 => { return Expr.joinWithComma( callback(ctx, all[0]) orelse Expr{ .data = .{ .e_missing = .{} }, .loc = all[0].loc, }, callback(ctx, all[1]) orelse Expr{ .data = .{ .e_missing = .{} }, .loc = all[1].loc, }, allocator, ); }, else => { var i: usize = 1; var expr = callback(ctx, all[0]) orelse Expr{ .data = .{ .e_missing = .{} }, .loc = all[0].loc, }; while (i < all.len) : (i += 1) { expr = Expr.joinWithComma(expr, callback(ctx, all[i]) orelse Expr{ .data = .{ .e_missing = .{} }, .loc = all[i].loc, }, allocator); } return expr; }, } } pub fn jsonStringify(self: *const @This(), options: anytype, writer: anytype) !void { return try std.json.stringify(Serializable{ .@"type" = std.meta.activeTag(self.data), .object = "expr", .value = self.data, .loc = self.loc }, options, writer); } pub fn extractNumericValues(left: Expr.Data, right: Expr.Data) ?[2]f64 { if (!(@as(Expr.Tag, left) == .e_number and @as(Expr.Tag, right) == .e_number)) { return null; } return [2]f64{ left.e_number.value, right.e_number.value }; } pub fn isAnonymousNamed(e: *Expr) bool { switch (e.data) { .e_arrow => { return true; }, .e_function => |func| { return func.func.name == null; }, .e_class => |class| { return class.class_name == null; }, else => { return false; }, } } pub var icount: usize = 0; // We don't need to dynamically allocate booleans var true_bool = E.Boolean{ .value = true }; var false_bool = E.Boolean{ .value = false }; var bool_values = [_]*E.Boolean{ &false_bool, &true_bool }; pub fn init(exp: anytype, loc: logger.Loc) Expr { icount += 1; const st = exp.*; switch (@TypeOf(st)) { E.Array => { return Expr{ .loc = loc, .data = Data{ .e_array = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Class => { return Expr{ .loc = loc, .data = Data{ .e_class = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Unary => { return Expr{ .loc = loc, .data = Data{ .e_unary = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Binary => { return Expr{ .loc = loc, .data = Data{ .e_binary = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.This => { return Expr{ .loc = loc, .data = Data{ .e_this = st, }, }; }, E.Boolean => { return Expr{ .loc = loc, .data = Data{ .e_boolean = st, }, }; }, E.Super => { return Expr{ .loc = loc, .data = Data{ .e_super = st, }, }; }, E.Null => { return Expr{ .loc = loc, .data = Data{ .e_null = st, }, }; }, E.Undefined => { return Expr{ .loc = loc, .data = Data{ .e_undefined = st, }, }; }, E.New => { return Expr{ .loc = loc, .data = Data{ .e_new = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.NewTarget => { return Expr{ .loc = loc, .data = Data{ .e_new_target = st, }, }; }, E.Function => { return Expr{ .loc = loc, .data = Data{ .e_function = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.ImportMeta => { return Expr{ .loc = loc, .data = Data{ .e_import_meta = st, }, }; }, E.Call => { return Expr{ .loc = loc, .data = Data{ .e_call = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Dot => { return Expr{ .loc = loc, .data = Data{ .e_dot = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Index => { return Expr{ .loc = loc, .data = Data{ .e_index = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Arrow => { return Expr{ .loc = loc, .data = Data{ .e_arrow = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Identifier => { return Expr{ .loc = loc, .data = Data{ .e_identifier = Data.Store.Identifier.append(@TypeOf(st), st), }, }; }, E.ImportIdentifier => { return Expr{ .loc = loc, .data = Data{ .e_import_identifier = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.PrivateIdentifier => { return Expr{ .loc = loc, .data = Data{ .e_private_identifier = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.JSXElement => { return Expr{ .loc = loc, .data = Data{ .e_jsx_element = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Missing => { return Expr{ .loc = loc, .data = Data{ .e_missing = E.Missing{} } }; }, E.Number => { return Expr{ .loc = loc, .data = Data{ .e_number = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.BigInt => { return Expr{ .loc = loc, .data = Data{ .e_big_int = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Object => { return Expr{ .loc = loc, .data = Data{ .e_object = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Spread => { return Expr{ .loc = loc, .data = Data{ .e_spread = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.String => { if (comptime isDebug) { // Sanity check: assert string is not a null ptr if (st.isUTF8()) { std.debug.assert(st.utf8[0] > 0); } else if (st.value.len > 0) { std.debug.assert(st.value[0] > 0); } } return Expr{ .loc = loc, .data = Data{ .e_string = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.TemplatePart => { return Expr{ .loc = loc, .data = Data{ .e_template_part = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Template => { return Expr{ .loc = loc, .data = Data{ .e_template = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.RegExp => { return Expr{ .loc = loc, .data = Data{ .e_reg_exp = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Await => { return Expr{ .loc = loc, .data = Data{ .e_await = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Yield => { return Expr{ .loc = loc, .data = Data{ .e_yield = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.If => { return Expr{ .loc = loc, .data = Data{ .e_if = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.RequireOrRequireResolve => { return Expr{ .loc = loc, .data = Data{ .e_require_or_require_resolve = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Import => { return Expr{ .loc = loc, .data = Data{ .e_import = Data.Store.All.append(@TypeOf(st), st), }, }; }, E.Require => { return Expr{ .loc = loc, .data = Data{ .e_require = Data.Store.All.append(@TypeOf(st), st), }, }; }, *E.String => { return Expr{ .loc = loc, .data = Data{ .e_string = Data.Store.All.append(@TypeOf(st.*), st.*), }, }; }, else => { @compileError("Invalid type passed to Expr.init: " ++ @typeName(@TypeOf(st))); }, } } pub fn alloc(allocator: *std.mem.Allocator, st: anytype, loc: logger.Loc) Expr { icount += 1; return init(&st, loc); } pub const Tag = enum(u6) { e_array, e_unary, e_binary, e_boolean, e_super, e_null, e_undefined, e_new, e_function, e_new_target, e_import_meta, e_call, e_dot, e_index, e_arrow, e_identifier, e_import_identifier, e_private_identifier, e_jsx_element, e_missing, e_number, e_big_int, e_object, e_spread, e_string, e_template_part, e_template, e_reg_exp, e_await, e_yield, e_if, e_require_or_require_resolve, e_import, e_this, e_class, e_require, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } pub fn isArray(self: Tag) bool { switch (self) { .e_array => { return true; }, else => { return false; }, } } pub fn isUnary(self: Tag) bool { switch (self) { .e_unary => { return true; }, else => { return false; }, } } pub fn isBinary(self: Tag) bool { switch (self) { .e_binary => { return true; }, else => { return false; }, } } pub fn isThis(self: Tag) bool { switch (self) { .e_this => { return true; }, else => { return false; }, } } pub fn isClass(self: Tag) bool { switch (self) { .e_class => { return true; }, else => { return false; }, } } pub fn isBoolean(self: Tag) bool { switch (self) { .e_boolean => { return true; }, else => { return false; }, } } pub fn isSuper(self: Tag) bool { switch (self) { .e_super => { return true; }, else => { return false; }, } } pub fn isNull(self: Tag) bool { switch (self) { .e_null => { return true; }, else => { return false; }, } } pub fn isUndefined(self: Tag) bool { switch (self) { .e_undefined => { return true; }, else => { return false; }, } } pub fn isNew(self: Tag) bool { switch (self) { .e_new => { return true; }, else => { return false; }, } } pub fn isNewTarget(self: Tag) bool { switch (self) { .e_new_target => { return true; }, else => { return false; }, } } pub fn isFunction(self: Tag) bool { switch (self) { .e_function => { return true; }, else => { return false; }, } } pub fn isImportMeta(self: Tag) bool { switch (self) { .e_import_meta => { return true; }, else => { return false; }, } } pub fn isCall(self: Tag) bool { switch (self) { .e_call => { return true; }, else => { return false; }, } } pub fn isDot(self: Tag) bool { switch (self) { .e_dot => { return true; }, else => { return false; }, } } pub fn isIndex(self: Tag) bool { switch (self) { .e_index => { return true; }, else => { return false; }, } } pub fn isArrow(self: Tag) bool { switch (self) { .e_arrow => { return true; }, else => { return false; }, } } pub fn isIdentifier(self: Tag) bool { switch (self) { .e_identifier => { return true; }, else => { return false; }, } } pub fn isImportIdentifier(self: Tag) bool { switch (self) { .e_import_identifier => { return true; }, else => { return false; }, } } pub fn isPrivateIdentifier(self: Tag) bool { switch (self) { .e_private_identifier => { return true; }, else => { return false; }, } } pub fn isJsxElement(self: Tag) bool { switch (self) { .e_jsx_element => { return true; }, else => { return false; }, } } pub fn isMissing(self: Tag) bool { switch (self) { .e_missing => { return true; }, else => { return false; }, } } pub fn isNumber(self: Tag) bool { switch (self) { .e_number => { return true; }, else => { return false; }, } } pub fn isBigInt(self: Tag) bool { switch (self) { .e_big_int => { return true; }, else => { return false; }, } } pub fn isObject(self: Tag) bool { switch (self) { .e_object => { return true; }, else => { return false; }, } } pub fn isSpread(self: Tag) bool { switch (self) { .e_spread => { return true; }, else => { return false; }, } } pub fn isString(self: Tag) bool { switch (self) { .e_string => { return true; }, else => { return false; }, } } pub fn isTemplatePart(self: Tag) bool { switch (self) { .e_template_part => { return true; }, else => { return false; }, } } pub fn isTemplate(self: Tag) bool { switch (self) { .e_template => { return true; }, else => { return false; }, } } pub fn isRegExp(self: Tag) bool { switch (self) { .e_reg_exp => { return true; }, else => { return false; }, } } pub fn isAwait(self: Tag) bool { switch (self) { .e_await => { return true; }, else => { return false; }, } } pub fn isYield(self: Tag) bool { switch (self) { .e_yield => { return true; }, else => { return false; }, } } pub fn isIf(self: Tag) bool { switch (self) { .e_if => { return true; }, else => { return false; }, } } pub fn isRequireOrRequireResolve(self: Tag) bool { switch (self) { .e_require_or_require_resolve => { return true; }, else => { return false; }, } } pub fn isImport(self: Tag) bool { switch (self) { .e_import => { return true; }, else => { return false; }, } } }; pub fn isBoolean(a: Expr) bool { switch (a.data) { .e_boolean => { return true; }, .e_if => |ex| { return isBoolean(ex.yes) and isBoolean(ex.no); }, .e_unary => |ex| { return ex.op == .un_not or ex.op == .un_delete; }, .e_binary => |ex| { switch (ex.op) { .bin_strict_eq, .bin_strict_ne, .bin_loose_eq, .bin_loose_ne, .bin_lt, .bin_gt, .bin_le, .bin_ge, .bin_instanceof, .bin_in => { return true; }, .bin_logical_or => { return isBoolean(ex.left) and isBoolean(ex.right); }, .bin_logical_and => { return isBoolean(ex.left) and isBoolean(ex.right); }, else => {}, } }, else => {}, } return false; } pub fn assign(a: Expr, b: Expr, allocator: *std.mem.Allocator) Expr { return alloc(allocator, E.Binary{ .op = .bin_assign, .left = a, .right = b, }, a.loc); } pub inline fn at(expr: *Expr, t: anytype, allocator: *std.mem.Allocator) Expr { return alloc(allocator, t, expr.loc); } // Wraps the provided expression in the "!" prefix operator. The expression // will potentially be simplified to avoid generating unnecessary extra "!" // operators. For example, calling this with "!!x" will return "!x" instead // of returning "!!!x". pub fn not(expr: *Expr, allocator: *std.mem.Allocator) Expr { return maybeSimplifyNot(expr, allocator) orelse expr.*; } pub fn hasValueForThisInCall(expr: *const Expr) bool { return switch (expr.data) { .e_dot, .e_index => true, else => false, }; } // The given "expr" argument should be the operand of a "!" prefix operator // (i.e. the "x" in "!x"). This returns a simplified expression for the // whole operator (i.e. the "!x") if it can be simplified, or false if not. // It's separate from "Not()" above to avoid allocation on failure in case // that is undesired. pub fn maybeSimplifyNot(expr: *Expr, allocator: *std.mem.Allocator) ?Expr { switch (expr.data) { .e_null, .e_undefined => { return expr.at(E.Boolean{ .value = true }, allocator); }, .e_boolean => |b| { return expr.at(E.Boolean{ .value = b.value }, allocator); }, .e_number => |n| { return expr.at(E.Boolean{ .value = (n.value == 0 or std.math.isNan(n.value)) }, allocator); }, .e_big_int => |b| { return expr.at(E.Boolean{ .value = strings.eqlComptime(b.value, "0") }, allocator); }, .e_function, .e_arrow, .e_reg_exp, => { return expr.at(E.Boolean{ .value = false }, allocator); }, // "!!!a" => "!a" .e_unary => |un| { if (un.op == Op.Code.un_not and isBoolean(un.value)) { return un.value; } }, .e_binary => |ex| { // TODO: evaluate whether or not it is safe to do this mutation since it's modifying in-place. // Make sure that these transformations are all safe for special values. // For example, "!(a < b)" is not the same as "a >= b" if a and/or b are // NaN (or undefined, or null, or possibly other problem cases too). switch (ex.op) { Op.Code.bin_loose_eq => { ex.op = .bin_loose_ne; return expr.*; }, Op.Code.bin_loose_ne => { ex.op = .bin_loose_eq; return expr.*; }, Op.Code.bin_strict_eq => { ex.op = .bin_strict_ne; return expr.*; }, Op.Code.bin_strict_ne => { ex.op = .bin_strict_eq; return expr.*; }, Op.Code.bin_comma => { ex.right = ex.right.not(allocator); return expr.*; }, else => {}, } }, else => {}, } return null; } pub fn assignStmt(a: Expr, b: Expr, allocator: *std.mem.Allocator) Stmt { return Stmt.alloc( allocator, S.SExpr{ .value = Expr.assign(a, b, allocator), }, a.loc, ); } pub fn isOptionalChain(self: *const @This()) bool { return switch (self.data) { .e_dot => self.getDot().optional_chain != null, .e_index => self.getIndex().optional_chain != null, .e_call => self.getCall().optional_chain != null, else => false, }; } pub const Data = union(Tag) { e_array: *E.Array, e_unary: *E.Unary, e_binary: *E.Binary, e_class: *E.Class, e_new: *E.New, e_function: *E.Function, e_call: *E.Call, e_dot: *E.Dot, e_index: *E.Index, e_arrow: *E.Arrow, e_identifier: *E.Identifier, e_import_identifier: *E.ImportIdentifier, e_private_identifier: *E.PrivateIdentifier, e_jsx_element: *E.JSXElement, e_object: *E.Object, e_spread: *E.Spread, e_template_part: *E.TemplatePart, e_template: *E.Template, e_reg_exp: *E.RegExp, e_await: *E.Await, e_yield: *E.Yield, e_if: *E.If, e_require: *E.Require, e_require_or_require_resolve: *E.RequireOrRequireResolve, e_import: *E.Import, e_boolean: E.Boolean, e_number: *E.Number, e_big_int: *E.BigInt, e_string: *E.String, e_missing: E.Missing, e_this: E.This, e_super: E.Super, e_null: E.Null, e_undefined: E.Undefined, e_new_target: E.NewTarget, e_import_meta: E.ImportMeta, pub const Store = struct { const often = 512; const medium = 256; const rare = 24; const Identifier = NewBaseStore([_]type{E.Identifier}, 512); pub const All = NewBaseStore( &([_]type{ E.Array, E.Unary, E.Binary, E.Class, E.Boolean, E.Super, E.New, E.Function, E.Call, E.Dot, E.Index, E.Arrow, E.ImportIdentifier, E.PrivateIdentifier, E.JSXElement, E.Number, E.BigInt, E.Object, E.Spread, E.String, E.TemplatePart, E.Template, E.RegExp, E.Await, E.Yield, E.If, E.Require, E.RequireOrRequireResolve, E.Import, }), 512, ); threadlocal var has_inited = false; pub fn create(allocator: *std.mem.Allocator) void { if (has_inited) { return; } has_inited = true; _ = All.init(allocator); _ = Identifier.init(allocator); } pub fn reset() void { All.reset(); Identifier.reset(); } pub fn append(comptime ValueType: type, value: anytype) *ValueType { if (ValueType == E.Identifier) { return Identifier.append(ValueType, value); } else { return All.append(ValueType, value); } } }; pub fn isBooleanValue(self: *Expr) bool { // TODO: return false; // return switch (self) { // Expr.e_boolean => |dot| true, // Expr.e_if => |dot| dot.optional_chain != OptionalChain.none, // Expr.e_call => |dot| dot.optional_chain != OptionalChain.none, // else => false, // }; } pub fn isNumericValue(self: *Expr) bool { // TODO: return false; } pub inline fn isStringValue(self: Data) bool { return @as(Expr.Tag, self) == .e_string; } }; }; pub const EnumValue = struct { loc: logger.Loc, ref: Ref, name: E.String, value: ?ExprNodeIndex, }; pub const S = struct { pub const Block = struct { stmts: StmtNodeList }; pub const SExpr = struct { value: ExprNodeIndex, // This is set to true for automatically-generated expressions that should // not affect tree shaking. For example, calling a function from the runtime // that doesn't have externally-visible side effects. does_not_affect_tree_shaking: bool = false, }; pub const Comment = struct { text: string }; pub const Directive = struct { value: JavascriptString, }; pub const ExportClause = struct { items: []ClauseItem, is_single_line: bool = false }; pub const Empty = struct {}; pub const ExportStar = struct { namespace_ref: Ref, alias: ?G.ExportStarAlias = null, import_record_index: u32, }; // This is an "export = value;" statement in TypeScript pub const ExportEquals = struct { value: ExprNodeIndex }; // The decision of whether to export an expression using "module.exports" or // "export default" is deferred until linking using this statement kind pub const LazyExport = struct { value: ExprNodeIndex }; pub const Label = struct { name: LocRef, stmt: StmtNodeIndex }; // This is a stand-in for a TypeScript type declaration pub const TypeScript = struct {}; pub const Debugger = struct {}; pub const ExportFrom = struct { items: []ClauseItem, namespace_ref: Ref, import_record_index: u32, is_single_line: bool, }; pub const ExportDefault = struct { default_name: LocRef, // value may be a SFunction or SClass value: StmtOrExpr }; pub const Enum = struct { name: LocRef, arg: Ref, values: []EnumValue, is_export: bool, }; pub const Namespace = struct { name: LocRef, arg: Ref, stmts: StmtNodeList, is_export: bool, }; pub const Function = struct { func: G.Fn, }; pub const Class = struct { class: G.Class, is_export: bool = false }; pub const If = struct { test_: ExprNodeIndex, yes: StmtNodeIndex, no: ?StmtNodeIndex, }; pub const For = struct { // May be a SConst, SLet, SVar, or SExpr init: ?StmtNodeIndex = null, test_: ?ExprNodeIndex = null, update: ?ExprNodeIndex = null, body: StmtNodeIndex }; pub const ForIn = struct { // May be a SConst, SLet, SVar, or SExpr init: StmtNodeIndex, value: ExprNodeIndex, body: StmtNodeIndex }; pub const ForOf = struct { is_await: bool = false, // May be a SConst, SLet, SVar, or SExpr init: StmtNodeIndex, value: ExprNodeIndex, body: StmtNodeIndex, }; pub const DoWhile = struct { body: StmtNodeIndex, test_: ExprNodeIndex }; pub const While = struct { test_: ExprNodeIndex, body: StmtNodeIndex, }; pub const With = struct { value: ExprNodeIndex, body: StmtNodeIndex, body_loc: logger.Loc, }; pub const Try = struct { body_loc: logger.Loc, body: StmtNodeList, catch_: ?Catch = null, finally: ?Finally = null, }; pub const Switch = struct { test_: ExprNodeIndex, body_loc: logger.Loc, cases: []Case, }; // This object represents all of these types of import statements: // // import 'path' // import {item1, item2} from 'path' // import * as ns from 'path' // import defaultItem, {item1, item2} from 'path' // import defaultItem, * as ns from 'path' // // Many parts are optional and can be combined in different ways. The only // restriction is that you cannot have both a clause and a star namespace. pub const Import = struct { // If this is a star import: This is a Ref for the namespace symbol. The Loc // for the symbol is StarLoc. // // Otherwise: This is an auto-generated Ref for the namespace representing // the imported file. In this case StarLoc is nil. The NamespaceRef is used // when converting this module to a CommonJS module. namespace_ref: Ref, default_name: ?LocRef = null, items: []ClauseItem = &([_]ClauseItem{}), star_name_loc: ?logger.Loc = null, import_record_index: u32, is_single_line: bool = false, }; pub const Return = struct { value: ?ExprNodeIndex = null }; pub const Throw = struct { value: ExprNodeIndex }; pub const Local = struct { kind: Kind = Kind.k_var, decls: []G.Decl, is_export: bool = false, // The TypeScript compiler doesn't generate code for "import foo = bar" // statements where the import is never used. was_ts_import_equals: bool = false, pub const Kind = enum(u2) { k_var, k_let, k_const, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; }; pub const Break = struct { label: ?LocRef = null, }; pub const Continue = struct { label: ?LocRef = null, }; }; pub const Catch = struct { loc: logger.Loc, binding: ?BindingNodeIndex = null, body: StmtNodeList, }; pub const Finally = struct { loc: logger.Loc, stmts: StmtNodeList, }; pub const Case = struct { loc: logger.Loc, value: ?ExprNodeIndex, body: StmtNodeList }; pub const Op = struct { // If you add a new token, remember to add it to "Table" too pub const Code = enum { // Prefix un_pos, un_neg, un_cpl, un_not, un_void, un_typeof, un_delete, // Prefix update un_pre_dec, un_pre_inc, // Postfix update un_post_dec, un_post_inc, // Left-associative bin_add, bin_sub, bin_mul, bin_div, bin_rem, bin_pow, bin_lt, bin_le, bin_gt, bin_ge, bin_in, bin_instanceof, bin_shl, bin_shr, bin_u_shr, bin_loose_eq, bin_loose_ne, bin_strict_eq, bin_strict_ne, bin_nullish_coalescing, bin_logical_or, bin_logical_and, bin_bitwise_or, bin_bitwise_and, bin_bitwise_xor, // Non-associative bin_comma, // Right-associative bin_assign, bin_add_assign, bin_sub_assign, bin_mul_assign, bin_div_assign, bin_rem_assign, bin_pow_assign, bin_shl_assign, bin_shr_assign, bin_u_shr_assign, bin_bitwise_or_assign, bin_bitwise_and_assign, bin_bitwise_xor_assign, bin_nullish_coalescing_assign, bin_logical_or_assign, bin_logical_and_assign, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } pub fn unaryAssignTarget(code: Op.Code) AssignTarget { if (@enumToInt(code) >= @enumToInt(Op.Code.un_pre_dec) and @enumToInt(code) <= @enumToInt(Op.Code.un_post_inc)) { return AssignTarget.update; } else { return AssignTarget.none; } } pub fn isLeftAssociative(code: Op.Code) bool { return @enumToInt(code) >= @enumToInt(Op.Code.bin_add) and @enumToInt(code) < @enumToInt(Op.Code.bin_comma) and code != .bin_pow; } pub fn isRightAssociative(code: Op.Code) bool { return @enumToInt(code) >= @enumToInt(Op.Code.bin_assign) or code == .bin_pow; } pub fn binaryAssignTarget(code: Op.Code) AssignTarget { if (code == .bin_assign) { return AssignTarget.replace; } else if (@enumToInt(code) > @enumToInt(Op.Code.bin_assign)) { return .update; } else { return .none; } } pub fn isPrefix(code: Op.Code) bool { return @enumToInt(code) < @enumToInt(Op.Code.un_post_dec); } }; pub const Level = enum(u6) { lowest, comma, spread, yield, assign, conditional, nullish_coalescing, logical_or, logical_and, bitwise_or, bitwise_xor, bitwise_and, equals, compare, shift, add, multiply, exponentiation, prefix, postfix, new, call, member, pub fn lt(self: Level, b: Level) bool { return @enumToInt(self) < @enumToInt(b); } pub fn gt(self: Level, b: Level) bool { return @enumToInt(self) > @enumToInt(b); } pub fn gte(self: Level, b: Level) bool { return @enumToInt(self) >= @enumToInt(b); } pub fn lte(self: Level, b: Level) bool { return @enumToInt(self) <= @enumToInt(b); } pub fn eql(self: Level, b: Level) bool { return @enumToInt(self) == @enumToInt(b); } pub fn sub(self: Level, i: anytype) Level { return @intToEnum(Level, @enumToInt(self) - i); } pub fn add(self: Level, i: anytype) Level { return @intToEnum(Level, @enumToInt(self) + i); } }; text: string, level: Level, is_keyword: bool = false, pub fn init(triple: anytype) Op { return Op{ .text = triple.@"0", .level = triple.@"1", .is_keyword = triple.@"2", }; } pub fn jsonStringify(self: *const @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(self.text, opts, o); } pub const TableType: std.EnumArray(Op.Code, Op) = undefined; pub const Table = brk: { var table = std.EnumArray(Op.Code, Op).initUndefined(); // Prefix table.set(Op.Code.un_pos, Op.init(.{ "+", Level.prefix, false })); table.set(Op.Code.un_neg, Op.init(.{ "-", Level.prefix, false })); table.set(Op.Code.un_cpl, Op.init(.{ "~", Level.prefix, false })); table.set(Op.Code.un_not, Op.init(.{ "!", Level.prefix, false })); table.set(Op.Code.un_void, Op.init(.{ "void", Level.prefix, true })); table.set(Op.Code.un_typeof, Op.init(.{ "typeof", Level.prefix, true })); table.set(Op.Code.un_delete, Op.init(.{ "delete", Level.prefix, true })); // Prefix update table.set(Op.Code.un_pre_dec, Op.init(.{ "--", Level.prefix, false })); table.set(Op.Code.un_pre_inc, Op.init(.{ "++", Level.prefix, false })); // Postfix update table.set(Op.Code.un_post_dec, Op.init(.{ "--", Level.postfix, false })); table.set(Op.Code.un_post_inc, Op.init(.{ "++", Level.postfix, false })); // Left-associative table.set(Op.Code.bin_add, Op.init(.{ "+", Level.add, false })); table.set(Op.Code.bin_sub, Op.init(.{ "-", Level.add, false })); table.set(Op.Code.bin_mul, Op.init(.{ "*", Level.multiply, false })); table.set(Op.Code.bin_div, Op.init(.{ "/", Level.multiply, false })); table.set(Op.Code.bin_rem, Op.init(.{ "%", Level.multiply, false })); table.set(Op.Code.bin_pow, Op.init(.{ "**", Level.exponentiation, false })); table.set(Op.Code.bin_lt, Op.init(.{ "<", Level.compare, false })); table.set(Op.Code.bin_le, Op.init(.{ "<=", Level.compare, false })); table.set(Op.Code.bin_gt, Op.init(.{ ">", Level.compare, false })); table.set(Op.Code.bin_ge, Op.init(.{ ">=", Level.compare, false })); table.set(Op.Code.bin_in, Op.init(.{ "in", Level.compare, true })); table.set(Op.Code.bin_instanceof, Op.init(.{ "instanceof", Level.compare, true })); table.set(Op.Code.bin_shl, Op.init(.{ "<<", Level.shift, false })); table.set(Op.Code.bin_shr, Op.init(.{ ">>", Level.shift, false })); table.set(Op.Code.bin_u_shr, Op.init(.{ ">>>", Level.shift, false })); table.set(Op.Code.bin_loose_eq, Op.init(.{ "==", Level.equals, false })); table.set(Op.Code.bin_loose_ne, Op.init(.{ "!=", Level.equals, false })); table.set(Op.Code.bin_strict_eq, Op.init(.{ "===", Level.equals, false })); table.set(Op.Code.bin_strict_ne, Op.init(.{ "!==", Level.equals, false })); table.set(Op.Code.bin_nullish_coalescing, Op.init(.{ "??", Level.nullish_coalescing, false })); table.set(Op.Code.bin_logical_or, Op.init(.{ "||", Level.logical_or, false })); table.set(Op.Code.bin_logical_and, Op.init(.{ "&&", Level.logical_and, false })); table.set(Op.Code.bin_bitwise_or, Op.init(.{ "|", Level.bitwise_or, false })); table.set(Op.Code.bin_bitwise_and, Op.init(.{ "&", Level.bitwise_and, false })); table.set(Op.Code.bin_bitwise_xor, Op.init(.{ "^", Level.bitwise_xor, false })); // Non-associative table.set(Op.Code.bin_comma, Op.init(.{ ",", Level.comma, false })); // Right-associative table.set(Op.Code.bin_assign, Op.init(.{ "=", Level.assign, false })); table.set(Op.Code.bin_add_assign, Op.init(.{ "+=", Level.assign, false })); table.set(Op.Code.bin_sub_assign, Op.init(.{ "-=", Level.assign, false })); table.set(Op.Code.bin_mul_assign, Op.init(.{ "*=", Level.assign, false })); table.set(Op.Code.bin_div_assign, Op.init(.{ "/=", Level.assign, false })); table.set(Op.Code.bin_rem_assign, Op.init(.{ "%=", Level.assign, false })); table.set(Op.Code.bin_pow_assign, Op.init(.{ "**=", Level.assign, false })); table.set(Op.Code.bin_shl_assign, Op.init(.{ "<<=", Level.assign, false })); table.set(Op.Code.bin_shr_assign, Op.init(.{ ">>=", Level.assign, false })); table.set(Op.Code.bin_u_shr_assign, Op.init(.{ ">>>=", Level.assign, false })); table.set(Op.Code.bin_bitwise_or_assign, Op.init(.{ "|=", Level.assign, false })); table.set(Op.Code.bin_bitwise_and_assign, Op.init(.{ "&=", Level.assign, false })); table.set(Op.Code.bin_bitwise_xor_assign, Op.init(.{ "^=", Level.assign, false })); table.set(Op.Code.bin_nullish_coalescing_assign, Op.init(.{ "??=", Level.assign, false })); table.set(Op.Code.bin_logical_or_assign, Op.init(.{ "||=", Level.assign, false })); table.set(Op.Code.bin_logical_and_assign, Op.init(.{ "&&=", Level.assign, false })); break :brk table; }; }; pub const ArrayBinding = struct { binding: BindingNodeIndex, default_value: ?ExprNodeIndex = null, }; pub const Ast = struct { approximate_newline_count: usize = 0, has_lazy_export: bool = false, runtime_imports: Runtime.Imports, runtime_import_record_id: ?u32 = null, needs_runtime: bool = false, externals: []u32 = &[_]u32{}, // This is a list of CommonJS features. When a file uses CommonJS features, // it's not a candidate for "flat bundling" and must be wrapped in its own // closure. has_top_level_return: bool = false, uses_exports_ref: bool = false, uses_module_ref: bool = false, exports_kind: ExportsKind = ExportsKind.none, bundle_export_ref: ?Ref = null, // This is a list of ES6 features. They are ranges instead of booleans so // that they can be used in log messages. Check to see if "Len > 0". import_keyword: ?logger.Range = null, // Does not include TypeScript-specific syntax or "import()" export_keyword: ?logger.Range = null, // Does not include TypeScript-specific syntax top_level_await_keyword: ?logger.Range = null, // These are stored at the AST level instead of on individual AST nodes so // they can be manipulated efficiently without a full AST traversal import_records: []ImportRecord = &([_]ImportRecord{}), hashbang: ?string = null, directive: ?string = null, url_for_css: ?string = null, parts: []Part, symbols: []Symbol = &([_]Symbol{}), module_scope: ?Scope = null, // char_freq: *CharFreq, exports_ref: ?Ref = null, module_ref: ?Ref = null, wrapper_ref: ?Ref = null, require_ref: ?Ref = null, bundle_namespace_ref: ?Ref = null, // These are used when bundling. They are filled in during the parser pass // since we already have to traverse the AST then anyway and the parser pass // is conveniently fully parallelized. named_imports: NamedImports = undefined, named_exports: NamedExports = undefined, top_level_symbol_to_parts: AutoHashMap(Ref, std.ArrayList(u32)) = undefined, export_star_import_records: []u32 = &([_]u32{}), pub const NamedImports = std.ArrayHashMap(Ref, NamedImport, RefHashCtx, true); pub const NamedExports = std.StringArrayHashMap(NamedExport); pub fn initTest(parts: []Part) Ast { return Ast{ .parts = parts, .runtime_imports = .{}, }; } pub const empty = Ast{ .parts = &[_]Part{}, .runtime_imports = undefined }; pub fn toJSON(self: *const Ast, allocator: *std.mem.Allocator, stream: anytype) !void { const opts = std.json.StringifyOptions{ .whitespace = std.json.StringifyOptions.Whitespace{ .separator = true, } }; try std.json.stringify(self.parts, opts, stream); } }; pub const Span = struct { text: string, range: logger.Range, }; pub const ExportsKind = enum { // This file doesn't have any kind of export, so it's impossible to say what // kind of file this is. An empty file is in this category, for example. none, // The exports are stored on "module" and/or "exports". Calling "require()" // on this module returns "module.exports". All imports to this module are // allowed but may return undefined. cjs, // All export names are known explicitly. Calling "require()" on this module // generates an exports object (stored in "exports") with getters for the // export names. Named imports to this module are only allowed if they are // in the set of export names. esm, // Some export names are known explicitly, but others fall back to a dynamic // run-time object. This is necessary when using the "export * from" syntax // with either a CommonJS module or an external module (i.e. a module whose // export names are not known at compile-time). // // Calling "require()" on this module generates an exports object (stored in // "exports") with getters for the export names. All named imports to this // module are allowed. Direct named imports reference the corresponding export // directly. Other imports go through property accesses on "exports". esm_with_dyn, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub fn isDynamicExport(exp: ExportsKind) bool { return kind == .cjs || kind == .esm_with_dyn; } pub const DeclaredSymbol = packed struct { ref: Ref, is_top_level: bool = false, }; pub const Dependency = packed struct { source_index: u32 = 0, part_index: u32 = 0, }; pub const ExprList = std.ArrayList(Expr); pub const StmtList = std.ArrayList(Stmt); pub const BindingList = std.ArrayList(Binding); // Each file is made up of multiple parts, and each part consists of one or // more top-level statements. Parts are used for tree shaking and code // splitting analysis. Individual parts of a file can be discarded by tree // shaking and can be assigned to separate chunks (i.e. output files) by code // splitting. pub const Part = struct { stmts: []Stmt, scopes: []*Scope = &([_]*Scope{}), // Each is an index into the file-level import record list import_record_indices: []u32 = &([_]u32{}), // All symbols that are declared in this part. Note that a given symbol may // have multiple declarations, and so may end up being declared in multiple // parts (e.g. multiple "var" declarations with the same name). Also note // that this list isn't deduplicated and may contain duplicates. declared_symbols: []DeclaredSymbol = &([_]DeclaredSymbol{}), // An estimate of the number of uses of all symbols used within this part. symbol_uses: SymbolUseMap = undefined, // The indices of the other parts in this file that are needed if this part // is needed. dependencies: []Dependency = &([_]Dependency{}), // If true, this part can be removed if none of the declared symbols are // used. If the file containing this part is imported, then all parts that // don't have this flag enabled must be included. can_be_removed_if_unused: bool = false, // This is used for generated parts that we don't want to be present if they // aren't needed. This enables tree shaking for these parts even if global // tree shaking isn't enabled. force_tree_shaking: bool = false, // This is true if this file has been marked as live by the tree shaking // algorithm. is_live: bool = false, tag: Tag = Tag.none, pub const Tag = enum { none, jsx_import, }; pub const SymbolUseMap = AutoHashMap(Ref, Symbol.Use); pub fn jsonStringify(self: *const Part, options: std.json.StringifyOptions, writer: anytype) !void { return std.json.stringify(self.stmts, options, writer); } }; pub const Result = struct { ast: Ast, ok: bool = false, }; pub const StmtOrExpr = union(enum) { stmt: StmtNodeIndex, expr: ExprNodeIndex, }; pub const NamedImport = struct { // Parts within this file that use this import local_parts_with_uses: []u32 = &([_]u32{}), alias: ?string, alias_loc: ?logger.Loc, namespace_ref: ?Ref, import_record_index: u32, // If true, the alias refers to the entire export namespace object of a // module. This is no longer represented as an alias called "*" because of // the upcoming "Arbitrary module namespace identifier names" feature: // https://github.com/tc39/ecma262/pull/2154 alias_is_star: bool = false, // It's useful to flag exported imports because if they are in a TypeScript // file, we can't tell if they are a type or a value. is_exported: bool = false, }; pub const NamedExport = struct { ref: Ref, alias_loc: logger.Loc, }; pub const StrictModeKind = enum(u7) { sloppy_mode, explicit_strict_mode, implicit_strict_mode_import, implicit_strict_mode_export, implicit_strict_mode_top_level_await, implicit_strict_mode_class, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub const Scope = struct { id: usize = 0, kind: Kind = Kind.block, parent: ?*Scope, children: std.ArrayList(*Scope), members: StringHashMap(Member), generated: std.ArrayList(Ref), // This is used to store the ref of the label symbol for ScopeLabel scopes. label_ref: ?Ref = null, label_stmt_is_loop: bool = false, // If a scope contains a direct eval() expression, then none of the symbols // inside that scope can be renamed. We conservatively assume that the // evaluated code might reference anything that it has access to. contains_direct_eval: bool = false, // This is to help forbid "arguments" inside class body scopes forbid_arguments: bool = false, strict_mode: StrictModeKind = StrictModeKind.sloppy_mode, pub fn reset(this: *Scope) void { this.children.clearRetainingCapacity(); this.generated.clearRetainingCapacity(); this.members.clearRetainingCapacity(); this.parent = null; this.id = 0; this.label_ref = null; this.label_stmt_is_loop = false; this.contains_direct_eval = false; this.strict_mode = .sloppy_mode; this.kind = .block; } // Do not make this a packed struct // Two hours of debugging time lost to that. // It causes a crash due to undefined memory pub const Member = struct { ref: Ref, loc: logger.Loc, pub fn eql(a: Member, b: Member) bool { return @call(.{ .modifier = .always_inline }, Ref.eql, .{ a.ref, b.ref }) and a.loc.start == b.loc.start; } }; pub const Kind = enum(u8) { block, with, label, class_name, class_body, // The scopes below stop hoisted variables from extending into parent scopes entry, // This is a module, TypeScript enum, or TypeScript namespace function_args, function_body, pub fn jsonStringify(self: @This(), opts: anytype, o: anytype) !void { return try std.json.stringify(@tagName(self), opts, o); } }; pub fn recursiveSetStrictMode(s: *Scope, kind: StrictModeKind) void { if (s.strict_mode == .sloppy_mode) { s.strict_mode = kind; for (s.children.items) |child| { child.recursiveSetStrictMode(kind); } } } pub fn kindStopsHoisting(s: *Scope) bool { return @enumToInt(s.kind) >= @enumToInt(Kind.entry); } }; pub fn printmem(comptime format: string, args: anytype) void { // Output.print(format, args); } test "Binding.init" { var binding = Binding.alloc( std.heap.page_allocator, B.Identifier{ .ref = Ref{ .source_index = 0, .inner_index = 10 } }, logger.Loc{ .start = 1 }, ); std.testing.expect(binding.loc.start == 1); std.testing.expect(@as(Binding.Tag, binding.data) == Binding.Tag.b_identifier); printmem("-------Binding: {d} bits\n", .{@bitSizeOf(Binding)}); printmem("B.Identifier: {d} bits\n", .{@bitSizeOf(B.Identifier)}); printmem("B.Array: {d} bits\n", .{@bitSizeOf(B.Array)}); printmem("B.Property: {d} bits\n", .{@bitSizeOf(B.Property)}); printmem("B.Object: {d} bits\n", .{@bitSizeOf(B.Object)}); printmem("B.Missing: {d} bits\n", .{@bitSizeOf(B.Missing)}); printmem("-------Binding: {d} bits\n", .{@bitSizeOf(Binding)}); } test "Stmt.init" { var stmt = Stmt.alloc( std.heap.page_allocator, S.Continue{}, logger.Loc{ .start = 1 }, ); std.testing.expect(stmt.loc.start == 1); std.testing.expect(@as(Stmt.Tag, stmt.data) == Stmt.Tag.s_continue); printmem("-----Stmt {d} bits\n", .{@bitSizeOf(Stmt)}); printmem("StmtNodeList: {d} bits\n", .{@bitSizeOf(StmtNodeList)}); printmem("StmtOrExpr: {d} bits\n", .{@bitSizeOf(StmtOrExpr)}); printmem("S.Block {d} bits\n", .{@bitSizeOf(S.Block)}); printmem("S.Comment {d} bits\n", .{@bitSizeOf(S.Comment)}); printmem("S.Directive {d} bits\n", .{@bitSizeOf(S.Directive)}); printmem("S.ExportClause {d} bits\n", .{@bitSizeOf(S.ExportClause)}); printmem("S.Empty {d} bits\n", .{@bitSizeOf(S.Empty)}); printmem("S.TypeScript {d} bits\n", .{@bitSizeOf(S.TypeScript)}); printmem("S.Debugger {d} bits\n", .{@bitSizeOf(S.Debugger)}); printmem("S.ExportFrom {d} bits\n", .{@bitSizeOf(S.ExportFrom)}); printmem("S.ExportDefault {d} bits\n", .{@bitSizeOf(S.ExportDefault)}); printmem("S.Enum {d} bits\n", .{@bitSizeOf(S.Enum)}); printmem("S.Namespace {d} bits\n", .{@bitSizeOf(S.Namespace)}); printmem("S.Function {d} bits\n", .{@bitSizeOf(S.Function)}); printmem("S.Class {d} bits\n", .{@bitSizeOf(S.Class)}); printmem("S.If {d} bits\n", .{@bitSizeOf(S.If)}); printmem("S.For {d} bits\n", .{@bitSizeOf(S.For)}); printmem("S.ForIn {d} bits\n", .{@bitSizeOf(S.ForIn)}); printmem("S.ForOf {d} bits\n", .{@bitSizeOf(S.ForOf)}); printmem("S.DoWhile {d} bits\n", .{@bitSizeOf(S.DoWhile)}); printmem("S.While {d} bits\n", .{@bitSizeOf(S.While)}); printmem("S.With {d} bits\n", .{@bitSizeOf(S.With)}); printmem("S.Try {d} bits\n", .{@bitSizeOf(S.Try)}); printmem("S.Switch {d} bits\n", .{@bitSizeOf(S.Switch)}); printmem("S.Import {d} bits\n", .{@bitSizeOf(S.Import)}); printmem("S.Return {d} bits\n", .{@bitSizeOf(S.Return)}); printmem("S.Throw {d} bits\n", .{@bitSizeOf(S.Throw)}); printmem("S.Local {d} bits\n", .{@bitSizeOf(S.Local)}); printmem("S.Break {d} bits\n", .{@bitSizeOf(S.Break)}); printmem("S.Continue {d} bits\n", .{@bitSizeOf(S.Continue)}); printmem("-----Stmt {d} bits\n", .{@bitSizeOf(Stmt)}); } test "Expr.init" { var allocator = std.heap.page_allocator; const ident = Expr.alloc(allocator, E.Identifier{}, logger.Loc{ .start = 100 }); var list = [_]Expr{ident}; var expr = Expr.alloc( allocator, E.Array{ .items = list[0..] }, logger.Loc{ .start = 1 }, ); try std.testing.expect(expr.loc.start == 1); try std.testing.expect(@as(Expr.Tag, expr.data) == Expr.Tag.e_array); try std.testing.expect(expr.data.e_array.items[0].loc.start == 100); printmem("--Ref {d} bits\n", .{@bitSizeOf(Ref)}); printmem("--LocRef {d} bits\n", .{@bitSizeOf(LocRef)}); printmem("--logger.Loc {d} bits\n", .{@bitSizeOf(logger.Loc)}); printmem("--logger.Range {d} bits\n", .{@bitSizeOf(logger.Range)}); printmem("----------Expr: {d} bits\n", .{@bitSizeOf(Expr)}); printmem("ExprNodeList: {d} bits\n", .{@bitSizeOf(ExprNodeList)}); printmem("E.Array: {d} bits\n", .{@bitSizeOf(E.Array)}); printmem("E.Unary: {d} bits\n", .{@bitSizeOf(E.Unary)}); printmem("E.Binary: {d} bits\n", .{@bitSizeOf(E.Binary)}); printmem("E.Boolean: {d} bits\n", .{@bitSizeOf(E.Boolean)}); printmem("E.Super: {d} bits\n", .{@bitSizeOf(E.Super)}); printmem("E.Null: {d} bits\n", .{@bitSizeOf(E.Null)}); printmem("E.Undefined: {d} bits\n", .{@bitSizeOf(E.Undefined)}); printmem("E.New: {d} bits\n", .{@bitSizeOf(E.New)}); printmem("E.NewTarget: {d} bits\n", .{@bitSizeOf(E.NewTarget)}); printmem("E.Function: {d} bits\n", .{@bitSizeOf(E.Function)}); printmem("E.ImportMeta: {d} bits\n", .{@bitSizeOf(E.ImportMeta)}); printmem("E.Call: {d} bits\n", .{@bitSizeOf(E.Call)}); printmem("E.Dot: {d} bits\n", .{@bitSizeOf(E.Dot)}); printmem("E.Index: {d} bits\n", .{@bitSizeOf(E.Index)}); printmem("E.Arrow: {d} bits\n", .{@bitSizeOf(E.Arrow)}); printmem("E.Identifier: {d} bits\n", .{@bitSizeOf(E.Identifier)}); printmem("E.ImportIdentifier: {d} bits\n", .{@bitSizeOf(E.ImportIdentifier)}); printmem("E.PrivateIdentifier: {d} bits\n", .{@bitSizeOf(E.PrivateIdentifier)}); printmem("E.JSXElement: {d} bits\n", .{@bitSizeOf(E.JSXElement)}); printmem("E.Missing: {d} bits\n", .{@bitSizeOf(E.Missing)}); printmem("E.Number: {d} bits\n", .{@bitSizeOf(E.Number)}); printmem("E.BigInt: {d} bits\n", .{@bitSizeOf(E.BigInt)}); printmem("E.Object: {d} bits\n", .{@bitSizeOf(E.Object)}); printmem("E.Spread: {d} bits\n", .{@bitSizeOf(E.Spread)}); printmem("E.String: {d} bits\n", .{@bitSizeOf(E.String)}); printmem("E.TemplatePart: {d} bits\n", .{@bitSizeOf(E.TemplatePart)}); printmem("E.Template: {d} bits\n", .{@bitSizeOf(E.Template)}); printmem("E.RegExp: {d} bits\n", .{@bitSizeOf(E.RegExp)}); printmem("E.Await: {d} bits\n", .{@bitSizeOf(E.Await)}); printmem("E.Yield: {d} bits\n", .{@bitSizeOf(E.Yield)}); printmem("E.If: {d} bits\n", .{@bitSizeOf(E.If)}); printmem("E.RequireOrRequireResolve: {d} bits\n", .{@bitSizeOf(E.RequireOrRequireResolve)}); printmem("E.Import: {d} bits\n", .{@bitSizeOf(E.Import)}); printmem("----------Expr: {d} bits\n", .{@bitSizeOf(Expr)}); } // -- ESBuild bit sizes // EArray | 256 // EArrow | 512 // EAwait | 192 // EBinary | 448 // ECall | 448 // EDot | 384 // EIdentifier | 96 // EIf | 576 // EImport | 448 // EImportIdentifier | 96 // EIndex | 448 // EJSXElement | 448 // ENew | 448 // EnumValue | 384 // EObject | 256 // EPrivateIdentifier | 64 // ERequire | 32 // ERequireResolve | 32 // EString | 256 // ETemplate | 640 // EUnary | 256 // Expr | 192 // ExprOrStmt | 128 // EYield | 128 // Finally | 256 // Fn | 704 // FnBody | 256 // LocRef | 96 // NamedExport | 96 // NamedImport | 512 // NameMinifier | 256 // NamespaceAlias | 192 // opTableEntry | 256 // Part | 1088 // Property | 640 // PropertyBinding | 512 // Ref | 64 // SBlock | 192 // SBreak | 64 // SClass | 704 // SComment | 128 // SContinue | 64 // Scope | 704 // ScopeMember | 96 // SDirective | 256 // SDoWhile | 384 // SEnum | 448 // SExportClause | 256 // SExportDefault | 256 // SExportEquals | 192 // SExportFrom | 320 // SExportStar | 192 // SExpr | 256 // SFor | 384 // SForIn | 576 // SForOf | 640 // SFunction | 768 // SIf | 448 // SImport | 320 // SLabel | 320 // SLazyExport | 192 // SLocal | 256 // SNamespace | 448 // Span | 192 // SReturn | 64 // SSwitch | 448 // SThrow | 192 // Stmt | 192 // STry | 384 // -- ESBuild bit sizes