use oxc_allocator::{Box, Vec};
#[allow(clippy::wildcard_imports)]
use oxc_ast::ast::*;
use oxc_span::GetSpan;
use oxc_syntax::{
identifier::{LS, PS},
keyword::is_reserved_keyword_or_global_object,
number::NumberBase,
operator::{BinaryOperator, UnaryOperator},
precedence::{GetPrecedence, Precedence},
};
use crate::{
annotation_comment::{gen_comment, get_leading_annotate_comment},
Codegen, Context, Operator,
};
pub trait Gen<const MINIFY: bool> {
fn gen(&self, _p: &mut Codegen<{ MINIFY }>, _ctx: Context) {}
}
pub trait GenExpr<const MINIFY: bool> {
fn gen_expr(&self, _p: &mut Codegen<{ MINIFY }>, _precedence: Precedence, _ctx: Context) {}
}
impl<'a, const MINIFY: bool, T> Gen<MINIFY> for Box<'a, T>
where
T: Gen<MINIFY>,
{
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
(**self).gen(p, ctx);
}
}
pub trait GenComment<const MINIFY: bool> {
fn gen_comment(&self, _p: &mut Codegen<{ MINIFY }>, _ctx: Context) {}
}
impl<'a, const MINIFY: bool, T> GenExpr<MINIFY> for Box<'a, T>
where
T: GenExpr<MINIFY>,
{
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
(**self).gen_expr(p, precedence, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Program<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if let Some(hashbang) = &self.hashbang {
hashbang.gen(p, ctx);
}
p.print_directives_and_statements(Some(&self.directives), &self.body, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Hashbang<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.print_str(b"#!");
p.print_str(self.value.as_bytes());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Directive<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.wrap_quote(self.directive.as_str(), |p, _| {
p.print_str(self.directive.as_bytes());
});
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Statement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::BlockStatement(stmt) => stmt.gen(p, ctx),
Self::BreakStatement(stmt) => stmt.gen(p, ctx),
Self::ContinueStatement(stmt) => stmt.gen(p, ctx),
Self::DebuggerStatement(stmt) => stmt.gen(p, ctx),
Self::DoWhileStatement(stmt) => stmt.gen(p, ctx),
Self::EmptyStatement(stmt) => stmt.gen(p, ctx),
Self::ExpressionStatement(stmt) => stmt.gen(p, ctx),
Self::ForInStatement(stmt) => stmt.gen(p, ctx),
Self::ForOfStatement(stmt) => stmt.gen(p, ctx),
Self::ForStatement(stmt) => stmt.gen(p, ctx),
Self::IfStatement(stmt) => stmt.gen(p, ctx),
Self::LabeledStatement(stmt) => stmt.gen(p, ctx),
Self::ReturnStatement(stmt) => stmt.gen(p, ctx),
Self::SwitchStatement(stmt) => stmt.gen(p, ctx),
Self::ThrowStatement(stmt) => stmt.gen(p, ctx),
Self::TryStatement(stmt) => stmt.gen(p, ctx),
Self::WhileStatement(stmt) => stmt.gen(p, ctx),
Self::WithStatement(stmt) => stmt.gen(p, ctx),
Self::ImportDeclaration(decl) => decl.gen(p, ctx),
Self::ExportAllDeclaration(decl) => decl.gen(p, ctx),
Self::ExportDefaultDeclaration(decl) => decl.gen(p, ctx),
Self::ExportNamedDeclaration(decl) => decl.gen(p, ctx),
Self::TSExportAssignment(decl) => decl.gen(p, ctx),
Self::TSNamespaceExportDeclaration(decl) => decl.gen(p, ctx),
Self::VariableDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_semicolon_after_statement();
}
Self::FunctionDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_soft_newline();
}
Self::ClassDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_soft_newline();
}
Self::UsingDeclaration(declaration) => {
p.print_indent();
declaration.gen(p, ctx);
p.print_semicolon_after_statement();
}
Self::TSModuleDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_soft_newline();
}
Self::TSTypeAliasDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_semicolon_after_statement();
}
Self::TSInterfaceDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_soft_newline();
}
Self::TSEnumDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_soft_newline();
}
Self::TSImportEqualsDeclaration(decl) => {
p.print_indent();
decl.gen(p, ctx);
p.print_semicolon_after_statement();
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ExpressionStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.start_of_stmt = p.code_len();
p.print_expression(&self.expression);
if self.expression.is_specific_id("let") {
p.print_semicolon();
} else {
p.print_semicolon_after_statement();
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for IfStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
print_if(self, p, ctx);
}
}
fn print_if<const MINIFY: bool>(
if_stmt: &IfStatement<'_>,
p: &mut Codegen<{ MINIFY }>,
ctx: Context,
) {
p.print_str(b"if");
p.print_soft_space();
p.print(b'(');
p.print_expression(&if_stmt.test);
p.print(b')');
match &if_stmt.consequent {
Statement::BlockStatement(block) => {
p.print_soft_space();
p.print_block_statement(block, ctx);
if if_stmt.alternate.is_some() {
p.print_soft_space();
} else {
p.print_soft_newline();
}
}
stmt if wrap_to_avoid_ambiguous_else(stmt) => {
p.print_soft_space();
p.print_block_start(stmt.span().start);
stmt.gen(p, ctx);
p.needs_semicolon = false;
p.print_block_end(stmt.span().end);
if if_stmt.alternate.is_some() {
p.print_soft_space();
} else {
p.print_soft_newline();
}
}
stmt => p.print_body(stmt, false, ctx),
}
if let Some(alternate) = if_stmt.alternate.as_ref() {
p.print_semicolon_if_needed();
p.print_space_before_identifier();
p.print_str(b"else");
match alternate {
Statement::BlockStatement(block) => {
p.print_soft_space();
p.print_block_statement(block, ctx);
p.print_soft_newline();
}
Statement::IfStatement(if_stmt) => {
p.print_hard_space();
print_if(if_stmt, p, ctx);
}
stmt => p.print_body(stmt, true, ctx),
}
}
}
fn wrap_to_avoid_ambiguous_else(stmt: &Statement) -> bool {
let mut current = stmt;
loop {
current = match current {
Statement::IfStatement(if_stmt) => {
if let Some(stmt) = &if_stmt.alternate {
stmt
} else {
return true;
}
}
Statement::ForStatement(for_stmt) => &for_stmt.body,
Statement::ForOfStatement(for_of_stmt) => &for_of_stmt.body,
Statement::ForInStatement(for_in_stmt) => &for_in_stmt.body,
Statement::WhileStatement(while_stmt) => &while_stmt.body,
Statement::WithStatement(with_stmt) => &with_stmt.body,
Statement::LabeledStatement(labeled_stmt) => &labeled_stmt.body,
_ => return false,
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for BlockStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_indent();
p.print_block_statement(self, ctx);
p.print_soft_newline();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ForStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"for");
p.print_soft_space();
p.print(b'(');
if let Some(init) = self.init.as_ref() {
let ctx = Context::empty();
match init {
ForStatementInit::UsingDeclaration(decl) => decl.gen(p, ctx),
match_expression!(ForStatementInit) => {
init.to_expression().gen_expr(p, Precedence::lowest(), ctx);
}
ForStatementInit::VariableDeclaration(var) => var.gen(p, ctx),
}
}
p.print_semicolon();
if let Some(test) = self.test.as_ref() {
p.print_soft_space();
p.print_expression(test);
}
p.print_semicolon();
if let Some(update) = self.update.as_ref() {
p.print_soft_space();
p.print_expression(update);
}
p.print(b')');
p.print_body(&self.body, false, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ForInStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"for");
p.print_soft_space();
p.print(b'(');
self.left.gen(p, ctx);
p.print_soft_space();
p.print_space_before_identifier();
p.print_str(b"in");
p.print_hard_space();
p.print_expression(&self.right);
p.print(b')');
p.print_body(&self.body, false, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ForOfStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"for");
p.print_soft_space();
if self.r#await {
p.print_str(b" await");
}
p.print(b'(');
self.left.gen(p, ctx);
p.print_soft_space();
p.print_space_before_identifier();
p.print_str(b"of ");
self.right.gen_expr(p, Precedence::Assign, Context::default());
p.print(b')');
p.print_body(&self.body, false, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ForStatementLeft<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
ForStatementLeft::UsingDeclaration(var) => var.gen(p, ctx),
ForStatementLeft::VariableDeclaration(var) => var.gen(p, ctx),
ForStatementLeft::AssignmentTargetIdentifier(identifier) => {
let wrap = identifier.name == "async";
p.wrap(wrap, |p| self.to_assignment_target().gen(p, ctx));
}
match_assignment_target!(ForStatementLeft) => {
p.wrap(false, |p| self.to_assignment_target().gen(p, ctx));
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for WhileStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"while");
p.print_soft_space();
p.print(b'(');
p.print_expression(&self.test);
p.print(b')');
p.print_body(&self.body, false, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for DoWhileStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"do ");
if let Statement::BlockStatement(block) = &self.body {
p.print_block_statement(block, ctx);
p.print_soft_space();
} else {
p.print_soft_newline();
p.indent();
self.body.gen(p, ctx);
p.print_semicolon_if_needed();
p.dedent();
p.print_indent();
}
p.print_str(b"while");
p.print_soft_space();
p.print(b'(');
p.print_expression(&self.test);
p.print(b')');
p.print_semicolon_after_statement();
}
}
impl<const MINIFY: bool> Gen<MINIFY> for EmptyStatement {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_semicolon();
p.print_soft_newline();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ContinueStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"continue");
if let Some(label) = &self.label {
p.print_hard_space();
label.gen(p, ctx);
}
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for BreakStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"break");
if let Some(label) = &self.label {
p.print_hard_space();
label.gen(p, ctx);
}
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for SwitchStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"switch");
p.print_soft_space();
p.print(b'(');
p.print_expression(&self.discriminant);
p.print(b')');
p.print_soft_space();
p.print_curly_braces(self.span, self.cases.is_empty(), |p| {
for case in &self.cases {
p.add_source_mapping(case.span.start);
case.gen(p, ctx);
}
});
p.print_soft_newline();
p.needs_semicolon = false;
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for SwitchCase<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_semicolon_if_needed();
p.print_indent();
match &self.test {
Some(test) => {
p.print_str(b"case ");
p.print_expression(test);
}
None => p.print_str(b"default"),
}
p.print_colon();
if self.consequent.len() == 1 {
p.print_body(&self.consequent[0], false, ctx);
return;
}
p.print_soft_newline();
p.indent();
for item in &self.consequent {
p.print_semicolon_if_needed();
item.gen(p, ctx);
}
p.dedent();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ReturnStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"return");
if let Some(arg) = &self.argument {
p.print_hard_space();
p.print_expression(arg);
}
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for LabeledStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if !MINIFY && (p.indent > 0 || p.print_next_indent_as_space) {
p.add_source_mapping(self.span.start);
p.print_indent();
}
p.print_space_before_identifier();
self.label.gen(p, ctx);
p.print_colon();
p.print_body(&self.body, false, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TryStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_space_before_identifier();
p.print_str(b"try");
p.print_soft_space();
p.print_block_statement(&self.block, ctx);
if let Some(handler) = &self.handler {
p.print_soft_space();
p.print_str(b"catch");
if let Some(param) = &handler.param {
p.print_soft_space();
p.print_str(b"(");
param.pattern.gen(p, ctx);
p.print_str(b")");
}
p.print_soft_space();
p.print_block_statement(&handler.body, ctx);
if self.finalizer.is_some() {
p.print_soft_newline();
}
}
if let Some(finalizer) = &self.finalizer {
p.print_soft_space();
p.print_str(b"finally");
p.print_soft_space();
p.print_block_statement(finalizer, ctx);
}
p.print_soft_newline();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ThrowStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"throw ");
p.print_expression(&self.argument);
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for WithStatement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"with");
p.print(b'(');
p.print_expression(&self.object);
p.print(b')');
p.print_body(&self.body, false, ctx);
}
}
impl<const MINIFY: bool> Gen<MINIFY> for DebuggerStatement {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"debugger");
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for UsingDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.is_await {
p.print_str(b"await");
p.print_soft_space();
}
p.print_str(b"using");
p.print_soft_space();
p.print_list(&self.declarations, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for VariableDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
if self.declare {
p.print_str(b"declare ");
}
if p.comment_options.preserve_annotate_comments
&& matches!(self.kind, VariableDeclarationKind::Const)
{
if let Some(declarator) = self.declarations.first() {
if let Some(ref init) = declarator.init {
if let Some(leading_annotate_comment) =
get_leading_annotate_comment(self.span.start, p)
{
p.move_comment(init.span().start, leading_annotate_comment);
}
}
}
}
p.print_str(match self.kind {
VariableDeclarationKind::Const => "const",
VariableDeclarationKind::Let => "let",
VariableDeclarationKind::Var => "var",
});
if !self.declarations.is_empty() {
p.print_hard_space();
}
p.print_list(&self.declarations, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for VariableDeclarator<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.id.gen(p, ctx);
if let Some(init) = &self.init {
p.print_soft_space();
p.print_equal();
p.print_soft_space();
init.gen_expr(p, Precedence::Assign, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Function<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
self.gen_comment(p, ctx);
let n = p.code_len();
let wrap = self.is_expression() && (p.start_of_stmt == n || p.start_of_default_export == n);
p.wrap(wrap, |p| {
if self.declare {
p.print_str(b"declare ");
}
if self.r#async {
p.print_str(b"async ");
}
p.print_str(b"function");
if self.generator {
p.print(b'*');
p.print_soft_space();
}
if let Some(id) = &self.id {
p.print_space_before_identifier();
id.gen(p, ctx);
}
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
p.print(b'(');
if let Some(this_param) = &self.this_param {
this_param.gen(p, ctx);
if !self.params.is_empty() || self.params.rest.is_some() {
p.print_str(b",");
}
p.print_soft_space();
}
self.params.gen(p, ctx);
p.print(b')');
if let Some(return_type) = &self.return_type {
p.print_str(b": ");
return_type.gen(p, ctx);
}
if let Some(body) = &self.body {
p.print_soft_space();
body.gen(p, ctx);
} else {
p.print_semicolon();
}
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for FunctionBody<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_curly_braces(self.span, self.is_empty(), |p| {
p.print_directives_and_statements(Some(&self.directives), &self.statements, ctx);
});
p.needs_semicolon = false;
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for FormalParameter<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.decorators.gen(p, ctx);
if let Some(accessibility) = self.accessibility {
accessibility.gen(p, ctx);
}
if self.readonly {
p.print_str(b"readonly ");
}
self.pattern.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for FormalParameters<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_list(&self.items, ctx);
if let Some(rest) = &self.rest {
if !self.items.is_empty() {
p.print_comma();
p.print_soft_space();
}
rest.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ImportDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"import ");
if self.import_kind.is_type() {
p.print_str(b"type ");
}
if let Some(specifiers) = &self.specifiers {
if specifiers.is_empty() {
p.print_str(b"{}");
p.print_soft_space();
p.print_str(b"from");
p.print_soft_space();
p.print(b'\'');
p.print_str(self.source.value.as_bytes());
p.print(b'\'');
if self.with_clause.is_some() {
p.print_hard_space();
}
self.with_clause.gen(p, ctx);
p.print_semicolon_after_statement();
return;
}
let mut in_block = false;
for (index, specifier) in specifiers.iter().enumerate() {
match specifier {
ImportDeclarationSpecifier::ImportDefaultSpecifier(spec) => {
if in_block {
p.print_soft_space();
p.print_str(b"},");
in_block = false;
} else if index != 0 {
p.print_comma();
p.print_soft_space();
}
spec.local.gen(p, ctx);
}
ImportDeclarationSpecifier::ImportNamespaceSpecifier(spec) => {
if in_block {
p.print_soft_space();
p.print_str(b"},");
in_block = false;
} else if index != 0 {
p.print_comma();
p.print_soft_space();
}
p.print_str(b"* as ");
spec.local.gen(p, ctx);
}
ImportDeclarationSpecifier::ImportSpecifier(spec) => {
if in_block {
p.print_comma();
p.print_soft_space();
} else {
if index != 0 {
p.print_comma();
p.print_soft_space();
}
in_block = true;
p.print(b'{');
p.print_soft_space();
}
if spec.import_kind.is_type() {
p.print_str(b"type ");
}
let imported_name = match &spec.imported {
ModuleExportName::IdentifierName(identifier) => {
identifier.gen(p, ctx);
identifier.name.as_bytes()
}
ModuleExportName::IdentifierReference(identifier) => {
identifier.gen(p, ctx);
identifier.name.as_bytes()
}
ModuleExportName::StringLiteral(literal) => {
literal.gen(p, ctx);
literal.value.as_bytes()
}
};
let local_name = spec.local.name.as_bytes();
if imported_name != local_name {
p.print_str(b" as ");
spec.local.gen(p, ctx);
}
}
}
}
if in_block {
p.print_soft_space();
p.print(b'}');
}
p.print_str(b" from ");
}
self.source.gen(p, ctx);
if self.with_clause.is_some() {
p.print_hard_space();
}
self.with_clause.gen(p, ctx);
p.add_source_mapping(self.span.end);
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Option<WithClause<'a>> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if let Some(with_clause) = self {
with_clause.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for WithClause<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
self.attributes_keyword.gen(p, ctx);
p.print_soft_space();
p.print_block_start(self.span.start);
p.print_sequence(&self.with_entries, ctx);
p.print_block_end(self.span.end);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ImportAttribute<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match &self.key {
ImportAttributeKey::Identifier(identifier) => {
p.print_str(identifier.name.as_bytes());
}
ImportAttributeKey::StringLiteral(literal) => literal.gen(p, ctx),
};
p.print_colon();
p.print_soft_space();
self.value.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ExportNamedDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
if p.comment_options.preserve_annotate_comments {
match &self.declaration {
Some(Declaration::FunctionDeclaration(_)) => {
gen_comment(self.span.start, p);
}
Some(Declaration::VariableDeclaration(var_decl))
if matches!(var_decl.kind, VariableDeclarationKind::Const) =>
{
if let Some(declarator) = var_decl.declarations.first() {
if let Some(ref init) = declarator.init {
if let Some(leading_annotate_comment) =
get_leading_annotate_comment(self.span.start, p)
{
p.move_comment(init.span().start, leading_annotate_comment);
}
}
}
}
_ => {}
};
}
p.print_str(b"export ");
if self.export_kind.is_type() {
p.print_str(b"type ");
}
match &self.declaration {
Some(decl) => {
match decl {
Declaration::VariableDeclaration(decl) => decl.gen(p, ctx),
Declaration::FunctionDeclaration(decl) => decl.gen(p, ctx),
Declaration::ClassDeclaration(decl) => decl.gen(p, ctx),
Declaration::UsingDeclaration(declaration) => declaration.gen(p, ctx),
Declaration::TSModuleDeclaration(decl) => decl.gen(p, ctx),
Declaration::TSTypeAliasDeclaration(decl) => decl.gen(p, ctx),
Declaration::TSInterfaceDeclaration(decl) => decl.gen(p, ctx),
Declaration::TSEnumDeclaration(decl) => decl.gen(p, ctx),
Declaration::TSImportEqualsDeclaration(decl) => decl.gen(p, ctx),
}
if matches!(
decl,
Declaration::VariableDeclaration(_)
| Declaration::UsingDeclaration(_)
| Declaration::TSTypeAliasDeclaration(_)
| Declaration::TSImportEqualsDeclaration(_)
) {
p.print_semicolon_after_statement();
} else {
p.print_soft_newline();
p.needs_semicolon = false;
}
}
None => {
p.print(b'{');
if !self.specifiers.is_empty() {
p.print_soft_space();
p.print_list(&self.specifiers, ctx);
p.print_soft_space();
}
p.print(b'}');
if let Some(source) = &self.source {
p.print_soft_space();
p.print_str(b"from");
p.print_soft_space();
source.gen(p, ctx);
}
p.print_semicolon_after_statement();
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSExportAssignment<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_indent();
p.print_str(b"export = ");
self.expression.gen_expr(p, Precedence::lowest(), ctx);
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSNamespaceExportDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_indent();
p.print_str(b"export as namespace ");
self.id.gen(p, ctx);
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ExportSpecifier<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.export_kind.is_type() {
p.print_str(b"type ");
}
self.local.gen(p, ctx);
if self.local.name() != self.exported.name() {
p.print_str(b" as ");
self.exported.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ModuleExportName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::IdentifierName(identifier) => p.print_str(identifier.name.as_bytes()),
Self::IdentifierReference(identifier) => p.print_str(identifier.name.as_bytes()),
Self::StringLiteral(literal) => literal.gen(p, ctx),
};
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ExportAllDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"export ");
if self.export_kind.is_type() {
p.print_str(b"type ");
}
p.print(b'*');
if let Some(exported) = &self.exported {
p.print_str(b" as ");
exported.gen(p, ctx);
}
p.print_str(b" from ");
self.source.gen(p, ctx);
if self.with_clause.is_some() {
p.print_hard_space();
}
self.with_clause.gen(p, ctx);
p.print_semicolon_after_statement();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ExportDefaultDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_indent();
p.print_str(b"export default ");
self.declaration.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ExportDefaultDeclarationKind<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
match_expression!(Self) => {
p.start_of_default_export = p.code_len();
self.to_expression().gen_expr(p, Precedence::Assign, Context::default());
p.print_semicolon_after_statement();
}
Self::FunctionDeclaration(fun) => fun.gen(p, ctx),
Self::ClassDeclaration(class) => {
class.gen(p, ctx);
p.print_soft_newline();
}
Self::TSInterfaceDeclaration(interface) => interface.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for Expression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
match self {
Self::BooleanLiteral(lit) => lit.gen(p, ctx),
Self::NullLiteral(lit) => lit.gen(p, ctx),
Self::NumericLiteral(lit) => lit.gen(p, ctx),
Self::BigIntLiteral(lit) => lit.gen(p, ctx),
Self::RegExpLiteral(lit) => lit.gen(p, ctx),
Self::StringLiteral(lit) => lit.gen(p, ctx),
Self::Identifier(ident) => ident.gen(p, ctx),
Self::ThisExpression(expr) => expr.gen(p, ctx),
match_member_expression!(Self) => {
self.to_member_expression().gen_expr(p, precedence, ctx);
}
Self::CallExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::ArrayExpression(expr) => expr.gen(p, ctx),
Self::ObjectExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::FunctionExpression(expr) => expr.gen(p, ctx),
Self::ArrowFunctionExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::YieldExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::UpdateExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::UnaryExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::BinaryExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::PrivateInExpression(expr) => expr.gen(p, ctx),
Self::LogicalExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::ConditionalExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::AssignmentExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::SequenceExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::ImportExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::TemplateLiteral(literal) => literal.gen(p, ctx),
Self::TaggedTemplateExpression(expr) => expr.gen(p, ctx),
Self::Super(sup) => sup.gen(p, ctx),
Self::AwaitExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::ChainExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::NewExpression(expr) => expr.gen_expr(p, precedence, ctx),
Self::MetaProperty(expr) => expr.gen(p, ctx),
Self::ClassExpression(expr) => expr.gen(p, ctx),
Self::JSXElement(el) => el.gen(p, ctx),
Self::JSXFragment(fragment) => fragment.gen(p, ctx),
Self::ParenthesizedExpression(e) => e.gen_expr(p, precedence, ctx),
Self::TSAsExpression(e) => e.gen_expr(p, precedence, ctx),
Self::TSSatisfiesExpression(e) => {
e.expression.gen_expr(p, precedence, ctx);
p.print_str(b" satisfies ");
e.type_annotation.gen(p, ctx);
}
Self::TSTypeAssertion(e) => e.gen_expr(p, precedence, ctx),
Self::TSNonNullExpression(e) => e.expression.gen_expr(p, precedence, ctx),
Self::TSInstantiationExpression(e) => e.expression.gen_expr(p, precedence, ctx),
}
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for TSAsExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
self.expression.gen_expr(p, precedence, ctx);
p.print_str(b" as ");
self.type_annotation.gen(p, ctx);
}
}
impl<const MINIFY: bool> GenComment<MINIFY> for ArrowFunctionExpression<'_> {
fn gen_comment(&self, codegen: &mut Codegen<{ MINIFY }>, _ctx: Context) {
gen_comment(self.span.start, codegen);
}
}
impl<const MINIFY: bool> GenComment<MINIFY> for Function<'_> {
fn gen_comment(&self, codegen: &mut Codegen<{ MINIFY }>, _ctx: Context) {
gen_comment(self.span.start, codegen);
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for ParenthesizedExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.print_str(b"(");
self.expression.gen_expr(p, precedence, ctx);
p.print_str(b")");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for IdentifierReference<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping_for_name(self.span, &self.name);
p.print_str(self.name.as_bytes());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for IdentifierName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(self.name.as_bytes());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for BindingIdentifier<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.print_symbol(self.span, self.symbol_id.get(), self.name.as_str());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for LabelIdentifier<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping_for_name(self.span, &self.name);
p.print_str(self.name.as_bytes());
}
}
impl<const MINIFY: bool> Gen<MINIFY> for BooleanLiteral {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(self.as_str().as_bytes());
}
}
impl<const MINIFY: bool> Gen<MINIFY> for NullLiteral {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.print_space_before_identifier();
p.add_source_mapping(self.span.start);
p.print_str(b"null");
}
}
fn need_space_before_dot<const MINIFY: bool>(bytes: &[u8], p: &mut Codegen<{ MINIFY }>) {
if !bytes.iter().any(|&b| matches!(b, b'.' | b'e' | b'x')) {
p.need_space_before_dot = p.code_len();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for NumericLiteral<'a> {
#[allow(clippy::cast_sign_loss, clippy::cast_possible_truncation)]
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
if self.value != f64::INFINITY && (MINIFY || self.raw.is_empty()) {
p.print_space_before_identifier();
let abs_value = self.value.abs();
if self.value.is_sign_negative() {
p.print_space_before_operator(Operator::Unary(UnaryOperator::UnaryNegation));
p.print_str(b"-");
}
let result = if self.base == NumberBase::Float {
print_non_negative_float(abs_value, p)
} else {
let value = abs_value as u64;
if value < 1000 {
format!("{value}")
} else if (1_000_000_000_000..=0xFFFF_FFFF_FFFF_F800).contains(&value) {
let hex = format!("{value:#x}");
let result = print_non_negative_float(abs_value, p);
if hex.len() < result.len() {
hex
} else {
result
}
} else {
print_non_negative_float(abs_value, p)
}
};
let bytes = result.as_bytes();
p.print_str(bytes);
need_space_before_dot(bytes, p);
} else {
let bytes = self.raw.as_bytes();
p.print_str(bytes);
need_space_before_dot(bytes, p);
};
}
}
fn print_non_negative_float<const MINIFY: bool>(value: f64, _p: &Codegen<{ MINIFY }>) -> String {
let mut result = value.to_string();
let chars = result.as_bytes();
let len = chars.len();
let dot = chars.iter().position(|&c| c == b'.');
let u8_to_string = |num: &[u8]| {
#[allow(unsafe_code)]
unsafe {
String::from_utf8_unchecked(num.to_vec())
}
};
if dot == Some(1) && chars[0] == b'0' {
let stripped_result = &chars[1..];
let after_dot = 1;
if stripped_result[after_dot] == b'0' {
let mut i = after_dot + 1;
while stripped_result[i] == b'0' {
i += 1;
}
let remaining = &stripped_result[i..];
let exponent = format!("-{}", remaining.len() - after_dot + i);
if stripped_result.len() > remaining.len() + 1 + exponent.len() {
result = format!("{}e{}", u8_to_string(remaining), exponent);
} else {
result = u8_to_string(stripped_result);
}
} else {
result = u8_to_string(stripped_result);
}
} else if chars[len - 1] == b'0' {
let mut i = len - 1;
while i > 0 && chars[i - 1] == b'0' {
i -= 1;
}
let remaining = &chars[0..i];
let exponent = format!("{}", chars.len() - i);
if chars.len() > remaining.len() + 1 + exponent.len() {
result = format!("{}e{}", u8_to_string(remaining), exponent);
} else {
result = u8_to_string(chars);
}
}
result
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for BigIntLiteral<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(self.raw.as_bytes());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for RegExpLiteral<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
let last = p.peek_nth(0);
if Some('/') == last
|| (Some('<') == last
&& self.regex.pattern.as_str().to_lowercase().starts_with("script"))
{
p.print_hard_space();
}
p.print(b'/');
p.print_str(self.regex.pattern.as_bytes());
p.print(b'/');
p.print_str(self.regex.flags.to_string().as_bytes());
p.prev_reg_exp_end = p.code().len();
}
}
fn print_unquoted_str<const MINIFY: bool>(s: &str, quote: char, p: &mut Codegen<{ MINIFY }>) {
let mut chars = s.chars().peekable();
while let Some(c) = chars.next() {
match c {
'\x00' => {
if chars.peek().is_some_and(|&next| next.is_ascii_digit()) {
p.print_str(b"\\x00");
} else {
p.print_str(b"\\0");
}
}
'\x07' => {
p.print_str(b"\\x07");
}
'\u{8}' => {
p.print_str(b"\\b");
}
'\u{b}' => {
p.print_str(b"\\v");
}
'\u{c}' => {
p.print_str(b"\\f");
}
'\n' => {
p.print_str(b"\\n");
}
'\r' => {
p.print_str(b"\\r");
}
'\x1B' => {
p.print_str(b"\\x1B");
}
'\\' => {
p.print_str(b"\\\\");
}
'\'' => {
if quote == '\'' {
p.print_str(b"\\'");
} else {
p.print_str(b"'");
}
}
'\"' => {
if quote == '"' {
p.print_str(b"\\\"");
} else {
p.print_str(b"\"");
}
}
'`' => {
if quote == '`' {
p.print_str(b"\\`");
} else {
p.print_str(b"`");
}
}
'$' => {
if chars.peek().is_some_and(|&next| next == '{') {
p.print_str(b"\\$");
} else {
p.print_str(b"$");
}
}
LS => p.print_str(b"\\u2028"),
PS => p.print_str(b"\\u2029"),
'\u{a0}' => {
p.print_str(b"\\xA0");
}
_ => {
p.print_str(c.encode_utf8([0; 4].as_mut()).as_bytes());
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for StringLiteral<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
let s = self.value.as_str();
p.wrap_quote(s, |p, quote| {
print_unquoted_str(s, quote, p);
});
}
}
impl<const MINIFY: bool> Gen<MINIFY> for ThisExpression {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_space_before_identifier();
p.print_str(b"this");
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for MemberExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.wrap(precedence > self.precedence(), |p| match self {
Self::ComputedMemberExpression(expr) => {
expr.gen_expr(p, self.precedence(), ctx.and_in(true));
}
Self::StaticMemberExpression(expr) => expr.gen_expr(p, self.precedence(), ctx),
Self::PrivateFieldExpression(expr) => expr.gen_expr(p, self.precedence(), ctx),
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for ComputedMemberExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, _precedence: Precedence, ctx: Context) {
self.object.gen_expr(p, Precedence::Postfix, ctx);
if self.optional {
p.print_str(b"?.");
}
p.print(b'[');
self.expression.gen_expr(p, Precedence::lowest(), ctx);
p.print(b']');
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for StaticMemberExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, _precedence: Precedence, ctx: Context) {
self.object.gen_expr(p, Precedence::Postfix, ctx);
if self.optional {
p.print(b'?');
} else if p.need_space_before_dot == p.code_len() {
p.print_hard_space();
}
p.print(b'.');
self.property.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for PrivateFieldExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, _precedence: Precedence, ctx: Context) {
self.object.gen_expr(p, Precedence::Postfix, ctx);
if self.optional {
p.print_str(b"?");
}
p.print(b'.');
self.field.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for CallExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
let wrap = precedence > self.precedence() || ctx.has_forbid_call();
let ctx = ctx.and_forbid_call(false);
p.wrap(wrap, |p| {
p.add_source_mapping(self.span.start);
self.callee.gen_expr(p, self.precedence(), ctx);
if self.optional {
p.print_str(b"?.");
}
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
p.print(b'(');
p.print_list(&self.arguments, ctx);
p.print(b')');
p.add_source_mapping(self.span.end);
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Argument<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::SpreadElement(elem) => elem.gen(p, ctx),
match_expression!(Self) => {
self.to_expression().gen_expr(p, Precedence::Assign, Context::default());
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ArrayExpressionElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
match_expression!(Self) => {
self.to_expression().gen_expr(p, Precedence::Assign, Context::default());
}
Self::SpreadElement(elem) => elem.gen(p, ctx),
Self::Elision(_span) => {}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for SpreadElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_ellipsis();
self.argument.gen_expr(p, Precedence::Assign, Context::default());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ArrayExpression<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print(b'[');
p.print_list(&self.elements, ctx);
if self.trailing_comma.is_some() {
p.print_comma();
}
p.print(b']');
p.add_source_mapping(self.span.end);
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for ObjectExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, _precedence: Precedence, ctx: Context) {
let n = p.code_len();
p.wrap(p.start_of_stmt == n || p.start_of_arrow_expr == n, |p| {
let single_line = self.properties.len() <= 1;
p.print_curly_braces(self.span, single_line, |p| {
for (index, item) in self.properties.iter().enumerate() {
if index != 0 {
p.print_comma();
p.print_soft_newline();
}
if !single_line {
p.print_indent();
}
item.gen(p, ctx);
}
if !single_line {
p.print_soft_newline();
}
});
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ObjectPropertyKind<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::ObjectProperty(prop) => prop.gen(p, ctx),
Self::SpreadProperty(elem) => elem.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ObjectProperty<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if let Expression::FunctionExpression(func) = &self.value {
p.add_source_mapping(self.span.start);
let is_accessor = match &self.kind {
PropertyKind::Init => false,
PropertyKind::Get => {
p.add_source_mapping(self.span.start);
p.print_str(b"get ");
true
}
PropertyKind::Set => {
p.add_source_mapping(self.span.start);
p.print_str(b"set ");
true
}
};
if self.method || is_accessor {
if func.r#async {
p.print_str(b"async ");
}
if func.generator {
p.print_str(b"*");
}
if self.computed {
p.print(b'[');
}
self.key.gen(p, ctx);
if self.computed {
p.print(b']');
}
if let Some(type_parameters) = &func.type_parameters {
type_parameters.gen(p, ctx);
}
p.print(b'(');
func.params.gen(p, ctx);
p.print(b')');
if let Some(body) = &func.body {
p.print_soft_space();
body.gen(p, ctx);
}
return;
}
}
if self.computed {
p.print(b'[');
}
if !self.shorthand {
self.key.gen(p, ctx);
}
if self.computed {
p.print(b']');
}
if !self.shorthand {
p.print_colon();
p.print_soft_space();
}
self.value.gen_expr(p, Precedence::Assign, Context::default());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for PropertyKey<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::StaticIdentifier(ident) => ident.gen(p, ctx),
Self::PrivateIdentifier(ident) => ident.gen(p, ctx),
match_expression!(Self) => {
self.to_expression().gen_expr(p, Precedence::Assign, Context::default());
}
}
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for ArrowFunctionExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.wrap(precedence > Precedence::Assign, |p| {
self.gen_comment(p, ctx);
if self.r#async {
p.add_source_mapping(self.span.start);
p.print_str(b"async");
}
if self.r#async {
p.print_hard_space();
}
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
p.add_source_mapping(self.span.start);
p.print(b'(');
self.params.gen(p, ctx);
p.print(b')');
if let Some(return_type) = &self.return_type {
p.print_str(b":");
p.print_soft_space();
return_type.gen(p, ctx);
}
p.print_soft_space();
p.print_str(b"=>");
p.print_soft_space();
if self.expression {
if let Statement::ExpressionStatement(stmt) = &self.body.statements[0] {
p.start_of_arrow_expr = p.code_len();
stmt.expression.gen_expr(p, Precedence::Assign, ctx);
}
} else {
self.body.gen(p, ctx);
}
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for YieldExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.wrap(precedence >= self.precedence(), |p| {
p.add_source_mapping(self.span.start);
p.print_space_before_identifier();
p.print_str(b"yield");
if self.delegate {
p.print(b'*');
p.print_soft_space();
}
if let Some(argument) = self.argument.as_ref() {
if !self.delegate {
p.print_hard_space();
}
argument.gen_expr(p, Precedence::Assign, ctx);
}
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for UpdateExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
let operator = self.operator.as_str().as_bytes();
p.wrap(precedence > self.precedence(), |p| {
if self.prefix {
p.add_source_mapping(self.span.start);
p.print_space_before_operator(self.operator.into());
p.print_str(operator);
p.prev_op = Some(self.operator.into());
p.prev_op_end = p.code().len();
self.argument.gen_expr(p, Precedence::Prefix, ctx);
} else {
p.print_space_before_operator(self.operator.into());
self.argument.gen_expr(p, Precedence::Postfix, ctx);
p.print_str(operator);
p.prev_op = Some(self.operator.into());
p.prev_op_end = p.code().len();
}
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for UnaryExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.wrap(precedence > self.precedence() || precedence == Precedence::Exponential, |p| {
let operator = self.operator.as_str().as_bytes();
if self.operator.is_keyword() {
p.print_space_before_identifier();
p.print_str(operator);
p.print_hard_space();
} else {
p.print_space_before_operator(self.operator.into());
p.print_str(operator);
p.prev_op = Some(self.operator.into());
p.prev_op_end = p.code().len();
}
self.argument.gen_expr(p, Precedence::Prefix, ctx);
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for BinaryExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
let wrap_in = self.operator == BinaryOperator::In && !ctx.has_in();
let wrap = precedence >= self.precedence() || wrap_in;
p.wrap(wrap, |p| {
let left_precedence = if self.precedence().is_right_associative() {
self.precedence()
} else {
self.operator.lower_precedence()
};
self.left.gen_expr(p, left_precedence, ctx);
if self.operator.is_keyword() {
p.print_space_before_identifier();
} else {
p.print_soft_space();
}
self.operator.gen(p, ctx);
let right_precedence = if self.precedence().is_left_associative() {
self.precedence()
} else {
self.operator.lower_precedence()
};
self.right.gen_expr(p, right_precedence, ctx.union_in_if(wrap));
});
}
}
impl<const MINIFY: bool> Gen<MINIFY> for BinaryOperator {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
let operator = self.as_str().as_bytes();
if self.is_keyword() {
p.print_str(operator);
p.print_hard_space();
} else {
let op: Operator = (*self).into();
p.print_space_before_operator(op);
p.print_str(operator);
p.print_soft_space();
p.prev_op = Some(op);
p.prev_op_end = p.code().len();
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for PrivateInExpression<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.left.gen(p, ctx);
p.print_str(b" in ");
self.right.gen_expr(p, Precedence::Shift, Context::default());
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for LogicalExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
let mixed = matches!(
(precedence, self.precedence()),
(Precedence::Coalesce, Precedence::LogicalAnd | Precedence::LogicalOr)
);
p.wrap(mixed || (precedence > self.precedence()), |p| {
self.left.gen_expr(p, self.precedence(), ctx);
p.print_soft_space();
p.print_str(self.operator.as_str().as_bytes());
p.print_soft_space();
self.right.gen_expr(p, self.precedence(), ctx);
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for ConditionalExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
let wrap = precedence > self.precedence();
p.wrap(wrap, |p| {
self.test.gen_expr(p, self.precedence(), ctx);
p.print_soft_space();
p.print(b'?');
p.print_soft_space();
self.consequent.gen_expr(p, Precedence::Assign, ctx.and_in(true));
p.print_soft_space();
p.print_colon();
p.print_soft_space();
self.alternate.gen_expr(p, Precedence::Assign, ctx.union_in_if(wrap));
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for AssignmentExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
let n = p.code_len();
let identifier_is_keyword = match &self.left {
AssignmentTarget::AssignmentTargetIdentifier(target) => {
is_reserved_keyword_or_global_object(target.name.as_str())
}
AssignmentTarget::ComputedMemberExpression(expression) => match &expression.object {
Expression::Identifier(ident) => {
is_reserved_keyword_or_global_object(ident.name.as_str())
}
_ => false,
},
AssignmentTarget::StaticMemberExpression(expression) => {
is_reserved_keyword_or_global_object(expression.property.name.as_str())
}
AssignmentTarget::PrivateFieldExpression(expression) => {
is_reserved_keyword_or_global_object(expression.field.name.as_str())
}
_ => false,
};
let wrap = ((p.start_of_stmt == n || p.start_of_arrow_expr == n)
&& matches!(self.left, AssignmentTarget::ObjectAssignmentTarget(_)))
|| identifier_is_keyword;
p.wrap(wrap || precedence > self.precedence(), |p| {
self.left.gen(p, ctx);
p.print_soft_space();
p.print_str(self.operator.as_str().as_bytes());
p.print_soft_space();
self.right.gen_expr(p, Precedence::Assign, ctx);
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTarget<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
match_simple_assignment_target!(Self) => {
self.to_simple_assignment_target().gen_expr(
p,
Precedence::Assign,
Context::default(),
);
}
match_assignment_target_pattern!(Self) => {
self.to_assignment_target_pattern().gen(p, ctx);
}
}
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for SimpleAssignmentTarget<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
match self {
Self::AssignmentTargetIdentifier(ident) => ident.gen(p, ctx),
match_member_expression!(Self) => {
self.to_member_expression().gen_expr(p, precedence, ctx);
}
Self::TSAsExpression(e) => e.gen_expr(p, precedence, ctx),
Self::TSSatisfiesExpression(e) => e.expression.gen_expr(p, precedence, ctx),
Self::TSNonNullExpression(e) => e.expression.gen_expr(p, precedence, ctx),
Self::TSTypeAssertion(e) => e.gen_expr(p, precedence, ctx),
Self::TSInstantiationExpression(e) => e.expression.gen_expr(p, precedence, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTargetPattern<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::ArrayAssignmentTarget(target) => target.gen(p, ctx),
Self::ObjectAssignmentTarget(target) => target.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ArrayAssignmentTarget<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print(b'[');
p.print_list(&self.elements, ctx);
if let Some(target) = &self.rest {
if !self.elements.is_empty() {
p.print_comma();
}
p.add_source_mapping(self.span.start);
target.gen(p, ctx);
}
if self.trailing_comma.is_some() {
p.print_comma();
}
p.print(b']');
p.add_source_mapping(self.span.end);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Option<AssignmentTargetMaybeDefault<'a>> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if let Some(arg) = self {
arg.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ObjectAssignmentTarget<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print(b'{');
p.print_list(&self.properties, ctx);
if let Some(target) = &self.rest {
if !self.properties.is_empty() {
p.print_comma();
}
p.add_source_mapping(self.span.start);
target.gen(p, ctx);
}
p.print(b'}');
p.add_source_mapping(self.span.end);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTargetMaybeDefault<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
match_assignment_target!(Self) => self.to_assignment_target().gen(p, ctx),
Self::AssignmentTargetWithDefault(target) => target.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTargetWithDefault<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.binding.gen(p, ctx);
p.print_soft_space();
p.print_equal();
p.print_soft_space();
self.init.gen_expr(p, Precedence::Assign, Context::default());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTargetProperty<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::AssignmentTargetPropertyIdentifier(ident) => ident.gen(p, ctx),
Self::AssignmentTargetPropertyProperty(prop) => prop.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTargetPropertyIdentifier<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.binding.gen(p, ctx);
if let Some(expr) = &self.init {
p.print_soft_space();
p.print_equal();
p.print_soft_space();
expr.gen_expr(p, Precedence::Assign, Context::default());
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTargetPropertyProperty<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match &self.name {
PropertyKey::StaticIdentifier(ident) => {
ident.gen(p, ctx);
}
PropertyKey::PrivateIdentifier(ident) => {
ident.gen(p, ctx);
}
key @ match_expression!(PropertyKey) => {
p.print(b'[');
key.to_expression().gen_expr(p, Precedence::Assign, Context::default());
p.print(b']');
}
}
p.print_colon();
p.print_soft_space();
self.binding.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentTargetRest<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_ellipsis();
self.target.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for SequenceExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, _ctx: Context) {
p.wrap(precedence > self.precedence(), |p| {
p.print_expressions(&self.expressions, Precedence::Assign, Context::default());
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for ImportExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
let wrap = precedence > self.precedence() || ctx.has_forbid_call();
let ctx = ctx.and_forbid_call(false);
p.wrap(wrap, |p| {
p.add_source_mapping(self.span.start);
p.print_str(b"import(");
self.source.gen_expr(p, Precedence::Assign, ctx);
if !self.arguments.is_empty() {
p.print_comma();
p.print_expressions(&self.arguments, Precedence::Assign, ctx);
}
p.print(b')');
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TemplateLiteral<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.print(b'`');
let mut expressions = self.expressions.iter();
for quasi in &self.quasis {
p.add_source_mapping(quasi.span.start);
p.print_str(quasi.value.raw.as_bytes());
if let Some(expr) = expressions.next() {
p.print_str(b"${");
p.print_expression(expr);
p.print(b'}');
}
}
p.print(b'`');
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TaggedTemplateExpression<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
self.tag.gen_expr(p, Precedence::Postfix, Context::default());
self.quasi.gen(p, ctx);
}
}
impl<const MINIFY: bool> Gen<MINIFY> for Super {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(b"super");
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for AwaitExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.wrap(precedence > self.precedence(), |p| {
p.add_source_mapping(self.span.start);
p.print_str(b"await ");
self.argument.gen_expr(p, self.precedence(), ctx);
});
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for ChainExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
match &self.expression {
ChainElement::CallExpression(expr) => expr.gen_expr(p, precedence, ctx),
match_member_expression!(ChainElement) => {
self.expression.to_member_expression().gen_expr(p, precedence, ctx);
}
}
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for NewExpression<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.wrap(precedence > self.precedence(), |p| {
p.add_source_mapping(self.span.start);
p.print_str(b"new ");
self.callee.gen_expr(p, Precedence::NewWithoutArgs, ctx.and_forbid_call(true));
p.print(b'(');
p.print_list(&self.arguments, ctx);
p.print(b')');
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for MetaProperty<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
self.meta.gen(p, ctx);
p.print(b'.');
self.property.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Class<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
if self.declare {
p.print_str(b"declare ");
}
if self.r#abstract {
p.print_str(b"abstract ");
}
let n = p.code_len();
let wrap = self.is_expression() && (p.start_of_stmt == n || p.start_of_default_export == n);
p.wrap(wrap, |p| {
self.decorators.gen(p, ctx);
p.print_str(b"class");
if let Some(id) = &self.id {
p.print_hard_space();
id.gen(p, ctx);
if let Some(type_parameters) = self.type_parameters.as_ref() {
type_parameters.gen(p, ctx);
}
}
if let Some(super_class) = self.super_class.as_ref() {
p.print_str(b" extends ");
super_class.gen_expr(p, Precedence::Call, Context::default());
if let Some(super_type_parameters) = &self.super_type_parameters {
super_type_parameters.gen(p, ctx);
}
}
if let Some(implements) = self.implements.as_ref() {
p.print_str(b" implements ");
p.print_list(implements, ctx);
}
p.print_soft_space();
self.body.gen(p, ctx);
p.needs_semicolon = false;
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ClassBody<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_curly_braces(self.span, self.body.is_empty(), |p| {
for item in &self.body {
p.print_semicolon_if_needed();
p.print_indent();
item.gen(p, ctx);
}
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ClassElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::StaticBlock(elem) => {
elem.gen(p, ctx);
p.print_soft_newline();
}
Self::MethodDefinition(elem) => {
elem.gen(p, ctx);
p.print_soft_newline();
}
Self::PropertyDefinition(elem) => {
elem.gen(p, ctx);
p.print_semicolon_after_statement();
}
Self::AccessorProperty(elem) => {
elem.gen(p, ctx);
p.print_semicolon_after_statement();
}
Self::TSIndexSignature(elem) => {
elem.gen(p, ctx);
p.print_semicolon_after_statement();
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXIdentifier<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping_for_name(self.span, &self.name);
p.print_str(self.name.as_bytes());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXMemberExpressionObject<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::Identifier(ident) => ident.gen(p, ctx),
Self::MemberExpression(member_expr) => member_expr.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXMemberExpression<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.object.gen(p, ctx);
p.print(b'.');
self.property.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXElementName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::Identifier(identifier) => identifier.gen(p, ctx),
Self::NamespacedName(namespaced_name) => namespaced_name.gen(p, ctx),
Self::MemberExpression(member_expr) => member_expr.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXNamespacedName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.namespace.gen(p, ctx);
p.print_colon();
self.property.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXAttributeName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::Identifier(ident) => ident.gen(p, ctx),
Self::NamespacedName(namespaced_name) => namespaced_name.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXAttribute<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.name.gen(p, ctx);
if let Some(value) = &self.value {
p.print_equal();
value.gen(p, ctx);
}
}
}
impl<const MINIFY: bool> Gen<MINIFY> for JSXEmptyExpression {
fn gen(&self, _: &mut Codegen<{ MINIFY }>, _ctx: Context) {}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXExpression<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
match_expression!(Self) => p.print_expression(self.to_expression()),
Self::EmptyExpression(expr) => expr.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXExpressionContainer<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print(b'{');
self.expression.gen(p, ctx);
p.print(b'}');
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXAttributeValue<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::Fragment(fragment) => fragment.gen(p, ctx),
Self::Element(el) => el.gen(p, ctx),
Self::StringLiteral(lit) => {
p.print(b'"');
print_unquoted_str(&lit.value, '"', p);
p.print(b'"');
}
Self::ExpressionContainer(expr_container) => expr_container.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXSpreadAttribute<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.print_str(b"{...");
self.argument.gen_expr(p, Precedence::Assign, Context::default());
p.print(b'}');
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXAttributeItem<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::Attribute(attr) => attr.gen(p, ctx),
Self::SpreadAttribute(spread_attr) => spread_attr.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXOpeningElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(b"<");
self.name.gen(p, ctx);
for attr in &self.attributes {
p.print_hard_space();
attr.gen(p, ctx);
}
if self.self_closing {
p.print_str(b"/>");
} else {
p.print(b'>');
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXClosingElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(b"</");
self.name.gen(p, ctx);
p.print(b'>');
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.opening_element.gen(p, ctx);
for child in &self.children {
child.gen(p, ctx);
}
if let Some(closing_element) = &self.closing_element {
closing_element.gen(p, ctx);
}
}
}
impl<const MINIFY: bool> Gen<MINIFY> for JSXOpeningFragment {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(b"<>");
}
}
impl<const MINIFY: bool> Gen<MINIFY> for JSXClosingFragment {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(b"</>");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXText<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(self.value.as_bytes());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXSpreadChild<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.print_str(b"...");
p.print_expression(&self.expression);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXChild<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::Fragment(fragment) => fragment.gen(p, ctx),
Self::Element(el) => el.gen(p, ctx),
Self::Spread(spread) => p.print_expression(&spread.expression),
Self::ExpressionContainer(expr_container) => expr_container.gen(p, ctx),
Self::Text(text) => text.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSXFragment<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.opening_fragment.gen(p, ctx);
for child in &self.children {
child.gen(p, ctx);
}
self.closing_fragment.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for StaticBlock<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_str(b"static");
p.print_soft_space();
p.print_curly_braces(self.span, self.body.is_empty(), |p| {
for stmt in &self.body {
p.print_semicolon_if_needed();
stmt.gen(p, ctx);
}
});
p.needs_semicolon = false;
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for MethodDefinition<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
self.decorators.gen(p, ctx);
if let Some(accessibility) = &self.accessibility {
accessibility.gen(p, ctx);
}
if self.r#type == MethodDefinitionType::TSAbstractMethodDefinition {
p.print_str(b"abstract ");
}
if self.r#static {
p.print_str(b"static ");
}
match &self.kind {
MethodDefinitionKind::Constructor | MethodDefinitionKind::Method => {}
MethodDefinitionKind::Get => {
p.print_str(b"get ");
}
MethodDefinitionKind::Set => {
p.print_str(b"set ");
}
}
if self.value.r#async {
p.print_str(b"async ");
}
if self.value.generator {
p.print_str(b"*");
}
if self.computed {
p.print(b'[');
}
self.key.gen(p, ctx);
if self.computed {
p.print(b']');
}
if self.optional {
p.print(b'?');
}
if let Some(type_parameters) = self.value.type_parameters.as_ref() {
type_parameters.gen(p, ctx);
}
p.print(b'(');
self.value.params.gen(p, ctx);
p.print(b')');
if let Some(return_type) = &self.value.return_type {
p.print_colon();
p.print_soft_space();
return_type.gen(p, ctx);
}
if let Some(body) = &self.value.body {
p.print_soft_space();
body.gen(p, ctx);
} else {
p.print_semicolon();
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for PropertyDefinition<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
self.decorators.gen(p, ctx);
if let Some(accessibility) = &self.accessibility {
accessibility.gen(p, ctx);
}
if self.r#type == PropertyDefinitionType::TSAbstractPropertyDefinition {
p.print_str(b"abstract ");
}
if self.r#static {
p.print_str(b"static ");
}
if self.readonly {
p.print_str(b"readonly ");
}
if self.computed {
p.print(b'[');
}
self.key.gen(p, ctx);
if self.computed {
p.print(b']');
}
if self.optional {
p.print_str(b"?");
}
if let Some(type_annotation) = &self.type_annotation {
p.print_colon();
p.print_soft_space();
type_annotation.gen(p, ctx);
}
if let Some(value) = &self.value {
p.print_soft_space();
p.print_equal();
p.print_soft_space();
value.gen_expr(p, Precedence::Assign, Context::default());
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AccessorProperty<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
if self.r#type.is_abstract() {
p.print_str(b"abstract ");
}
if self.r#static {
p.print_str(b"static ");
}
p.print_str(b"accessor ");
if self.computed {
p.print(b'[');
}
self.key.gen(p, ctx);
if self.computed {
p.print(b']');
}
if let Some(value) = &self.value {
p.print_equal();
value.gen_expr(p, Precedence::Assign, Context::default());
}
p.print_semicolon();
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for PrivateIdentifier<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
p.add_source_mapping_for_name(self.span, &self.name);
p.print(b'#');
p.print_str(self.name.as_bytes());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for BindingPattern<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match &self.kind {
BindingPatternKind::BindingIdentifier(ident) => ident.gen(p, ctx),
BindingPatternKind::ObjectPattern(pattern) => pattern.gen(p, ctx),
BindingPatternKind::ArrayPattern(pattern) => pattern.gen(p, ctx),
BindingPatternKind::AssignmentPattern(pattern) => pattern.gen(p, ctx),
}
if self.optional {
p.print_str(b"?");
}
if let Some(type_annotation) = &self.type_annotation {
p.print_colon();
p.print_soft_space();
type_annotation.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ObjectPattern<'a> {
fn gen(&self, p: &mut Codegen<MINIFY>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print(b'{');
p.print_soft_space();
p.print_list(&self.properties, ctx);
if let Some(rest) = &self.rest {
if !self.properties.is_empty() {
p.print_comma();
}
rest.gen(p, ctx);
}
p.print_soft_space();
p.print(b'}');
p.add_source_mapping(self.span.end);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for BindingProperty<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
if self.computed {
p.print(b'[');
}
if !self.shorthand {
self.key.gen(p, ctx);
}
if self.computed {
p.print(b']');
}
if !self.shorthand {
p.print_colon();
p.print_soft_space();
}
self.value.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for BindingRestElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print_ellipsis();
self.argument.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for ArrayPattern<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.add_source_mapping(self.span.start);
p.print(b'[');
for (index, item) in self.elements.iter().enumerate() {
if index != 0 {
p.print_comma();
if item.is_some() {
p.print_soft_space();
}
}
if let Some(item) = item {
item.gen(p, ctx);
}
if index == self.elements.len() - 1 && (item.is_none() || self.rest.is_some()) {
p.print_comma();
}
}
if let Some(rest) = &self.rest {
p.print_soft_space();
rest.gen(p, ctx);
}
p.print(b']');
p.add_source_mapping(self.span.end);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for AssignmentPattern<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.left.gen(p, ctx);
p.print_soft_space();
p.print_equal();
p.print_soft_space();
self.right.gen_expr(p, Precedence::Assign, Context::default());
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Vec<'a, Decorator<'a>> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
for decorator in self {
decorator.gen(p, ctx);
p.print_hard_space();
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for Decorator<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
fn need_wrap(expr: &Expression) -> bool {
match expr {
Expression::Identifier(_)
| Expression::StaticMemberExpression(_)
| Expression::PrivateFieldExpression(_) => false,
Expression::CallExpression(call_expr) => need_wrap(&call_expr.callee),
_ => true,
}
}
p.add_source_mapping(self.span.start);
p.print(b'@');
let wrap = need_wrap(&self.expression);
p.wrap(wrap, |p| {
self.expression.gen_expr(p, Precedence::Assign, Context::default());
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSClassImplements<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.expression.gen(p, ctx);
if let Some(type_parameters) = self.type_parameters.as_ref() {
type_parameters.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeParameterDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"<");
p.print_list(&self.params, ctx);
p.print_str(b">");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeAnnotation<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.type_annotation.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::TSFunctionType(ty) => ty.gen(p, ctx),
Self::TSConstructorType(ty) => ty.gen(p, ctx),
Self::TSArrayType(ty) => ty.gen(p, ctx),
Self::TSTupleType(ty) => ty.gen(p, ctx),
Self::TSUnionType(ty) => ty.gen(p, ctx),
Self::TSParenthesizedType(ty) => ty.gen(p, ctx),
Self::TSIntersectionType(ty) => ty.gen(p, ctx),
Self::TSConditionalType(ty) => ty.gen(p, ctx),
Self::TSInferType(ty) => ty.gen(p, ctx),
Self::TSIndexedAccessType(ty) => ty.gen(p, ctx),
Self::TSMappedType(ty) => ty.gen(p, ctx),
Self::TSNamedTupleMember(ty) => ty.gen(p, ctx),
Self::TSLiteralType(ty) => ty.literal.gen(p, ctx),
Self::TSImportType(ty) => ty.gen(p, ctx),
Self::TSQualifiedName(ty) => ty.gen(p, ctx),
Self::TSAnyKeyword(_) => p.print_str(b"any"),
Self::TSBigIntKeyword(_) => p.print_str(b"bigint"),
Self::TSBooleanKeyword(_) => p.print_str(b"boolean"),
Self::TSIntrinsicKeyword(_) => p.print_str(b"intrinsic"),
Self::TSNeverKeyword(_) => p.print_str(b"never"),
Self::TSNullKeyword(_) => p.print_str(b"null"),
Self::TSNumberKeyword(_) => p.print_str(b"number"),
Self::TSObjectKeyword(_) => p.print_str(b"object"),
Self::TSStringKeyword(_) => p.print_str(b"string"),
Self::TSSymbolKeyword(_) => p.print_str(b"symbol"),
Self::TSThisType(_) => p.print_str(b"this"),
Self::TSUndefinedKeyword(_) => p.print_str(b"undefined"),
Self::TSUnknownKeyword(_) => p.print_str(b"unknown"),
Self::TSVoidKeyword(_) => p.print_str(b"void"),
Self::TSTemplateLiteralType(ty) => ty.gen(p, ctx),
Self::TSTypeLiteral(ty) => ty.gen(p, ctx),
Self::TSTypeOperatorType(ty) => ty.gen(p, ctx),
Self::TSTypePredicate(ty) => ty.gen(p, ctx),
Self::TSTypeQuery(ty) => ty.gen(p, ctx),
Self::TSTypeReference(ty) => ty.gen(p, ctx),
Self::JSDocNullableType(ty) => ty.gen(p, ctx),
Self::JSDocNonNullableType(ty) => ty.gen(p, ctx),
Self::JSDocUnknownType(_ty) => p.print_str(b"unknown"),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSArrayType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.element_type.gen(p, ctx);
p.print_str(b"[]");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTupleType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"[");
p.print_list(&self.element_types, ctx);
p.print_str(b"]");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSUnionType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.types.len() == 1 {
self.types[0].gen(p, ctx);
return;
}
for (index, item) in self.types.iter().enumerate() {
if index != 0 {
p.print_soft_space();
p.print_str(b"|");
p.print_soft_space();
}
item.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSParenthesizedType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print(b'(');
self.type_annotation.gen(p, ctx);
p.print(b')');
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSIntersectionType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.types.len() == 1 {
self.types[0].gen(p, ctx);
return;
}
for (index, item) in self.types.iter().enumerate() {
if index != 0 {
p.print_soft_space();
p.print_str(b"&");
p.print_soft_space();
}
item.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSConditionalType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.check_type.gen(p, ctx);
p.print_str(b" extends ");
self.extends_type.gen(p, ctx);
p.print_str(b" ? ");
self.true_type.gen(p, ctx);
p.print_str(b" : ");
self.false_type.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSInferType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"infer ");
self.type_parameter.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSIndexedAccessType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.object_type.gen(p, ctx);
p.print_str(b"[");
self.index_type.gen(p, ctx);
p.print_str(b"]");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSMappedType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"{");
match self.readonly {
TSMappedTypeModifierOperator::True => {
p.print_str(b"readonly");
}
TSMappedTypeModifierOperator::Plus => {
p.print_str(b"+readonly");
}
TSMappedTypeModifierOperator::Minus => {
p.print_str(b"-readonly");
}
TSMappedTypeModifierOperator::None => {}
}
p.print_hard_space();
p.print_str(b"[");
self.type_parameter.name.gen(p, ctx);
if let Some(constraint) = &self.type_parameter.constraint {
p.print_str(b" in ");
constraint.gen(p, ctx);
}
if let Some(default) = &self.type_parameter.default {
p.print_str(b" = ");
default.gen(p, ctx);
}
if let Some(name_type) = &self.name_type {
p.print_str(b" as ");
name_type.gen(p, ctx);
}
p.print_str(b"]");
match self.optional {
TSMappedTypeModifierOperator::True => {
p.print_str(b"?");
}
TSMappedTypeModifierOperator::Plus => {
p.print_str(b"+?");
}
TSMappedTypeModifierOperator::Minus => {
p.print_str(b"-?");
}
TSMappedTypeModifierOperator::None => {}
}
p.print_soft_space();
if let Some(type_annotation) = &self.type_annotation {
p.print_str(b":");
p.print_soft_space();
type_annotation.gen(p, ctx);
}
p.print_str(b"}");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSQualifiedName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.left.gen(p, ctx);
p.print_str(b".");
self.right.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeOperator<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self.operator {
TSTypeOperatorOperator::Keyof => {
p.print_str(b"keyof ");
}
TSTypeOperatorOperator::Unique => {
p.print_str(b"unique ");
}
TSTypeOperatorOperator::Readonly => {
p.print_str(b"readonly ");
}
}
self.type_annotation.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypePredicate<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.asserts {
p.print_str(b"asserts ");
}
match &self.parameter_name {
TSTypePredicateName::Identifier(ident) => {
ident.gen(p, ctx);
}
TSTypePredicateName::This(_ident) => {
p.print_str(b"this");
}
}
if let Some(type_annotation) = &self.type_annotation {
p.print_str(b" is ");
type_annotation.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeReference<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.type_name.gen(p, ctx);
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSDocNullableType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.postfix {
self.type_annotation.gen(p, ctx);
p.print_str(b"?");
} else {
p.print_str(b"?");
self.type_annotation.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for JSDocNonNullableType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.postfix {
self.type_annotation.gen(p, ctx);
p.print_str(b"!");
} else {
p.print_str(b"!");
self.type_annotation.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTemplateLiteralType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"`");
for (index, item) in self.quasis.iter().enumerate() {
if index != 0 {
if let Some(types) = self.types.get(index - 1) {
p.print_str(b"${");
types.gen(p, ctx);
p.print_str(b"}");
}
}
p.print_str(item.value.raw.as_bytes());
}
p.print_str(b"`");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeLiteral<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
let single_line = self.members.len() <= 1;
p.print_curly_braces(self.span, single_line, |p| {
for item in &self.members {
p.print_indent();
item.gen(p, ctx);
if !single_line {
p.print_semicolon();
p.print_soft_newline();
}
}
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::IdentifierReference(decl) => {
p.print_str(decl.name.as_bytes());
}
Self::QualifiedName(decl) => {
decl.left.gen(p, ctx);
p.print_str(b".");
decl.right.gen(p, ctx);
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSLiteral<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::BooleanLiteral(decl) => decl.gen(p, ctx),
Self::NullLiteral(decl) => decl.gen(p, ctx),
Self::NumericLiteral(decl) => decl.gen(p, ctx),
Self::BigIntLiteral(decl) => decl.gen(p, ctx),
Self::RegExpLiteral(decl) => decl.gen(p, ctx),
Self::StringLiteral(decl) => decl.gen(p, ctx),
Self::TemplateLiteral(decl) => decl.gen(p, ctx),
Self::UnaryExpression(decl) => decl.gen_expr(p, Precedence::Assign, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeParameter<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.r#const {
p.print_str(b"const ");
}
self.name.gen(p, ctx);
if let Some(constraint) = &self.constraint {
p.print_str(b" extends ");
constraint.gen(p, ctx);
}
if let Some(default) = &self.default {
p.print_str(b" = ");
default.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSFunctionType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
p.print_str(b"(");
if let Some(this_param) = &self.this_param {
this_param.gen(p, ctx);
if !self.params.is_empty() || self.params.rest.is_some() {
p.print_str(b",");
}
p.print_soft_space();
}
self.params.gen(p, ctx);
p.print_str(b")");
p.print_soft_space();
p.print_str(b"=>");
p.print_soft_space();
self.return_type.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSThisParameter<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.this.gen(p, ctx);
if let Some(type_annotation) = &self.type_annotation {
p.print_str(b": ");
type_annotation.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSSignature<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::TSIndexSignature(signature) => signature.gen(p, ctx),
Self::TSPropertySignature(signature) => {
if signature.readonly {
p.print_str(b"readonly ");
}
if signature.computed {
p.print(b'[');
signature.key.gen(p, ctx);
p.print(b']');
} else {
match &signature.key {
PropertyKey::StaticIdentifier(key) => {
key.gen(p, ctx);
}
PropertyKey::PrivateIdentifier(key) => {
p.print_str(key.name.as_bytes());
}
key @ match_expression!(PropertyKey) => {
key.to_expression().gen_expr(p, Precedence::Assign, ctx);
}
}
}
if signature.optional {
p.print_str(b"?");
}
if let Some(type_annotation) = &signature.type_annotation {
p.print_colon();
p.print_soft_space();
type_annotation.gen(p, ctx);
}
}
Self::TSCallSignatureDeclaration(signature) => {
if let Some(type_parameters) = signature.type_parameters.as_ref() {
type_parameters.gen(p, ctx);
}
p.print_str(b"(");
if let Some(this_param) = &signature.this_param {
this_param.gen(p, ctx);
if !signature.params.is_empty() || signature.params.rest.is_some() {
p.print_str(b",");
}
p.print_soft_space();
}
signature.params.gen(p, ctx);
p.print_str(b")");
if let Some(return_type) = &signature.return_type {
p.print_colon();
p.print_soft_space();
return_type.gen(p, ctx);
}
}
Self::TSConstructSignatureDeclaration(signature) => {
p.print_str(b"new ");
if let Some(type_parameters) = signature.type_parameters.as_ref() {
type_parameters.gen(p, ctx);
}
p.print_str(b"(");
signature.params.gen(p, ctx);
p.print_str(b")");
if let Some(return_type) = &signature.return_type {
p.print_colon();
p.print_soft_space();
return_type.gen(p, ctx);
}
}
Self::TSMethodSignature(signature) => {
match signature.kind {
TSMethodSignatureKind::Method => {}
TSMethodSignatureKind::Get => p.print_str(b"get "),
TSMethodSignatureKind::Set => p.print_str(b"set "),
}
if signature.computed {
p.print(b'[');
signature.key.gen(p, ctx);
p.print(b']');
} else {
match &signature.key {
PropertyKey::StaticIdentifier(key) => {
key.gen(p, ctx);
}
PropertyKey::PrivateIdentifier(key) => {
p.print_str(key.name.as_bytes());
}
key @ match_expression!(PropertyKey) => {
key.to_expression().gen_expr(p, Precedence::Assign, ctx);
}
}
}
if signature.optional {
p.print_str(b"?");
}
if let Some(type_parameters) = &signature.type_parameters {
type_parameters.gen(p, ctx);
}
p.print_str(b"(");
if let Some(this_param) = &signature.this_param {
this_param.gen(p, ctx);
if !signature.params.is_empty() || signature.params.rest.is_some() {
p.print_str(b",");
}
p.print_soft_space();
}
signature.params.gen(p, ctx);
p.print_str(b")");
if let Some(return_type) = &signature.return_type {
p.print_colon();
p.print_soft_space();
return_type.gen(p, ctx);
}
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeQuery<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"typeof ");
self.expr_name.gen(p, ctx);
if let Some(type_params) = &self.type_parameters {
type_params.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeQueryExprName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
match_ts_type_name!(Self) => self.to_ts_type_name().gen(p, ctx),
Self::TSImportType(decl) => decl.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSImportType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.is_type_of {
p.print_str(b"typeof ");
}
p.print_str(b"import(");
self.parameter.gen(p, ctx);
if let Some(attributes) = &self.attributes {
p.print_str(", ");
attributes.gen(p, ctx);
}
p.print_str(b")");
if let Some(qualifier) = &self.qualifier {
p.print(b'.');
qualifier.gen(p, ctx);
}
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSImportAttributes<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"{ with: { ");
p.print_list(&self.elements, ctx);
p.print_str(b" }}");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSImportAttribute<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.name.gen(p, ctx);
p.print_str(": ");
self.value.gen_expr(p, Precedence::Member, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSImportAttributeName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
TSImportAttributeName::Identifier(ident) => ident.gen(p, ctx),
TSImportAttributeName::StringLiteral(literal) => literal.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeParameterInstantiation<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"<");
p.print_list(&self.params, ctx);
p.print_str(b">");
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSIndexSignature<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.readonly {
p.print_str(b"readonly ");
}
p.print_str(b"[");
for (index, parameter) in self.parameters.iter().enumerate() {
if index != 0 {
p.print_str(b" | ");
}
p.print_str(parameter.name.as_bytes());
p.print_colon();
p.print_soft_space();
parameter.type_annotation.gen(p, ctx);
}
p.print_str(b"]");
p.print_colon();
p.print_soft_space();
self.type_annotation.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTupleElement<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
match_ts_type!(TSTupleElement) => self.to_ts_type().gen(p, ctx),
TSTupleElement::TSOptionalType(ts_type) => {
ts_type.type_annotation.gen(p, ctx);
p.print_str(b"?");
}
TSTupleElement::TSRestType(ts_type) => {
p.print_str(b"...");
ts_type.type_annotation.gen(p, ctx);
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSNamedTupleMember<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.label.gen(p, ctx);
if self.optional {
p.print_str(b"?");
}
p.print_str(b":");
p.print_soft_space();
self.element_type.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSModuleDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.declare {
p.print_str(b"declare ");
}
self.kind.gen(p, ctx);
if !self.kind.is_global() {
p.print_space_before_identifier();
self.id.gen(p, ctx);
}
if let Some(body) = &self.body {
let mut body = body;
loop {
match body {
TSModuleDeclarationBody::TSModuleDeclaration(b) => {
p.print(b'.');
b.id.gen(p, ctx);
if let Some(b) = &b.body {
body = b;
} else {
break;
}
}
TSModuleDeclarationBody::TSModuleBlock(body) => {
p.print_soft_space();
body.gen(p, ctx);
break;
}
}
}
}
p.needs_semicolon = false;
}
}
impl<const MINIFY: bool> Gen<MINIFY> for TSModuleDeclarationKind {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _: Context) {
match self {
TSModuleDeclarationKind::Global => {
p.print_str(b"global");
}
TSModuleDeclarationKind::Module => {
p.print_str(b"module");
}
TSModuleDeclarationKind::Namespace => {
p.print_str(b"namespace");
}
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSModuleDeclarationName<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::Identifier(ident) => ident.gen(p, ctx),
Self::StringLiteral(s) => s.gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSModuleBlock<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
let is_empty = self.directives.is_empty() && self.body.is_empty();
p.print_curly_braces(self.span, is_empty, |p| {
p.print_directives_and_statements(Some(&self.directives), &self.body, ctx);
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSTypeAliasDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.declare {
p.print_str(b"declare ");
}
p.print_str(b"type");
p.print_space_before_identifier();
self.id.gen(p, ctx);
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
p.print_soft_space();
p.print_str(b"=");
p.print_soft_space();
self.type_annotation.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSInterfaceDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"interface");
p.print_hard_space();
self.id.gen(p, ctx);
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
if let Some(extends) = &self.extends {
if !extends.is_empty() {
p.print_str(b" extends ");
p.print_list(extends, ctx);
}
}
p.print_soft_space();
p.print_curly_braces(self.body.span, self.body.body.is_empty(), |p| {
for item in &self.body.body {
p.print_indent();
item.gen(p, ctx);
p.print_semicolon();
p.print_soft_newline();
}
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSInterfaceHeritage<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
self.expression.gen_expr(p, Precedence::Call, ctx);
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSEnumDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_indent();
if self.declare {
p.print_str(b"declare ");
}
if self.r#const {
p.print_str(b"const ");
}
p.print_space_before_identifier();
p.print_str(b"enum ");
self.id.gen(p, ctx);
p.print_space_before_identifier();
p.print_curly_braces(self.span, self.members.is_empty(), |p| {
for member in &self.members {
p.print_indent();
member.gen(p, ctx);
p.print_comma();
p.print_soft_newline();
}
});
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSEnumMember<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match &self.id {
TSEnumMemberName::StaticIdentifier(decl) => decl.gen(p, ctx),
TSEnumMemberName::StaticStringLiteral(decl) => decl.gen(p, ctx),
TSEnumMemberName::StaticNumericLiteral(decl) => decl.gen(p, ctx),
decl @ match_expression!(TSEnumMemberName) => {
p.print_str(b"[");
decl.to_expression().gen_expr(p, Precedence::lowest(), ctx);
p.print_str(b"]");
}
}
if let Some(init) = &self.initializer {
p.print_soft_space();
p.print_equal();
p.print_soft_space();
init.gen_expr(p, Precedence::lowest(), ctx);
}
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSConstructorType<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
if self.r#abstract {
p.print_str(b"abstract ");
}
p.print_str(b"new ");
if let Some(type_parameters) = &self.type_parameters {
type_parameters.gen(p, ctx);
}
p.print_str(b"(");
self.params.gen(p, ctx);
p.print_str(b")");
p.print_soft_space();
p.print_str(b"=>");
p.print_soft_space();
self.return_type.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSImportEqualsDeclaration<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
p.print_str(b"import ");
self.id.gen(p, ctx);
p.print_str(b" = ");
self.module_reference.gen(p, ctx);
}
}
impl<'a, const MINIFY: bool> Gen<MINIFY> for TSModuleReference<'a> {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, ctx: Context) {
match self {
Self::ExternalModuleReference(decl) => {
p.print_str(b"require(");
decl.expression.gen(p, ctx);
p.print_str(b")");
}
match_ts_type_name!(Self) => self.to_ts_type_name().gen(p, ctx),
}
}
}
impl<'a, const MINIFY: bool> GenExpr<MINIFY> for TSTypeAssertion<'a> {
fn gen_expr(&self, p: &mut Codegen<{ MINIFY }>, precedence: Precedence, ctx: Context) {
p.wrap(precedence > self.precedence(), |p| {
p.print_str(b"<");
if matches!(self.type_annotation, TSType::TSFunctionType(_)) {
p.print_hard_space();
}
self.type_annotation.gen(p, ctx);
p.print_str(b">");
self.expression.gen_expr(p, Precedence::Grouping, ctx);
});
}
}
impl<const MINIFY: bool> Gen<MINIFY> for TSAccessibility {
fn gen(&self, p: &mut Codegen<{ MINIFY }>, _ctx: Context) {
match self {
Self::Public => p.print_str(b"public "),
Self::Private => p.print_str(b"private "),
Self::Protected => p.print_str(b"protected "),
}
}
}