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ladybird/Userland/Libraries/LibJS/Bytecode/Generator.cpp
Linus Groh 57dc179b1f Everywhere: Rename to_{string => deprecated_string}() where applicable 
This will make it easier to support both string types at the same time
while we convert code, and tracking down remaining uses.

One big exception is Value::to_string() in LibJS, where the name is
dictated by the ToString AO.
2022-12-06 08:54:33 +01:00

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/*
* Copyright (c) 2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <LibJS/AST.h>
#include <LibJS/Bytecode/BasicBlock.h>
#include <LibJS/Bytecode/Generator.h>
#include <LibJS/Bytecode/Instruction.h>
#include <LibJS/Bytecode/Op.h>
#include <LibJS/Bytecode/Register.h>
namespace JS::Bytecode {
Generator::Generator()
: m_string_table(make<StringTable>())
, m_identifier_table(make<IdentifierTable>())
{
}
CodeGenerationErrorOr<NonnullOwnPtr<Executable>> Generator::generate(ASTNode const& node, FunctionKind enclosing_function_kind)
{
Generator generator;
generator.switch_to_basic_block(generator.make_block());
generator.m_enclosing_function_kind = enclosing_function_kind;
if (generator.is_in_generator_or_async_function()) {
// Immediately yield with no value.
auto& start_block = generator.make_block();
generator.emit<Bytecode::Op::Yield>(Label { start_block });
generator.switch_to_basic_block(start_block);
// NOTE: This doesn't have to handle received throw/return completions, as GeneratorObject::resume_abrupt
// will not enter the generator from the SuspendedStart state and immediately completes the generator.
}
TRY(node.generate_bytecode(generator));
if (generator.is_in_generator_or_async_function()) {
// Terminate all unterminated blocks with yield return
for (auto& block : generator.m_root_basic_blocks) {
if (block.is_terminated())
continue;
generator.switch_to_basic_block(block);
generator.emit<Bytecode::Op::LoadImmediate>(js_undefined());
generator.emit<Bytecode::Op::Yield>(nullptr);
}
}
bool is_strict_mode = false;
if (is<Program>(node))
is_strict_mode = static_cast<Program const&>(node).is_strict_mode();
else if (is<FunctionBody>(node))
is_strict_mode = static_cast<FunctionBody const&>(node).in_strict_mode();
else if (is<FunctionDeclaration>(node))
is_strict_mode = static_cast<FunctionDeclaration const&>(node).is_strict_mode();
else if (is<FunctionExpression>(node))
is_strict_mode = static_cast<FunctionExpression const&>(node).is_strict_mode();
return adopt_own(*new Executable {
.name = {},
.basic_blocks = move(generator.m_root_basic_blocks),
.string_table = move(generator.m_string_table),
.identifier_table = move(generator.m_identifier_table),
.number_of_registers = generator.m_next_register,
.is_strict_mode = is_strict_mode });
}
void Generator::grow(size_t additional_size)
{
VERIFY(m_current_basic_block);
m_current_basic_block->grow(additional_size);
}
void* Generator::next_slot()
{
VERIFY(m_current_basic_block);
return m_current_basic_block->next_slot();
}
Register Generator::allocate_register()
{
VERIFY(m_next_register != NumericLimits<u32>::max());
return Register { m_next_register++ };
}
Label Generator::nearest_continuable_scope() const
{
return m_continuable_scopes.last().bytecode_target;
}
void Generator::begin_variable_scope(BindingMode mode, SurroundingScopeKind kind)
{
m_variable_scopes.append({ kind, mode, {} });
if (mode != BindingMode::Global) {
start_boundary(mode == BindingMode::Lexical ? BlockBoundaryType::LeaveLexicalEnvironment : BlockBoundaryType::LeaveVariableEnvironment);
emit<Bytecode::Op::CreateEnvironment>(
mode == BindingMode::Lexical
? Bytecode::Op::EnvironmentMode::Lexical
: Bytecode::Op::EnvironmentMode::Var);
}
}
void Generator::end_variable_scope()
{
auto mode = m_variable_scopes.take_last().mode;
if (mode != BindingMode::Global) {
end_boundary(mode == BindingMode::Lexical ? BlockBoundaryType::LeaveLexicalEnvironment : BlockBoundaryType::LeaveVariableEnvironment);
if (!m_current_basic_block->is_terminated()) {
emit<Bytecode::Op::LeaveEnvironment>(
mode == BindingMode::Lexical
? Bytecode::Op::EnvironmentMode::Lexical
: Bytecode::Op::EnvironmentMode::Var);
}
}
}
void Generator::begin_continuable_scope(Label continue_target, Vector<FlyString> const& language_label_set)
{
m_continuable_scopes.append({ continue_target, language_label_set });
start_boundary(BlockBoundaryType::Continue);
}
void Generator::end_continuable_scope()
{
m_continuable_scopes.take_last();
end_boundary(BlockBoundaryType::Continue);
}
Label Generator::nearest_breakable_scope() const
{
return m_breakable_scopes.last().bytecode_target;
}
void Generator::begin_breakable_scope(Label breakable_target, Vector<FlyString> const& language_label_set)
{
m_breakable_scopes.append({ breakable_target, language_label_set });
start_boundary(BlockBoundaryType::Break);
}
void Generator::end_breakable_scope()
{
m_breakable_scopes.take_last();
end_boundary(BlockBoundaryType::Break);
}
CodeGenerationErrorOr<void> Generator::emit_load_from_reference(JS::ASTNode const& node)
{
if (is<Identifier>(node)) {
auto& identifier = static_cast<Identifier const&>(node);
emit<Bytecode::Op::GetVariable>(intern_identifier(identifier.string()));
return {};
}
if (is<MemberExpression>(node)) {
auto& expression = static_cast<MemberExpression const&>(node);
TRY(expression.object().generate_bytecode(*this));
if (expression.is_computed()) {
auto object_reg = allocate_register();
emit<Bytecode::Op::Store>(object_reg);
TRY(expression.property().generate_bytecode(*this));
emit<Bytecode::Op::GetByValue>(object_reg);
} else if (expression.property().is_identifier()) {
auto identifier_table_ref = intern_identifier(verify_cast<Identifier>(expression.property()).string());
emit<Bytecode::Op::GetById>(identifier_table_ref);
} else {
return CodeGenerationError {
&expression,
"Unimplemented non-computed member expression"sv
};
}
return {};
}
VERIFY_NOT_REACHED();
}
CodeGenerationErrorOr<void> Generator::emit_store_to_reference(JS::ASTNode const& node)
{
if (is<Identifier>(node)) {
auto& identifier = static_cast<Identifier const&>(node);
emit<Bytecode::Op::SetVariable>(intern_identifier(identifier.string()));
return {};
}
if (is<MemberExpression>(node)) {
// NOTE: The value is in the accumulator, so we have to store that away first.
auto value_reg = allocate_register();
emit<Bytecode::Op::Store>(value_reg);
auto& expression = static_cast<MemberExpression const&>(node);
TRY(expression.object().generate_bytecode(*this));
auto object_reg = allocate_register();
emit<Bytecode::Op::Store>(object_reg);
if (expression.is_computed()) {
TRY(expression.property().generate_bytecode(*this));
auto property_reg = allocate_register();
emit<Bytecode::Op::Store>(property_reg);
emit<Bytecode::Op::Load>(value_reg);
emit<Bytecode::Op::PutByValue>(object_reg, property_reg);
} else if (expression.property().is_identifier()) {
emit<Bytecode::Op::Load>(value_reg);
auto identifier_table_ref = intern_identifier(verify_cast<Identifier>(expression.property()).string());
emit<Bytecode::Op::PutById>(object_reg, identifier_table_ref);
} else {
return CodeGenerationError {
&expression,
"Unimplemented non-computed member expression"sv
};
}
return {};
}
return CodeGenerationError {
&node,
"Unimplemented/invalid node used a reference"sv
};
}
CodeGenerationErrorOr<void> Generator::emit_delete_reference(JS::ASTNode const& node)
{
if (is<Identifier>(node)) {
auto& identifier = static_cast<Identifier const&>(node);
emit<Bytecode::Op::DeleteVariable>(intern_identifier(identifier.string()));
return {};
}
if (is<MemberExpression>(node)) {
auto& expression = static_cast<MemberExpression const&>(node);
TRY(expression.object().generate_bytecode(*this));
if (expression.is_computed()) {
auto object_reg = allocate_register();
emit<Bytecode::Op::Store>(object_reg);
TRY(expression.property().generate_bytecode(*this));
emit<Bytecode::Op::DeleteByValue>(object_reg);
} else if (expression.property().is_identifier()) {
auto identifier_table_ref = intern_identifier(verify_cast<Identifier>(expression.property()).string());
emit<Bytecode::Op::DeleteById>(identifier_table_ref);
} else {
// NOTE: Trying to delete a private field generates a SyntaxError in the parser.
return CodeGenerationError {
&expression,
"Unimplemented non-computed member expression"sv
};
}
return {};
}
// Though this will have no deletion effect, we still have to evaluate the node as it can have side effects.
// For example: delete a(); delete ++c.b; etc.
// 13.5.1.2 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-delete-operator-runtime-semantics-evaluation
// 1. Let ref be the result of evaluating UnaryExpression.
// 2. ReturnIfAbrupt(ref).
TRY(node.generate_bytecode(*this));
// 3. If ref is not a Reference Record, return true.
emit<Bytecode::Op::LoadImmediate>(Value(true));
// NOTE: The rest of the steps are handled by Delete{Variable,ByValue,Id}.
return {};
}
Label Generator::perform_needed_unwinds_for_labelled_break_and_return_target_block(FlyString const& break_label)
{
size_t current_boundary = m_boundaries.size();
for (auto& breakable_scope : m_breakable_scopes.in_reverse()) {
for (; current_boundary > 0; --current_boundary) {
auto boundary = m_boundaries[current_boundary - 1];
if (boundary == BlockBoundaryType::Unwind) {
emit<Bytecode::Op::LeaveUnwindContext>();
} else if (boundary == BlockBoundaryType::LeaveLexicalEnvironment) {
emit<Bytecode::Op::LeaveEnvironment>(Bytecode::Op::EnvironmentMode::Lexical);
} else if (boundary == BlockBoundaryType::LeaveVariableEnvironment) {
emit<Bytecode::Op::LeaveEnvironment>(Bytecode::Op::EnvironmentMode::Var);
} else if (boundary == BlockBoundaryType::Break) {
// Make sure we don't process this boundary twice if the current breakable scope doesn't contain the target label.
--current_boundary;
break;
}
}
if (breakable_scope.language_label_set.contains_slow(break_label))
return breakable_scope.bytecode_target;
}
// We must have a breakable scope available that contains the label, as this should be enforced by the parser.
VERIFY_NOT_REACHED();
}
Label Generator::perform_needed_unwinds_for_labelled_continue_and_return_target_block(FlyString const& continue_label)
{
size_t current_boundary = m_boundaries.size();
for (auto& continuable_scope : m_continuable_scopes.in_reverse()) {
for (; current_boundary > 0; --current_boundary) {
auto boundary = m_boundaries[current_boundary - 1];
if (boundary == BlockBoundaryType::Unwind) {
emit<Bytecode::Op::LeaveUnwindContext>();
} else if (boundary == BlockBoundaryType::LeaveLexicalEnvironment) {
emit<Bytecode::Op::LeaveEnvironment>(Bytecode::Op::EnvironmentMode::Lexical);
} else if (boundary == BlockBoundaryType::LeaveVariableEnvironment) {
emit<Bytecode::Op::LeaveEnvironment>(Bytecode::Op::EnvironmentMode::Var);
} else if (boundary == BlockBoundaryType::Continue) {
// Make sure we don't process this boundary twice if the current continuable scope doesn't contain the target label.
--current_boundary;
break;
}
}
if (continuable_scope.language_label_set.contains_slow(continue_label))
return continuable_scope.bytecode_target;
}
// We must have a continuable scope available that contains the label, as this should be enforced by the parser.
VERIFY_NOT_REACHED();
}
DeprecatedString CodeGenerationError::to_deprecated_string()
{
return DeprecatedString::formatted("CodeGenerationError in {}: {}", failing_node ? failing_node->class_name() : "<unknown node>", reason_literal);
}
}
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