/*
* Copyright (c) 2020, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/CharacterTypes.h>
#include <AK/Utf16View.h>
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/PrimitiveString.h>
#include <LibJS/Runtime/PropertyKey.h>
#include <LibJS/Runtime/VM.h>
#include <LibJS/Runtime/Value.h>
namespace JS {
PrimitiveString::PrimitiveString(PrimitiveString& lhs, PrimitiveString& rhs)
: m_is_rope(true)
, m_lhs(&lhs)
, m_rhs(&rhs)
{
}
PrimitiveString::PrimitiveString(String string)
: m_has_utf8_string(true)
, m_utf8_string(move(string))
{
}
PrimitiveString::PrimitiveString(Utf16String string)
: m_has_utf16_string(true)
, m_utf16_string(move(string))
{
}
PrimitiveString::~PrimitiveString()
{
vm().string_cache().remove(m_utf8_string);
}
void PrimitiveString::visit_edges(Cell::Visitor& visitor)
{
Cell::visit_edges(visitor);
if (m_is_rope) {
visitor.visit(m_lhs);
visitor.visit(m_rhs);
}
}
bool PrimitiveString::is_empty() const
{
if (m_is_rope) {
// NOTE: We never make an empty rope string.
return false;
}
if (m_has_utf16_string)
return m_utf16_string.is_empty();
if (m_has_utf8_string)
return m_utf8_string.is_empty();
VERIFY_NOT_REACHED();
}
String const& PrimitiveString::string() const
{
resolve_rope_if_needed();
if (!m_has_utf8_string) {
m_utf8_string = m_utf16_string.to_utf8();
m_has_utf8_string = true;
}
return m_utf8_string;
}
Utf16String const& PrimitiveString::utf16_string() const
{
resolve_rope_if_needed();
if (!m_has_utf16_string) {
m_utf16_string = Utf16String(m_utf8_string);
m_has_utf16_string = true;
}
return m_utf16_string;
}
Utf16View PrimitiveString::utf16_string_view() const
{
return utf16_string().view();
}
Optional<Value> PrimitiveString::get(VM& vm, PropertyKey const& property_key) const
{
if (property_key.is_symbol())
return {};
if (property_key.is_string()) {
if (property_key.as_string() == vm.names.length.as_string()) {
auto length = utf16_string().length_in_code_units();
return Value(static_cast<double>(length));
}
}
auto index = canonical_numeric_index_string(property_key, CanonicalIndexMode::IgnoreNumericRoundtrip);
if (!index.is_index())
return {};
auto str = utf16_string_view();
auto length = str.length_in_code_units();
if (length <= index.as_index())
return {};
return js_string(vm, str.substring_view(index.as_index(), 1));
}
PrimitiveString* js_string(Heap& heap, Utf16View const& view)
{
return js_string(heap, Utf16String(view));
}
PrimitiveString* js_string(VM& vm, Utf16View const& view)
{
return js_string(vm.heap(), view);
}
PrimitiveString* js_string(Heap& heap, Utf16String string)
{
if (string.is_empty())
return &heap.vm().empty_string();
if (string.length_in_code_units() == 1) {
u16 code_unit = string.code_unit_at(0);
if (is_ascii(code_unit))
return &heap.vm().single_ascii_character_string(static_cast<u8>(code_unit));
}
return heap.allocate_without_realm<PrimitiveString>(move(string));
}
PrimitiveString* js_string(VM& vm, Utf16String string)
{
return js_string(vm.heap(), move(string));
}
PrimitiveString* js_string(Heap& heap, String string)
{
if (string.is_empty())
return &heap.vm().empty_string();
if (string.length() == 1) {
auto ch = static_cast<u8>(string.characters()[0]);
if (is_ascii(ch))
return &heap.vm().single_ascii_character_string(ch);
}
auto& string_cache = heap.vm().string_cache();
auto it = string_cache.find(string);
if (it == string_cache.end()) {
auto* new_string = heap.allocate_without_realm<PrimitiveString>(string);
string_cache.set(move(string), new_string);
return new_string;
}
return it->value;
}
PrimitiveString* js_string(VM& vm, String string)
{
return js_string(vm.heap(), move(string));
}
PrimitiveString* js_rope_string(VM& vm, PrimitiveString& lhs, PrimitiveString& rhs)
{
// We're here to concatenate two strings into a new rope string.
// However, if any of them are empty, no rope is required.
bool lhs_empty = lhs.is_empty();
bool rhs_empty = rhs.is_empty();
if (lhs_empty && rhs_empty)
return &vm.empty_string();
if (lhs_empty)
return &rhs;
if (rhs_empty)
return &lhs;
return vm.heap().allocate_without_realm<PrimitiveString>(lhs, rhs);
}
void PrimitiveString::resolve_rope_if_needed() const
{
if (!m_is_rope)
return;
// NOTE: Special case for two concatenated UTF-16 strings.
// This is here as an optimization, although I'm unsure how valuable it is.
if (m_lhs->has_utf16_string() && m_rhs->has_utf16_string()) {
auto const& lhs_string = m_lhs->utf16_string();
auto const& rhs_string = m_rhs->utf16_string();
Vector<u16, 1> combined;
combined.ensure_capacity(lhs_string.length_in_code_units() + rhs_string.length_in_code_units());
combined.extend(lhs_string.string());
combined.extend(rhs_string.string());
m_utf16_string = Utf16String(move(combined));
m_has_utf16_string = true;
m_is_rope = false;
m_lhs = nullptr;
m_rhs = nullptr;
return;
}
// This vector will hold all the pieces of the rope that need to be assembled
// into the resolved string.
Vector<PrimitiveString const*> pieces;
// NOTE: We traverse the rope tree without using recursion, since we'd run out of
// stack space quickly when handling a long sequence of unresolved concatenations.
Vector<PrimitiveString const*> stack;
stack.append(m_rhs);
stack.append(m_lhs);
while (!stack.is_empty()) {
auto* current = stack.take_last();
if (current->m_is_rope) {
stack.append(current->m_rhs);
stack.append(current->m_lhs);
continue;
}
pieces.append(current);
}
// Now that we have all the pieces, we can concatenate them using a StringBuilder.
StringBuilder builder;
// We keep track of the previous piece in order to handle surrogate pairs spread across two pieces.
PrimitiveString const* previous = nullptr;
for (auto const* current : pieces) {
if (!previous) {
// This is the very first piece, just append it and continue.
builder.append(current->string());
previous = current;
continue;
}
// Get the UTF-8 representations for both strings.
auto const& previous_string_as_utf8 = previous->string();
auto const& current_string_as_utf8 = current->string();
// NOTE: Now we need to look at the end of the previous string and the start
// of the current string, to see if they should be combined into a surrogate.
// Surrogates encoded as UTF-8 are 3 bytes.
if ((previous_string_as_utf8.length() < 3) || (current_string_as_utf8.length() < 3)) {
builder.append(current->string());
previous = current;
continue;
}
// Might the previous string end with a UTF-8 encoded surrogate?
if ((static_cast<u8>(previous_string_as_utf8[previous_string_as_utf8.length() - 3]) & 0xf0) != 0xe0) {
// If not, just append the current string and continue.
builder.append(current->string());
previous = current;
continue;
}
// Might the current string begin with a UTF-8 encoded surrogate?
if ((static_cast<u8>(current_string_as_utf8[0]) & 0xf0) != 0xe0) {
// If not, just append the current string and continue.
builder.append(current->string());
previous = current;
continue;
}
auto high_surrogate = *Utf8View(previous_string_as_utf8.substring_view(previous_string_as_utf8.length() - 3)).begin();
auto low_surrogate = *Utf8View(current_string_as_utf8).begin();
if (!Utf16View::is_high_surrogate(high_surrogate) || !Utf16View::is_low_surrogate(low_surrogate)) {
builder.append(current->string());
previous = current;
continue;
}
// Remove 3 bytes from the builder and replace them with the UTF-8 encoded code point.
builder.trim(3);
builder.append_code_point(Utf16View::decode_surrogate_pair(high_surrogate, low_surrogate));
// Append the remaining part of the current string.
builder.append(current_string_as_utf8.substring_view(3));
previous = current;
}
m_utf8_string = builder.to_string();
m_has_utf8_string = true;
m_is_rope = false;
m_lhs = nullptr;
m_rhs = nullptr;
}
}