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ladybird/Userland/Libraries/LibRegex/RegexMatcher.cpp
Timothy Flynn 9509433e25 LibRegex: Implement and use a REPEAT operation for bytecode repetition 
Currently, when we need to repeat an instruction N times, we simply add
that instruction N times in a for-loop. This doesn't scale well with
extremely large values of N, and ECMA-262 allows up to N = 2^53 - 1.

Instead, add a new REPEAT bytecode operation to defer this loop from the
parser to the runtime executor. This allows the parser to complete sans
any loops (for this instruction), and allows the executor to bail early
if the repeated bytecode fails.

Note: The templated ByteCode methods are to allow the Posix parsers to
continue using u32 because they are limited to N = 2^20.
2021-08-15 11:43:45 +01:00

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/*
* Copyright (c) 2020, Emanuel Sprung <emanuel.sprung@gmail.com>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/BumpAllocator.h>
#include <AK/Debug.h>
#include <AK/String.h>
#include <AK/StringBuilder.h>
#include <LibRegex/RegexMatcher.h>
#include <LibRegex/RegexParser.h>
#if REGEX_DEBUG
# include <LibRegex/RegexDebug.h>
#endif
namespace regex {
#if REGEX_DEBUG
static RegexDebug s_regex_dbg(stderr);
#endif
template<class Parser>
regex::Parser::Result Regex<Parser>::parse_pattern(StringView pattern, typename ParserTraits<Parser>::OptionsType regex_options)
{
regex::Lexer lexer(pattern);
Parser parser(lexer, regex_options);
return parser.parse();
}
template<class Parser>
Regex<Parser>::Regex(String pattern, typename ParserTraits<Parser>::OptionsType regex_options)
: pattern_value(move(pattern))
{
regex::Lexer lexer(pattern_value);
Parser parser(lexer, regex_options);
parser_result = parser.parse();
if (parser_result.error == regex::Error::NoError)
matcher = make<Matcher<Parser>>(this, regex_options);
}
template<class Parser>
Regex<Parser>::Regex(regex::Parser::Result parse_result, String pattern, typename ParserTraits<Parser>::OptionsType regex_options)
: pattern_value(move(pattern))
, parser_result(move(parse_result))
{
if (parser_result.error == regex::Error::NoError)
matcher = make<Matcher<Parser>>(this, regex_options);
}
template<class Parser>
Regex<Parser>::Regex(Regex&& regex)
: pattern_value(move(regex.pattern_value))
, parser_result(move(regex.parser_result))
, matcher(move(regex.matcher))
, start_offset(regex.start_offset)
{
if (matcher)
matcher->reset_pattern({}, this);
}
template<class Parser>
Regex<Parser>& Regex<Parser>::operator=(Regex&& regex)
{
pattern_value = move(regex.pattern_value);
parser_result = move(regex.parser_result);
matcher = move(regex.matcher);
if (matcher)
matcher->reset_pattern({}, this);
start_offset = regex.start_offset;
return *this;
}
template<class Parser>
typename ParserTraits<Parser>::OptionsType Regex<Parser>::options() const
{
if (!matcher || parser_result.error != Error::NoError)
return {};
return matcher->options();
}
template<class Parser>
String Regex<Parser>::error_string(Optional<String> message) const
{
StringBuilder eb;
eb.append("Error during parsing of regular expression:\n");
eb.appendff(" {}\n ", pattern_value);
for (size_t i = 0; i < parser_result.error_token.position(); ++i)
eb.append(' ');
eb.appendff("^---- {}", message.value_or(get_error_string(parser_result.error)));
return eb.build();
}
template<typename Parser>
RegexResult Matcher<Parser>::match(RegexStringView const& view, Optional<typename ParserTraits<Parser>::OptionsType> regex_options) const
{
AllOptions options = m_regex_options | regex_options.value_or({}).value();
if (options.has_flag_set(AllFlags::Multiline))
return match(view.lines(), regex_options); // FIXME: how do we know, which line ending a line has (1char or 2char)? This is needed to get the correct match offsets from start of string...
Vector<RegexStringView> views;
views.append(view);
return match(views, regex_options);
}
template<typename Parser>
RegexResult Matcher<Parser>::match(Vector<RegexStringView> const& views, Optional<typename ParserTraits<Parser>::OptionsType> regex_options) const
{
// If the pattern *itself* isn't stateful, reset any changes to start_offset.
if (!((AllFlags)m_regex_options.value() & AllFlags::Internal_Stateful))
m_pattern->start_offset = 0;
size_t match_count { 0 };
MatchInput input;
MatchState state;
size_t operations = 0;
input.regex_options = m_regex_options | regex_options.value_or({}).value();
input.start_offset = m_pattern->start_offset;
size_t lines_to_skip = 0;
bool unicode = input.regex_options.has_flag_set(AllFlags::Unicode);
for (auto& view : views)
const_cast<RegexStringView&>(view).set_unicode(unicode);
if (input.regex_options.has_flag_set(AllFlags::Internal_Stateful)) {
if (views.size() > 1 && input.start_offset > views.first().length()) {
dbgln_if(REGEX_DEBUG, "Started with start={}, goff={}, skip={}", input.start_offset, input.global_offset, lines_to_skip);
for (auto& view : views) {
if (input.start_offset < view.length() + 1)
break;
++lines_to_skip;
input.start_offset -= view.length() + 1;
input.global_offset += view.length() + 1;
}
dbgln_if(REGEX_DEBUG, "Ended with start={}, goff={}, skip={}", input.start_offset, input.global_offset, lines_to_skip);
}
}
if (c_match_preallocation_count) {
state.matches.ensure_capacity(c_match_preallocation_count);
state.capture_group_matches.ensure_capacity(c_match_preallocation_count);
auto& capture_groups_count = m_pattern->parser_result.capture_groups_count;
for (size_t j = 0; j < c_match_preallocation_count; ++j) {
state.matches.empend();
state.capture_group_matches.unchecked_append({});
state.capture_group_matches.at(j).ensure_capacity(capture_groups_count);
for (size_t k = 0; k < capture_groups_count; ++k)
state.capture_group_matches.at(j).unchecked_append({});
}
}
auto append_match = [](auto& input, auto& state, auto& start_position) {
if (state.matches.size() == input.match_index)
state.matches.empend();
VERIFY(start_position + state.string_position - start_position <= input.view.length());
if (input.regex_options.has_flag_set(AllFlags::StringCopyMatches)) {
state.matches.at(input.match_index) = { input.view.substring_view(start_position, state.string_position - start_position).to_string(), input.line, start_position, input.global_offset + start_position };
} else { // let the view point to the original string ...
state.matches.at(input.match_index) = { input.view.substring_view(start_position, state.string_position - start_position), input.line, start_position, input.global_offset + start_position };
}
};
#if REGEX_DEBUG
s_regex_dbg.print_header();
#endif
bool continue_search = input.regex_options.has_flag_set(AllFlags::Global) || input.regex_options.has_flag_set(AllFlags::Multiline);
if (input.regex_options.has_flag_set(AllFlags::Internal_Stateful))
continue_search = false;
for (auto& view : views) {
if (lines_to_skip != 0) {
++input.line;
--lines_to_skip;
continue;
}
input.view = view;
dbgln_if(REGEX_DEBUG, "[match] Starting match with view ({}): _{}_", view.length(), view);
auto view_length = view.length();
size_t view_index = m_pattern->start_offset;
state.string_position = view_index;
state.string_position_in_code_units = view_index;
bool succeeded = false;
if (view_index == view_length && m_pattern->parser_result.match_length_minimum == 0) {
// Run the code until it tries to consume something.
// This allows non-consuming code to run on empty strings, for instance
// e.g. "Exit"
size_t temp_operations = operations;
input.column = match_count;
input.match_index = match_count;
state.string_position = view_index;
state.string_position_in_code_units = view_index;
state.instruction_position = 0;
state.repetition_marks.clear();
auto success = execute(input, state, temp_operations);
// This success is acceptable only if it doesn't read anything from the input (input length is 0).
if (state.string_position <= view_index) {
if (success.has_value() && success.value()) {
operations = temp_operations;
if (!match_count) {
// Nothing was *actually* matched, so append an empty match.
append_match(input, state, view_index);
++match_count;
}
}
}
}
for (; view_index < view_length; ++view_index) {
auto& match_length_minimum = m_pattern->parser_result.match_length_minimum;
// FIXME: More performant would be to know the remaining minimum string
// length needed to match from the current position onwards within
// the vm. Add new OpCode for MinMatchLengthFromSp with the value of
// the remaining string length from the current path. The value though
// has to be filled in reverse. That implies a second run over bytecode
// after generation has finished.
if (match_length_minimum && match_length_minimum > view_length - view_index)
break;
input.column = match_count;
input.match_index = match_count;
state.string_position = view_index;
state.string_position_in_code_units = view_index;
state.instruction_position = 0;
state.repetition_marks.clear();
auto success = execute(input, state, operations);
if (!success.has_value())
return { false, 0, {}, {}, {}, operations };
if (success.value()) {
succeeded = true;
if (input.regex_options.has_flag_set(AllFlags::MatchNotEndOfLine) && state.string_position == input.view.length()) {
if (!continue_search)
break;
continue;
}
if (input.regex_options.has_flag_set(AllFlags::MatchNotBeginOfLine) && view_index == 0) {
if (!continue_search)
break;
continue;
}
dbgln_if(REGEX_DEBUG, "state.string_position={}, view_index={}", state.string_position, view_index);
dbgln_if(REGEX_DEBUG, "[match] Found a match (length={}): '{}'", state.string_position - view_index, input.view.substring_view(view_index, state.string_position - view_index));
++match_count;
if (continue_search) {
append_match(input, state, view_index);
bool has_zero_length = state.string_position == view_index;
view_index = state.string_position - (has_zero_length ? 0 : 1);
continue;
} else if (input.regex_options.has_flag_set(AllFlags::Internal_Stateful)) {
append_match(input, state, view_index);
break;
} else if (state.string_position < view_length) {
return { false, 0, {}, {}, {}, operations };
}
append_match(input, state, view_index);
break;
}
if (!continue_search)
break;
}
++input.line;
input.global_offset += view.length() + 1; // +1 includes the line break character
if (input.regex_options.has_flag_set(AllFlags::Internal_Stateful))
m_pattern->start_offset = state.string_position;
if (succeeded && !continue_search)
break;
}
RegexResult result {
match_count != 0,
match_count,
move(state.matches),
move(state.capture_group_matches),
operations,
m_pattern->parser_result.capture_groups_count,
m_pattern->parser_result.named_capture_groups_count,
};
if (match_count) {
// Make sure there are as many capture matches as there are actual matches.
if (result.capture_group_matches.size() < match_count)
result.capture_group_matches.resize(match_count);
for (auto& matches : result.capture_group_matches)
matches.resize(m_pattern->parser_result.capture_groups_count + 1);
if (!input.regex_options.has_flag_set(AllFlags::SkipTrimEmptyMatches)) {
for (auto& matches : result.capture_group_matches)
matches.template remove_all_matching([](auto& match) { return match.view.is_null(); });
}
} else {
result.capture_group_matches.clear_with_capacity();
}
return result;
}
template<typename T>
class BumpAllocatedLinkedList {
public:
BumpAllocatedLinkedList() = default;
ALWAYS_INLINE void append(T value)
{
auto new_node = m_allocator.allocate();
VERIFY(new_node);
auto node_ptr = new (new_node) Node { move(value), nullptr, nullptr };
if (!m_first) {
m_first = new_node;
m_last = new_node;
return;
}
node_ptr->previous = m_last;
m_last->next = node_ptr;
m_last = node_ptr;
}
ALWAYS_INLINE T take_last()
{
VERIFY(m_last);
T value = move(m_last->value);
if (m_last == m_first) {
m_last = nullptr;
m_first = nullptr;
} else {
m_last = m_last->previous;
m_last->next = nullptr;
}
return value;
}
ALWAYS_INLINE T& last()
{
return m_last->value;
}
ALWAYS_INLINE bool is_empty() const
{
return m_first == nullptr;
}
private:
struct Node {
T value;
Node* next { nullptr };
Node* previous { nullptr };
};
UniformBumpAllocator<Node, true, 2 * MiB> m_allocator;
Node* m_first { nullptr };
Node* m_last { nullptr };
};
template<class Parser>
Optional<bool> Matcher<Parser>::execute(MatchInput const& input, MatchState& state, size_t& operations) const
{
BumpAllocatedLinkedList<MatchState> states_to_try_next;
size_t recursion_level = 0;
auto& bytecode = m_pattern->parser_result.bytecode;
for (;;) {
auto& opcode = bytecode.get_opcode(state);
++operations;
#if REGEX_DEBUG
s_regex_dbg.print_opcode("VM", opcode, state, recursion_level, false);
#endif
ExecutionResult result;
if (input.fail_counter > 0) {
--input.fail_counter;
result = ExecutionResult::Failed_ExecuteLowPrioForks;
} else {
result = opcode.execute(input, state);
}
#if REGEX_DEBUG
s_regex_dbg.print_result(opcode, bytecode, input, state, result);
#endif
state.instruction_position += opcode.size();
switch (result) {
case ExecutionResult::Fork_PrioLow:
states_to_try_next.append(state);
states_to_try_next.last().instruction_position = state.fork_at_position;
continue;
case ExecutionResult::Fork_PrioHigh:
states_to_try_next.append(state);
state.instruction_position = state.fork_at_position;
++recursion_level;
continue;
case ExecutionResult::Continue:
continue;
case ExecutionResult::Succeeded:
return true;
case ExecutionResult::Failed:
if (!states_to_try_next.is_empty()) {
state = states_to_try_next.take_last();
continue;
}
return false;
case ExecutionResult::Failed_ExecuteLowPrioForks: {
if (states_to_try_next.is_empty()) {
if (input.regex_options.has_flag_set(AllFlags::Internal_Stateful))
return {};
return false;
}
state = states_to_try_next.take_last();
++recursion_level;
continue;
}
}
}
VERIFY_NOT_REACHED();
}
template class Matcher<PosixBasicParser>;
template class Regex<PosixBasicParser>;
template class Matcher<PosixExtendedParser>;
template class Regex<PosixExtendedParser>;
template class Matcher<ECMA262Parser>;
template class Regex<ECMA262Parser>;
}
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