kakoune/src/regex_impl.hh

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#ifndef regex_impl_hh_INCLUDED
#define regex_impl_hh_INCLUDED
#include "exception.hh"
#include "flags.hh"
#include "ref_ptr.hh"
#include "unicode.hh"
#include "utf8.hh"
#include "utf8_iterator.hh"
#include "vector.hh"
#include <string.h>
namespace Kakoune
{
enum class MatchDirection
{
Forward,
Backward
};
struct CompiledRegex : RefCountable
{
enum Op : char
{
Match,
Literal,
LiteralIgnoreCase,
AnyChar,
Matcher,
Jump,
Split_PrioritizeParent,
Split_PrioritizeChild,
Save,
LineStart,
LineEnd,
WordBoundary,
NotWordBoundary,
SubjectBegin,
SubjectEnd,
LookAhead,
NegativeLookAhead,
LookBehind,
NegativeLookBehind,
};
using Offset = unsigned;
explicit operator bool() const { return not bytecode.empty(); }
Vector<char> bytecode;
Vector<std::function<bool (Codepoint)>> matchers;
MatchDirection direction;
size_t save_count;
struct StartChars { bool map[256]; };
std::unique_ptr<StartChars> start_chars;
};
CompiledRegex compile_regex(StringView re, MatchDirection direction = MatchDirection::Forward);
enum class RegexExecFlags
{
None = 0,
Search = 1 << 0,
NotBeginOfLine = 1 << 1,
NotEndOfLine = 1 << 2,
NotBeginOfWord = 1 << 3,
NotEndOfWord = 1 << 4,
NotBeginOfSubject = 1 << 5,
NotInitialNull = 1 << 6,
AnyMatch = 1 << 7,
NoSaves = 1 << 8,
};
constexpr bool with_bit_ops(Meta::Type<RegexExecFlags>) { return true; }
template<typename Iterator, MatchDirection direction>
struct ChooseUtf8It
{
using Type = utf8::iterator<Iterator>;
};
template<typename Iterator>
struct ChooseUtf8It<Iterator, MatchDirection::Backward>
{
using Type = std::reverse_iterator<utf8::iterator<Iterator>>;
};
template<typename Iterator, MatchDirection direction>
class ThreadedRegexVM
{
public:
ThreadedRegexVM(const CompiledRegex& program)
: m_program{program}
{
kak_assert(m_program);
if (direction != program.direction)
throw runtime_error{"Regex and VM direction mismatch"};
}
ThreadedRegexVM(const ThreadedRegexVM&) = delete;
ThreadedRegexVM& operator=(const ThreadedRegexVM&) = delete;
~ThreadedRegexVM()
{
for (auto* saves : m_saves)
{
for (size_t i = m_program.save_count-1; i > 0; --i)
saves->pos[i].~Iterator();
saves->~Saves();
}
}
bool exec(Iterator begin, Iterator end, RegexExecFlags flags)
{
const bool forward = direction == MatchDirection::Forward;
m_begin = Utf8It{utf8::iterator<Iterator>{forward ? begin : end, begin, end}};
m_end = Utf8It{utf8::iterator<Iterator>{forward ? end : begin, begin, end}};
m_flags = flags;
if (flags & RegexExecFlags::NotInitialNull and m_begin == m_end)
return false;
Vector<Thread> current_threads, next_threads;
const bool no_saves = (m_flags & RegexExecFlags::NoSaves);
Utf8It start{m_begin};
const bool* start_chars = m_program.start_chars ? m_program.start_chars->map : nullptr;
if (flags & RegexExecFlags::Search)
to_next_start(start, m_end, start_chars);
if (exec_from(start, no_saves ? nullptr : new_saves<false>(nullptr),
current_threads, next_threads))
return true;
if (not (flags & RegexExecFlags::Search))
return false;
do
{
to_next_start(++start, m_end, start_chars);
if (exec_from(start, no_saves ? nullptr : new_saves<false>(nullptr),
current_threads, next_threads))
return true;
}
while (start != m_end);
return false;
}
ArrayView<const Iterator> captures() const
{
if (m_captures)
return { m_captures->pos, m_program.save_count };
return {};
}
private:
struct Saves
{
int refcount;
Iterator pos[1];
};
template<bool copy>
Saves* new_saves(Iterator* pos)
{
kak_assert(not copy or pos != nullptr);
const auto count = m_program.save_count;
if (not m_free_saves.empty())
{
Saves* res = m_free_saves.back();
m_free_saves.pop_back();
res->refcount = 1;
if (copy)
std::copy(pos, pos + count, res->pos);
else
std::fill(res->pos, res->pos + count, Iterator{});
return res;
}
void* ptr = ::operator new (sizeof(Saves) + (count-1) * sizeof(Iterator));
Saves* saves = new (ptr) Saves{1, copy ? pos[0] : Iterator{}};
for (size_t i = 1; i < count; ++i)
new (&saves->pos[i]) Iterator{copy ? pos[i] : Iterator{}};
m_saves.push_back(saves);
return saves;
}
void release_saves(Saves* saves)
{
if (saves and --saves->refcount == 0)
m_free_saves.push_back(saves);
};
struct Thread
{
const char* inst;
Saves* saves;
};
using Utf8It = typename ChooseUtf8It<Iterator, direction>::Type;
enum class StepResult { Consumed, Matched, Failed };
StepResult step(const Utf8It& pos, Thread& thread, Vector<Thread>& threads)
{
const auto prog_start = m_program.bytecode.data();
const auto prog_end = prog_start + m_program.bytecode.size();
while (true)
{
const Codepoint cp = pos == m_end ? 0 : *pos;
const CompiledRegex::Op op = (CompiledRegex::Op)*thread.inst++;
switch (op)
{
case CompiledRegex::Literal:
if (utf8::read_codepoint(thread.inst, prog_end) == cp)
return StepResult::Consumed;
return StepResult::Failed;
case CompiledRegex::LiteralIgnoreCase:
if (utf8::read_codepoint(thread.inst, prog_end) == to_lower(cp))
return StepResult::Consumed;
return StepResult::Failed;
case CompiledRegex::AnyChar:
return StepResult::Consumed;
case CompiledRegex::Jump:
thread.inst = prog_start + get_offset(thread.inst);
break;
case CompiledRegex::Split_PrioritizeParent:
{
auto parent = thread.inst + sizeof(CompiledRegex::Offset);
auto child = prog_start + get_offset(thread.inst);
thread.inst = parent;
if (thread.saves)
++thread.saves->refcount;
threads.push_back({child, thread.saves});
break;
}
case CompiledRegex::Split_PrioritizeChild:
{
auto parent = thread.inst + sizeof(CompiledRegex::Offset);
auto child = prog_start + get_offset(thread.inst);
thread.inst = child;
if (thread.saves)
++thread.saves->refcount;
threads.push_back({parent, thread.saves});
break;
}
case CompiledRegex::Save:
{
const size_t index = *thread.inst++;
if (thread.saves == nullptr)
break;
if (thread.saves->refcount > 1)
{
--thread.saves->refcount;
thread.saves = new_saves<true>(thread.saves->pos);
}
thread.saves->pos[index] = get_base(pos);
break;
}
case CompiledRegex::Matcher:
{
const int matcher_id = *thread.inst++;
return m_program.matchers[matcher_id](cp) ?
StepResult::Consumed : StepResult::Failed;
}
case CompiledRegex::LineStart:
if (not is_line_start(pos))
return StepResult::Failed;
break;
case CompiledRegex::LineEnd:
if (not is_line_end(pos))
return StepResult::Failed;
break;
case CompiledRegex::WordBoundary:
if (not is_word_boundary(pos))
return StepResult::Failed;
break;
case CompiledRegex::NotWordBoundary:
if (is_word_boundary(pos))
return StepResult::Failed;
break;
case CompiledRegex::SubjectBegin:
if (pos != m_begin or (m_flags & RegexExecFlags::NotBeginOfSubject))
return StepResult::Failed;
break;
case CompiledRegex::SubjectEnd:
if (pos != m_end)
return StepResult::Failed;
break;
case CompiledRegex::LookAhead:
case CompiledRegex::NegativeLookAhead:
{
int count = *thread.inst++;
for (auto it = pos; count and it != m_end; ++it, --count)
if (*it != utf8::read(thread.inst))
break;
if ((op == CompiledRegex::LookAhead and count != 0) or
(op == CompiledRegex::NegativeLookAhead and count == 0))
return StepResult::Failed;
thread.inst = utf8::advance(thread.inst, prog_end, CharCount{count - 1});
break;
}
case CompiledRegex::LookBehind:
case CompiledRegex::NegativeLookBehind:
{
int count = *thread.inst++;
for (auto it = pos-1; count and it >= m_begin; --it, --count)
if (*it != utf8::read(thread.inst))
break;
if ((op == CompiledRegex::LookBehind and count != 0) or
(op == CompiledRegex::NegativeLookBehind and count == 0))
return StepResult::Failed;
thread.inst = utf8::advance(thread.inst, prog_end, CharCount{count - 1});
break;
}
case CompiledRegex::Match:
return StepResult::Matched;
}
}
return StepResult::Failed;
}
bool exec_from(const Utf8It& start, Saves* initial_saves, Vector<Thread>& current_threads, Vector<Thread>& next_threads)
{
current_threads.push_back({m_program.bytecode.data(), initial_saves});
next_threads.clear();
bool found_match = false;
for (Utf8It pos = start; pos != m_end; ++pos)
{
while (not current_threads.empty())
{
auto thread = current_threads.back();
current_threads.pop_back();
switch (step(pos, thread, current_threads))
{
case StepResult::Matched:
if (not (m_flags & RegexExecFlags::Search) or // We are not at end, this is not a full match
(m_flags & RegexExecFlags::NotInitialNull and pos == m_begin))
{
release_saves(thread.saves);
continue;
}
release_saves(m_captures);
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m_captures = thread.saves;
if (m_flags & RegexExecFlags::AnyMatch)
return true;
found_match = true;
current_threads.clear(); // remove this and lower priority threads
break;
case StepResult::Failed:
release_saves(thread.saves);
break;
case StepResult::Consumed:
if (contains_that(next_threads, [&](auto& t) { return t.inst == thread.inst; }))
release_saves(thread.saves);
else
next_threads.push_back(thread);
break;
}
}
if (next_threads.empty())
return found_match;
std::swap(current_threads, next_threads);
std::reverse(current_threads.begin(), current_threads.end());
}
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if (found_match)
return true;
// Step remaining threads to see if they match without consuming anything else
while (not current_threads.empty())
{
auto thread = current_threads.back();
current_threads.pop_back();
if (step(m_end, thread, current_threads) == StepResult::Matched)
{
release_saves(m_captures);
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m_captures = thread.saves;
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return true;
}
}
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return false;
}
void to_next_start(Utf8It& start, const Utf8It& end, const bool* start_chars)
{
if (not start_chars)
return;
while (start != end and *start >= 0 and *start < 256 and
not start_chars[*start])
++start;
}
static CompiledRegex::Offset get_offset(const char* ptr)
{
CompiledRegex::Offset res;
memcpy(&res, ptr, sizeof(CompiledRegex::Offset));
return res;
}
bool is_line_start(const Utf8It& pos) const
{
return (pos == m_begin and not (m_flags & RegexExecFlags::NotBeginOfLine)) or
*(pos-1) == '\n';
}
bool is_line_end(const Utf8It& pos) const
{
return (pos == m_end and not (m_flags & RegexExecFlags::NotEndOfLine)) or
*pos == '\n';
}
bool is_word_boundary(const Utf8It& pos) const
{
return (pos == m_begin and not (m_flags & RegexExecFlags::NotBeginOfWord)) or
(pos == m_end and not (m_flags & RegexExecFlags::NotEndOfWord)) or
is_word(*(pos-1)) != is_word(*pos);
}
static const Iterator& get_base(const utf8::iterator<Iterator>& it) { return it.base(); }
static const Iterator& get_base(const std::reverse_iterator<utf8::iterator<Iterator>>& it) { return it.base().base(); }
const CompiledRegex& m_program;
Utf8It m_begin;
Utf8It m_end;
RegexExecFlags m_flags;
Vector<Saves*> m_saves;
Vector<Saves*> m_free_saves;
Saves* m_captures = nullptr;
};
template<typename It, MatchDirection direction = MatchDirection::Forward>
bool regex_match(It begin, It end, const CompiledRegex& re, RegexExecFlags flags = RegexExecFlags::None)
{
ThreadedRegexVM<It, direction> vm{re};
return vm.exec(begin, end, (RegexExecFlags)(flags & ~(RegexExecFlags::Search)) |
RegexExecFlags::AnyMatch | RegexExecFlags::NoSaves);
}
template<typename It, MatchDirection direction = MatchDirection::Forward>
bool regex_match(It begin, It end, Vector<It>& captures, const CompiledRegex& re,
RegexExecFlags flags = RegexExecFlags::None)
{
ThreadedRegexVM<It, direction> vm{re};
if (vm.exec(begin, end, flags & ~(RegexExecFlags::Search)))
{
std::copy(vm.captures().begin(), vm.captures().end(), std::back_inserter(captures));
return true;
}
return false;
}
template<typename It, MatchDirection direction = MatchDirection::Forward>
bool regex_search(It begin, It end, const CompiledRegex& re,
RegexExecFlags flags = RegexExecFlags::None)
{
ThreadedRegexVM<It, direction> vm{re};
return vm.exec(begin, end, flags | RegexExecFlags::Search | RegexExecFlags::AnyMatch | RegexExecFlags::NoSaves);
}
template<typename It, MatchDirection direction = MatchDirection::Forward>
bool regex_search(It begin, It end, Vector<It>& captures, const CompiledRegex& re,
RegexExecFlags flags = RegexExecFlags::None)
{
ThreadedRegexVM<It, direction> vm{re};
if (vm.exec(begin, end, flags | RegexExecFlags::Search))
{
std::copy(vm.captures().begin(), vm.captures().end(), std::back_inserter(captures));
return true;
}
return false;
}
}
#endif // regex_impl_hh_INCLUDED