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kakoune/src/regex_impl.hh
Maxime Coste 7ed5d53fe6 Fix RegexCompileFlags::Backwards having the same value as Optimize 
That means every Optimized regex had the Backwards version
compiled as well, which doubled the time it took to compile them
and doubled the memory usage of regex.

This should improve #2152
2018-07-19 18:34:40 +10:00

637 lines
23 KiB
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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"
namespace Kakoune
{
struct regex_error : runtime_error
{
using runtime_error::runtime_error;
};
enum class MatchDirection
{
Forward,
Backward
};
enum class CharacterType : unsigned char
{
None = 0,
Whitespace = 1 << 0,
HorizontalWhitespace = 1 << 1,
Word = 1 << 2,
Digit = 1 << 3,
NotWhitespace = 1 << 4,
NotHorizontalWhitespace = 1 << 5,
NotWord = 1 << 6,
NotDigit = 1 << 7
};
constexpr bool with_bit_ops(Meta::Type<CharacterType>) { return true; }
struct CharacterClass
{
struct Range { Codepoint min, max; };
Vector<Range, MemoryDomain::Regex> ranges;
CharacterType ctypes = CharacterType::None;
bool negative = false;
bool ignore_case = false;
};
bool is_character_class(const CharacterClass& character_class, Codepoint cp);
bool is_ctype(CharacterType ctype, Codepoint cp);
struct CompiledRegex : RefCountable, UseMemoryDomain<MemoryDomain::Regex>
{
enum Op : char
{
Match,
FindNextStart,
Literal,
Literal_IgnoreCase,
AnyChar,
AnyCharExceptNewLine,
Class,
CharacterType,
Jump,
Split_PrioritizeParent,
Split_PrioritizeChild,
Save,
LineStart,
LineEnd,
WordBoundary,
NotWordBoundary,
SubjectBegin,
SubjectEnd,
LookAhead,
NegativeLookAhead,
LookBehind,
NegativeLookBehind,
LookAhead_IgnoreCase,
NegativeLookAhead_IgnoreCase,
LookBehind_IgnoreCase,
NegativeLookBehind_IgnoreCase,
};
struct Instruction
{
Op op;
// Those mutables are used during execution
mutable bool scheduled;
mutable uint16_t last_step;
uint32_t param;
};
static_assert(sizeof(Instruction) == 8, "");
static constexpr uint16_t search_prefix_size = 3;
explicit operator bool() const { return not instructions.empty(); }
Vector<Instruction, MemoryDomain::Regex> instructions;
Vector<CharacterClass, MemoryDomain::Regex> character_classes;
Vector<Codepoint, MemoryDomain::Regex> lookarounds;
uint32_t first_backward_inst; // -1 if no backward support, 0 if only backward, >0 if both forward and backward
uint32_t save_count;
struct StartDesc : UseMemoryDomain<MemoryDomain::Regex>
{
static constexpr Codepoint count = 128;
static constexpr Codepoint other = 0;
bool map[count];
};
std::unique_ptr<StartDesc> forward_start_desc;
std::unique_ptr<StartDesc> backward_start_desc;
};
String dump_regex(const CompiledRegex& program);
enum class RegexCompileFlags
{
None = 0,
NoSubs = 1 << 0,
Optimize = 1 << 1,
Backward = 1 << 2,
NoForward = 1 << 3,
};
constexpr bool with_bit_ops(Meta::Type<RegexCompileFlags>) { return true; }
CompiledRegex compile_regex(StringView re, RegexCompileFlags flags);
enum class RegexExecFlags
{
None = 0,
Search = 1 << 0,
NotBeginOfLine = 1 << 1,
NotEndOfLine = 1 << 2,
NotBeginOfWord = 1 << 3,
NotEndOfWord = 1 << 4,
NotInitialNull = 1 << 5,
AnyMatch = 1 << 6,
NoSaves = 1 << 7,
};
constexpr bool with_bit_ops(Meta::Type<RegexExecFlags>) { return true; }
template<typename Iterator, MatchDirection direction>
class ThreadedRegexVM
{
public:
ThreadedRegexVM(const CompiledRegex& program)
: m_program{program}
{
kak_assert((direction == MatchDirection::Forward and program.first_backward_inst != 0) or
(direction == MatchDirection::Backward and program.first_backward_inst != -1));
}
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();
operator delete(saves);
}
}
bool exec(Iterator begin, Iterator end,
Iterator subject_begin, Iterator subject_end,
RegexExecFlags flags)
{
if (flags & RegexExecFlags::NotInitialNull and begin == end)
return false;
constexpr bool forward = direction == MatchDirection::Forward;
if (not forward) // Flip line begin/end flags as we flipped the instructions on compilation.
flags = (RegexExecFlags)(flags & ~(RegexExecFlags::NotEndOfLine | RegexExecFlags::NotBeginOfLine)) |
((flags & RegexExecFlags::NotEndOfLine) ? RegexExecFlags::NotBeginOfLine : RegexExecFlags::None) |
((flags & RegexExecFlags::NotBeginOfLine) ? RegexExecFlags::NotEndOfLine : RegexExecFlags::None);
const bool search = (flags & RegexExecFlags::Search);
ConstArrayView<CompiledRegex::Instruction> instructions{m_program.instructions};
if (direction == MatchDirection::Forward)
instructions = instructions.subrange(0, m_program.first_backward_inst);
else
instructions = instructions.subrange(m_program.first_backward_inst);
if (not search)
instructions = instructions.subrange(CompiledRegex::search_prefix_size);
const ExecConfig config{
EffectiveIt{Utf8It{forward ? begin : end, subject_begin, subject_end}},
EffectiveIt{Utf8It{forward ? end : begin, subject_begin, subject_end}},
EffectiveIt{Utf8It{forward ? subject_begin : subject_end, subject_begin, subject_end}},
EffectiveIt{Utf8It{forward ? subject_end : subject_begin, subject_begin, subject_end}},
flags,
instructions
};
EffectiveIt start{config.begin};
if (const auto& start_desc = direction == MatchDirection::Forward ?
m_program.forward_start_desc : m_program.backward_start_desc)
{
if (search)
{
to_next_start(start, config.end, *start_desc);
if (start == config.end) // If start_desc is not null, it means we consume at least one char
return false;
}
else if (start != config.end and
not start_desc->map[*start < StartDesc::count ? *start : StartDesc::other])
return false;
}
return exec_program(std::move(start), config);
}
ArrayView<const Iterator> captures() const
{
if (m_captures >= 0)
return { m_saves[m_captures]->pos, m_program.save_count };
return {};
}
private:
struct Saves
{
union // ref count when in use, next_free when in free list
{
int16_t refcount;
int16_t next_free;
};
Iterator pos[1];
};
template<bool copy>
int16_t new_saves(Iterator* pos)
{
kak_assert(not copy or pos != nullptr);
const auto count = m_program.save_count;
if (m_first_free >= 0)
{
const int16_t res = m_first_free;
Saves* save = m_saves[res];
m_first_free = save->next_free;
save->refcount = 1;
if (copy)
std::copy(pos, pos + count, save->pos);
else
std::fill(save->pos, save->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 static_cast<int16_t>(m_saves.size() - 1);
}
void release_saves(int16_t saves)
{
if (saves >= 0 and --m_saves[saves]->refcount == 0)
{
m_saves[saves]->next_free = m_first_free;
m_first_free = saves;
}
};
struct Thread
{
int16_t inst;
int16_t saves;
};
using StartDesc = CompiledRegex::StartDesc;
using Utf8It = utf8::iterator<Iterator>;
using EffectiveIt = std::conditional_t<direction == MatchDirection::Forward,
Utf8It, std::reverse_iterator<Utf8It>>;
struct ExecConfig
{
const EffectiveIt begin;
const EffectiveIt end;
const EffectiveIt subject_begin;
const EffectiveIt subject_end;
const RegexExecFlags flags;
ConstArrayView<CompiledRegex::Instruction> instructions;
};
enum class StepResult { Consumed, Matched, Failed, FindNextStart };
// Steps a thread until it consumes the current character, matches or fail
StepResult step(EffectiveIt& pos, uint16_t current_step, Thread& thread, const ExecConfig& config)
{
const bool no_saves = (config.flags & RegexExecFlags::NoSaves);
auto* instructions = m_program.instructions.data();
while (true)
{
auto& inst = instructions[thread.inst++];
// if this instruction was already executed for this step in another thread,
// then this thread is redundant and can be dropped
if (inst.last_step == current_step)
return StepResult::Failed;
inst.last_step = current_step;
switch (inst.op)
{
case CompiledRegex::Literal:
if (pos != config.end and inst.param == *pos)
return StepResult::Consumed;
return StepResult::Failed;
case CompiledRegex::Literal_IgnoreCase:
if (pos != config.end and inst.param == to_lower(*pos))
return StepResult::Consumed;
return StepResult::Failed;
case CompiledRegex::AnyChar:
return StepResult::Consumed;
case CompiledRegex::AnyCharExceptNewLine:
if (pos != config.end and *pos != '\n')
return StepResult::Consumed;
return StepResult::Failed;
case CompiledRegex::Jump:
thread.inst = static_cast<int16_t>(inst.param);
break;
case CompiledRegex::Split_PrioritizeParent:
{
if (thread.saves >= 0)
++m_saves[thread.saves]->refcount;
m_threads.push_current({static_cast<int16_t>(inst.param), thread.saves});
break;
}
case CompiledRegex::Split_PrioritizeChild:
{
if (thread.saves >= 0)
++m_saves[thread.saves]->refcount;
m_threads.push_current({thread.inst, thread.saves});
thread.inst = static_cast<uint16_t>(inst.param);
break;
}
case CompiledRegex::Save:
{
if (no_saves)
break;
if (thread.saves < 0)
thread.saves = new_saves<false>(nullptr);
else if (m_saves[thread.saves]->refcount > 1)
{
--m_saves[thread.saves]->refcount;
thread.saves = new_saves<true>(m_saves[thread.saves]->pos);
}
m_saves[thread.saves]->pos[inst.param] = get_base(pos);
break;
}
case CompiledRegex::Class:
if (pos == config.end)
return StepResult::Failed;
return is_character_class(m_program.character_classes[inst.param], *pos) ?
StepResult::Consumed : StepResult::Failed;
case CompiledRegex::CharacterType:
if (pos == config.end)
return StepResult::Failed;
return is_ctype((CharacterType)inst.param, *pos) ?
StepResult::Consumed : StepResult::Failed;;
case CompiledRegex::LineStart:
if (not is_line_start(pos, config))
return StepResult::Failed;
break;
case CompiledRegex::LineEnd:
if (not is_line_end(pos, config))
return StepResult::Failed;
break;
case CompiledRegex::WordBoundary:
if (not is_word_boundary(pos, config))
return StepResult::Failed;
break;
case CompiledRegex::NotWordBoundary:
if (is_word_boundary(pos, config))
return StepResult::Failed;
break;
case CompiledRegex::SubjectBegin:
if (pos != config.subject_begin)
return StepResult::Failed;
break;
case CompiledRegex::SubjectEnd:
if (pos != config.subject_end)
return StepResult::Failed;
break;
case CompiledRegex::LookAhead:
case CompiledRegex::NegativeLookAhead:
if (lookaround<MatchDirection::Forward, false>(inst.param, pos, config) !=
(inst.op == CompiledRegex::LookAhead))
return StepResult::Failed;
break;
case CompiledRegex::LookAhead_IgnoreCase:
case CompiledRegex::NegativeLookAhead_IgnoreCase:
if (lookaround<MatchDirection::Forward, true>(inst.param, pos, config) !=
(inst.op == CompiledRegex::LookAhead_IgnoreCase))
return StepResult::Failed;
break;
case CompiledRegex::LookBehind:
case CompiledRegex::NegativeLookBehind:
if (lookaround<MatchDirection::Backward, false>(inst.param, pos, config) !=
(inst.op == CompiledRegex::LookBehind))
return StepResult::Failed;
break;
case CompiledRegex::LookBehind_IgnoreCase:
case CompiledRegex::NegativeLookBehind_IgnoreCase:
if (lookaround<MatchDirection::Backward, true>(inst.param, pos, config) !=
(inst.op == CompiledRegex::LookBehind_IgnoreCase))
return StepResult::Failed;
break;
case CompiledRegex::FindNextStart:
kak_assert(m_threads.current_is_empty()); // search thread should by construction be the lower priority one
if (m_threads.next_is_empty())
return StepResult::FindNextStart;
return StepResult::Consumed;
case CompiledRegex::Match:
return StepResult::Matched;
}
}
return StepResult::Failed;
}
bool exec_program(EffectiveIt pos, const ExecConfig& config)
{
kak_assert(m_threads.current_is_empty() and m_threads.next_is_empty());
release_saves(m_captures);
m_captures = -1;
m_threads.push_current({static_cast<int16_t>(&config.instructions[0] - &m_program.instructions[0]), -1});
const auto& start_desc = direction == MatchDirection::Forward ? m_program.forward_start_desc
: m_program.backward_start_desc;
uint16_t current_step = -1;
bool found_match = false;
while (true) // Iterate on all codepoints and once at the end
{
if (++current_step == 0)
{
// We wrapped, avoid potential collision on inst.last_step by resetting them
for (auto& inst : config.instructions)
inst.last_step = 0;
current_step = 1; // step 0 is never valid
}
bool find_next_start = false;
while (not m_threads.current_is_empty())
{
auto thread = m_threads.pop_current();
switch (step(pos, current_step, thread, config))
{
case StepResult::Matched:
if ((pos != config.end and not (config.flags & RegexExecFlags::Search)) or
(config.flags & RegexExecFlags::NotInitialNull and pos == config.begin))
{
release_saves(thread.saves);
continue;
}
release_saves(m_captures);
m_captures = thread.saves;
found_match = true;
// remove this and lower priority threads
while (not m_threads.current_is_empty())
release_saves(m_threads.pop_current().saves);
break;
case StepResult::Failed:
release_saves(thread.saves);
break;
case StepResult::Consumed:
if (m_program.instructions[thread.inst].scheduled)
{
release_saves(thread.saves);
continue;
}
m_program.instructions[thread.inst].scheduled = true;
m_threads.push_next(thread);
break;
case StepResult::FindNextStart:
m_threads.push_next(thread);
find_next_start = true;
break;
}
}
for (auto& thread : m_threads.next_threads())
m_program.instructions[thread.inst].scheduled = false;
if (pos == config.end or m_threads.next_is_empty() or
(found_match and (config.flags & RegexExecFlags::AnyMatch)))
{
for (auto& t : m_threads.next_threads())
release_saves(t.saves);
m_threads.clear_next();
return found_match;
}
m_threads.swap_next();
++pos;
if (find_next_start and start_desc)
to_next_start(pos, config.end, *start_desc);
}
}
void to_next_start(EffectiveIt& start, const EffectiveIt& end, const StartDesc& start_desc)
{
Codepoint cp;
while (start != end and (cp = *start) >= 0 and
not start_desc.map[cp < StartDesc::count ? cp : StartDesc::other])
++start;
}
template<MatchDirection look_direction, bool ignore_case>
bool lookaround(uint32_t index, EffectiveIt pos, const ExecConfig& config) const
{
const auto end = (look_direction == MatchDirection::Forward ? config.subject_end : config.subject_begin);
for (auto it = m_program.lookarounds.begin() + index; *it != -1; ++it)
{
if (pos == end)
return false;
Codepoint cp = (look_direction == MatchDirection::Forward ? *pos : *(pos-1));
if (ignore_case)
cp = to_lower(cp);
const Codepoint ref = *it;
if (ref == 0xF000)
{} // any character matches
else if (ref == 0xF001)
{
if (cp == '\n')
return false;
}
else if (ref > 0xF0000 and ref < 0xF8000)
{
if (not is_character_class(m_program.character_classes[ref - 0xF0001], cp))
return false;
}
else if (ref >= 0xF8000 and ref <= 0xFFFFD)
{
if (not is_ctype((CharacterType)(ref & 0xFF), cp))
return false;
}
else if (ref != cp)
return false;
(look_direction == MatchDirection::Forward) ? ++pos : --pos;
}
return true;
}
static bool is_line_start(const EffectiveIt& pos, const ExecConfig& config)
{
if (pos == config.subject_begin)
return not (config.flags & RegexExecFlags::NotBeginOfLine);
return *(pos-1) == '\n';
}
static bool is_line_end(const EffectiveIt& pos, const ExecConfig& config)
{
if (pos == config.subject_end)
return not (config.flags & RegexExecFlags::NotEndOfLine);
return *pos == '\n';
}
static bool is_word_boundary(const EffectiveIt& pos, const ExecConfig& config)
{
if (pos == config.subject_begin)
return not (config.flags & RegexExecFlags::NotBeginOfWord);
if (pos == config.subject_end)
return not (config.flags & RegexExecFlags::NotEndOfWord);
return is_word(*(pos-1)) != is_word(*pos);
}
static const Iterator& get_base(const Utf8It& it) { return it.base(); }
static Iterator get_base(const std::reverse_iterator<Utf8It>& it) { return it.base().base(); }
const CompiledRegex& m_program;
struct DualThreadStack
{
bool current_is_empty() const { return m_current == 0; }
bool next_is_empty() const { return m_next == m_capacity; }
void push_current(Thread thread) { grow_ifn(); m_data[m_current++] = thread; }
Thread pop_current() { kak_assert(m_current > 0); return m_data[--m_current]; }
void push_next(Thread thread) { grow_ifn(); m_data[--m_next] = thread; }
void clear_next() { m_next = m_capacity; }
ConstArrayView<Thread> next_threads() const { return { m_data + m_next, m_data + m_capacity }; }
void swap_next()
{
for (; m_next < m_capacity; m_current++, m_next++)
m_data[m_current] = m_data[m_next];
}
private:
void grow_ifn()
{
if (m_current != m_next)
return;
const auto new_capacity = m_capacity ? m_capacity * 2 : 4;
Thread* new_data = new Thread[new_capacity];
std::copy(m_data, m_data + m_current, new_data);
const auto new_next = new_capacity - (m_capacity - m_next);
std::copy(m_data + m_next, m_data + m_capacity, new_data + new_next);
delete[] m_data;
m_capacity = new_capacity;
m_next = new_next;
m_data = new_data;
}
Thread* m_data = nullptr;
int16_t m_capacity = 0;
int16_t m_current = 0;
int16_t m_next = 0;
};
DualThreadStack m_threads;
Vector<Saves*, MemoryDomain::Regex> m_saves;
int16_t m_first_free = -1;
int16_t m_captures = -1;
};
}
#endif // regex_impl_hh_INCLUDED
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