#include "selection.hh" #include "buffer_utils.hh" #include "changes.hh" #include "utf8.hh" namespace Kakoune { SelectionList::SelectionList(Buffer& buffer, Selection s, size_t timestamp) : m_selections({ std::move(s) }), m_buffer(&buffer), m_timestamp(timestamp) { check_invariant(); } SelectionList::SelectionList(Buffer& buffer, Selection s) : SelectionList(buffer, std::move(s), buffer.timestamp()) {} SelectionList::SelectionList(Buffer& buffer, Vector list, size_t timestamp) : m_selections(std::move(list)), m_buffer(&buffer), m_timestamp(timestamp) { kak_assert(size() > 0); m_main = size() - 1; check_invariant(); } SelectionList::SelectionList(Buffer& buffer, Vector list) : SelectionList(buffer, std::move(list), buffer.timestamp()) {} void SelectionList::remove(size_t index) { m_selections.erase(begin() + index); if (index < m_main or m_main == m_selections.size()) --m_main; } void SelectionList::set(Vector list, size_t main) { kak_assert(main < list.size()); m_selections = std::move(list); m_main = main; m_timestamp = m_buffer->timestamp(); sort_and_merge_overlapping(); check_invariant(); } bool compare_selections(const Selection& lhs, const Selection& rhs) { const auto& lmin = lhs.min(), rmin = rhs.min(); return lmin == rmin ? lhs.max() < rhs.max() : lmin < rmin; } namespace { BufferCoord update_insert(BufferCoord coord, BufferCoord begin, BufferCoord end) { if (coord < begin) return coord; if (begin.line == coord.line) coord.column += end.column - begin.column; coord.line += end.line - begin.line; kak_assert(coord.line >= 0 and coord.column >= 0); return coord; } /* For reference BufferCoord update_erase(BufferCoord coord, BufferCoord begin, BufferCoord end) { if (coord < begin) return coord; if (coord <= end) return begin; if (end.line == coord.line) coord.column -= end.column - begin.column; coord.line -= end.line - begin.line; kak_assert(coord.line >= 0 and coord.column >= 0); return coord; } */ template Iterator merge_overlapping(Iterator begin, Iterator end, size_t& main, OverlapsFunc overlaps) { if (begin == end) return begin; kak_assert(std::is_sorted(begin, end, compare_selections)); size_t size = end - begin; size_t i = 0; for (size_t j = 1; j < size; ++j) { if (overlaps(begin[i], begin[j])) { begin[i].min() = std::min(begin[i].min(), begin[j].min()); begin[i].max() = std::max(begin[i].max(), begin[j].max()); if (i < main) --main; } else { ++i; if (i != j) begin[i] = std::move(begin[j]); } } kak_assert(std::is_sorted(begin, begin + i +1, compare_selections)); return begin + i + 1; } } BufferCoord& get_first(Selection& sel) { return sel.min(); } BufferCoord& get_last(Selection& sel) { return sel.max(); } Vector compute_modified_ranges(const Buffer& buffer, size_t timestamp) { Vector ranges; auto changes = buffer.changes_since(timestamp); auto change_it = changes.begin(); while (change_it != changes.end()) { auto forward_end = forward_sorted_until(change_it, changes.end()); auto backward_end = backward_sorted_until(change_it, changes.end()); kak_assert(std::is_sorted(ranges.begin(), ranges.end(), compare_selections)); size_t prev_size; size_t dummy = 0; if (forward_end >= backward_end) { update_forward({ change_it, forward_end }, ranges); ranges.erase(merge_overlapping(ranges.begin(), ranges.end(), dummy, overlaps), ranges.end()); prev_size = ranges.size(); ForwardChangesTracker changes_tracker; for (; change_it != forward_end; ++change_it) { if (change_it->type == Buffer::Change::Insert) ranges.emplace_back(change_it->begin, change_it->end); else ranges.emplace_back(change_it->begin); changes_tracker.update(*change_it); } } else { update_backward({ change_it, backward_end }, ranges); ranges.erase(merge_overlapping(ranges.begin(), ranges.end(), dummy, overlaps), ranges.end()); prev_size = ranges.size(); using ReverseIt = std::reverse_iterator; ForwardChangesTracker changes_tracker; for (ReverseIt it{backward_end}, end{change_it}; it != end; ++it) { auto change = *it; change.begin = changes_tracker.get_new_coord(change.begin); change.end = changes_tracker.get_new_coord(change.end); if (change.type == Buffer::Change::Insert) ranges.emplace_back(change.begin, change.end); else ranges.emplace_back(change.begin); changes_tracker.update(change); } change_it = backward_end; } kak_assert(std::is_sorted(ranges.begin() + prev_size, ranges.end(), compare_selections)); std::inplace_merge(ranges.begin(), ranges.begin() + prev_size, ranges.end(), compare_selections); // The newly added ranges might be overlapping pre-existing ones ranges.erase(merge_overlapping(ranges.begin(), ranges.end(), dummy, overlaps), ranges.end()); } const auto end_coord = buffer.end_coord(); for (auto& range : ranges) { range.anchor() = std::min(range.anchor(), end_coord); range.cursor() = std::min(range.cursor(), end_coord); } auto touches = [&](const Selection& lhs, const Selection& rhs) { return lhs.max() == end_coord or buffer.char_next(lhs.max()) >= rhs.min(); }; size_t dummy = 0; ranges.erase(merge_overlapping(ranges.begin(), ranges.end(), dummy, touches), ranges.end()); for (auto& sel : ranges) { kak_assert(buffer.is_valid(sel.anchor())); kak_assert(buffer.is_valid(sel.cursor())); if (buffer.is_end(sel.anchor())) sel.anchor() = buffer.back_coord(); if (buffer.is_end(sel.cursor())) sel.cursor() = buffer.back_coord(); if (sel.anchor() != sel.cursor()) sel.cursor() = buffer.char_prev(sel.cursor()); } return ranges; } static void clamp(Selection& sel, const Buffer& buffer) { sel.anchor() = buffer.clamp(sel.anchor()); sel.cursor() = buffer.clamp(sel.cursor()); } void clamp_selections(Vector& selections, const Buffer& buffer) { for (auto& sel : selections) clamp(sel, buffer); } void update_selections(Vector& selections, size_t& main, const Buffer& buffer, size_t timestamp, bool merge) { if (timestamp == buffer.timestamp()) return; auto changes = buffer.changes_since(timestamp); auto change_it = changes.begin(); while (change_it != changes.end()) { auto forward_end = forward_sorted_until(change_it, changes.end()); auto backward_end = backward_sorted_until(change_it, changes.end()); if (forward_end >= backward_end) { update_forward({ change_it, forward_end }, selections); change_it = forward_end; } else { update_backward({ change_it, backward_end }, selections); change_it = backward_end; } kak_assert(std::is_sorted(selections.begin(), selections.end(), compare_selections)); if (merge) selections.erase( merge_overlapping(selections.begin(), selections.end(), main, overlaps), selections.end()); } for (auto& sel : selections) clamp(sel, buffer); if (merge) selections.erase(merge_overlapping(selections.begin(), selections.end(), main, overlaps), selections.end()); } void SelectionList::update(bool merge) { update_selections(m_selections, m_main, *m_buffer, m_timestamp, merge); check_invariant(); m_timestamp = m_buffer->timestamp(); } void SelectionList::check_invariant() const { #ifdef KAK_DEBUG auto& buffer = this->buffer(); kak_assert(size() > 0); kak_assert(m_main < size()); const size_t timestamp = buffer.timestamp(); kak_assert(timestamp >= m_timestamp); // cannot check further in that case if (timestamp != m_timestamp) return; const auto end_coord = buffer.end_coord(); BufferCoord last_min{0,0}; for (auto& sel : m_selections) { auto& min = sel.min(); kak_assert(min >= last_min); last_min = min; const auto anchor = sel.anchor(); kak_assert(anchor >= BufferCoord{0,0} and anchor < end_coord); kak_assert(anchor.column < buffer[anchor.line].length()); const auto cursor = sel.cursor(); kak_assert(cursor >= BufferCoord{0,0} and cursor < end_coord); kak_assert(cursor.column < buffer[cursor.line].length()); } #endif } void sort_selections(Vector& selections, size_t& main_index) { if (selections.size() == 1) return; const auto& main = selections[main_index]; const auto main_begin = main.min(); main_index = std::count_if(selections.begin(), selections.end(), [&](const Selection& sel) { auto begin = sel.min(); if (begin == main_begin) return &sel < &main; else return begin < main_begin; }); std::stable_sort(selections.begin(), selections.end(), compare_selections); } void merge_overlapping_selections(Vector& selections, size_t& main_index) { if (selections.size() == 1) return; selections.erase(Kakoune::merge_overlapping(selections.begin(), selections.end(), main_index, overlaps), selections.end()); } void SelectionList::sort() { sort_selections(m_selections, m_main); } void SelectionList::merge_overlapping() { merge_overlapping_selections(m_selections, m_main); } void SelectionList::merge_consecutive() { if (size() == 1) return; auto touches = [this](const Selection& lhs, const Selection& rhs) { return m_buffer->char_next(lhs.max()) >= rhs.min(); }; m_selections.erase(Kakoune::merge_overlapping(begin(), end(), m_main, touches), end()); } void SelectionList::sort_and_merge_overlapping() { sort(); merge_overlapping(); } BufferCoord get_insert_pos(const Buffer& buffer, const Selection& sel, InsertMode mode) { switch (mode) { case InsertMode::Insert: return sel.min(); case InsertMode::InsertCursor: return sel.cursor(); case InsertMode::Append: return buffer.char_next(sel.max()); case InsertMode::InsertAtLineBegin: return sel.min().line; case InsertMode::AppendAtLineEnd: return {sel.max().line, buffer[sel.max().line].length() - 1}; case InsertMode::InsertAtNextLineBegin: return sel.max().line+1; default: kak_assert(false); return {}; } } static void fix_overflowing_selections(Vector& selections, const Buffer& buffer) { const BufferCoord back_coord = buffer.back_coord(); for (auto& sel : selections) { sel.cursor() = std::min(buffer.clamp(sel.cursor()), back_coord); sel.anchor() = std::min(buffer.clamp(sel.anchor()), back_coord); } } void SelectionList::insert(ConstArrayView strings, InsertMode mode, Vector* out_insert_pos) { if (strings.empty()) return; update(); Vector insert_pos; if (mode != InsertMode::Replace) { for (auto& sel : m_selections) insert_pos.push_back(get_insert_pos(*m_buffer, sel, mode)); } ForwardChangesTracker changes_tracker; for (size_t index = 0; index < m_selections.size(); ++index) { auto& sel = m_selections[index]; sel.anchor() = changes_tracker.get_new_coord_tolerant(sel.anchor()); sel.cursor() = changes_tracker.get_new_coord_tolerant(sel.cursor()); kak_assert(m_buffer->is_valid(sel.anchor()) and m_buffer->is_valid(sel.cursor())); const String& str = strings[std::min(index, strings.size()-1)]; const auto pos = (mode == InsertMode::Replace) ? sel.min() : changes_tracker.get_new_coord(insert_pos[index]); if (mode == InsertMode::Replace) replace(*m_buffer, sel, str); else m_buffer->insert(pos, str); size_t old_timestamp = m_timestamp; changes_tracker.update(*m_buffer, m_timestamp); if (out_insert_pos) out_insert_pos->push_back(pos); if (mode == InsertMode::Replace) { auto changes = m_buffer->changes_since(old_timestamp); if (changes.size() == 1) // Nothing got inserted, either str was empty, or just \n at end of buffer sel.anchor() = sel.cursor() = m_buffer->clamp(pos); else if (changes.size() == 2) { // we want min and max from *before* we do any change auto& min = sel.min(); auto& max = sel.max(); min = changes.back().begin; max = m_buffer->char_prev(changes.back().end); } else kak_assert(changes.empty()); } else if (not str.empty()) { auto& change = m_buffer->changes_since(0).back(); sel.anchor() = m_buffer->clamp(update_insert(sel.anchor(), change.begin, change.end)); sel.cursor() = m_buffer->clamp(update_insert(sel.cursor(), change.begin, change.end)); } } // We might just have been deleting text if strings were empty, // in which case we could have some selections pushed out of the buffer if (mode == InsertMode::Replace) fix_overflowing_selections(m_selections, *m_buffer); check_invariant(); m_buffer->check_invariant(); } void SelectionList::erase() { update(); merge_overlapping(); ForwardChangesTracker changes_tracker; for (auto& sel : m_selections) { sel.anchor() = changes_tracker.get_new_coord(sel.anchor()); kak_assert(m_buffer->is_valid(sel.anchor())); sel.cursor() = changes_tracker.get_new_coord(sel.cursor()); kak_assert(m_buffer->is_valid(sel.cursor())); auto pos = Kakoune::erase(*m_buffer, sel); sel.anchor() = sel.cursor() = pos; changes_tracker.update(*m_buffer, m_timestamp); } fix_overflowing_selections(m_selections, *m_buffer); m_buffer->check_invariant(); } String selection_to_string(ColumnType column_type, const Buffer& buffer, const Selection& selection, ColumnCount tabstop) { const auto& cursor = selection.cursor(); const auto& anchor = selection.anchor(); switch (column_type) { default: case ColumnType::Byte: return format("{}.{},{}.{}", anchor.line + 1, anchor.column + 1, cursor.line + 1, cursor.column + 1); case ColumnType::Codepoint: return format("{}.{},{}.{}", anchor.line + 1, buffer[anchor.line].char_count_to(anchor.column) + 1, cursor.line + 1, buffer[cursor.line].char_count_to(cursor.column) + 1); case ColumnType::DisplayColumn: kak_assert(tabstop != -1); return format("{}.{},{}.{}", anchor.line + 1, get_column(buffer, tabstop, anchor) + 1, cursor.line + 1, get_column(buffer, tabstop, cursor) + 1); } } String selection_list_to_string(ColumnType column_type, const SelectionList& selections, ColumnCount tabstop) { auto& buffer = selections.buffer(); kak_assert(selections.timestamp() == buffer.timestamp()); auto to_string = [&](const Selection& selection) { return selection_to_string(column_type, buffer, selection, tabstop); }; auto beg = &*selections.begin(), end = &*selections.end(); auto main = beg + selections.main_index(); using View = ConstArrayView; return join(concatenated(View{main, end}, View{beg, main}) | transform(to_string), ' ', false); } Selection selection_from_string(ColumnType column_type, const Buffer& buffer, StringView desc, ColumnCount tabstop) { auto comma = find(desc, ','); auto dot_anchor = find(StringView{desc.begin(), comma}, '.'); auto dot_cursor = find(StringView{comma, desc.end()}, '.'); if (comma == desc.end() or dot_anchor == comma or dot_cursor == desc.end()) throw runtime_error(format("'{}' does not follow .,. format", desc)); auto compute_coord = [&](int line, int column) -> BufferCoord { if (line < 0 or column < 0) throw runtime_error(format("coordinate {}.{} does not exist in buffer", line + 1, column + 1)); switch (column_type) { default: case ColumnType::Byte: return {line, column}; case ColumnType::Codepoint: if (buffer.line_count() <= line or buffer[line].char_length() <= column) throw runtime_error(format("coordinate {}.{} does not exist in buffer", line + 1, column + 1)); return {line, buffer[line].byte_count_to(CharCount{column})}; case ColumnType::DisplayColumn: kak_assert(tabstop != -1); if (buffer.line_count() <= line or column_length(buffer, tabstop, line) <= column) throw runtime_error(format("coordinate {}.{} does not exist in buffer", line + 1, column + 1)); return {line, get_byte_to_column(buffer, tabstop, DisplayCoord{line, ColumnCount{column}})}; } }; auto anchor = compute_coord(str_to_int({desc.begin(), dot_anchor}) - 1, str_to_int({dot_anchor+1, comma}) - 1); auto cursor = compute_coord(str_to_int({comma+1, dot_cursor}) - 1, str_to_int({dot_cursor+1, desc.end()}) - 1); return Selection{anchor, cursor}; } }