#include "config.h" // IWYU pragma: keep // IWYU pragma: no_include #include #include #include #include #include #include #include "common.h" #include "complete.h" #include "fallback.h" #include "highlight.h" #include "pager.h" #include "reader.h" #include "screen.h" #include "util.h" #include "wutil.h" // IWYU pragma: keep typedef pager_t::comp_t comp_t; typedef std::vector completion_list_t; typedef std::vector comp_info_list_t; /// The minimum width (in characters) the terminal must to show completions at all. #define PAGER_MIN_WIDTH 16 /// The maximum number of columns of completion to attempt to fit onto the screen. #define PAGER_MAX_COLS 6 /// Width of the search field. #define PAGER_SEARCH_FIELD_WIDTH 12 /// Text we use for the search field. #define SEARCH_FIELD_PROMPT _(L"search: ") /// Returns numer / denom, rounding up. As a "courtesy" 0/0 is 0. static size_t divide_round_up(size_t numer, size_t denom) { if (numer == 0) return 0; assert(denom > 0); bool has_rem = (numer % denom) > 0; return numer / denom + (has_rem ? 1 : 0); } /// This function calculates the minimum width for each completion entry in the specified /// array_list. This width depends on the terminal size, so this function should be called when the /// terminal changes size. void pager_t::recalc_min_widths(comp_info_list_t *lst) const { for (size_t i = 0; i < lst->size(); i++) { comp_t *c = &lst->at(i); c->min_width = mini(c->desc_width, maxi((size_t)0, available_term_width / 3 - 2)) + mini(c->desc_width, maxi((size_t)0, available_term_width / 5 - 4)) + 4; } } /// Print the specified string, but use at most the specified amount of space. If the whole string /// can't be fitted, ellipsize it. /// /// \param str the string to print /// \param color the color to apply to every printed character /// \param max the maximum space that may be used for printing /// \param has_more if this flag is true, this is not the entire string, and the string should be /// ellisiszed even if the string fits but takes up the whole space. static int print_max(const wcstring &str, highlight_spec_t color, int max, bool has_more, line_t *line) { int written = 0; for (size_t i = 0; i < str.size(); i++) { wchar_t c = str.at(i); if (written + fish_wcwidth(c) > max) break; if ((written + fish_wcwidth(c) == max) && (has_more || i + 1 < str.size())) { line->append(ellipsis_char, color); written += fish_wcwidth(ellipsis_char); break; } line->append(c, color); written += fish_wcwidth(c); } return written; } /// Print the specified item using at the specified amount of space. line_t pager_t::completion_print_item(const wcstring &prefix, const comp_t *c, size_t row, size_t column, int width, bool secondary, bool selected, page_rendering_t *rendering) const { UNUSED(column); UNUSED(row); UNUSED(rendering); size_t comp_width, desc_width; line_t line_data; if (c->preferred_width() <= width) { // The entry fits, we give it as much space as it wants. comp_width = c->comp_width; desc_width = c->desc_width; } else { // The completion and description won't fit on the allocated space. Give a maximum of 2/3 of // the space to the completion, and whatever is left to the description. int desc_all = c->desc_width ? c->desc_width + 4 : 0; comp_width = maxi(mini((int)c->comp_width, 2 * (width - 4) / 3), width - desc_all); desc_width = c->desc_width ? width - 4 - comp_width : 0; } int bg_color = secondary ? highlight_spec_pager_secondary : highlight_spec_normal; if (selected) { bg_color = highlight_spec_search_match; } int written = 0; for (size_t i = 0; i < c->comp.size(); i++) { const wcstring &comp = c->comp.at(i); if (i != 0) written += print_max(PAGER_SPACER_STRING, highlight_spec_normal, comp_width - written, true /* has_more */, &line_data); int packed_color = highlight_spec_pager_prefix | highlight_make_background(bg_color); written += print_max(prefix, packed_color, comp_width - written, !comp.empty(), &line_data); packed_color = highlight_spec_pager_completion | highlight_make_background(bg_color); written += print_max(comp, packed_color, comp_width - written, i + 1 < c->comp.size(), &line_data); } if (desc_width) { int packed_color = highlight_spec_pager_description | highlight_make_background(bg_color); while (written < (width - desc_width - 2)) // the 2 here refers to the parenthesis below { written += print_max(L" ", packed_color, 1, false, &line_data); } // hack - this just works around the issue print_max(L"(", highlight_spec_pager_completion | highlight_make_background(bg_color), 1, false, &line_data); print_max(c->desc, packed_color, desc_width, false, &line_data); print_max(L")", highlight_spec_pager_completion | highlight_make_background(bg_color), 1, false, &line_data); } else { while (written < width) { written += print_max(L" ", 0, 1, false, &line_data); } } return line_data; } /// Print the specified part of the completion list, using the specified column offsets and quoting /// style. /// /// \param cols number of columns to print in /// \param width_per_column An array specifying the width of each column /// \param row_start The first row to print /// \param row_stop the row after the last row to print /// \param prefix The string to print before each completion /// \param lst The list of completions to print void pager_t::completion_print(size_t cols, int *width_per_column, size_t row_start, size_t row_stop, const wcstring &prefix, const comp_info_list_t &lst, page_rendering_t *rendering) const { // Teach the rendering about the rows it printed. assert(row_start >= 0); assert(row_stop >= row_start); rendering->row_start = row_start; rendering->row_end = row_stop; size_t rows = (lst.size() - 1) / cols + 1; size_t effective_selected_idx = this->visual_selected_completion_index(rows, cols); for (size_t row = row_start; row < row_stop; row++) { for (size_t col = 0; col < cols; col++) { int is_last = (col == (cols - 1)); if (lst.size() <= col * rows + row) continue; size_t idx = col * rows + row; const comp_t *el = &lst.at(idx); bool is_selected = (idx == effective_selected_idx); // Print this completion on its own "line". line_t line = completion_print_item( prefix, el, row, col, width_per_column[col] - (is_last ? 0 : PAGER_SPACER_STRING_WIDTH), row % 2, is_selected, rendering); // If there's more to come, append two spaces. if (col + 1 < cols) { line.append(PAGER_SPACER_STRING, 0); } // Append this to the real line. rendering->screen_data.create_line(row - row_start).append_line(line); } } } /// Trim leading and trailing whitespace, and compress other whitespace runs into a single space. static void mangle_1_completion_description(wcstring *str) { size_t leading = 0, trailing = 0, len = str->size(); // Skip leading spaces. for (; leading < len; leading++) { if (!iswspace(str->at(leading))) break; } // Compress runs of spaces to a single space. bool was_space = false; for (; leading < len; leading++) { wchar_t wc = str->at(leading); bool is_space = iswspace(wc); if (!is_space) { // normal character str->at(trailing++) = wc; } else if (!was_space) { // initial space in a run str->at(trailing++) = L' '; } // else non-initial space in a run, do nothing was_space = is_space; } // leading is now at len, trailing is the new length of the string. Delete trailing spaces. while (trailing > 0 && iswspace(str->at(trailing - 1))) { trailing--; } str->resize(trailing); } static void join_completions(comp_info_list_t *comps) { // A map from description to index in the completion list of the element with that description. // The indexes are stored +1. std::map desc_table; // Note that we mutate the completion list as we go, so the size changes. for (size_t i = 0; i < comps->size(); i++) { const comp_t &new_comp = comps->at(i); const wcstring &desc = new_comp.desc; if (desc.empty()) continue; // See if it's in the table. size_t prev_idx_plus_one = desc_table[desc]; if (prev_idx_plus_one == 0) { // We're the first with this description. desc_table[desc] = i + 1; } else { // There's a prior completion with this description. Append the new ones to it. comp_t *prior_comp = &comps->at(prev_idx_plus_one - 1); prior_comp->comp.insert(prior_comp->comp.end(), new_comp.comp.begin(), new_comp.comp.end()); // Erase the element at this index, and decrement the index to reflect that fact. comps->erase(comps->begin() + i); i -= 1; } } } /// Generate a list of comp_t structures from a list of completions. static comp_info_list_t process_completions_into_infos(const completion_list_t &lst) { const size_t lst_size = lst.size(); // Make the list of the correct size up-front. comp_info_list_t result(lst_size); for (size_t i = 0; i < lst_size; i++) { const completion_t &comp = lst.at(i); comp_t *comp_info = &result.at(i); // Append the single completion string. We may later merge these into multiple. comp_info->comp.push_back(escape_string(comp.completion, ESCAPE_ALL | ESCAPE_NO_QUOTED)); // Append the mangled description. comp_info->desc = comp.description; mangle_1_completion_description(&comp_info->desc); // Set the representative completion. comp_info->representative = comp; } return result; } void pager_t::measure_completion_infos(comp_info_list_t *infos, const wcstring &prefix) const { size_t prefix_len = fish_wcswidth(prefix.c_str()); for (size_t i = 0; i < infos->size(); i++) { comp_t *comp = &infos->at(i); // Compute comp_width. const wcstring_list_t &comp_strings = comp->comp; for (size_t j = 0; j < comp_strings.size(); j++) { // If there's more than one, append the length of ', '. if (j >= 1) comp->comp_width += 2; comp->comp_width += prefix_len + fish_wcswidth(comp_strings.at(j).c_str()); } // Compute desc_width. comp->desc_width = fish_wcswidth(comp->desc.c_str()); } recalc_min_widths(infos); } // Indicates if the given completion info passes any filtering we have. bool pager_t::completion_info_passes_filter(const comp_t &info) const { // If we have no filter, everything passes. if (!search_field_shown || this->search_field_line.empty()) return true; const wcstring &needle = this->search_field_line.text; // We do substring matching. const fuzzy_match_type_t limit = fuzzy_match_substring; // Match against the description. if (string_fuzzy_match_string(needle, info.desc, limit).type != fuzzy_match_none) { return true; } // Match against the completion strings. for (size_t i = 0; i < info.comp.size(); i++) { if (string_fuzzy_match_string(needle, prefix + info.comp.at(i), limit).type != fuzzy_match_none) { return true; } } return false; // no match } // Update completion_infos from unfiltered_completion_infos, to reflect the filter. void pager_t::refilter_completions() { this->completion_infos.clear(); for (size_t i = 0; i < this->unfiltered_completion_infos.size(); i++) { const comp_t &info = this->unfiltered_completion_infos.at(i); if (this->completion_info_passes_filter(info)) { this->completion_infos.push_back(info); } } } void pager_t::set_completions(const completion_list_t &raw_completions) { // Get completion infos out of it. unfiltered_completion_infos = process_completions_into_infos(raw_completions); // Maybe join them. if (prefix == L"-") join_completions(&unfiltered_completion_infos); // Compute their various widths. measure_completion_infos(&unfiltered_completion_infos, prefix); // Refilter them. this->refilter_completions(); } void pager_t::set_prefix(const wcstring &pref) { prefix = pref; } void pager_t::set_term_size(int w, int h) { assert(w > 0); assert(h > 0); available_term_width = w; available_term_height = h; recalc_min_widths(&completion_infos); } /// Try to print the list of completions l with the prefix prefix using cols as the number of /// columns. Return true if the completion list was printed, false if the terminal is too narrow for /// the specified number of columns. Always succeeds if cols is 1. bool pager_t::completion_try_print(size_t cols, const wcstring &prefix, const comp_info_list_t &lst, page_rendering_t *rendering, size_t suggested_start_row) const { // The calculated preferred width of each column. int pref_width[PAGER_MAX_COLS] = {0}; // The calculated minimum width of each column. int min_width[PAGER_MAX_COLS] = {0}; // If the list can be printed with this width, width will contain the width of each column. int *width = pref_width; // Set to one if the list should be printed at this width. bool print = false; // Compute the effective term width and term height, accounting for disclosure. size_t term_width = this->available_term_width; size_t term_height = this->available_term_height - 1 - (search_field_shown ? 1 : 0); // we always subtract 1 to make room for a comment row if (!this->fully_disclosed) { term_height = mini(term_height, (size_t)PAGER_UNDISCLOSED_MAX_ROWS); } size_t row_count = divide_round_up(lst.size(), cols); // We have more to disclose if we are not fully disclosed and there's more rows than we have in // our term height. if (!this->fully_disclosed && row_count > term_height) { rendering->remaining_to_disclose = row_count - term_height; } else { rendering->remaining_to_disclose = 0; } // If we have only one row remaining to disclose, then squelch the comment row. This prevents us // from consuming a line to show "...and 1 more row". if (!this->fully_disclosed && rendering->remaining_to_disclose == 1) { term_height += 1; rendering->remaining_to_disclose = 0; } size_t pref_tot_width = 0; size_t min_tot_width = 0; // Skip completions on tiny terminals. if (term_width < PAGER_MIN_WIDTH) return true; // Calculate how wide the list would be. for (size_t col = 0; col < cols; col++) { for (size_t row = 0; row < row_count; row++) { int pref, min; const comp_t *c; if (lst.size() <= col * row_count + row) continue; c = &lst.at(col * row_count + row); pref = c->preferred_width(); min = c->min_width; if (col != cols - 1) { pref += 2; min += 2; } min_width[col] = maxi(min_width[col], min); pref_width[col] = maxi(pref_width[col], pref); } min_tot_width += min_width[col]; pref_tot_width += pref_width[col]; } // Force fit if one column. if (cols == 1) { if (pref_tot_width > term_width) { pref_width[0] = term_width; } width = pref_width; print = true; } else if (pref_tot_width <= term_width) { // Terminal is wide enough. Print the list! width = pref_width; print = true; } if (!print) { return false; // no need to continue } // Determine the starting and stop row. size_t start_row = 0, stop_row = 0; if (row_count <= term_height) { // Easy, we can show everything. start_row = 0; stop_row = row_count; } else { // We can only show part of the full list. Determine which part based on the // suggested_start_row. assert(row_count > term_height); size_t last_starting_row = row_count - term_height; start_row = mini(suggested_start_row, last_starting_row); stop_row = start_row + term_height; assert(start_row >= 0 && start_row <= last_starting_row); } assert(stop_row >= start_row); assert(stop_row <= row_count); assert(stop_row - start_row <= term_height); completion_print(cols, width, start_row, stop_row, prefix, lst, rendering); // Ellipsis helper string. Either empty or containing the ellipsis char. const wchar_t ellipsis_string[] = {ellipsis_char == L'\x2026' ? L'\x2026' : L'\0', L'\0'}; // Add the progress line. It's a "more to disclose" line if necessary, or a row listing if // it's scrollable; otherwise ignore it. wcstring progress_text; if (rendering->remaining_to_disclose == 1) { // I don't expect this case to ever happen. progress_text = format_string(_(L"%lsand 1 more row"), ellipsis_string); } else if (rendering->remaining_to_disclose > 1) { progress_text = format_string(_(L"%lsand %lu more rows"), ellipsis_string, (unsigned long)rendering->remaining_to_disclose); } else if (start_row > 0 || stop_row < row_count) { // We have a scrollable interface. The +1 here is because we are zero indexed, but want // to present things as 1-indexed. We do not add 1 to stop_row or row_count because // these are the "past the last value". progress_text = format_string(_(L"rows %lu to %lu of %lu"), start_row + 1, stop_row, row_count); } else if (completion_infos.empty() && !unfiltered_completion_infos.empty()) { // Everything is filtered. progress_text = _(L"(no matches)"); } if (!progress_text.empty()) { line_t &line = rendering->screen_data.add_line(); print_max(progress_text, highlight_spec_pager_progress | highlight_make_background(highlight_spec_pager_progress), term_width, true /* has_more */, &line); } if (search_field_shown) { // Add the search field. wcstring search_field_text = search_field_line.text; // Append spaces to make it at least the required width. if (search_field_text.size() < PAGER_SEARCH_FIELD_WIDTH) { search_field_text.append(PAGER_SEARCH_FIELD_WIDTH - search_field_text.size(), L' '); } line_t *search_field = &rendering->screen_data.insert_line_at_index(0); // We limit the width to term_width - 1. int search_field_written = print_max(SEARCH_FIELD_PROMPT, highlight_spec_normal, term_width - 1, false, search_field); print_max(search_field_text, highlight_modifier_force_underline, term_width - search_field_written - 1, false, search_field); } return true; } page_rendering_t pager_t::render() const { /// Try to print the completions. Start by trying to print the list in PAGER_MAX_COLS columns, /// if the completions won't fit, reduce the number of columns by one. Printing a single column /// never fails. page_rendering_t rendering; rendering.term_width = this->available_term_width; rendering.term_height = this->available_term_height; rendering.search_field_shown = this->search_field_shown; rendering.search_field_line = this->search_field_line; for (size_t cols = PAGER_MAX_COLS; cols > 0; cols--) { // Initially empty rendering. rendering.screen_data.resize(0); // Determine how many rows we would need if we had 'cols' columns. Then determine how many // columns we want from that. For example, say we had 19 completions. We can fit them into 6 // columns, 4 rows, with the last row containing only 1 entry. Or we can fit them into 5 // columns, 4 rows, the last row containing 4 entries. Since fewer columns with the same // number of rows is better, skip cases where we know we can do better. size_t min_rows_required_for_cols = divide_round_up(completion_infos.size(), cols); size_t min_cols_required_for_rows = divide_round_up(completion_infos.size(), min_rows_required_for_cols); assert(min_cols_required_for_rows <= cols); if (cols > 1 && min_cols_required_for_rows < cols) { // Next iteration will be better, so skip this one. continue; } rendering.cols = (size_t)cols; rendering.rows = min_rows_required_for_cols; rendering.selected_completion_idx = this->visual_selected_completion_index(rendering.rows, rendering.cols); if (completion_try_print(cols, prefix, completion_infos, &rendering, suggested_row_start)) { break; } } return rendering; } void pager_t::update_rendering(page_rendering_t *rendering) const { if (rendering->term_width != this->available_term_width || rendering->term_height != this->available_term_height || rendering->selected_completion_idx != this->visual_selected_completion_index(rendering->rows, rendering->cols) || rendering->search_field_shown != this->search_field_shown || rendering->search_field_line.text != this->search_field_line.text || rendering->search_field_line.position != this->search_field_line.position || (rendering->remaining_to_disclose > 0 && this->fully_disclosed)) { *rendering = this->render(); } } pager_t::pager_t() : available_term_width(0), available_term_height(0), selected_completion_idx(PAGER_SELECTION_NONE), suggested_row_start(0), fully_disclosed(false), search_field_shown(false) {} bool pager_t::empty() const { return unfiltered_completion_infos.empty(); } bool pager_t::select_next_completion_in_direction(selection_direction_t direction, const page_rendering_t &rendering) { // Must have something to select. if (this->completion_infos.empty()) { return false; } // Handle the case of nothing selected yet. if (selected_completion_idx == PAGER_SELECTION_NONE) { switch (direction) { case direction_south: case direction_page_south: case direction_next: case direction_prev: { // These directions do something sane. if (direction == direction_prev) { selected_completion_idx = completion_infos.size() - 1; } else { selected_completion_idx = 0; } return true; } case direction_north: case direction_page_north: case direction_east: case direction_west: case direction_deselect: { // These do nothing. return false; } } } // Ok, we had something selected already. Select something different. size_t new_selected_completion_idx; if (!selection_direction_is_cardinal(direction)) { // Next, previous, or deselect, all easy. if (direction == direction_deselect) { new_selected_completion_idx = PAGER_SELECTION_NONE; } else if (direction == direction_next) { new_selected_completion_idx = selected_completion_idx + 1; if (new_selected_completion_idx >= completion_infos.size()) { new_selected_completion_idx = 0; } } else if (direction == direction_prev) { if (selected_completion_idx == 0) { new_selected_completion_idx = completion_infos.size() - 1; } else { new_selected_completion_idx = selected_completion_idx - 1; } } else { DIE("unknown non-cardinal direction"); } } else { // Cardinal directions. We have a completion index; we wish to compute its row and column. size_t current_row = this->get_selected_row(rendering); size_t current_col = this->get_selected_column(rendering); size_t page_height = maxi(rendering.term_height - 1, (size_t)1); switch (direction) { case direction_page_north: { if (current_row > page_height) { current_row = current_row - page_height; } else { current_row = 0; } break; } case direction_north: { // Go up a whole row. If we cycle, go to the previous column. if (current_row > 0) { current_row--; } else { current_row = rendering.rows - 1; if (current_col > 0) current_col--; } break; } case direction_page_south: { if (current_row + page_height < rendering.rows) { current_row += page_height; } else { current_row = rendering.rows - 1; if (current_col * rendering.rows + current_row >= completion_infos.size()) { current_row = (completion_infos.size() - 1) % rendering.rows; } } break; } case direction_south: { // Go down, unless we are in the last row. Note that this means that we may set // selected_completion_idx to an out-of-bounds value if the last row is incomplete; // this is a feature (it allows "last column memory"). if (current_row + 1 < rendering.rows) { current_row++; } else { current_row = 0; if (current_col + 1 < rendering.cols) current_col++; } break; } case direction_east: { // Go east, wrapping to the next row. There is no "row memory," so if we run off the // end, wrap. if (current_col + 1 < rendering.cols && (current_col + 1) * rendering.rows + current_row < completion_infos.size()) { current_col++; } else { current_col = 0; if (current_row + 1 < rendering.rows) current_row++; } break; } case direction_west: { // Go west, wrapping to the previous row. if (current_col > 0) { current_col--; } else { current_col = rendering.cols - 1; if (current_row > 0) current_row--; } break; } default: { DIE("unknown cardinal direction"); break; } } // Compute the new index based on the changed row. new_selected_completion_idx = current_col * rendering.rows + current_row; } if (selected_completion_idx == new_selected_completion_idx) { return false; } selected_completion_idx = new_selected_completion_idx; // Update suggested_row_start to ensure the selection is visible. suggested_row_start * // rendering.cols is the first suggested visible completion; add the visible completion // count to that to get the last one. size_t visible_row_count = rendering.row_end - rendering.row_start; if (visible_row_count == 0 || selected_completion_idx == PAGER_SELECTION_NONE) { return true; // this should never happen but be paranoid } // Ensure our suggested row start is not past the selected row. size_t row_containing_selection = this->get_selected_row(rendering); if (suggested_row_start > row_containing_selection) { suggested_row_start = row_containing_selection; } // Ensure our suggested row start is not too early before it. if (suggested_row_start + visible_row_count <= row_containing_selection) { // The user moved south past the bottom completion. if (!fully_disclosed && rendering.remaining_to_disclose > 0) { fully_disclosed = true; // perform disclosure } else { // Scroll suggested_row_start = row_containing_selection - visible_row_count + 1; // Ensure fully_disclosed is set. I think we can hit this case if the user // resizes the window - we don't want to drop back to the disclosed style. fully_disclosed = true; } } return true; } size_t pager_t::visual_selected_completion_index(size_t rows, size_t cols) const { // No completions -> no selection. if (completion_infos.empty() || rows == 0 || cols == 0) { return PAGER_SELECTION_NONE; } size_t result = selected_completion_idx; if (result != PAGER_SELECTION_NONE) { // If the selected completion is beyond the last selection, go left by columns until it's // within it. This is how we implement "column memory". while (result >= completion_infos.size() && result >= rows) { result -= rows; } // If we are still beyond the last selection, clamp it. if (result >= completion_infos.size()) result = completion_infos.size() - 1; } assert(result == PAGER_SELECTION_NONE || result < completion_infos.size()); return result; } // It's possible we have no visual selection but are still navigating the contents, e.g. every // completion is filtered. bool pager_t::is_navigating_contents() const { return selected_completion_idx != PAGER_SELECTION_NONE; } void pager_t::set_fully_disclosed(bool flag) { fully_disclosed = flag; } const completion_t *pager_t::selected_completion(const page_rendering_t &rendering) const { const completion_t *result = NULL; size_t idx = visual_selected_completion_index(rendering.rows, rendering.cols); if (idx != PAGER_SELECTION_NONE) { result = &completion_infos.at(idx).representative; } return result; } /// Get the selected row and column. Completions are rendered column first, i.e. we go south before /// we go west. So if we have N rows, and our selected index is N + 2, then our row is 2 (mod by N) /// and our column is 1 (divide by N). size_t pager_t::get_selected_row(const page_rendering_t &rendering) const { if (rendering.rows == 0) return PAGER_SELECTION_NONE; return selected_completion_idx == PAGER_SELECTION_NONE ? PAGER_SELECTION_NONE : selected_completion_idx % rendering.rows; } size_t pager_t::get_selected_column(const page_rendering_t &rendering) const { if (rendering.rows == 0) return PAGER_SELECTION_NONE; return selected_completion_idx == PAGER_SELECTION_NONE ? PAGER_SELECTION_NONE : selected_completion_idx / rendering.rows; } void pager_t::clear() { unfiltered_completion_infos.clear(); completion_infos.clear(); prefix.clear(); selected_completion_idx = PAGER_SELECTION_NONE; fully_disclosed = false; search_field_shown = false; search_field_line.clear(); } void pager_t::set_search_field_shown(bool flag) { this->search_field_shown = flag; } bool pager_t::is_search_field_shown() const { return this->search_field_shown; } size_t pager_t::cursor_position() const { size_t result = wcslen(SEARCH_FIELD_PROMPT) + this->search_field_line.position; // Clamp it to the right edge. if (available_term_width > 0 && result + 1 > available_term_width) { result = available_term_width - 1; } return result; } // Constructor page_rendering_t::page_rendering_t() : term_width(-1), term_height(-1), rows(0), cols(0), row_start(0), row_end(0), selected_completion_idx(-1), remaining_to_disclose(0), search_field_shown(false) {}