/* * Copyright (c) 2020, Andreas Kling * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include namespace Web::Layout { TableFormattingContext::TableFormattingContext(LayoutState& state, Box const& root, FormattingContext* parent) : FormattingContext(Type::Table, state, root, parent) { } TableFormattingContext::~TableFormattingContext() = default; static inline bool is_table_column_group(Box const& box) { return box.display().is_table_column_group(); } static inline bool is_table_column(Box const& box) { return box.display().is_table_column(); } CSSPixels TableFormattingContext::run_caption_layout(LayoutMode layout_mode, CSS::CaptionSide phase) { CSSPixels caption_height = 0; for (auto* child = table_box().first_child(); child; child = child->next_sibling()) { if (!child->display().is_table_caption() || child->computed_values().caption_side() != phase) { continue; } // The caption boxes are principal block-level boxes that retain their own content, padding, margin, and border areas, // and are rendered as normal block boxes inside the table wrapper box, as described in https://www.w3.org/TR/CSS22/tables.html#model auto caption_context = make(m_state, *verify_cast(child), this); caption_context->run(table_box(), layout_mode, *m_available_space); VERIFY(child->is_box()); auto const& child_box = static_cast(*child); // FIXME: Since caption only has inline children, BlockFormattingContext doesn't resolve the vertical metrics. // We need to do it manually here. caption_context->resolve_vertical_box_model_metrics(child_box); auto const& caption_state = m_state.get(child_box); if (phase == CSS::CaptionSide::Top) { m_state.get_mutable(table_box()).set_content_y(caption_state.content_height() + caption_state.margin_box_bottom()); } else { m_state.get_mutable(child_box).set_content_y( m_state.get(table_box()).margin_box_height() + caption_state.margin_box_top()); } caption_height += caption_state.margin_box_height(); } return caption_height; } void TableFormattingContext::compute_constrainedness() { // Definition of constrainedness: https://www.w3.org/TR/css-tables-3/#constrainedness // NB: The definition uses https://www.w3.org/TR/CSS21/visudet.html#propdef-width for width, which doesn't include // keyword values. The remaining checks can be simplified to checking whether the size is a length. size_t column_index = 0; TableGrid::for_each_child_box_matching(table_box(), is_table_column_group, [&](auto& column_group_box) { TableGrid::for_each_child_box_matching(column_group_box, is_table_column, [&](auto& column_box) { auto const& computed_values = column_box.computed_values(); if (computed_values.width().is_length()) { m_columns[column_index].is_constrained = true; } auto const& col_node = static_cast(*column_box.dom_node()); unsigned span = col_node.get_attribute_value(HTML::AttributeNames::span).to_number().value_or(1); column_index += span; }); }); for (auto& row : m_rows) { auto const& computed_values = row.box->computed_values(); if (computed_values.height().is_length()) { row.is_constrained = true; } } for (auto& cell : m_cells) { auto const& computed_values = cell.box->computed_values(); if (computed_values.width().is_length()) { m_columns[cell.column_index].is_constrained = true; } if (computed_values.height().is_length()) { m_rows[cell.row_index].is_constrained = true; } } } void TableFormattingContext::compute_cell_measures() { // Implements https://www.w3.org/TR/css-tables-3/#computing-cell-measures. auto const& containing_block = m_state.get(*table_wrapper().containing_block()); compute_constrainedness(); for (auto& cell : m_cells) { auto const& computed_values = cell.box->computed_values(); CSSPixels padding_top = computed_values.padding().top().to_px(cell.box, containing_block.content_height()); CSSPixels padding_bottom = computed_values.padding().bottom().to_px(cell.box, containing_block.content_height()); CSSPixels padding_left = computed_values.padding().left().to_px(cell.box, containing_block.content_width()); CSSPixels padding_right = computed_values.padding().right().to_px(cell.box, containing_block.content_width()); auto const& cell_state = m_state.get(cell.box); auto use_collapsing_borders_model = cell_state.override_borders_data().has_value(); // Implement the collapsing border model https://www.w3.org/TR/CSS22/tables.html#collapsing-borders. CSSPixels border_top = use_collapsing_borders_model ? round(cell_state.border_top / 2) : computed_values.border_top().width; CSSPixels border_bottom = use_collapsing_borders_model ? round(cell_state.border_bottom / 2) : computed_values.border_bottom().width; CSSPixels border_left = use_collapsing_borders_model ? round(cell_state.border_left / 2) : computed_values.border_left().width; CSSPixels border_right = use_collapsing_borders_model ? round(cell_state.border_right / 2) : computed_values.border_right().width; auto min_content_width = calculate_min_content_width(cell.box); auto max_content_width = calculate_max_content_width(cell.box); auto min_content_height = calculate_min_content_height(cell.box, max_content_width); auto max_content_height = calculate_max_content_height(cell.box, min_content_width); // The outer min-content height of a table-cell is max(min-height, min-content height) adjusted by the cell intrinsic offsets. auto min_height = computed_values.min_height().to_px(cell.box, containing_block.content_height()); auto cell_intrinsic_height_offsets = padding_top + padding_bottom + border_top + border_bottom; cell.outer_min_height = max(min_height, min_content_height) + cell_intrinsic_height_offsets; // The outer min-content width of a table-cell is max(min-width, min-content width) adjusted by the cell intrinsic offsets. auto min_width = computed_values.min_width().to_px(cell.box, containing_block.content_width()); auto cell_intrinsic_width_offsets = padding_left + padding_right + border_left + border_right; // For fixed mode, according to https://www.w3.org/TR/css-tables-3/#computing-column-measures: // The min-content and max-content width of cells is considered zero unless they are directly specified as a length-percentage, // in which case they are resolved based on the table width (if it is definite, otherwise use 0). auto width_is_specified_length_or_percentage = computed_values.width().is_length() || computed_values.width().is_percentage(); if (!use_fixed_mode_layout() || width_is_specified_length_or_percentage) { cell.outer_min_width = max(min_width, min_content_width) + cell_intrinsic_width_offsets; } // The tables specification isn't explicit on how to use the height and max-height CSS properties in the outer max-content formulas. // However, during this early phase we don't have enough information to resolve percentage sizes yet and the formulas for outer sizes // in the specification give enough clues to pick defaults in a way that makes sense. auto height = computed_values.height().is_length() ? computed_values.height().to_px(cell.box, containing_block.content_height()) : 0; auto max_height = computed_values.max_height().is_length() ? computed_values.max_height().to_px(cell.box, containing_block.content_height()) : CSSPixels::max(); if (m_rows[cell.row_index].is_constrained) { // The outer max-content height of a table-cell in a constrained row is // max(min-height, height, min-content height, min(max-height, height)) adjusted by the cell intrinsic offsets. // NB: min(max-height, height) doesn't have any effect here, we can simplify the expression to max(min-height, height, min-content height). cell.outer_max_height = max(min_height, max(height, min_content_height)) + cell_intrinsic_height_offsets; } else { // The outer max-content height of a table-cell in a non-constrained row is // max(min-height, height, min-content height, min(max-height, max-content height)) adjusted by the cell intrinsic offsets. cell.outer_max_height = max(min_height, max(height, max(min_content_height, min(max_height, max_content_height)))) + cell_intrinsic_height_offsets; } // See the explanation for height and max_height above. auto width = computed_values.width().is_length() ? computed_values.width().to_px(cell.box, containing_block.content_width()) : 0; auto max_width = computed_values.max_width().is_length() ? computed_values.max_width().to_px(cell.box, containing_block.content_width()) : CSSPixels::max(); if (use_fixed_mode_layout() && !width_is_specified_length_or_percentage) { continue; } if (m_columns[cell.column_index].is_constrained) { // The outer max-content width of a table-cell in a constrained column is // max(min-width, width, min-content width, min(max-width, width)) adjusted by the cell intrinsic offsets. // NB: min(max-width, width) doesn't have any effect here, we can simplify the expression to max(min-width, width, min-content width). cell.outer_max_width = max(min_width, max(width, min_content_width)) + cell_intrinsic_width_offsets; } else { // The outer max-content width of a table-cell in a non-constrained column is // max(min-width, width, min-content width, min(max-width, max-content width)) adjusted by the cell intrinsic offsets. cell.outer_max_width = max(min_width, max(width, max(min_content_width, min(max_width, max_content_width)))) + cell_intrinsic_width_offsets; } } } void TableFormattingContext::compute_outer_content_sizes() { auto const& containing_block = m_state.get(*table_wrapper().containing_block()); size_t column_index = 0; TableGrid::for_each_child_box_matching(table_box(), is_table_column_group, [&](auto& column_group_box) { TableGrid::for_each_child_box_matching(column_group_box, is_table_column, [&](auto& column_box) { auto const& computed_values = column_box.computed_values(); auto min_width = computed_values.min_width().to_px(column_box, containing_block.content_width()); auto max_width = computed_values.max_width().is_length() ? computed_values.max_width().to_px(column_box, containing_block.content_width()) : CSSPixels::max(); auto width = computed_values.width().to_px(column_box, containing_block.content_width()); // The outer min-content width of a table-column or table-column-group is max(min-width, width). m_columns[column_index].min_size = max(min_width, width); // The outer max-content width of a table-column or table-column-group is max(min-width, min(max-width, width)). m_columns[column_index].max_size = max(min_width, min(max_width, width)); auto const& col_node = static_cast(*column_box.dom_node()); unsigned span = col_node.get_attribute_value(HTML::AttributeNames::span).to_number().value_or(1); column_index += span; }); }); for (auto& row : m_rows) { auto const& computed_values = row.box->computed_values(); auto min_height = computed_values.min_height().to_px(row.box, containing_block.content_height()); auto max_height = computed_values.max_height().is_length() ? computed_values.max_height().to_px(row.box, containing_block.content_height()) : CSSPixels::max(); auto height = computed_values.height().to_px(row.box, containing_block.content_height()); // The outer min-content height of a table-row or table-row-group is max(min-height, height). row.min_size = max(min_height, height); // The outer max-content height of a table-row or table-row-group is max(min-height, min(max-height, height)). row.max_size = max(min_height, min(max_height, height)); } } template<> void TableFormattingContext::initialize_table_measures() { auto const& containing_block = m_state.get(*table_wrapper().containing_block()); for (auto& cell : m_cells) { auto const& computed_values = cell.box->computed_values(); if (cell.row_span == 1) { auto specified_height = computed_values.height().to_px(cell.box, containing_block.content_height()); // https://www.w3.org/TR/css-tables-3/#row-layout makes specified cell height part of the initialization formula for row table measures: // This is done by running the same algorithm as the column measurement, with the span=1 value being initialized (for min-content) with // the largest of the resulting height of the previous row layout, the height specified on the corresponding table-row (if any), and // the largest height specified on cells that span this row only (the algorithm starts by considering cells of span 2 on top of that assignment). m_rows[cell.row_index].min_size = max(m_rows[cell.row_index].min_size, max(cell.outer_min_height, specified_height)); m_rows[cell.row_index].max_size = max(m_rows[cell.row_index].max_size, cell.outer_max_height); } } } template<> void TableFormattingContext::initialize_table_measures() { // Implement the following parts of the specification, accounting for fixed layout mode: // https://www.w3.org/TR/css-tables-3/#min-content-width-of-a-column-based-on-cells-of-span-up-to-1 // https://www.w3.org/TR/css-tables-3/#max-content-width-of-a-column-based-on-cells-of-span-up-to-1 for (auto& cell : m_cells) { if (cell.column_span == 1 && (cell.row_index == 0 || !use_fixed_mode_layout())) { m_columns[cell.column_index].min_size = max(m_columns[cell.column_index].min_size, cell.outer_min_width); m_columns[cell.column_index].max_size = max(m_columns[cell.column_index].max_size, cell.outer_max_width); } } } template void TableFormattingContext::compute_intrinsic_percentage(size_t max_cell_span) { auto& rows_or_columns = table_rows_or_columns(); // https://www.w3.org/TR/css-tables-3/#intrinsic-percentage-width-of-a-column-based-on-cells-of-span-up-to-1 initialize_intrinsic_percentages_from_rows_or_columns(); initialize_intrinsic_percentages_from_cells(); // Stores intermediate values for intrinsic percentage based on cells of span up to N for the iterative algorithm, to store them back at the end of the step. Vector intrinsic_percentage_contribution_by_index; intrinsic_percentage_contribution_by_index.resize(rows_or_columns.size()); for (size_t rc_index = 0; rc_index < rows_or_columns.size(); ++rc_index) { intrinsic_percentage_contribution_by_index[rc_index] = rows_or_columns[rc_index].intrinsic_percentage; } for (size_t current_span = 2; current_span <= max_cell_span; current_span++) { // https://www.w3.org/TR/css-tables-3/#intrinsic-percentage-width-of-a-column-based-on-cells-of-span-up-to-n-n--1 for (auto& cell : m_cells) { auto cell_span_value = cell_span(cell); if (cell_span_value != current_span) { continue; } auto cell_start_rc_index = cell_index(cell); auto cell_end_rc_index = cell_start_rc_index + cell_span_value; // 1. Start with the percentage contribution of the cell. CSSPixels cell_contribution = CSSPixels::nearest_value_for(cell_percentage_contribution(cell)); // 2. Subtract the intrinsic percentage width of the column based on cells of span up to N-1 of all columns // that the cell spans. If this gives a negative result, change it to 0%. for (auto rc_index = cell_start_rc_index; rc_index < cell_end_rc_index; rc_index++) { cell_contribution -= CSSPixels::nearest_value_for(rows_or_columns[rc_index].intrinsic_percentage); cell_contribution = max(cell_contribution, 0); } // Compute the sum of the non-spanning max-content sizes of all rows / columns spanned by the cell that have an intrinsic percentage // size of the row / column based on cells of span up to N-1 equal to 0%, to be used in step 3 of the cell contribution algorithm. CSSPixels width_sum_of_columns_with_zero_intrinsic_percentage = 0; size_t number_of_columns_with_zero_intrinsic_percentage = 0; for (auto rc_index = cell_start_rc_index; rc_index < cell_end_rc_index; rc_index++) { if (rows_or_columns[rc_index].intrinsic_percentage == 0) { width_sum_of_columns_with_zero_intrinsic_percentage += rows_or_columns[rc_index].max_size; ++number_of_columns_with_zero_intrinsic_percentage; } } for (size_t rc_index = cell_start_rc_index; rc_index < cell_end_rc_index; rc_index++) { // If the intrinsic percentage width of a column based on cells of span up to N-1 is greater than 0%, then the intrinsic percentage width of // the column based on cells of span up to N is the same as the intrinsic percentage width of the column based on cells of span up to N-1. if (rows_or_columns[rc_index].intrinsic_percentage > 0) { continue; } // Otherwise, it is the largest of the contributions of the cells in the column whose colSpan is N, // where the contribution of a cell is the result of taking the following steps: // 1. Start with the percentage contribution of the cell. // 2. Subtract the intrinsic percentage width of the column based on cells of span up to N-1 of all columns // that the cell spans. If this gives a negative result, change it to 0%. // 3. Multiply by the ratio of the column’s non-spanning max-content width to the sum of the non-spanning max-content widths of all // columns spanned by the cell that have an intrinsic percentage width of the column based on cells of span up to N-1 equal to 0%. CSSPixels ajusted_cell_contribution; if (width_sum_of_columns_with_zero_intrinsic_percentage != 0) { ajusted_cell_contribution = cell_contribution.scaled(rows_or_columns[rc_index].max_size / static_cast(width_sum_of_columns_with_zero_intrinsic_percentage)); } else { // However, if this ratio is undefined because the denominator is zero, instead use the 1 divided by the number of columns // spanned by the cell that have an intrinsic percentage width of the column based on cells of span up to N-1 equal to zero. ajusted_cell_contribution = cell_contribution * 1 / number_of_columns_with_zero_intrinsic_percentage; } intrinsic_percentage_contribution_by_index[rc_index] = max(static_cast(ajusted_cell_contribution), intrinsic_percentage_contribution_by_index[rc_index]); } } for (size_t rc_index = 0; rc_index < rows_or_columns.size(); ++rc_index) { rows_or_columns[rc_index].intrinsic_percentage = intrinsic_percentage_contribution_by_index[rc_index]; } } // Clamp total intrinsic percentage to 100%: https://www.w3.org/TR/css-tables-3/#intrinsic-percentage-width-of-a-column double total_intrinsic_percentage = 0; for (auto& rows_or_column : rows_or_columns) { rows_or_column.intrinsic_percentage = max(min(100 - total_intrinsic_percentage, rows_or_column.intrinsic_percentage), 0); total_intrinsic_percentage += rows_or_column.intrinsic_percentage; } } template void TableFormattingContext::compute_table_measures() { initialize_table_measures(); auto& rows_or_columns = table_rows_or_columns(); size_t max_cell_span = 1; for (auto& cell : m_cells) { max_cell_span = max(max_cell_span, cell_span(cell)); } // Since the intrinsic percentage specification uses non-spanning max-content size for the iterative algorithm, // run it before we compute the spanning max-content size with its own iterative algorithm for span up to N. compute_intrinsic_percentage(max_cell_span); for (size_t current_span = 2; current_span <= max_cell_span; current_span++) { // https://www.w3.org/TR/css-tables-3/#min-content-width-of-a-column-based-on-cells-of-span-up-to-n-n--1 Vector> cell_min_contributions_by_rc_index; cell_min_contributions_by_rc_index.resize(rows_or_columns.size()); // https://www.w3.org/TR/css-tables-3/#max-content-width-of-a-column-based-on-cells-of-span-up-to-n-n--1 Vector> cell_max_contributions_by_rc_index; cell_max_contributions_by_rc_index.resize(rows_or_columns.size()); for (auto& cell : m_cells) { auto cell_span_value = cell_span(cell); if (cell_span_value == current_span) { // Define the baseline max-content size as the sum of the max-content sizes based on cells of span up to N-1 of all columns that the cell spans. auto cell_start_rc_index = cell_index(cell); auto cell_end_rc_index = cell_start_rc_index + cell_span_value; CSSPixels baseline_max_content_size = 0; for (auto rc_index = cell_start_rc_index; rc_index < cell_end_rc_index; rc_index++) { baseline_max_content_size += rows_or_columns[rc_index].max_size; } CSSPixels baseline_min_content_size = 0; for (auto rc_index = cell_start_rc_index; rc_index < cell_end_rc_index; rc_index++) { baseline_min_content_size += rows_or_columns[rc_index].min_size; } // Define the baseline border spacing as the sum of the horizontal border-spacing for any columns spanned by the cell, other than the one in which the cell originates. auto baseline_border_spacing = border_spacing() * (cell_span_value - 1); // Add contribution from all rows / columns, since we've weighted the gap to the desired spanned size by the the // ratio of the max-content size based on cells of span up to N-1 of the row / column to the baseline max-content width. for (auto rc_index = cell_start_rc_index; rc_index < cell_end_rc_index; rc_index++) { // The contribution of the cell is the sum of: // the min-content size of the column based on cells of span up to N-1 auto cell_min_contribution = rows_or_columns[rc_index].min_size; // the product of: // - the ratio of: // - the max-content size of the row / column based on cells of span up to N-1 of the row / column minus the // min-content size of the row / column based on cells of span up to N-1 of the row / column, to // - the baseline max-content size minus the baseline min-content size // or zero if this ratio is undefined, and // - the outer min-content size of the cell minus the baseline min-content size and the baseline border spacing, clamped // to be at least 0 and at most the difference between the baseline max-content size and the baseline min-content size auto normalized_max_min_diff = baseline_max_content_size != baseline_min_content_size ? (rows_or_columns[rc_index].max_size - rows_or_columns[rc_index].min_size) / static_cast(baseline_max_content_size - baseline_min_content_size) : 0; auto clamped_diff_to_baseline_min = min( max(cell_min_size(cell) - baseline_min_content_size - baseline_border_spacing, 0), baseline_max_content_size - baseline_min_content_size); cell_min_contribution += CSSPixels::nearest_value_for(normalized_max_min_diff * clamped_diff_to_baseline_min); // the product of: // - the ratio of the max-content size based on cells of span up to N-1 of the column to the baseline max-content size // - the outer min-content size of the cell minus the baseline max-content size and baseline border spacing, or 0 if this is negative if (baseline_max_content_size != 0) { cell_min_contribution += CSSPixels::nearest_value_for(rows_or_columns[rc_index].max_size / static_cast(baseline_max_content_size)) * max(CSSPixels(0), cell_min_size(cell) - baseline_max_content_size - baseline_border_spacing); } // The contribution of the cell is the sum of: // the max-content size of the column based on cells of span up to N-1 auto cell_max_contribution = rows_or_columns[rc_index].max_size; // and the product of: // - the ratio of the max-content size based on cells of span up to N-1 of the column to the baseline max-content size // - the outer max-content size of the cell minus the baseline max-content size and the baseline border spacing, or 0 if this is negative if (baseline_max_content_size != 0) { cell_max_contribution += CSSPixels::nearest_value_for(rows_or_columns[rc_index].max_size / static_cast(baseline_max_content_size)) * max(CSSPixels(0), cell_max_size(cell) - baseline_max_content_size - baseline_border_spacing); } cell_min_contributions_by_rc_index[rc_index].append(cell_min_contribution); cell_max_contributions_by_rc_index[rc_index].append(cell_max_contribution); } } } for (size_t rc_index = 0; rc_index < rows_or_columns.size(); rc_index++) { // min-content size of a row / column based on cells of span up to N (N > 1) is // the largest of the min-content size of the row / column based on cells of span up to N-1 and // the contributions of the cells in the row / column whose rowSpan / colSpan is N for (auto min_contribution : cell_min_contributions_by_rc_index[rc_index]) rows_or_columns[rc_index].min_size = max(rows_or_columns[rc_index].min_size, min_contribution); // max-content size of a row / column based on cells of span up to N (N > 1) is // the largest of the max-content size based on cells of span up to N-1 and the contributions of // the cells in the row / column whose rowSpan / colSpan is N for (auto max_contribution : cell_max_contributions_by_rc_index[rc_index]) rows_or_columns[rc_index].max_size = max(rows_or_columns[rc_index].max_size, max_contribution); } } } CSSPixels TableFormattingContext::compute_capmin() { // The caption width minimum (CAPMIN) is the largest of the table captions min-content contribution: // https://drafts.csswg.org/css-tables-3/#computing-the-table-width CSSPixels capmin = 0; for (auto* child = table_box().first_child(); child; child = child->next_sibling()) { if (!child->display().is_table_caption()) { continue; } VERIFY(child->is_box()); capmin = max(calculate_min_content_width(static_cast(*child)), capmin); } return capmin; } static bool width_is_auto_relative_to_state(CSS::Size const& width, LayoutState::UsedValues const& state) { return width.is_auto() || (width.contains_percentage() && !state.has_definite_width()); } void TableFormattingContext::compute_table_width() { // https://drafts.csswg.org/css-tables-3/#computing-the-table-width auto& table_box_state = m_state.get_mutable(table_box()); auto& computed_values = table_box().computed_values(); auto width_of_table_containing_block = m_available_space->width; // Percentages on 'width' and 'height' on the table are relative to the table wrapper box's containing block, // not the table wrapper box itself. auto const& containing_block_state = m_state.get(*table_wrapper().containing_block()); CSSPixels width_of_table_wrapper_containing_block = containing_block_state.content_width(); // Compute undistributable space due to border spacing: https://www.w3.org/TR/css-tables-3/#computing-undistributable-space. auto undistributable_space = (m_columns.size() + 1) * border_spacing_horizontal(); // The row/column-grid width minimum (GRIDMIN) width is the sum of the min-content width // of all the columns plus cell spacing or borders. CSSPixels grid_min = 0; for (auto& column : m_columns) { grid_min += column.min_size; } grid_min += undistributable_space; // The row/column-grid width maximum (GRIDMAX) width is the sum of the max-content width // of all the columns plus cell spacing or borders. CSSPixels grid_max = 0; for (auto& column : m_columns) { grid_max += column.max_size; } grid_max += undistributable_space; // The used min-width of a table is the greater of the resolved min-width, CAPMIN, and GRIDMIN. auto used_min_width = max(grid_min, compute_capmin()); if (!computed_values.min_width().is_auto()) { used_min_width = max(used_min_width, computed_values.min_width().to_px(table_box(), width_of_table_wrapper_containing_block)); } CSSPixels used_width; if (width_is_auto_relative_to_state(computed_values.width(), containing_block_state)) { // If the table-root has 'width: auto', the used width is the greater of // min(GRIDMAX, the table’s containing block width), the used min-width of the table. if (width_of_table_containing_block.is_definite()) used_width = max(min(grid_max, width_of_table_containing_block.to_px_or_zero()), used_min_width); else used_width = max(grid_max, used_min_width); // https://www.w3.org/TR/CSS22/tables.html#auto-table-layout // A percentage value for a column width is relative to the table width. If the table has 'width: auto', // a percentage represents a constraint on the column's width, which a UA should try to satisfy. for (auto& cell : m_cells) { auto const& cell_width = cell.box->computed_values().width(); if (cell_width.is_percentage()) { CSSPixels adjusted_used_width = undistributable_space; if (cell_width.percentage().value() != 0) adjusted_used_width += CSSPixels::nearest_value_for(ceil(100 / cell_width.percentage().value() * cell.outer_max_width)); if (width_of_table_containing_block.is_definite()) used_width = min(max(used_width, adjusted_used_width), width_of_table_containing_block.to_px_or_zero()); else used_width = max(used_width, adjusted_used_width); } } } else if (computed_values.width().is_max_content()) { used_width = grid_max; } else { // If the table-root’s width property has a computed value (resolving to // resolved-table-width) other than auto, the used width is the greater // of resolved-table-width, and the used min-width of the table. CSSPixels resolved_table_width = computed_values.width().to_px(table_box(), width_of_table_wrapper_containing_block); // Since used_width is content width, we need to subtract the border spacing from the specified width for a consistent comparison. used_width = max(resolved_table_width - table_box_state.border_box_left() - table_box_state.border_box_right(), used_min_width); if (!should_treat_max_width_as_none(table_box(), m_available_space->width)) used_width = min(used_width, computed_values.max_width().to_px(table_box(), width_of_table_wrapper_containing_block)); } table_box_state.set_content_width(used_width); auto& table_wrapper_box_state = m_state.get_mutable(table_wrapper()); table_wrapper_box_state.set_content_width(table_box_state.border_box_width()); } CSSPixels TableFormattingContext::compute_columns_total_used_width() const { CSSPixels total_used_width = 0; for (auto& column : m_columns) { total_used_width += column.used_width; } return total_used_width; } static CSSPixels compute_columns_total_candidate_width(Vector const& candidate_widths) { CSSPixels total_candidate_width = 0; for (auto width : candidate_widths) { total_candidate_width += width; } return total_candidate_width; } void TableFormattingContext::commit_candidate_column_widths(Vector const& candidate_widths) { VERIFY(candidate_widths.size() == m_columns.size()); for (size_t i = 0; i < m_columns.size(); ++i) { m_columns[i].used_width = candidate_widths[i]; } } void TableFormattingContext::assign_columns_width_linear_combination(Vector const& candidate_widths, CSSPixels available_width) { auto columns_total_candidate_width = compute_columns_total_candidate_width(candidate_widths); auto columns_total_used_width = compute_columns_total_used_width(); if (columns_total_candidate_width == columns_total_used_width) { return; } auto candidate_weight = (available_width - columns_total_used_width) / static_cast(columns_total_candidate_width - columns_total_used_width); for (size_t i = 0; i < m_columns.size(); ++i) { auto& column = m_columns[i]; column.used_width = CSSPixels::nearest_value_for(candidate_weight * candidate_widths[i] + (1 - candidate_weight) * column.used_width); } } template bool TableFormattingContext::distribute_excess_width_proportionally_to_base_width(CSSPixels excess_width, ColumnFilter column_filter, BaseWidthGetter base_width_getter) { bool found_matching_columns = false; CSSPixels total_base_width = 0; for (auto const& column : m_columns) { if (column_filter(column)) { total_base_width += base_width_getter(column); found_matching_columns = true; } } if (!found_matching_columns) { return false; } VERIFY(total_base_width > 0); for (auto& column : m_columns) { if (column_filter(column)) { column.used_width += CSSPixels::nearest_value_for(excess_width * base_width_getter(column) / static_cast(total_base_width)); } } return true; } template bool TableFormattingContext::distribute_excess_width_equally(CSSPixels excess_width, ColumnFilter column_filter) { size_t matching_column_count = 0; for (auto const& column : m_columns) { if (column_filter(column)) { ++matching_column_count; } } if (matching_column_count == 0) { return false; } for (auto& column : m_columns) { if (column_filter(column)) { column.used_width += excess_width / matching_column_count; } } return matching_column_count; } template bool TableFormattingContext::distribute_excess_width_by_intrinsic_percentage(CSSPixels excess_width, ColumnFilter column_filter) { bool found_matching_columns = false; double total_percentage_width = 0; for (auto const& column : m_columns) { if (column_filter(column)) { found_matching_columns = true; total_percentage_width += column.intrinsic_percentage; } } if (!found_matching_columns) { return false; } for (auto& column : m_columns) { if (column_filter(column)) { column.used_width += CSSPixels::nearest_value_for(excess_width * column.intrinsic_percentage / total_percentage_width); } } return true; } void TableFormattingContext::distribute_width_to_columns() { // Implements https://www.w3.org/TR/css-tables-3/#width-distribution-algorithm // The total horizontal border spacing is defined for each table: // - For tables laid out in separated-borders mode containing at least one column, the horizontal component of the computed value of the border-spacing property times one plus the number of columns in the table // - Otherwise, 0 auto total_horizontal_border_spacing = m_columns.is_empty() ? 0 : (m_columns.size() + 1) * border_spacing_horizontal(); // The assignable table width is the used width of the table minus the total horizontal border spacing (if any). // This is the width that we will be able to allocate to the columns. const CSSPixels available_width = m_state.get(table_box()).content_width() - total_horizontal_border_spacing; Vector candidate_widths; candidate_widths.resize(m_columns.size()); // 1. The min-content sizing-guess is the set of column width assignments where each column is assigned its min-content width. for (size_t i = 0; i < m_columns.size(); ++i) { auto& column = m_columns[i]; // In fixed mode, the min-content width of percent-columns and auto-columns is considered to be zero: // https://www.w3.org/TR/css-tables-3/#width-distribution-in-fixed-mode if (use_fixed_mode_layout() && !column.is_constrained) { continue; } column.used_width = column.min_size; candidate_widths[i] = column.min_size; } // 2. The min-content-percentage sizing-guess is the set of column width assignments where: // - each percent-column is assigned the larger of: // - its intrinsic percentage width times the assignable width and // - its min-content width. // - all other columns are assigned their min-content width. for (size_t i = 0; i < m_columns.size(); ++i) { auto& column = m_columns[i]; if (column.has_intrinsic_percentage) { candidate_widths[i] = max(column.min_size, CSSPixels::nearest_value_for(column.intrinsic_percentage / 100 * available_width)); } } // If the assignable table width is less than or equal to the max-content sizing-guess, the used widths of the columns must be the // linear combination (with weights adding to 1) of the two consecutive sizing-guesses whose width sums bound the available width. if (available_width < compute_columns_total_candidate_width(candidate_widths)) { assign_columns_width_linear_combination(candidate_widths, available_width); return; } else { commit_candidate_column_widths(candidate_widths); } // 3. The min-content-specified sizing-guess is the set of column width assignments where: // - each percent-column is assigned the larger of: // - its intrinsic percentage width times the assignable width and // - its min-content width // - any other column that is constrained is assigned its max-content width // - all other columns are assigned their min-content width. for (size_t i = 0; i < m_columns.size(); ++i) { auto& column = m_columns[i]; if (column.is_constrained) { candidate_widths[i] = column.max_size; } } if (available_width < compute_columns_total_candidate_width(candidate_widths)) { assign_columns_width_linear_combination(candidate_widths, available_width); return; } else { commit_candidate_column_widths(candidate_widths); } // 4. The max-content sizing-guess is the set of column width assignments where: // - each percent-column is assigned the larger of: // - its intrinsic percentage width times the assignable width and // - its min-content width // - all other columns are assigned their max-content width. for (size_t i = 0; i < m_columns.size(); ++i) { auto& column = m_columns[i]; if (!column.has_intrinsic_percentage) { candidate_widths[i] = column.max_size; } } if (available_width < compute_columns_total_candidate_width(candidate_widths)) { assign_columns_width_linear_combination(candidate_widths, available_width); return; } else { commit_candidate_column_widths(candidate_widths); } // Otherwise, the used widths of the columns are the result of starting from the max-content sizing-guess and distributing // the excess width to the columns of the table according to the rules for distributing excess width to columns (for used width). distribute_excess_width_to_columns(available_width); } void TableFormattingContext::distribute_excess_width_to_columns(CSSPixels available_width) { // Implements https://www.w3.org/TR/css-tables-3/#distributing-width-to-columns auto columns_total_used_width = compute_columns_total_used_width(); if (columns_total_used_width >= available_width) { return; } auto excess_width = available_width - columns_total_used_width; if (excess_width == 0) { return; } if (use_fixed_mode_layout()) { distribute_excess_width_to_columns_fixed_mode(excess_width); return; } // 1. If there are non-constrained columns that have originating cells with intrinsic percentage width of 0% and with nonzero // max-content width (aka the columns allowed to grow by this rule), the distributed widths of the columns allowed to grow // by this rule are increased in proportion to max-content width so the total increase adds to the excess width. if (distribute_excess_width_proportionally_to_base_width( excess_width, [](auto const& column) { return !column.is_constrained && column.has_originating_cells && column.intrinsic_percentage == 0 && column.max_size > 0; }, [](auto const& column) { return column.max_size; })) { excess_width = available_width - compute_columns_total_used_width(); } if (excess_width == 0) { return; } // 2. Otherwise, if there are non-constrained columns that have originating cells with intrinsic percentage width of 0% (aka the columns // allowed to grow by this rule, which thanks to the previous rule must have zero max-content width), the distributed widths of the // columns allowed to grow by this rule are increased by equal amounts so the total increase adds to the excess width. if (distribute_excess_width_equally(excess_width, [](auto const& column) { return !column.is_constrained && column.has_originating_cells && column.intrinsic_percentage == 0; })) { excess_width = available_width - compute_columns_total_used_width(); } if (excess_width == 0) { return; } // 3. Otherwise, if there are constrained columns with intrinsic percentage width of 0% and with nonzero max-content width // (aka the columns allowed to grow by this rule, which, due to other rules, must have originating cells), the distributed widths of the // columns allowed to grow by this rule are increased in proportion to max-content width so the total increase adds to the excess width. if (distribute_excess_width_proportionally_to_base_width( excess_width, [](auto const& column) { return column.is_constrained && column.intrinsic_percentage == 0 && column.max_size > 0; }, [](auto const& column) { return column.max_size; })) { excess_width = available_width - compute_columns_total_used_width(); } if (excess_width == 0) { return; } // 4. Otherwise, if there are columns with intrinsic percentage width greater than 0% (aka the columns allowed to grow by this rule, // which, due to other rules, must have originating cells), the distributed widths of the columns allowed to grow by this rule are // increased in proportion to intrinsic percentage width so the total increase adds to the excess width. if (distribute_excess_width_by_intrinsic_percentage(excess_width, [](auto const& column) { return column.intrinsic_percentage > 0; })) { excess_width = available_width - compute_columns_total_used_width(); } if (excess_width == 0) { return; } // 5. Otherwise, if there is any such column, the distributed widths of all columns that have originating cells are increased by equal amounts // so the total increase adds to the excess width. if (distribute_excess_width_equally( excess_width, [](auto const& column) { return column.has_originating_cells; })) { excess_width = available_width - compute_columns_total_used_width(); } if (excess_width == 0) { return; } // 6. Otherwise, the distributed widths of all columns are increased by equal amounts so the total increase adds to the excess width. distribute_excess_width_equally(excess_width, [](auto const&) { return true; }); } void TableFormattingContext::distribute_excess_width_to_columns_fixed_mode(CSSPixels excess_width) { // Implements the fixed mode for https://www.w3.org/TR/css-tables-3/#distributing-width-to-columns. // If there are any columns with no width specified, the excess width is distributed in equally to such columns if (distribute_excess_width_equally(excess_width, [](auto const& column) { return !column.is_constrained && !column.has_intrinsic_percentage; })) { return; } // otherwise, if there are columns with non-zero length widths from the base assignment, the excess width is distributed proportionally to width among those columns if (distribute_excess_width_proportionally_to_base_width( excess_width, [](auto const& column) { return column.used_width > 0; }, [](auto const& column) { return column.used_width; })) { return; } // otherwise, if there are columns with non-zero percentage widths from the base assignment, the excess width is distributed proportionally to percentage width among those columns if (distribute_excess_width_by_intrinsic_percentage(excess_width, [](auto const& column) { return column.intrinsic_percentage > 0; })) { return; } // otherwise, the excess width is distributed equally to the zero-sized columns distribute_excess_width_equally(excess_width, [](auto const& column) { return column.used_width == 0; }); } void TableFormattingContext::compute_table_height(LayoutMode layout_mode) { // First pass of row height calculation: for (auto& row : m_rows) { auto row_computed_height = row.box->computed_values().height(); if (row_computed_height.is_length()) { auto height_of_containing_block = m_state.get(*row.box->containing_block()).content_height(); auto row_used_height = row_computed_height.to_px(row.box, height_of_containing_block); row.base_height = max(row.base_height, row_used_height); } } // First pass of cells layout: for (auto& cell : m_cells) { auto& row = m_rows[cell.row_index]; auto& cell_state = m_state.get_mutable(cell.box); CSSPixels span_width = 0; for (size_t i = 0; i < cell.column_span; ++i) span_width += m_columns[cell.column_index + i].used_width; auto width_of_containing_block = m_state.get(*cell.box->containing_block()).content_width(); auto height_of_containing_block = m_state.get(*cell.box->containing_block()).content_height(); cell_state.padding_top = cell.box->computed_values().padding().top().to_px(cell.box, width_of_containing_block); cell_state.padding_bottom = cell.box->computed_values().padding().bottom().to_px(cell.box, width_of_containing_block); cell_state.padding_left = cell.box->computed_values().padding().left().to_px(cell.box, width_of_containing_block); cell_state.padding_right = cell.box->computed_values().padding().right().to_px(cell.box, width_of_containing_block); if (cell.box->computed_values().border_collapse() == CSS::BorderCollapse::Separate) { cell_state.border_top = cell.box->computed_values().border_top().width; cell_state.border_bottom = cell.box->computed_values().border_bottom().width; cell_state.border_left = cell.box->computed_values().border_left().width; cell_state.border_right = cell.box->computed_values().border_right().width; } auto cell_computed_height = cell.box->computed_values().height(); if (cell_computed_height.is_length()) { auto cell_used_height = cell_computed_height.to_px(cell.box, height_of_containing_block); cell_state.set_content_height(cell_used_height - cell_state.border_box_top() - cell_state.border_box_bottom()); row.base_height = max(row.base_height, cell_used_height); } // Compute cell width as specified by https://www.w3.org/TR/css-tables-3/#bounding-box-assignment: // The position of any table-cell, table-track, or table-track-group box within the table is defined as the rectangle whose width/height is the sum of: // - the widths/heights of all spanned visible columns/rows // - the horizontal/vertical border-spacing times the amount of spanned visible columns/rows minus one // FIXME: Account for visibility. cell_state.set_content_width(span_width - cell_state.border_box_left() - cell_state.border_box_right() + (cell.column_span - 1) * border_spacing_horizontal()); if (auto independent_formatting_context = layout_inside(cell.box, layout_mode, cell_state.available_inner_space_or_constraints_from(*m_available_space))) { cell_state.set_content_height(independent_formatting_context->automatic_content_height()); independent_formatting_context->parent_context_did_dimension_child_root_box(); } cell.baseline = box_baseline(cell.box); // Implements https://www.w3.org/TR/css-tables-3/#computing-the-table-height // The minimum height of a row is the maximum of: // - the computed height (if definite, percentages being considered 0px) of its corresponding table-row (if nay) // - the computed height of each cell spanning the current row exclusively (if definite, percentages being treated as 0px), and // - the minimum height (ROWMIN) required by the cells spanning the row. // Note that we've already applied the first rule at the top of the method. if (cell.row_span == 1) { row.base_height = max(row.base_height, cell_state.border_box_height()); } row.base_height = max(row.base_height, m_rows[cell.row_index].min_size); row.baseline = max(row.baseline, cell.baseline); } CSSPixels sum_rows_height = 0; for (auto& row : m_rows) { sum_rows_height += row.base_height; } m_table_height = sum_rows_height; if (!table_box().computed_values().height().is_auto()) { // If the table has a height property with a value other than auto, it is treated as a minimum height for the // table grid, and will eventually be distributed to the height of the rows if their collective minimum height // ends up smaller than this number. CSSPixels height_of_table_containing_block = m_state.get(*table_wrapper().containing_block()).content_height(); auto specified_table_height = table_box().computed_values().height().to_px(table_box(), height_of_table_containing_block); auto const& table_state = m_state.get(table_box()); m_table_height = max(m_table_height, specified_table_height - table_state.border_box_top() - table_state.border_box_bottom()); } for (auto& row : m_rows) { // Reference size is the largest of // - its initial base height and // - its new base height (the one evaluated during the second layout pass, where percentages used in // rowgroups/rows/cells' specified heights were resolved according to the table height, instead of // being ignored as 0px). // Assign reference size to base size. Later, the reference size might change to a larger value during // the second pass of rows layout. row.reference_height = row.base_height; } // Second pass of rows height calculation: // At this point, percentage row height can be resolved because the final table height is calculated. for (auto& row : m_rows) { auto row_computed_height = row.box->computed_values().height(); if (row_computed_height.is_percentage()) { auto row_used_height = row_computed_height.to_px(row.box, m_table_height); row.reference_height = max(row.reference_height, row_used_height); } else { continue; } } // Second pass cells layout: // At this point, percentage cell height can be resolved because the final table height is calculated. for (auto& cell : m_cells) { auto& row = m_rows[cell.row_index]; auto& cell_state = m_state.get_mutable(cell.box); CSSPixels span_width = 0; for (size_t i = 0; i < cell.column_span; ++i) span_width += m_columns[cell.column_index + i].used_width; auto cell_computed_height = cell.box->computed_values().height(); if (cell_computed_height.is_percentage()) { auto cell_used_height = cell_computed_height.to_px(cell.box, m_table_height); cell_state.set_content_height(cell_used_height - cell_state.border_box_top() - cell_state.border_box_bottom()); row.reference_height = max(row.reference_height, cell_used_height); } else { continue; } cell_state.set_content_width(span_width - cell_state.border_box_left() - cell_state.border_box_right() + (cell.column_span - 1) * border_spacing_horizontal()); if (auto independent_formatting_context = layout_inside(cell.box, layout_mode, cell_state.available_inner_space_or_constraints_from(*m_available_space))) { independent_formatting_context->parent_context_did_dimension_child_root_box(); } cell.baseline = box_baseline(cell.box); row.reference_height = max(row.reference_height, cell_state.border_box_height()); row.baseline = max(row.baseline, cell.baseline); } } void TableFormattingContext::distribute_height_to_rows() { CSSPixels sum_reference_height = 0; for (auto& row : m_rows) { sum_reference_height += row.reference_height; } if (sum_reference_height == 0) return; Vector rows_with_auto_height; for (auto& row : m_rows) { if (row.box->computed_values().height().is_auto()) { rows_with_auto_height.append(row); } } if (m_table_height <= sum_reference_height) { // If the table height is equal or smaller than sum of reference sizes, the final height assigned to each row // will be the weighted mean of the base and the reference size that yields the correct total height. for (auto& row : m_rows) { auto weight = row.reference_height / static_cast(sum_reference_height); auto final_height = m_table_height * weight; row.final_height = CSSPixels::nearest_value_for(final_height); } } else if (rows_with_auto_height.size() > 0) { // Else, if the table owns any “auto-height” row (a row whose size is only determined by its content size and // none of the specified heights), each non-auto-height row receives its reference height and auto-height rows // receive their reference size plus some increment which is equal to the height missing to amount to the // specified table height divided by the amount of such rows. for (auto& row : m_rows) { row.final_height = row.reference_height; } auto auto_height_rows_increment = (m_table_height - sum_reference_height) / rows_with_auto_height.size(); for (auto& row : rows_with_auto_height) { row.final_height += auto_height_rows_increment; } } else { // Else, all rows receive their reference size plus some increment which is equal to the height missing to // amount to the specified table height divided by the amount of rows. auto increment = (m_table_height - sum_reference_height) / m_rows.size(); for (auto& row : m_rows) { row.final_height = row.reference_height + increment; } } // Add undistributable space due to border spacing: https://www.w3.org/TR/css-tables-3/#computing-undistributable-space. m_table_height += (m_rows.size() + 1) * border_spacing_vertical(); } void TableFormattingContext::position_row_boxes() { auto const& table_state = m_state.get(table_box()); CSSPixels row_top_offset = table_state.offset.y() + table_state.padding_top + border_spacing_vertical(); CSSPixels row_left_offset = table_state.border_left + table_state.padding_left + border_spacing_horizontal(); for (size_t y = 0; y < m_rows.size(); y++) { auto& row = m_rows[y]; auto& row_state = m_state.get_mutable(row.box); CSSPixels row_width = 0; for (auto& column : m_columns) { row_width += column.used_width; } row_state.set_content_height(row.final_height); row_state.set_content_width(row_width); row_state.set_content_x(row_left_offset); row_state.set_content_y(row_top_offset); row_top_offset += row_state.content_height() + border_spacing_vertical(); } CSSPixels row_group_top_offset = table_state.border_top + table_state.padding_top; CSSPixels row_group_left_offset = table_state.border_left + table_state.padding_left; TableGrid::for_each_child_box_matching(table_box(), TableGrid::is_table_row_group, [&](auto& row_group_box) { CSSPixels row_group_height = 0; CSSPixels row_group_width = 0; auto& row_group_box_state = m_state.get_mutable(row_group_box); row_group_box_state.set_content_x(row_group_left_offset); row_group_box_state.set_content_y(row_group_top_offset); TableGrid::for_each_child_box_matching(row_group_box, TableGrid::is_table_row, [&](auto& row) { auto const& row_state = m_state.get(row); row_group_height += row_state.border_box_height(); row_group_width = max(row_group_width, row_state.border_box_width()); }); row_group_box_state.set_content_height(row_group_height); row_group_box_state.set_content_width(row_group_width); row_group_top_offset += row_group_height; }); auto total_content_height = max(row_top_offset, row_group_top_offset) - table_state.offset.y() - table_state.padding_top; m_table_height = max(total_content_height, m_table_height); } void TableFormattingContext::position_cell_boxes() { CSSPixels left_column_offset = 0; for (auto& column : m_columns) { column.left_offset = left_column_offset; left_column_offset += column.used_width; } for (auto& cell : m_cells) { auto& cell_state = m_state.get_mutable(cell.box); auto& row_state = m_state.get(m_rows[cell.row_index].box); CSSPixels const cell_border_box_height = cell_state.content_height() + cell_state.border_box_top() + cell_state.border_box_bottom(); CSSPixels const row_content_height = compute_row_content_height(cell); auto const& vertical_align = cell.box->computed_values().vertical_align(); // The following image shows various alignment lines of a row: // https://www.w3.org/TR/css-tables-3/images/cell-align-explainer.png if (vertical_align.has()) { auto height_diff = row_content_height - cell_border_box_height; switch (vertical_align.get()) { case CSS::VerticalAlign::Middle: { cell_state.padding_top += height_diff / 2; cell_state.padding_bottom += height_diff / 2; break; } case CSS::VerticalAlign::Top: { cell_state.padding_bottom += height_diff; break; } case CSS::VerticalAlign::Bottom: { cell_state.padding_top += height_diff; break; } case CSS::VerticalAlign::Baseline: { cell_state.padding_top += m_rows[cell.row_index].baseline - cell.baseline; cell_state.padding_bottom += height_diff; break; } case CSS::VerticalAlign::Sub: { dbgln("FIXME: Implement \"vertical-align: sub\" support for table cells"); break; } case CSS::VerticalAlign::Super: { dbgln("FIXME: Implement \"vertical-align: super\" support for table cells"); break; } case CSS::VerticalAlign::TextBottom: { dbgln("FIXME: Implement \"vertical-align: text-bottom\" support for table cells"); break; } case CSS::VerticalAlign::TextTop: { dbgln("FIXME: Implement \"vertical-align: text-top\" support for table cells"); break; } default: VERIFY_NOT_REACHED(); } } // Compute cell position as specified by https://www.w3.org/TR/css-tables-3/#bounding-box-assignment: // left/top location is the sum of: // - for top: the height reserved for top captions (including margins), if any // - the padding-left/padding-top and border-left-width/border-top-width of the table // FIXME: Account for visibility. cell_state.offset = row_state.offset.translated( cell_state.border_box_left() + m_columns[cell.column_index].left_offset + cell.column_index * border_spacing_horizontal(), cell_state.border_box_top()); } } bool TableFormattingContext::use_fixed_mode_layout() const { // Implements https://www.w3.org/TR/css-tables-3/#in-fixed-mode. // A table-root is said to be laid out in fixed mode whenever the computed value of the table-layout property is equal to fixed, and the // specified width of the table root is either a , min-content or fit-content. When the specified width is not one of // those values, or if the computed value of the table-layout property is auto, then the table-root is said to be laid out in auto mode. auto const& width = table_box().computed_values().width(); return table_box().computed_values().table_layout() == CSS::TableLayout::Fixed && (width.is_length() || width.is_percentage() || width.is_min_content() || width.is_fit_content()); } bool TableFormattingContext::border_is_less_specific(const CSS::BorderData& a, const CSS::BorderData& b) { // Implements criteria for steps 1, 2 and 3 of border conflict resolution algorithm, as described in // https://www.w3.org/TR/CSS22/tables.html#border-conflict-resolution. static HashMap const line_style_score = { { CSS::LineStyle::Inset, 0 }, { CSS::LineStyle::Groove, 1 }, { CSS::LineStyle::Outset, 2 }, { CSS::LineStyle::Ridge, 3 }, { CSS::LineStyle::Dotted, 4 }, { CSS::LineStyle::Dashed, 5 }, { CSS::LineStyle::Solid, 6 }, { CSS::LineStyle::Double, 7 }, }; // 1. Borders with the 'border-style' of 'hidden' take precedence over all other conflicting borders. Any border with this // value suppresses all borders at this location. if (a.line_style == CSS::LineStyle::Hidden) { return false; } if (b.line_style == CSS::LineStyle::Hidden) { return true; } // 2. Borders with a style of 'none' have the lowest priority. Only if the border properties of all the elements meeting // at this edge are 'none' will the border be omitted (but note that 'none' is the default value for the border style.) if (a.line_style == CSS::LineStyle::None) { return true; } if (b.line_style == CSS::LineStyle::None) { return false; } // 3. If none of the styles are 'hidden' and at least one of them is not 'none', then narrow borders are discarded in favor // of wider ones. If several have the same 'border-width' then styles are preferred in this order: 'double', 'solid', // 'dashed', 'dotted', 'ridge', 'outset', 'groove', and the lowest: 'inset'. if (a.width > b.width) { return false; } else if (a.width < b.width) { return true; } if (*line_style_score.get(a.line_style) > *line_style_score.get(b.line_style)) { return false; } else if (*line_style_score.get(a.line_style) < *line_style_score.get(b.line_style)) { return true; } return false; } const CSS::BorderData& TableFormattingContext::border_data_conflicting_edge(TableFormattingContext::ConflictingEdge const& conflicting_edge) { auto const& style = conflicting_edge.element->computed_values(); switch (conflicting_edge.side) { case ConflictingSide::Top: { return style.border_top(); } case ConflictingSide::Bottom: { return style.border_bottom(); } case ConflictingSide::Left: { return style.border_left(); } case ConflictingSide::Right: { return style.border_right(); } default: { VERIFY_NOT_REACHED(); } } } const Painting::PaintableBox::BorderDataWithElementKind TableFormattingContext::border_data_with_element_kind_from_conflicting_edge(ConflictingEdge const& conflicting_edge) { auto const& border_data = border_data_conflicting_edge(conflicting_edge); return { .border_data = border_data, .element_kind = conflicting_edge.element_kind }; } TableFormattingContext::ConflictingEdge const& TableFormattingContext::winning_conflicting_edge(TableFormattingContext::ConflictingEdge const& a, TableFormattingContext::ConflictingEdge const& b) { auto a_border_data = border_data_conflicting_edge(a); auto b_border_data = border_data_conflicting_edge(b); // First check if step 4 of border conflict resolution applies, as described in https://www.w3.org/TR/CSS22/tables.html#border-conflict-resolution. if (a_border_data.line_style == b_border_data.line_style && a_border_data.width == b_border_data.width) { // 4. If border styles differ only in color, then a style set on a cell wins over one on a row, which wins over a // row group, column, column group and, lastly, table. When two elements of the same type conflict, then the one // further to the left (if the table's 'direction' is 'ltr'; right, if it is 'rtl') and further to the top wins. if (static_cast(a.element_kind) < static_cast(b.element_kind)) { return a; } else if (static_cast(a.element_kind) > static_cast(b.element_kind)) { return b; } // Here the element kind is the same, thus the coordinates are either both set or not set. VERIFY(a.column.has_value() == b.column.has_value()); VERIFY(a.row.has_value() == b.row.has_value()); if (a.column.has_value()) { if (a.column.value() < b.column.value()) { return a; } else if (a.column.value() > b.column.value()) { return b; } } if (a.row.has_value()) { if (a.row.value() < b.row.value()) { return a; } else if (a.row.value() > b.row.value()) { return b; } } return a; } // Apply steps 1, 2 and 3 of the border conflict resolution algorithm. return border_is_less_specific(a_border_data, b_border_data) ? b : a; } void TableFormattingContext::border_conflict_resolution() { // Implements border conflict resolution, as described in https://www.w3.org/TR/CSS22/tables.html#border-conflict-resolution. BorderConflictFinder finder(this); for (auto& cell : m_cells) { auto& cell_state = m_state.get_mutable(cell.box); cell_state.set_table_cell_coordinates( Painting::PaintableBox::TableCellCoordinates { .row_index = cell.row_index, .column_index = cell.column_index, .row_span = cell.row_span, .column_span = cell.column_span }); if (cell.box->computed_values().border_collapse() == CSS::BorderCollapse::Separate) { continue; } Painting::PaintableBox::BordersDataWithElementKind override_borders_data; ConflictingEdge winning_edge_left { .element = cell.box, .element_kind = Painting::PaintableBox::ConflictingElementKind::Cell, .side = ConflictingSide::Left, .row = cell.row_index, .column = cell.column_index, }; for (auto const& conflicting_edge : finder.conflicting_edges(cell, ConflictingSide::Left)) { winning_edge_left = winning_conflicting_edge(winning_edge_left, conflicting_edge); } override_borders_data.left = border_data_with_element_kind_from_conflicting_edge(winning_edge_left); cell_state.border_left = override_borders_data.left.border_data.width; ConflictingEdge winning_edge_right { .element = cell.box, .element_kind = Painting::PaintableBox::ConflictingElementKind::Cell, .side = ConflictingSide::Right, .row = cell.row_index, .column = cell.column_index, }; for (auto const& conflicting_edge : finder.conflicting_edges(cell, ConflictingSide::Right)) { winning_edge_right = winning_conflicting_edge(winning_edge_right, conflicting_edge); } override_borders_data.right = border_data_with_element_kind_from_conflicting_edge(winning_edge_right); cell_state.border_right = override_borders_data.right.border_data.width; ConflictingEdge winning_edge_top { .element = cell.box, .element_kind = Painting::PaintableBox::ConflictingElementKind::Cell, .side = ConflictingSide::Top, .row = cell.row_index, .column = cell.column_index, }; for (auto const& conflicting_edge : finder.conflicting_edges(cell, ConflictingSide::Top)) { winning_edge_top = winning_conflicting_edge(winning_edge_top, conflicting_edge); } override_borders_data.top = border_data_with_element_kind_from_conflicting_edge(winning_edge_top); cell_state.border_top = override_borders_data.top.border_data.width; ConflictingEdge winning_edge_bottom { .element = cell.box, .element_kind = Painting::PaintableBox::ConflictingElementKind::Cell, .side = ConflictingSide::Bottom, .row = cell.row_index, .column = cell.column_index, }; for (auto const& conflicting_edge : finder.conflicting_edges(cell, ConflictingSide::Bottom)) { winning_edge_bottom = winning_conflicting_edge(winning_edge_bottom, conflicting_edge); } override_borders_data.bottom = border_data_with_element_kind_from_conflicting_edge(winning_edge_bottom); cell_state.border_bottom = override_borders_data.bottom.border_data.width; cell_state.set_override_borders_data(override_borders_data); } } CSSPixels TableFormattingContext::compute_row_content_height(Cell const& cell) const { auto& row_state = m_state.get(m_rows[cell.row_index].box); if (cell.row_span == 1) { return row_state.content_height(); } // The height of a cell is the sum of all spanned rows, as described in // https://www.w3.org/TR/css-tables-3/#bounding-box-assignment // When the row span is greater than 1, the borders of inner rows within the span have to be // included in the content height of the spanning cell. First top and final bottom borders are // excluded to be consistent with the handling of row span 1 case above, which uses the content // height (no top and bottom borders) of the row. CSSPixels span_height = 0; for (size_t i = 0; i < cell.row_span; ++i) { auto const& row_state = m_state.get(m_rows[cell.row_index + i].box); if (i == 0) { span_height += row_state.content_height() + row_state.border_box_bottom(); } else if (i == cell.row_span - 1) { span_height += row_state.border_box_top() + row_state.content_height(); } else { span_height += row_state.border_box_height(); } } // Compute cell height as specified by https://www.w3.org/TR/css-tables-3/#bounding-box-assignment: // width/height is the sum of: // - the widths/heights of all spanned visible columns/rows // - the horizontal/vertical border-spacing times the amount of spanned visible columns/rows minus one // FIXME: Account for visibility. span_height += (cell.row_span - 1) * border_spacing_vertical(); return span_height; } TableFormattingContext::BorderConflictFinder::BorderConflictFinder(TableFormattingContext const* context) : m_context(context) { collect_conflicting_col_elements(); collect_conflicting_row_group_elements(); } void TableFormattingContext::BorderConflictFinder::collect_conflicting_col_elements() { m_col_elements_by_index.resize(m_context->m_columns.size()); for (auto* child = m_context->table_box().first_child(); child; child = child->next_sibling()) { if (!child->display().is_table_column_group()) { continue; } size_t column_index = 0; for (auto* child_of_column_group = child->first_child(); child_of_column_group; child_of_column_group = child_of_column_group->next_sibling()) { VERIFY(child_of_column_group->display().is_table_column()); auto const& col_node = static_cast(*child_of_column_group->dom_node()); unsigned span = col_node.get_attribute_value(HTML::AttributeNames::span).to_number().value_or(1); for (size_t i = column_index; i < column_index + span; ++i) { m_col_elements_by_index[i] = child_of_column_group; } column_index += span; } } } void TableFormattingContext::BorderConflictFinder::collect_conflicting_row_group_elements() { m_row_group_elements_by_index.resize(m_context->m_rows.size()); size_t current_row_index = 0; TableGrid::for_each_child_box_matching(m_context->table_box(), TableGrid::is_table_row_group, [&](auto& row_group_box) { auto start_row_index = current_row_index; size_t row_count = 0; TableGrid::for_each_child_box_matching(row_group_box, TableGrid::is_table_row, [&](auto&) { ++row_count; }); TableGrid::for_each_child_box_matching(row_group_box, TableGrid::is_table_row, [&](auto&) { m_row_group_elements_by_index[current_row_index] = RowGroupInfo { .row_group = &row_group_box, .start_index = start_row_index, .row_count = row_count }; ++current_row_index; return IterationDecision::Continue; }); }); } void TableFormattingContext::BorderConflictFinder::collect_cell_conflicting_edges(Vector& result, Cell const& cell, TableFormattingContext::ConflictingSide edge) const { // Right edge of the cell to the left. if (cell.column_index >= cell.column_span && edge == ConflictingSide::Left) { auto left_cell_column_index = cell.column_index - cell.column_span; auto maybe_cell_to_left = m_context->m_cells_by_coordinate[cell.row_index][left_cell_column_index]; if (maybe_cell_to_left.has_value()) { result.append({ maybe_cell_to_left->box, Painting::PaintableBox::ConflictingElementKind::Cell, ConflictingSide::Right, cell.row_index, left_cell_column_index }); } } // Left edge of the cell to the right. if (cell.column_index + cell.column_span < m_context->m_cells_by_coordinate[cell.row_index].size() && edge == ConflictingSide::Right) { auto right_cell_column_index = cell.column_index + cell.column_span; auto maybe_cell_to_right = m_context->m_cells_by_coordinate[cell.row_index][right_cell_column_index]; if (maybe_cell_to_right.has_value()) { result.append({ maybe_cell_to_right->box, Painting::PaintableBox::ConflictingElementKind::Cell, ConflictingSide::Left, cell.row_index, right_cell_column_index }); } } // Bottom edge of the cell above. if (cell.row_index >= cell.row_span && edge == ConflictingSide::Top) { auto above_cell_row_index = cell.row_index - cell.row_span; auto maybe_cell_above = m_context->m_cells_by_coordinate[above_cell_row_index][cell.column_index]; if (maybe_cell_above.has_value()) { result.append({ maybe_cell_above->box, Painting::PaintableBox::ConflictingElementKind::Cell, ConflictingSide::Bottom, above_cell_row_index, cell.column_index }); } } // Top edge of the cell below. if (cell.row_index + cell.row_span < m_context->m_cells_by_coordinate.size() && edge == ConflictingSide::Bottom) { auto below_cell_row_index = cell.row_index + cell.row_span; auto maybe_cell_below = m_context->m_cells_by_coordinate[below_cell_row_index][cell.column_index]; if (maybe_cell_below.has_value()) { result.append({ maybe_cell_below->box, Painting::PaintableBox::ConflictingElementKind::Cell, ConflictingSide::Top, below_cell_row_index, cell.column_index }); } } } void TableFormattingContext::BorderConflictFinder::collect_row_conflicting_edges(Vector& result, Cell const& cell, TableFormattingContext::ConflictingSide edge) const { // Top edge of the row. if (edge == ConflictingSide::Top) { result.append({ m_context->m_rows[cell.row_index].box, Painting::PaintableBox::ConflictingElementKind::Row, ConflictingSide::Top, cell.row_index, {} }); } // Bottom edge of the row. if (edge == ConflictingSide::Bottom) { result.append({ m_context->m_rows[cell.row_index].box, Painting::PaintableBox::ConflictingElementKind::Row, ConflictingSide::Bottom, cell.row_index, {} }); } // Bottom edge of the row above. if (cell.row_index >= cell.row_span && edge == ConflictingSide::Top) { auto above_row_index = cell.row_index - cell.row_span; result.append({ m_context->m_rows[above_row_index].box, Painting::PaintableBox::ConflictingElementKind::Row, ConflictingSide::Bottom, above_row_index, {} }); } // Top edge of the row below. if (cell.row_index + cell.row_span < m_context->m_rows.size() && edge == ConflictingSide::Bottom) { auto below_row_index = cell.row_index + cell.row_span; result.append({ m_context->m_rows[below_row_index].box, Painting::PaintableBox::ConflictingElementKind::Row, ConflictingSide::Top, below_row_index, {} }); } } void TableFormattingContext::BorderConflictFinder::collect_row_group_conflicting_edges(Vector& result, Cell const& cell, TableFormattingContext::ConflictingSide edge) const { auto const& maybe_row_group = m_row_group_elements_by_index[cell.row_index]; // Top edge of the row group. if (maybe_row_group.has_value() && cell.row_index == maybe_row_group->start_index && edge == ConflictingSide::Top) { result.append({ maybe_row_group->row_group, Painting::PaintableBox::ConflictingElementKind::RowGroup, ConflictingSide::Top, maybe_row_group->start_index, {} }); } // Bottom edge of the row group above. if (cell.row_index >= cell.row_span) { auto const& maybe_row_group_above = m_row_group_elements_by_index[cell.row_index - cell.row_span]; if (maybe_row_group_above.has_value() && cell.row_index == maybe_row_group_above->start_index + maybe_row_group_above->row_count && edge == ConflictingSide::Top) { result.append({ maybe_row_group_above->row_group, Painting::PaintableBox::ConflictingElementKind::RowGroup, ConflictingSide::Bottom, maybe_row_group_above->start_index, {} }); } } // Bottom edge of the row group. if (maybe_row_group.has_value() && cell.row_index == maybe_row_group->start_index + maybe_row_group->row_count - 1 && edge == ConflictingSide::Bottom) { result.append({ maybe_row_group->row_group, Painting::PaintableBox::ConflictingElementKind::RowGroup, ConflictingSide::Bottom, maybe_row_group->start_index, {} }); } // Top edge of the row group below. if (cell.row_index + cell.row_span < m_row_group_elements_by_index.size()) { auto const& maybe_row_group_below = m_row_group_elements_by_index[cell.row_index + cell.row_span]; if (maybe_row_group_below.has_value() && cell.row_index + cell.row_span == maybe_row_group_below->start_index && edge == ConflictingSide::Bottom) { result.append({ maybe_row_group_below->row_group, Painting::PaintableBox::ConflictingElementKind::RowGroup, ConflictingSide::Top, maybe_row_group_below->start_index, {} }); } } } void TableFormattingContext::BorderConflictFinder::collect_column_group_conflicting_edges(Vector& result, Cell const& cell, TableFormattingContext::ConflictingSide edge) const { // Left edge of the column group. if (m_col_elements_by_index[cell.column_index] && edge == ConflictingSide::Left) { result.append({ m_col_elements_by_index[cell.column_index], Painting::PaintableBox::ConflictingElementKind::ColumnGroup, ConflictingSide::Left, {}, cell.column_index }); } // Right edge of the column group to the left. if (cell.column_index >= cell.column_span && m_col_elements_by_index[cell.column_index - cell.column_span] && edge == ConflictingSide::Left) { auto left_column_index = cell.column_index - cell.column_span; result.append({ m_col_elements_by_index[left_column_index], Painting::PaintableBox::ConflictingElementKind::ColumnGroup, ConflictingSide::Right, {}, left_column_index }); } // Right edge of the column group. if (m_col_elements_by_index[cell.column_index] && edge == ConflictingSide::Right) { result.append({ m_col_elements_by_index[cell.column_index], Painting::PaintableBox::ConflictingElementKind::ColumnGroup, ConflictingSide::Right, {}, cell.column_index }); } // Left edge of the column group to the right. if (cell.column_index + cell.column_span < m_col_elements_by_index.size() && m_col_elements_by_index[cell.column_index + cell.column_span] && edge == ConflictingSide::Right) { auto right_column_index = cell.column_index + cell.column_span; result.append({ m_col_elements_by_index[right_column_index], Painting::PaintableBox::ConflictingElementKind::ColumnGroup, ConflictingSide::Left, {}, right_column_index }); } } void TableFormattingContext::BorderConflictFinder::collect_table_box_conflicting_edges(Vector& result, Cell const& cell, TableFormattingContext::ConflictingSide edge) const { // Top edge from column group or table. Left and right edges of the column group are handled in collect_column_group_conflicting_edges. if (cell.row_index == 0 && edge == ConflictingSide::Top) { if (m_col_elements_by_index[cell.column_index]) { result.append({ m_col_elements_by_index[cell.column_index], Painting::PaintableBox::ConflictingElementKind::ColumnGroup, ConflictingSide::Top, {}, cell.column_index }); } result.append({ &m_context->table_box(), Painting::PaintableBox::ConflictingElementKind::Table, ConflictingSide::Top, {}, {} }); } // Bottom edge from column group or table. Left and right edges of the column group are handled in collect_column_group_conflicting_edges. if (cell.row_index + cell.row_span == m_context->m_rows.size() && edge == ConflictingSide::Bottom) { if (m_col_elements_by_index[cell.column_index]) { result.append({ m_col_elements_by_index[cell.column_index], Painting::PaintableBox::ConflictingElementKind::ColumnGroup, ConflictingSide::Bottom, {}, cell.column_index }); } result.append({ &m_context->table_box(), Painting::PaintableBox::ConflictingElementKind::Table, ConflictingSide::Bottom, {}, {} }); } // Left edge from row group or table. Top and bottom edges of the row group are handled in collect_row_group_conflicting_edges. if (cell.column_index == 0 && edge == ConflictingSide::Left) { result.append({ m_context->m_rows[cell.row_index].box, Painting::PaintableBox::ConflictingElementKind::Row, ConflictingSide::Left, cell.row_index, {} }); if (m_row_group_elements_by_index[cell.row_index].has_value()) { result.append({ m_row_group_elements_by_index[cell.row_index]->row_group, Painting::PaintableBox::ConflictingElementKind::RowGroup, ConflictingSide::Left, cell.row_index, {} }); } result.append({ &m_context->table_box(), Painting::PaintableBox::ConflictingElementKind::Table, ConflictingSide::Left, {}, {} }); } // Right edge from row group or table. Top and bottom edges of the row group are handled in collect_row_group_conflicting_edges. if (cell.column_index + cell.column_span == m_context->m_columns.size() && edge == ConflictingSide::Right) { result.append({ m_context->m_rows[cell.row_index].box, Painting::PaintableBox::ConflictingElementKind::Row, ConflictingSide::Right, cell.row_index, {} }); if (m_row_group_elements_by_index[cell.row_index].has_value()) { result.append({ m_row_group_elements_by_index[cell.row_index]->row_group, Painting::PaintableBox::ConflictingElementKind::RowGroup, ConflictingSide::Right, cell.row_index, {} }); } result.append({ &m_context->table_box(), Painting::PaintableBox::ConflictingElementKind::Table, ConflictingSide::Right, {}, {} }); } } Vector TableFormattingContext::BorderConflictFinder::conflicting_edges( Cell const& cell, TableFormattingContext::ConflictingSide edge) const { Vector result = {}; collect_cell_conflicting_edges(result, cell, edge); collect_row_conflicting_edges(result, cell, edge); collect_row_group_conflicting_edges(result, cell, edge); collect_column_group_conflicting_edges(result, cell, edge); collect_table_box_conflicting_edges(result, cell, edge); return result; } void TableFormattingContext::finish_grid_initialization(TableGrid const& table_grid) { m_columns.resize(table_grid.column_count()); m_cells_by_coordinate.resize(m_rows.size()); for (auto& position_to_cell_row : m_cells_by_coordinate) { position_to_cell_row.resize(table_grid.column_count()); } for (auto const& cell : m_cells) { m_cells_by_coordinate[cell.row_index][cell.column_index] = cell; m_columns[cell.column_index].has_originating_cells = true; } } void TableFormattingContext::run(Box const& box, LayoutMode layout_mode, AvailableSpace const& available_space) { m_available_space = available_space; auto total_captions_height = run_caption_layout(layout_mode, CSS::CaptionSide::Top); // Determine the number of rows/columns the table requires. finish_grid_initialization(TableGrid::calculate_row_column_grid(box, m_cells, m_rows)); border_conflict_resolution(); // Compute the minimum width of each column. compute_cell_measures(); compute_outer_content_sizes(); compute_table_measures(); // https://www.w3.org/TR/css-tables-3/#row-layout // Since during row layout the specified heights of cells in the row were ignored and cells that were spanning more than one rows // have not been sized correctly, their height will need to be eventually distributed to the set of rows they spanned. This is done // by running the same algorithm as the column measurement, with the span=1 value being initialized (for min-content) with the largest // of the resulting height of the previous row layout, the height specified on the corresponding table-row (if any), and the largest // height specified on cells that span this row only (the algorithm starts by considering cells of span 2 on top of that assignment). compute_table_measures(); // Compute the width of the table. compute_table_width(); if (available_space.width.is_intrinsic_sizing_constraint() && !available_space.height.is_intrinsic_sizing_constraint()) { return; } // Distribute the width of the table among columns. distribute_width_to_columns(); compute_table_height(layout_mode); distribute_height_to_rows(); position_row_boxes(); position_cell_boxes(); m_state.get_mutable(table_box()).set_content_height(m_table_height); total_captions_height += run_caption_layout(layout_mode, CSS::CaptionSide::Bottom); // Table captions are positioned between the table margins and its borders (outside the grid box borders) as described in // https://www.w3.org/TR/css-tables-3/#bounding-box-assignment // A visual representation of this model can be found at https://www.w3.org/TR/css-tables-3/images/table_container.png m_state.get_mutable(table_box()).margin_bottom += total_captions_height; m_automatic_content_height = m_table_height; } CSSPixels TableFormattingContext::automatic_content_width() const { return greatest_child_width(context_box()); } CSSPixels TableFormattingContext::automatic_content_height() const { return m_automatic_content_height; } template<> size_t TableFormattingContext::cell_span(TableFormattingContext::Cell const& cell) { return cell.row_span; } template<> size_t TableFormattingContext::cell_span(TableFormattingContext::Cell const& cell) { return cell.column_span; } template<> size_t TableFormattingContext::cell_index(TableFormattingContext::Cell const& cell) { return cell.row_index; } template<> size_t TableFormattingContext::cell_index(TableFormattingContext::Cell const& cell) { return cell.column_index; } template<> CSSPixels TableFormattingContext::cell_min_size(TableFormattingContext::Cell const& cell) { return cell.outer_min_height; } template<> CSSPixels TableFormattingContext::cell_min_size(TableFormattingContext::Cell const& cell) { return cell.outer_min_width; } template<> CSSPixels TableFormattingContext::cell_max_size(TableFormattingContext::Cell const& cell) { return cell.outer_max_height; } template<> CSSPixels TableFormattingContext::cell_max_size(TableFormattingContext::Cell const& cell) { return cell.outer_max_width; } template<> double TableFormattingContext::cell_percentage_contribution(TableFormattingContext::Cell const& cell) { // Definition of percentage contribution: https://www.w3.org/TR/css-tables-3/#percentage-contribution auto const& computed_values = cell.box->computed_values(); auto max_height_percentage = computed_values.max_height().is_percentage() ? computed_values.max_height().percentage().value() : static_cast(INFINITY); auto height_percentage = computed_values.height().is_percentage() ? computed_values.height().percentage().value() : 0; return min(height_percentage, max_height_percentage); } template<> double TableFormattingContext::cell_percentage_contribution(TableFormattingContext::Cell const& cell) { // Definition of percentage contribution: https://www.w3.org/TR/css-tables-3/#percentage-contribution auto const& computed_values = cell.box->computed_values(); auto max_width_percentage = computed_values.max_width().is_percentage() ? computed_values.max_width().percentage().value() : static_cast(INFINITY); auto width_percentage = computed_values.width().is_percentage() ? computed_values.width().percentage().value() : 0; return min(width_percentage, max_width_percentage); } template<> bool TableFormattingContext::cell_has_intrinsic_percentage(TableFormattingContext::Cell const& cell) { return cell.box->computed_values().height().is_percentage(); } template<> bool TableFormattingContext::cell_has_intrinsic_percentage(TableFormattingContext::Cell const& cell) { return cell.box->computed_values().width().is_percentage(); } template<> void TableFormattingContext::initialize_intrinsic_percentages_from_rows_or_columns() { for (auto& row : m_rows) { auto const& computed_values = row.box->computed_values(); // Definition of percentage contribution: https://www.w3.org/TR/css-tables-3/#percentage-contribution auto max_height_percentage = computed_values.max_height().is_percentage() ? computed_values.max_height().percentage().value() : static_cast(INFINITY); auto height_percentage = computed_values.height().is_percentage() ? computed_values.height().percentage().value() : 0; row.has_intrinsic_percentage = computed_values.max_height().is_percentage() || computed_values.height().is_percentage(); row.intrinsic_percentage = min(height_percentage, max_height_percentage); } } template<> void TableFormattingContext::initialize_intrinsic_percentages_from_rows_or_columns() { size_t column_index = 0; TableGrid::for_each_child_box_matching(table_box(), is_table_column_group, [&](auto& column_group_box) { TableGrid::for_each_child_box_matching(column_group_box, is_table_column, [&](auto& column_box) { auto const& computed_values = column_box.computed_values(); // Definition of percentage contribution: https://www.w3.org/TR/css-tables-3/#percentage-contribution auto max_width_percentage = computed_values.max_width().is_percentage() ? computed_values.max_width().percentage().value() : static_cast(INFINITY); auto width_percentage = computed_values.width().is_percentage() ? computed_values.width().percentage().value() : 0; m_columns[column_index].has_intrinsic_percentage = computed_values.max_width().is_percentage() || computed_values.width().is_percentage(); m_columns[column_index].intrinsic_percentage = min(width_percentage, max_width_percentage); auto const& col_node = static_cast(*column_box.dom_node()); unsigned span = col_node.get_attribute_value(HTML::AttributeNames::span).to_number().value_or(1); column_index += span; }); }); } template void TableFormattingContext::initialize_intrinsic_percentages_from_cells() { auto& rows_or_columns = table_rows_or_columns(); for (auto& cell : m_cells) { auto cell_span_value = cell_span(cell); auto cell_start_rc_index = cell_index(cell); auto cell_end_rc_index = cell_start_rc_index + cell_span_value; if (cell_has_intrinsic_percentage(cell)) { for (auto rc_index = cell_start_rc_index; rc_index < cell_end_rc_index; rc_index++) { rows_or_columns[rc_index].has_intrinsic_percentage = true; } if (cell_span_value != 1) { continue; } } else { continue; } size_t rc_index = cell_index(cell); rows_or_columns[rc_index].has_intrinsic_percentage = true; rows_or_columns[rc_index].intrinsic_percentage = max(cell_percentage_contribution(cell), rows_or_columns[rc_index].intrinsic_percentage); } } template<> CSSPixels TableFormattingContext::border_spacing() { return border_spacing_vertical(); } template<> CSSPixels TableFormattingContext::border_spacing() { return border_spacing_horizontal(); } CSSPixels TableFormattingContext::border_spacing_horizontal() const { auto const& computed_values = table_box().computed_values(); // When a table is laid out in collapsed-borders mode, the border-spacing of the table-root is ignored (as if it was set to 0px): // https://www.w3.org/TR/css-tables-3/#collapsed-style-overrides if (computed_values.border_collapse() == CSS::BorderCollapse::Collapse) return 0; return computed_values.border_spacing_horizontal().to_px(table_box()); } CSSPixels TableFormattingContext::border_spacing_vertical() const { auto const& computed_values = table_box().computed_values(); // When a table is laid out in collapsed-borders mode, the border-spacing of the table-root is ignored (as if it was set to 0px): // https://www.w3.org/TR/css-tables-3/#collapsed-style-overrides if (computed_values.border_collapse() == CSS::BorderCollapse::Collapse) return 0; return computed_values.border_spacing_vertical().to_px(table_box()); } template<> Vector& TableFormattingContext::table_rows_or_columns() { return m_rows; } template<> Vector& TableFormattingContext::table_rows_or_columns() { return m_columns; } }