0ct0pu5/ladybird
1
0
Fork 0
Code Issues Pull requests Projects Releases Packages Wiki Activity Actions 2
ladybird/Userland/Libraries/LibWeb/Layout/GridFormattingContext.cpp
Aliaksandr Kalenik e4e1208050 LibWeb: Respect justify-self property of grid items
2023-07-14 15:48:58 +02:00

1999 lines
101 KiB
C++
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
* Copyright (c) 2022-2023, Martin Falisse <mfalisse@outlook.com>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <LibWeb/DOM/Node.h>
#include <LibWeb/Layout/Box.h>
#include <LibWeb/Layout/GridFormattingContext.h>
namespace Web::Layout {
GridFormattingContext::GridTrack GridFormattingContext::GridTrack::create_from_definition(CSS::ExplicitGridTrack const& definition)
{
// NOTE: repeat() is expected to be expanded beforehand.
VERIFY(!definition.is_repeat());
if (definition.is_minmax()) {
return GridTrack {
.min_track_sizing_function = definition.minmax().min_grid_size(),
.max_track_sizing_function = definition.minmax().max_grid_size(),
};
}
return GridTrack {
.min_track_sizing_function = definition.grid_size(),
.max_track_sizing_function = definition.grid_size(),
};
}
GridFormattingContext::GridTrack GridFormattingContext::GridTrack::create_auto()
{
return GridTrack {
.min_track_sizing_function = CSS::GridSize::make_auto(),
.max_track_sizing_function = CSS::GridSize::make_auto(),
};
}
GridFormattingContext::GridTrack GridFormattingContext::GridTrack::create_gap(CSSPixels size)
{
return GridTrack {
.min_track_sizing_function = CSS::GridSize(CSS::Length::make_px(size)),
.max_track_sizing_function = CSS::GridSize(CSS::Length::make_px(size)),
.base_size = size,
.is_gap = true,
};
}
GridFormattingContext::GridFormattingContext(LayoutState& state, Box const& grid_container, FormattingContext* parent)
: FormattingContext(Type::Grid, state, grid_container, parent)
{
}
GridFormattingContext::~GridFormattingContext() = default;
CSSPixels GridFormattingContext::resolve_definite_track_size(CSS::GridSize const& grid_size, AvailableSpace const& available_space)
{
VERIFY(grid_size.is_definite());
switch (grid_size.type()) {
case CSS::GridSize::Type::LengthPercentage: {
if (!grid_size.length_percentage().is_auto()) {
return grid_size.css_size().to_px(grid_container(), available_space.width.to_px());
}
break;
}
default:
VERIFY_NOT_REACHED();
}
return 0;
}
int GridFormattingContext::get_count_of_tracks(Vector<CSS::ExplicitGridTrack> const& track_list, AvailableSpace const& available_space)
{
auto track_count = 0;
for (auto const& explicit_grid_track : track_list) {
if (explicit_grid_track.is_repeat() && explicit_grid_track.repeat().is_default())
track_count += explicit_grid_track.repeat().repeat_count() * explicit_grid_track.repeat().grid_track_size_list().track_list().size();
else
track_count += 1;
}
if (track_list.size() == 1
&& track_list.first().is_repeat()
&& (track_list.first().repeat().is_auto_fill() || track_list.first().repeat().is_auto_fit())) {
track_count = count_of_repeated_auto_fill_or_fit_tracks(track_list, available_space);
}
return track_count;
}
int GridFormattingContext::count_of_repeated_auto_fill_or_fit_tracks(Vector<CSS::ExplicitGridTrack> const& track_list, AvailableSpace const& available_space)
{
// https://www.w3.org/TR/css-grid-2/#auto-repeat
// 7.2.3.2. Repeat-to-fill: auto-fill and auto-fit repetitions
// On a subgridded axis, the auto-fill keyword is only valid once per <line-name-list>, and repeats
// enough times for the name list to match the subgrids specified grid span (falling back to 0 if
// the span is already fulfilled).
// Otherwise on a standalone axis, when auto-fill is given as the repetition number
// If the grid container has a definite size or max size in the relevant axis, then the number of
// repetitions is the largest possible positive integer that does not cause the grid to overflow the
// content box of its grid container
CSSPixels sum_of_grid_track_sizes = 0;
// (treating each track as its max track sizing function if that is definite or its minimum track sizing
// function otherwise, flooring the max track sizing function by the min track sizing function if both
// are definite, and taking gap into account)
// FIXME: take gap into account
for (auto& explicit_grid_track : track_list.first().repeat().grid_track_size_list().track_list()) {
auto track_sizing_function = explicit_grid_track;
if (track_sizing_function.is_minmax()) {
if (track_sizing_function.minmax().max_grid_size().is_definite() && !track_sizing_function.minmax().min_grid_size().is_definite())
sum_of_grid_track_sizes += resolve_definite_track_size(track_sizing_function.minmax().max_grid_size(), available_space);
else if (track_sizing_function.minmax().min_grid_size().is_definite() && !track_sizing_function.minmax().max_grid_size().is_definite())
sum_of_grid_track_sizes += resolve_definite_track_size(track_sizing_function.minmax().min_grid_size(), available_space);
else if (track_sizing_function.minmax().min_grid_size().is_definite() && track_sizing_function.minmax().max_grid_size().is_definite())
sum_of_grid_track_sizes += min(resolve_definite_track_size(track_sizing_function.minmax().min_grid_size(), available_space), resolve_definite_track_size(track_sizing_function.minmax().max_grid_size(), available_space));
} else {
sum_of_grid_track_sizes += min(resolve_definite_track_size(track_sizing_function.grid_size(), available_space), resolve_definite_track_size(track_sizing_function.grid_size(), available_space));
}
}
return max(1, static_cast<int>((get_free_space(available_space, GridDimension::Column).to_px() / sum_of_grid_track_sizes).to_double()));
// For the purpose of finding the number of auto-repeated tracks in a standalone axis, the UA must
// floor the track size to a UA-specified value to avoid division by zero. It is suggested that this
// floor be 1px.
}
void GridFormattingContext::place_item_with_row_and_column_position(Box const& child_box)
{
int row_start = child_box.computed_values().grid_row_start().raw_value() - 1;
int row_end = child_box.computed_values().grid_row_end().raw_value() - 1;
int column_start = child_box.computed_values().grid_column_start().raw_value() - 1;
int column_end = child_box.computed_values().grid_column_end().raw_value() - 1;
// https://www.w3.org/TR/css-grid-2/#line-placement
// 8.3. Line-based Placement: the grid-row-start, grid-column-start, grid-row-end, and grid-column-end properties
// https://www.w3.org/TR/css-grid-2/#grid-placement-slot
// First attempt to match the grid areas edge to a named grid area: if there is a grid line whose
// line name is <custom-ident>-start (for grid-*-start) / <custom-ident>-end (for grid-*-end),
// contributes the first such line to the grid items placement.
// Otherwise, treat this as if the integer 1 had been specified along with the <custom-ident>.
// https://www.w3.org/TR/css-grid-2/#grid-placement-int
// Contributes the Nth grid line to the grid items placement. If a negative integer is given, it
// instead counts in reverse, starting from the end edge of the explicit grid.
if (row_end < 0)
row_end = m_occupation_grid.row_count() + row_end + 2;
if (column_end < 0)
column_end = m_occupation_grid.column_count() + column_end + 2;
// If a name is given as a <custom-ident>, only lines with that name are counted. If not enough
// lines with that name exist, all implicit grid lines are assumed to have that name for the purpose
// of finding this position.
// https://www.w3.org/TR/css-grid-2/#grid-placement-span-int
// Contributes a grid span to the grid items placement such that the corresponding edge of the grid
// items grid area is N lines from its opposite edge in the corresponding direction. For example,
// grid-column-end: span 2 indicates the second grid line in the endward direction from the
// grid-column-start line.
size_t row_span = 1;
size_t column_span = 1;
if (child_box.computed_values().grid_row_start().is_position() && child_box.computed_values().grid_row_end().is_span())
row_span = child_box.computed_values().grid_row_end().raw_value();
if (child_box.computed_values().grid_column_start().is_position() && child_box.computed_values().grid_column_end().is_span())
column_span = child_box.computed_values().grid_column_end().raw_value();
if (child_box.computed_values().grid_row_end().is_position() && child_box.computed_values().grid_row_start().is_span()) {
row_span = child_box.computed_values().grid_row_start().raw_value();
row_start = row_end - row_span;
}
if (child_box.computed_values().grid_column_end().is_position() && child_box.computed_values().grid_column_start().is_span()) {
column_span = child_box.computed_values().grid_column_start().raw_value();
column_start = column_end - column_span;
}
// If a name is given as a <custom-ident>, only lines with that name are counted. If not enough
// lines with that name exist, all implicit grid lines on the side of the explicit grid
// corresponding to the search direction are assumed to have that name for the purpose of counting
// this span.
// https://drafts.csswg.org/css-grid/#grid-placement-auto
// auto
// The property contributes nothing to the grid items placement, indicating auto-placement or a
// default span of one. (See §8 Placing Grid Items, above.)
// https://www.w3.org/TR/css-grid-2/#common-uses-named-lines
// 8.1.3. Named Lines and Spans
// Instead of counting lines by number, lines can be referenced by their line name:
if (child_box.computed_values().grid_column_end().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_column_end().line_name()); maybe_grid_area.has_value())
column_end = maybe_grid_area->column_end;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_column_end().line_name(), grid_container().computed_values().grid_template_columns()); line_name_index > -1)
column_end = line_name_index;
else
column_end = 1;
column_start = column_end - 1;
}
if (child_box.computed_values().grid_column_start().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_column_end().line_name()); maybe_grid_area.has_value())
column_start = maybe_grid_area->column_start;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_column_start().line_name(), grid_container().computed_values().grid_template_columns()); line_name_index > -1)
column_start = line_name_index;
else
column_start = 0;
}
if (child_box.computed_values().grid_row_end().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_row_end().line_name()); maybe_grid_area.has_value())
row_end = maybe_grid_area->row_end;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_row_end().line_name(), grid_container().computed_values().grid_template_rows()); line_name_index > -1)
row_end = line_name_index;
else
row_end = 1;
row_start = row_end - 1;
}
if (child_box.computed_values().grid_row_start().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_row_end().line_name()); maybe_grid_area.has_value())
row_start = maybe_grid_area->row_start;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_row_start().line_name(), grid_container().computed_values().grid_template_rows()); line_name_index > -1)
row_start = line_name_index;
else
row_start = 0;
}
// If there are multiple lines of the same name, they effectively establish a named set of grid
// lines, which can be exclusively indexed by filtering the placement by name:
// https://drafts.csswg.org/css-grid/#grid-placement-errors
// 8.3.1. Grid Placement Conflict Handling
// If the placement for a grid item contains two lines, and the start line is further end-ward than
// the end line, swap the two lines. If the start line is equal to the end line, remove the end
// line.
if (child_box.computed_values().grid_row_start().is_position() && child_box.computed_values().grid_row_end().is_position()) {
if (row_start > row_end)
swap(row_start, row_end);
if (row_start != row_end)
row_span = row_end - row_start;
}
if (child_box.computed_values().grid_column_start().is_position() && child_box.computed_values().grid_column_end().is_position()) {
if (column_start > column_end)
swap(column_start, column_end);
if (column_start != column_end)
column_span = column_end - column_start;
}
// If the placement contains two spans, remove the one contributed by the end grid-placement
// property.
if (child_box.computed_values().grid_row_start().is_span() && child_box.computed_values().grid_row_end().is_span())
row_span = child_box.computed_values().grid_row_start().raw_value();
if (child_box.computed_values().grid_column_start().is_span() && child_box.computed_values().grid_column_end().is_span())
column_span = child_box.computed_values().grid_column_start().raw_value();
// FIXME: If the placement contains only a span for a named line, replace it with a span of 1.
m_grid_items.append(GridItem {
.box = child_box,
.row = row_start,
.row_span = row_span,
.column = column_start,
.column_span = column_span });
m_occupation_grid.set_occupied(column_start, column_start + column_span, row_start, row_start + row_span);
}
void GridFormattingContext::place_item_with_row_position(Box const& child_box)
{
int row_start = child_box.computed_values().grid_row_start().raw_value() - 1;
int row_end = child_box.computed_values().grid_row_end().raw_value() - 1;
// https://www.w3.org/TR/css-grid-2/#line-placement
// 8.3. Line-based Placement: the grid-row-start, grid-column-start, grid-row-end, and grid-column-end properties
// https://www.w3.org/TR/css-grid-2/#grid-placement-slot
// First attempt to match the grid areas edge to a named grid area: if there is a grid line whose
// line name is <custom-ident>-start (for grid-*-start) / <custom-ident>-end (for grid-*-end),
// contributes the first such line to the grid items placement.
// Otherwise, treat this as if the integer 1 had been specified along with the <custom-ident>.
// https://www.w3.org/TR/css-grid-2/#grid-placement-int
// Contributes the Nth grid line to the grid items placement. If a negative integer is given, it
// instead counts in reverse, starting from the end edge of the explicit grid.
if (row_end < 0)
row_end = m_occupation_grid.row_count() + row_end + 2;
// If a name is given as a <custom-ident>, only lines with that name are counted. If not enough
// lines with that name exist, all implicit grid lines are assumed to have that name for the purpose
// of finding this position.
// https://www.w3.org/TR/css-grid-2/#grid-placement-span-int
// Contributes a grid span to the grid items placement such that the corresponding edge of the grid
// items grid area is N lines from its opposite edge in the corresponding direction. For example,
// grid-column-end: span 2 indicates the second grid line in the endward direction from the
// grid-column-start line.
size_t row_span = 1;
if (child_box.computed_values().grid_row_start().is_position() && child_box.computed_values().grid_row_end().is_span())
row_span = child_box.computed_values().grid_row_end().raw_value();
if (child_box.computed_values().grid_row_end().is_position() && child_box.computed_values().grid_row_start().is_span()) {
row_span = child_box.computed_values().grid_row_start().raw_value();
row_start = row_end - row_span;
// FIXME: Remove me once have implemented spans overflowing into negative indexes, e.g., grid-row: span 2 / 1
if (row_start < 0)
row_start = 0;
}
// If a name is given as a <custom-ident>, only lines with that name are counted. If not enough
// lines with that name exist, all implicit grid lines on the side of the explicit grid
// corresponding to the search direction are assumed to have that name for the purpose of counting
// this span.
// https://drafts.csswg.org/css-grid/#grid-placement-auto
// auto
// The property contributes nothing to the grid items placement, indicating auto-placement or a
// default span of one. (See §8 Placing Grid Items, above.)
// https://www.w3.org/TR/css-grid-2/#common-uses-named-lines
// 8.1.3. Named Lines and Spans
// Instead of counting lines by number, lines can be referenced by their line name:
if (child_box.computed_values().grid_row_end().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_row_end().line_name()); maybe_grid_area.has_value())
row_end = maybe_grid_area->row_end;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_row_end().line_name(), grid_container().computed_values().grid_template_rows()); line_name_index > -1)
row_end = line_name_index;
else
row_end = 1;
row_start = row_end - 1;
}
if (child_box.computed_values().grid_row_start().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_row_end().line_name()); maybe_grid_area.has_value())
row_start = maybe_grid_area->row_start;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_row_start().line_name(), grid_container().computed_values().grid_template_rows()); line_name_index > -1)
row_start = line_name_index;
else
row_start = 0;
}
// If there are multiple lines of the same name, they effectively establish a named set of grid
// lines, which can be exclusively indexed by filtering the placement by name:
// https://drafts.csswg.org/css-grid/#grid-placement-errors
// 8.3.1. Grid Placement Conflict Handling
// If the placement for a grid item contains two lines, and the start line is further end-ward than
// the end line, swap the two lines. If the start line is equal to the end line, remove the end
// line.
if (child_box.computed_values().grid_row_start().is_position() && child_box.computed_values().grid_row_end().is_position()) {
if (row_start > row_end)
swap(row_start, row_end);
if (row_start != row_end)
row_span = row_end - row_start;
}
// FIXME: Have yet to find the spec for this.
if (!child_box.computed_values().grid_row_start().is_position() && child_box.computed_values().grid_row_end().is_position() && row_end == 0)
row_start = 0;
// If the placement contains two spans, remove the one contributed by the end grid-placement
// property.
if (child_box.computed_values().grid_row_start().is_span() && child_box.computed_values().grid_row_end().is_span())
row_span = child_box.computed_values().grid_row_start().raw_value();
// FIXME: If the placement contains only a span for a named line, replace it with a span of 1.
int column_start = 0;
size_t column_span = child_box.computed_values().grid_column_start().is_span() ? child_box.computed_values().grid_column_start().raw_value() : 1;
bool found_available_column = false;
for (size_t column_index = column_start; column_index < m_occupation_grid.column_count(); column_index++) {
if (!m_occupation_grid.is_occupied(column_index, row_start)) {
found_available_column = true;
column_start = column_index;
break;
}
}
if (!found_available_column) {
column_start = m_occupation_grid.column_count();
}
m_occupation_grid.set_occupied(column_start, column_start + column_span, row_start, row_start + row_span);
m_grid_items.append(GridItem {
.box = child_box,
.row = row_start,
.row_span = row_span,
.column = column_start,
.column_span = column_span });
}
void GridFormattingContext::place_item_with_column_position(Box const& child_box, int& auto_placement_cursor_x, int& auto_placement_cursor_y)
{
int column_start;
if (child_box.computed_values().grid_column_start().raw_value() > 0) {
column_start = child_box.computed_values().grid_column_start().raw_value() - 1;
} else {
// NOTE: Negative indexes count from the end side of the explicit grid
column_start = m_explicit_columns_line_count + child_box.computed_values().grid_column_start().raw_value();
}
int column_end = child_box.computed_values().grid_column_end().raw_value() - 1;
// https://www.w3.org/TR/css-grid-2/#line-placement
// 8.3. Line-based Placement: the grid-row-start, grid-column-start, grid-row-end, and grid-column-end properties
// https://www.w3.org/TR/css-grid-2/#grid-placement-slot
// First attempt to match the grid areas edge to a named grid area: if there is a grid line whose
// line name is <custom-ident>-start (for grid-*-start) / <custom-ident>-end (for grid-*-end),
// contributes the first such line to the grid items placement.
// Otherwise, treat this as if the integer 1 had been specified along with the <custom-ident>.
// https://www.w3.org/TR/css-grid-2/#grid-placement-int
// Contributes the Nth grid line to the grid items placement. If a negative integer is given, it
// instead counts in reverse, starting from the end edge of the explicit grid.
if (column_end < 0)
column_end = m_occupation_grid.column_count() + column_end + 2;
// If a name is given as a <custom-ident>, only lines with that name are counted. If not enough
// lines with that name exist, all implicit grid lines are assumed to have that name for the purpose
// of finding this position.
// https://www.w3.org/TR/css-grid-2/#grid-placement-span-int
// Contributes a grid span to the grid items placement such that the corresponding edge of the grid
// items grid area is N lines from its opposite edge in the corresponding direction. For example,
// grid-column-end: span 2 indicates the second grid line in the endward direction from the
// grid-column-start line.
size_t column_span = 1;
size_t row_span = child_box.computed_values().grid_row_start().is_span() ? child_box.computed_values().grid_row_start().raw_value() : 1;
if (child_box.computed_values().grid_column_start().is_position() && child_box.computed_values().grid_column_end().is_span())
column_span = child_box.computed_values().grid_column_end().raw_value();
if (child_box.computed_values().grid_column_end().is_position() && child_box.computed_values().grid_column_start().is_span()) {
column_span = child_box.computed_values().grid_column_start().raw_value();
column_start = column_end - column_span;
// FIXME: Remove me once have implemented spans overflowing into negative indexes, e.g., grid-column: span 2 / 1
if (column_start < 0)
column_start = 0;
}
// FIXME: Have yet to find the spec for this.
if (!child_box.computed_values().grid_column_start().is_position() && child_box.computed_values().grid_column_end().is_position() && column_end == 0)
column_start = 0;
// If a name is given as a <custom-ident>, only lines with that name are counted. If not enough
// lines with that name exist, all implicit grid lines on the side of the explicit grid
// corresponding to the search direction are assumed to have that name for the purpose of counting
// this span.
// https://drafts.csswg.org/css-grid/#grid-placement-auto
// auto
// The property contributes nothing to the grid items placement, indicating auto-placement or a
// default span of one. (See §8 Placing Grid Items, above.)
// https://www.w3.org/TR/css-grid-2/#common-uses-named-lines
// 8.1.3. Named Lines and Spans
// Instead of counting lines by number, lines can be referenced by their line name:
if (child_box.computed_values().grid_column_end().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_column_end().line_name()); maybe_grid_area.has_value())
column_end = maybe_grid_area->column_end;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_column_end().line_name(), grid_container().computed_values().grid_template_columns()); line_name_index > -1)
column_end = line_name_index;
else
column_end = 1;
column_start = column_end - 1;
}
if (child_box.computed_values().grid_column_start().has_line_name()) {
if (auto maybe_grid_area = m_grid_areas.get(child_box.computed_values().grid_column_end().line_name()); maybe_grid_area.has_value())
column_start = maybe_grid_area->column_start;
else if (auto line_name_index = get_line_index_by_line_name(child_box.computed_values().grid_column_start().line_name(), grid_container().computed_values().grid_template_columns()); line_name_index > -1)
column_start = line_name_index;
else
column_start = 0;
}
// If there are multiple lines of the same name, they effectively establish a named set of grid
// lines, which can be exclusively indexed by filtering the placement by name:
// https://drafts.csswg.org/css-grid/#grid-placement-errors
// 8.3.1. Grid Placement Conflict Handling
// If the placement for a grid item contains two lines, and the start line is further end-ward than
// the end line, swap the two lines. If the start line is equal to the end line, remove the end
// line.
if (child_box.computed_values().grid_column_start().is_position() && child_box.computed_values().grid_column_end().is_position()) {
if (column_start > column_end)
swap(column_start, column_end);
if (column_start != column_end)
column_span = column_end - column_start;
}
// If the placement contains two spans, remove the one contributed by the end grid-placement
// property.
if (child_box.computed_values().grid_column_start().is_span() && child_box.computed_values().grid_column_end().is_span())
column_span = child_box.computed_values().grid_column_start().raw_value();
// FIXME: If the placement contains only a span for a named line, replace it with a span of 1.
// 4.1.1.1. Set the column position of the cursor to the grid item's column-start line. If this is
// less than the previous column position of the cursor, increment the row position by 1.
if (column_start < auto_placement_cursor_x)
auto_placement_cursor_y++;
auto_placement_cursor_x = column_start;
// 4.1.1.2. Increment the cursor's row position until a value is found where the grid item does not
// overlap any occupied grid cells (creating new rows in the implicit grid as necessary).
while (true) {
if (!m_occupation_grid.is_occupied(column_start, auto_placement_cursor_y)) {
break;
}
auto_placement_cursor_y++;
}
// 4.1.1.3. Set the item's row-start line to the cursor's row position, and set the item's row-end
// line according to its span from that position.
m_occupation_grid.set_occupied(column_start, column_start + column_span, auto_placement_cursor_y, auto_placement_cursor_y + row_span);
m_grid_items.append(GridItem {
.box = child_box,
.row = auto_placement_cursor_y,
.row_span = row_span,
.column = column_start,
.column_span = column_span });
}
void GridFormattingContext::place_item_with_no_declared_position(Box const& child_box, int& auto_placement_cursor_x, int& auto_placement_cursor_y)
{
// 4.1.2.1. Increment the column position of the auto-placement cursor until either this item's grid
// area does not overlap any occupied grid cells, or the cursor's column position, plus the item's
// column span, overflow the number of columns in the implicit grid, as determined earlier in this
// algorithm.
auto column_start = 0;
size_t column_span = 1;
if (child_box.computed_values().grid_column_start().is_span())
column_span = child_box.computed_values().grid_column_start().raw_value();
else if (child_box.computed_values().grid_column_end().is_span())
column_span = child_box.computed_values().grid_column_end().raw_value();
auto row_start = 0;
size_t row_span = 1;
if (child_box.computed_values().grid_row_start().is_span())
row_span = child_box.computed_values().grid_row_start().raw_value();
else if (child_box.computed_values().grid_row_end().is_span())
row_span = child_box.computed_values().grid_row_end().raw_value();
auto found_unoccupied_area = false;
while (true) {
while (auto_placement_cursor_x <= m_occupation_grid.max_column_index()) {
if (auto_placement_cursor_x + static_cast<int>(column_span) <= m_occupation_grid.max_column_index() + 1) {
auto found_all_available = true;
for (size_t span_index = 0; span_index < column_span; span_index++) {
if (m_occupation_grid.is_occupied(auto_placement_cursor_x + span_index, auto_placement_cursor_y))
found_all_available = false;
}
if (found_all_available) {
found_unoccupied_area = true;
column_start = auto_placement_cursor_x;
row_start = auto_placement_cursor_y;
break;
}
}
auto_placement_cursor_x++;
}
if (found_unoccupied_area) {
break;
}
// 4.1.2.2. If a non-overlapping position was found in the previous step, set the item's row-start
// and column-start lines to the cursor's position. Otherwise, increment the auto-placement cursor's
// row position (creating new rows in the implicit grid as necessary), set its column position to the
// start-most column line in the implicit grid, and return to the previous step.
if (!found_unoccupied_area) {
auto_placement_cursor_x = m_occupation_grid.min_column_index();
auto_placement_cursor_y++;
row_start = auto_placement_cursor_y;
}
}
m_occupation_grid.set_occupied(column_start, column_start + column_span, row_start, row_start + row_span);
m_grid_items.append(GridItem {
.box = child_box,
.row = row_start,
.row_span = row_span,
.column = column_start,
.column_span = column_span });
}
void GridFormattingContext::initialize_grid_tracks_from_definition(AvailableSpace const& available_space, Vector<CSS::ExplicitGridTrack> const& tracks_definition, Vector<GridTrack>& tracks)
{
auto track_count = get_count_of_tracks(tracks_definition, available_space);
for (auto const& track_definition : tracks_definition) {
auto repeat_count = (track_definition.is_repeat() && track_definition.repeat().is_default()) ? track_definition.repeat().repeat_count() : 1;
if (track_definition.is_repeat()) {
if (track_definition.repeat().is_auto_fill() || track_definition.repeat().is_auto_fit())
repeat_count = track_count;
}
for (auto _ = 0; _ < repeat_count; _++) {
switch (track_definition.type()) {
case CSS::ExplicitGridTrack::Type::Default:
case CSS::ExplicitGridTrack::Type::MinMax:
tracks.append(GridTrack::create_from_definition(track_definition));
break;
case CSS::ExplicitGridTrack::Type::Repeat:
for (auto& explicit_grid_track : track_definition.repeat().grid_track_size_list().track_list()) {
tracks.append(GridTrack::create_from_definition(explicit_grid_track));
}
break;
default:
VERIFY_NOT_REACHED();
}
}
}
}
void GridFormattingContext::initialize_grid_tracks_for_columns_and_rows(AvailableSpace const& available_space)
{
auto const& grid_computed_values = grid_container().computed_values();
auto const& grid_auto_columns = grid_computed_values.grid_auto_columns().track_list();
size_t implicit_column_index = 0;
// NOTE: If there are implicit tracks created by items with negative indexes they should prepend explicitly defined tracks
auto negative_index_implied_column_tracks_count = abs(m_occupation_grid.min_column_index());
for (int column_index = 0; column_index < negative_index_implied_column_tracks_count; column_index++) {
if (grid_auto_columns.size() > 0) {
auto definition = grid_auto_columns[implicit_column_index % grid_auto_columns.size()];
m_grid_columns.append(GridTrack::create_from_definition(definition));
} else {
m_grid_columns.append(GridTrack::create_auto());
}
implicit_column_index++;
}
initialize_grid_tracks_from_definition(available_space, grid_computed_values.grid_template_columns().track_list(), m_grid_columns);
for (size_t column_index = m_grid_columns.size(); column_index < m_occupation_grid.column_count(); column_index++) {
if (grid_auto_columns.size() > 0) {
auto definition = grid_auto_columns[implicit_column_index % grid_auto_columns.size()];
m_grid_columns.append(GridTrack::create_from_definition(definition));
} else {
m_grid_columns.append(GridTrack::create_auto());
}
implicit_column_index++;
}
auto const& grid_auto_rows = grid_computed_values.grid_auto_rows().track_list();
size_t implicit_row_index = 0;
// NOTE: If there are implicit tracks created by items with negative indexes they should prepend explicitly defined tracks
auto negative_index_implied_row_tracks_count = abs(m_occupation_grid.min_row_index());
for (int row_index = 0; row_index < negative_index_implied_row_tracks_count; row_index++) {
if (grid_auto_rows.size() > 0) {
auto definition = grid_auto_rows[implicit_row_index % grid_auto_rows.size()];
m_grid_rows.append(GridTrack::create_from_definition(definition));
} else {
m_grid_rows.append(GridTrack::create_auto());
}
implicit_row_index++;
}
initialize_grid_tracks_from_definition(available_space, grid_computed_values.grid_template_rows().track_list(), m_grid_rows);
for (size_t row_index = m_grid_rows.size(); row_index < m_occupation_grid.row_count(); row_index++) {
if (grid_auto_rows.size() > 0) {
auto definition = grid_auto_rows[implicit_row_index % grid_auto_rows.size()];
m_grid_rows.append(GridTrack::create_from_definition(definition));
} else {
m_grid_rows.append(GridTrack::create_auto());
}
implicit_row_index++;
}
}
void GridFormattingContext::initialize_gap_tracks(AvailableSpace const& available_space)
{
// https://www.w3.org/TR/css-grid-2/#gutters
// 11.1. Gutters: the row-gap, column-gap, and gap properties
// For the purpose of track sizing, each gutter is treated as an extra, empty, fixed-size track of
// the specified size, which is spanned by any grid items that span across its corresponding grid
// line.
if (!grid_container().computed_values().column_gap().is_auto() && m_grid_columns.size() > 0) {
auto column_gap_width = grid_container().computed_values().column_gap().to_px(grid_container(), available_space.width.to_px());
m_column_gap_tracks.ensure_capacity(m_grid_columns.size() - 1);
for (size_t column_index = 0; column_index < m_grid_columns.size(); column_index++) {
m_grid_columns_and_gaps.append(m_grid_columns[column_index]);
if (column_index != m_grid_columns.size() - 1) {
m_column_gap_tracks.append(GridTrack::create_gap(column_gap_width));
m_grid_columns_and_gaps.append(m_column_gap_tracks.last());
}
}
} else {
for (auto& track : m_grid_columns) {
m_grid_columns_and_gaps.append(track);
}
}
if (!grid_container().computed_values().row_gap().is_auto() && m_grid_rows.size() > 0) {
auto row_gap_height = grid_container().computed_values().row_gap().to_px(grid_container(), available_space.height.to_px());
m_row_gap_tracks.ensure_capacity(m_grid_rows.size() - 1);
for (size_t row_index = 0; row_index < m_grid_rows.size(); row_index++) {
m_grid_rows_and_gaps.append(m_grid_rows[row_index]);
if (row_index != m_grid_rows.size() - 1) {
m_row_gap_tracks.append(GridTrack::create_gap(row_gap_height));
m_grid_rows_and_gaps.append(m_row_gap_tracks.last());
}
}
} else {
for (auto& track : m_grid_rows) {
m_grid_rows_and_gaps.append(track);
}
}
}
void GridFormattingContext::initialize_track_sizes(AvailableSpace const& available_space, GridDimension const dimension)
{
// https://www.w3.org/TR/css-grid-2/#algo-init
// 12.4. Initialize Track Sizes
// Initialize each tracks base size and growth limit.
auto& tracks_and_gaps = dimension == GridDimension::Column ? m_grid_columns_and_gaps : m_grid_rows_and_gaps;
auto& available_size = dimension == GridDimension::Column ? available_space.width : available_space.height;
for (auto& track : tracks_and_gaps) {
if (track.is_gap)
continue;
if (track.min_track_sizing_function.is_fixed(available_size)) {
track.base_size = track.min_track_sizing_function.css_size().to_px(grid_container(), available_size.to_px());
} else if (track.min_track_sizing_function.is_intrinsic(available_size)) {
track.base_size = 0;
}
if (track.max_track_sizing_function.is_fixed(available_size)) {
track.growth_limit = track.max_track_sizing_function.css_size().to_px(grid_container(), available_size.to_px());
} else if (track.max_track_sizing_function.is_flexible_length()) {
track.growth_limit = INFINITY;
} else if (track.max_track_sizing_function.is_intrinsic(available_size)) {
track.growth_limit = INFINITY;
} else {
VERIFY_NOT_REACHED();
}
// In all cases, if the growth limit is less than the base size, increase the growth limit to match
// the base size.
if (track.growth_limit < track.base_size)
track.growth_limit = track.base_size;
}
}
void GridFormattingContext::resolve_intrinsic_track_sizes(AvailableSpace const& available_space, GridDimension const dimension)
{
// https://www.w3.org/TR/css-grid-2/#algo-content
// 12.5. Resolve Intrinsic Track Sizes
// This step resolves intrinsic track sizing functions to absolute lengths. First it resolves those
// sizes based on items that are contained wholly within a single track. Then it gradually adds in
// the space requirements of items that span multiple tracks, evenly distributing the extra space
// across those tracks insofar as possible.
auto& tracks_and_gaps = dimension == GridDimension::Column ? m_grid_columns_and_gaps : m_grid_rows_and_gaps;
// FIXME: 1. Shim baseline-aligned items so their intrinsic size contributions reflect their baseline alignment.
// 2. Size tracks to fit non-spanning items:
increase_sizes_to_accommodate_spanning_items_crossing_content_sized_tracks(available_space, dimension, 1);
// 3. Increase sizes to accommodate spanning items crossing content-sized tracks: Next, consider the
// items with a span of 2 that do not span a track with a flexible sizing function.
// Repeat incrementally for items with greater spans until all items have been considered.
size_t max_item_span = 1;
for (auto& item : m_grid_items)
max_item_span = max(item.span(dimension), max_item_span);
for (size_t span = 2; span <= max_item_span; span++) {
increase_sizes_to_accommodate_spanning_items_crossing_content_sized_tracks(available_space, dimension, 2);
}
// 4. Increase sizes to accommodate spanning items crossing flexible tracks: Next, repeat the previous
// step instead considering (together, rather than grouped by span size) all items that do span a
// track with a flexible sizing function while
increase_sizes_to_accommodate_spanning_items_crossing_flexible_tracks(dimension);
// 5. If any track still has an infinite growth limit (because, for example, it had no items placed in
// it or it is a flexible track), set its growth limit to its base size.
for (auto& track : tracks_and_gaps) {
if (!isfinite(track.growth_limit.to_double())) {
track.growth_limit = track.base_size;
}
}
}
template<typename Match>
void GridFormattingContext::distribute_extra_space_across_spanned_tracks_base_size(GridDimension dimension, CSSPixels item_size_contribution, SpaceDistributionPhase phase, Vector<GridTrack&>& spanned_tracks, Match matcher)
{
auto& available_size = dimension == GridDimension::Column ? m_available_space->width : m_available_space->height;
Vector<GridTrack&> affected_tracks;
for (auto& track : spanned_tracks) {
if (matcher(track))
affected_tracks.append(track);
}
for (auto& track : affected_tracks)
track.item_incurred_increase = 0;
// 1. Find the space to distribute:
CSSPixels spanned_tracks_sizes_sum = 0;
for (auto& track : spanned_tracks)
spanned_tracks_sizes_sum += track.base_size;
// Subtract the corresponding size of every spanned track from the items size contribution to find the items
// remaining size contribution.
auto extra_space = max(CSSPixels(0), item_size_contribution - spanned_tracks_sizes_sum);
// 2. Distribute space up to limits:
// FIXME: If a fixed-point type were used to represent CSS pixels, it would be possible to compare with 0
// instead of epsilon.
while (extra_space > NumericLimits<double>().epsilon()) {
auto all_frozen = all_of(affected_tracks, [](auto const& track) { return track.base_size_frozen; });
if (all_frozen)
break;
// Find the item-incurred increase for each spanned track with an affected size by: distributing the space
// equally among such tracks, freezing a tracks item-incurred increase as its affected size + item-incurred
// increase reaches its limit
CSSPixels increase_per_track = extra_space / affected_tracks.size();
for (auto& track : affected_tracks) {
if (track.base_size_frozen)
continue;
if (increase_per_track >= track.growth_limit) {
track.base_size_frozen = true;
track.item_incurred_increase = track.growth_limit;
extra_space -= track.growth_limit;
} else {
track.item_incurred_increase += increase_per_track;
extra_space -= increase_per_track;
}
}
}
// 3. Distribute space beyond limits
if (extra_space > 0) {
Vector<GridTrack&> tracks_to_grow_beyond_limits;
// If space remains after all tracks are frozen, unfreeze and continue to
// distribute space to the item-incurred increase of...
if (phase == SpaceDistributionPhase::AccommodateMinimumContribution || phase == SpaceDistributionPhase::AccommodateMinContentContribution) {
// when accommodating minimum contributions or accommodating min-content contributions: any affected track
// that happens to also have an intrinsic max track sizing function
for (auto& track : affected_tracks) {
if (track.max_track_sizing_function.is_intrinsic(available_size))
tracks_to_grow_beyond_limits.append(track);
}
// if there are no such tracks, then all affected tracks.
if (tracks_to_grow_beyond_limits.size() == 0)
tracks_to_grow_beyond_limits = affected_tracks;
}
// FIXME: when accommodating max-content contributions: any affected track that happens to also have a
// max-content max track sizing function; if there are no such tracks, then all affected tracks.
CSSPixels increase_per_track = extra_space / affected_tracks.size();
for (auto& track : affected_tracks)
track.item_incurred_increase += increase_per_track;
}
// 4. For each affected track, if the tracks item-incurred increase is larger than the tracks planned increase
// set the tracks planned increase to that value.
for (auto& track : affected_tracks) {
if (track.item_incurred_increase > track.planned_increase)
track.planned_increase = track.item_incurred_increase;
}
}
template<typename Match>
void GridFormattingContext::distribute_extra_space_across_spanned_tracks_growth_limit(CSSPixels item_size_contribution, Vector<GridTrack&>& spanned_tracks, Match matcher)
{
Vector<GridTrack&> affected_tracks;
for (auto& track : spanned_tracks) {
if (matcher(track))
affected_tracks.append(track);
}
for (auto& track : affected_tracks)
track.item_incurred_increase = 0;
// 1. Find the space to distribute:
CSSPixels spanned_tracks_sizes_sum = 0;
for (auto& track : spanned_tracks) {
if (isfinite(track.growth_limit.to_double())) {
spanned_tracks_sizes_sum += track.growth_limit;
} else {
spanned_tracks_sizes_sum += track.base_size;
}
}
// Subtract the corresponding size of every spanned track from the items size contribution to find the items
// remaining size contribution.
auto extra_space = max(CSSPixels(0), item_size_contribution - spanned_tracks_sizes_sum);
// 2. Distribute space up to limits:
// FIXME: If a fixed-point type were used to represent CSS pixels, it would be possible to compare with 0
// instead of epsilon.
while (extra_space > NumericLimits<double>().epsilon()) {
auto all_frozen = all_of(affected_tracks, [](auto const& track) { return track.growth_limit_frozen; });
if (all_frozen)
break;
// Find the item-incurred increase for each spanned track with an affected size by: distributing the space
// equally among such tracks, freezing a tracks item-incurred increase as its affected size + item-incurred
// increase reaches its limit
CSSPixels increase_per_track = extra_space / affected_tracks.size();
for (auto& track : affected_tracks) {
if (track.growth_limit_frozen)
continue;
// For growth limits, the limit is infinity if it is marked as infinitely growable, and equal to the
// growth limit otherwise.
auto limit = track.infinitely_growable ? INFINITY : track.growth_limit;
if (increase_per_track >= limit) {
track.growth_limit_frozen = true;
track.item_incurred_increase = limit;
extra_space -= limit;
} else {
track.item_incurred_increase += increase_per_track;
extra_space -= increase_per_track;
}
}
}
// FIXME: 3. Distribute space beyond limits
// 4. For each affected track, if the tracks item-incurred increase is larger than the tracks planned increase
// set the tracks planned increase to that value.
for (auto& track : spanned_tracks) {
if (track.item_incurred_increase > track.planned_increase)
track.planned_increase = track.item_incurred_increase;
}
}
void GridFormattingContext::increase_sizes_to_accommodate_spanning_items_crossing_content_sized_tracks(AvailableSpace const& available_space, GridDimension const dimension, size_t span)
{
auto& available_size = dimension == GridDimension::Column ? available_space.width : available_space.height;
auto& tracks = dimension == GridDimension::Column ? m_grid_columns : m_grid_rows;
for (auto& item : m_grid_items) {
auto const item_span = item.span(dimension);
if (item_span != span)
continue;
Vector<GridTrack&> spanned_tracks;
for_each_spanned_track_by_item(item, dimension, [&](GridTrack& track) {
spanned_tracks.append(track);
});
auto item_spans_tracks_with_flexible_sizing_function = any_of(spanned_tracks, [](auto& track) {
return track.min_track_sizing_function.is_flexible_length() || track.max_track_sizing_function.is_flexible_length();
});
if (item_spans_tracks_with_flexible_sizing_function)
continue;
// 1. For intrinsic minimums: First increase the base size of tracks with an intrinsic min track sizing
// function by distributing extra space as needed to accommodate these items minimum contributions.
auto item_size_contribution = [&] {
// If the grid container is being sized under a min- or max-content constraint, use the items limited
// min-content contributions in place of their minimum contributions here.
if (available_size.is_intrinsic_sizing_constraint())
return calculate_limited_min_content_contribution(item, dimension);
return calculate_minimum_contribution(item, dimension);
}();
distribute_extra_space_across_spanned_tracks_base_size(dimension, item_size_contribution, SpaceDistributionPhase::AccommodateMinimumContribution, spanned_tracks, [&](GridTrack const& track) {
return track.min_track_sizing_function.is_intrinsic(available_size);
});
for (auto& track : spanned_tracks) {
track.base_size += track.planned_increase;
track.planned_increase = 0;
}
// 2. For content-based minimums: Next continue to increase the base size of tracks with a min track
// sizing function of min-content or max-content by distributing extra space as needed to account for
// these items' min-content contributions.
auto item_min_content_contribution = calculate_min_content_contribution(item, dimension);
distribute_extra_space_across_spanned_tracks_base_size(dimension, item_min_content_contribution, SpaceDistributionPhase::AccommodateMinContentContribution, spanned_tracks, [&](GridTrack const& track) {
return track.min_track_sizing_function.is_min_content() || track.min_track_sizing_function.is_max_content();
});
for (auto& track : spanned_tracks) {
track.base_size += track.planned_increase;
track.planned_increase = 0;
}
// 3. For max-content minimums: Next, if the grid container is being sized under a max-content constraint,
// continue to increase the base size of tracks with a min track sizing function of auto or max-content by
// distributing extra space as needed to account for these items' limited max-content contributions.
if (available_size.is_max_content()) {
auto item_limited_max_content_contribution = calculate_limited_max_content_contribution(item, dimension);
distribute_extra_space_across_spanned_tracks_base_size(dimension, item_limited_max_content_contribution, SpaceDistributionPhase::AccommodateMaxContentContribution, spanned_tracks, [&](GridTrack const& track) {
return track.min_track_sizing_function.is_auto(available_size) || track.min_track_sizing_function.is_max_content();
});
for (auto& track : spanned_tracks) {
track.base_size += track.planned_increase;
track.planned_increase = 0;
}
}
// 4. If at this point any tracks growth limit is now less than its base size, increase its growth limit to
// match its base size.
for (auto& track : tracks) {
if (track.growth_limit < track.base_size)
track.growth_limit = track.base_size;
}
// 5. For intrinsic maximums: Next increase the growth limit of tracks with an intrinsic max track sizing
distribute_extra_space_across_spanned_tracks_growth_limit(item_min_content_contribution, spanned_tracks, [&](GridTrack const& track) {
return track.max_track_sizing_function.is_intrinsic(available_size);
});
for (auto& track : spanned_tracks) {
if (!isfinite(track.growth_limit.to_double())) {
// If the affected size is an infinite growth limit, set it to the tracks base size plus the planned increase.
track.growth_limit = track.base_size + track.planned_increase;
// Mark any tracks whose growth limit changed from infinite to finite in this step as infinitely growable
// for the next step.
track.infinitely_growable = true;
} else {
track.growth_limit += track.planned_increase;
}
track.planned_increase = 0;
}
// 6. For max-content maximums: Lastly continue to increase the growth limit of tracks with a max track
// sizing function of max-content by distributing extra space as needed to account for these items' max-
// content contributions.
auto item_max_content_contribution = calculate_max_content_contribution(item, dimension);
distribute_extra_space_across_spanned_tracks_growth_limit(item_max_content_contribution, spanned_tracks, [&](GridTrack const& track) {
return track.max_track_sizing_function.is_max_content() || track.max_track_sizing_function.is_auto(available_size);
});
for (auto& track : spanned_tracks) {
if (!isfinite(track.growth_limit.to_double())) {
// If the affected size is an infinite growth limit, set it to the tracks base size plus the planned increase.
track.growth_limit = track.base_size + track.planned_increase;
} else {
track.growth_limit += track.planned_increase;
}
track.planned_increase = 0;
}
}
}
void GridFormattingContext::increase_sizes_to_accommodate_spanning_items_crossing_flexible_tracks(GridDimension const dimension)
{
auto& tracks = dimension == GridDimension::Column ? m_grid_columns : m_grid_rows;
for (auto& item : m_grid_items) {
Vector<GridTrack&> spanned_tracks;
for_each_spanned_track_by_item(item, dimension, [&](GridTrack& track) {
spanned_tracks.append(track);
});
auto item_spans_tracks_with_flexible_sizing_function = any_of(spanned_tracks, [](auto& track) {
return track.min_track_sizing_function.is_flexible_length() || track.max_track_sizing_function.is_flexible_length();
});
if (!item_spans_tracks_with_flexible_sizing_function)
continue;
// 1. For intrinsic minimums: First increase the base size of tracks with an intrinsic min track sizing
// function by distributing extra space as needed to accommodate these items minimum contributions.
auto item_minimum_contribution = automatic_minimum_size(item, dimension);
distribute_extra_space_across_spanned_tracks_base_size(dimension,
item_minimum_contribution, SpaceDistributionPhase::AccommodateMinimumContribution, spanned_tracks, [&](GridTrack const& track) {
return track.min_track_sizing_function.is_flexible_length();
});
for (auto& track : spanned_tracks) {
track.base_size += track.planned_increase;
}
// 4. If at this point any tracks growth limit is now less than its base size, increase its growth limit to
// match its base size.
for (auto& track : tracks) {
if (track.growth_limit < track.base_size)
track.growth_limit = track.base_size;
}
}
}
void GridFormattingContext::maximize_tracks(AvailableSpace const& available_space, GridDimension const dimension)
{
// https://www.w3.org/TR/css-grid-2/#algo-grow-tracks
// 12.6. Maximize Tracks
auto& tracks = dimension == GridDimension::Column ? m_grid_columns : m_grid_rows;
auto get_free_space_px = [&]() -> CSSPixels {
// For the purpose of this step: if sizing the grid container under a max-content constraint, the
// free space is infinite; if sizing under a min-content constraint, the free space is zero.
auto free_space = get_free_space(available_space, dimension);
if (free_space.is_max_content()) {
return INFINITY;
} else if (free_space.is_min_content()) {
return 0;
} else {
return free_space.to_px();
}
};
auto free_space_px = get_free_space_px();
// If the free space is positive, distribute it equally to the base sizes of all tracks, freezing
// tracks as they reach their growth limits (and continuing to grow the unfrozen tracks as needed).
while (free_space_px > 0) {
auto free_space_to_distribute_per_track = free_space_px / tracks.size();
for (auto& track : tracks) {
if (track.base_size_frozen)
continue;
VERIFY(isfinite(track.growth_limit.to_double()));
track.base_size = min(track.growth_limit, track.base_size + free_space_to_distribute_per_track);
}
if (get_free_space_px() == free_space_px)
break;
free_space_px = get_free_space_px();
}
// FIXME: If this would cause the grid to be larger than the grid containers inner size as limited by its
// max-width/height, then redo this step, treating the available grid space as equal to the grid
// containers inner size when its sized to its max-width/height.
}
void GridFormattingContext::expand_flexible_tracks(AvailableSpace const& available_space, GridDimension const dimension)
{
// https://drafts.csswg.org/css-grid/#algo-flex-tracks
// 12.7. Expand Flexible Tracks
// This step sizes flexible tracks using the largest value it can assign to an fr without exceeding
// the available space.
auto& tracks_and_gaps = dimension == GridDimension::Column ? m_grid_columns_and_gaps : m_grid_rows_and_gaps;
auto& tracks = dimension == GridDimension::Column ? m_grid_columns : m_grid_rows;
auto& available_size = dimension == GridDimension::Column ? available_space.width : available_space.height;
auto find_the_size_of_an_fr = [&](Vector<GridTrack&> tracks, CSSPixels space_to_fill) -> CSSPixels {
// https://www.w3.org/TR/css-grid-2/#algo-find-fr-size
// 1. Let leftover space be the space to fill minus the base sizes of the non-flexible grid tracks.
auto leftover_space = space_to_fill;
for (auto& track : tracks) {
if (!track.max_track_sizing_function.is_flexible_length()) {
leftover_space -= track.base_size;
}
}
// 2. Let flex factor sum be the sum of the flex factors of the flexible tracks.
// If this value is less than 1, set it to 1 instead.
auto flex_factor_sum = 0;
for (auto& track : tracks) {
if (track.max_track_sizing_function.is_flexible_length())
flex_factor_sum += track.max_track_sizing_function.flex_factor();
}
if (flex_factor_sum < 1)
flex_factor_sum = 1;
// 3. Let the hypothetical fr size be the leftover space divided by the flex factor sum.
auto hypothetical_fr_size = leftover_space / flex_factor_sum;
// FIXME: 4. If the product of the hypothetical fr size and a flexible tracks flex factor is less than the tracks
// base size, restart this algorithm treating all such tracks as inflexible.
// 5. Return the hypothetical fr size.
return hypothetical_fr_size;
};
// First, find the grids used flex fraction:
auto flex_fraction = [&]() {
auto free_space = get_free_space(available_space, dimension);
// If the free space is zero or if sizing the grid container under a min-content constraint:
if (free_space.to_px() == 0 || available_size.is_min_content()) {
// The used flex fraction is zero.
return CSSPixels(0);
// Otherwise, if the free space is a definite length:
} else if (free_space.is_definite()) {
// The used flex fraction is the result of finding the size of an fr using all of the grid tracks and a space
// to fill of the available grid space.
return find_the_size_of_an_fr(tracks_and_gaps, available_size.to_px());
} else {
// Otherwise, if the free space is an indefinite length:
// The used flex fraction is the maximum of:
CSSPixels result = 0;
// For each flexible track, if the flexible tracks flex factor is greater than one, the result of dividing
// the tracks base size by its flex factor; otherwise, the tracks base size.
for (auto& track : tracks) {
if (track.max_track_sizing_function.is_flexible_length()) {
if (track.max_track_sizing_function.flex_factor() > 1) {
result = max(result, track.base_size / track.max_track_sizing_function.flex_factor());
} else {
result = max(result, track.base_size);
}
}
}
// For each grid item that crosses a flexible track, the result of finding the size of an fr using all the
// grid tracks that the item crosses and a space to fill of the items max-content contribution.
for (auto& item : m_grid_items) {
Vector<GridTrack&> spanned_tracks;
bool crosses_flexible_track = false;
for_each_spanned_track_by_item(item, dimension, [&](GridTrack& track) {
spanned_tracks.append(track);
if (track.max_track_sizing_function.is_flexible_length())
crosses_flexible_track = true;
});
if (crosses_flexible_track)
result = max(result, find_the_size_of_an_fr(spanned_tracks, calculate_max_content_size(item, dimension)));
}
return result;
}
}();
// For each flexible track, if the product of the used flex fraction and the tracks flex factor is greater than
// the tracks base size, set its base size to that product.
for (auto& track : tracks_and_gaps) {
if (track.max_track_sizing_function.flex_factor() * flex_fraction > track.base_size) {
track.base_size = track.max_track_sizing_function.flex_factor() * flex_fraction;
}
}
}
void GridFormattingContext::stretch_auto_tracks(AvailableSpace const& available_space, GridDimension const dimension)
{
// https://drafts.csswg.org/css-grid/#algo-stretch
// 12.8. Stretch auto Tracks
auto& tracks_and_gaps = dimension == GridDimension::Column ? m_grid_columns_and_gaps : m_grid_rows_and_gaps;
auto& available_size = dimension == GridDimension::Column ? available_space.width : available_space.height;
// When the content-distribution property of the grid container is normal or stretch in this axis,
// this step expands tracks that have an auto max track sizing function by dividing any remaining
// positive, definite free space equally amongst them. If the free space is indefinite, but the grid
// container has a definite min-width/height, use that size to calculate the free space for this
// step instead.
CSSPixels used_space = 0;
for (auto& track : tracks_and_gaps) {
if (!track.max_track_sizing_function.is_auto(available_size))
used_space += track.base_size;
}
CSSPixels remaining_space = available_size.is_definite() ? available_size.to_px() - used_space : 0;
auto count_of_auto_max_sizing_tracks = 0;
for (auto& track : tracks_and_gaps) {
if (track.max_track_sizing_function.is_auto(available_size))
count_of_auto_max_sizing_tracks++;
}
for (auto& track : tracks_and_gaps) {
if (track.max_track_sizing_function.is_auto(available_size))
track.base_size = max(track.base_size, remaining_space / count_of_auto_max_sizing_tracks);
}
}
void GridFormattingContext::run_track_sizing(AvailableSpace const& available_space, GridDimension const dimension)
{
// https://www.w3.org/TR/css-grid-2/#algo-track-sizing
// 12.3. Track Sizing Algorithm
// 1. Initialize Track Sizes
initialize_track_sizes(available_space, dimension);
// 2. Resolve Intrinsic Track Sizes
resolve_intrinsic_track_sizes(available_space, dimension);
// 3. Maximize Tracks
maximize_tracks(available_space, dimension);
// 4. Expand Flexible Tracks
expand_flexible_tracks(available_space, dimension);
// 5. Expand Stretched auto Tracks
stretch_auto_tracks(available_space, dimension);
// If calculating the layout of a grid item in this step depends on the available space in the block
// axis, assume the available space that it would have if any row with a definite max track sizing
// function had that size and all other rows were infinite. If both the grid container and all
// tracks have definite sizes, also apply align-content to find the final effective size of any gaps
// spanned by such items; otherwise ignore the effects of track alignment in this estimation.
}
void GridFormattingContext::build_grid_areas()
{
// https://www.w3.org/TR/css-grid-2/#grid-template-areas-property
// If a named grid area spans multiple grid cells, but those cells do not form a single
// filled-in rectangle, the declaration is invalid.
for (size_t y = 0; y < grid_container().computed_values().grid_template_areas().size(); y++) {
for (size_t x = 0; x < grid_container().computed_values().grid_template_areas()[y].size(); x++) {
auto grid_area_name = grid_container().computed_values().grid_template_areas()[y][x];
auto maybe_grid_area = m_grid_areas.get(grid_area_name);
if (!maybe_grid_area.has_value()) {
m_grid_areas.set(grid_area_name, { grid_area_name, y, y + 1, x, x + 1 });
} else {
auto& grid_area = maybe_grid_area.value();
if (grid_area.row_start == y) {
if (grid_area.column_end == x)
grid_area.column_end = grid_area.column_end + 1;
else
return;
} else {
if (grid_area.row_end == y) {
if (grid_area.column_start != x)
return;
grid_area.row_end = grid_area.row_end + 1;
} else if (grid_area.row_end == y + 1) {
if (grid_area.column_end < x || grid_area.column_end > x + 1)
return;
} else {
return;
}
}
}
}
}
}
void GridFormattingContext::place_grid_items(AvailableSpace const& available_space)
{
auto grid_template_columns = grid_container().computed_values().grid_template_columns();
auto grid_template_rows = grid_container().computed_values().grid_template_rows();
auto column_count = get_count_of_tracks(grid_template_columns.track_list(), available_space);
auto row_count = get_count_of_tracks(grid_template_rows.track_list(), available_space);
// https://drafts.csswg.org/css-grid/#overview-placement
// 2.2. Placing Items
// The contents of the grid container are organized into individual grid items (analogous to
// flex items), which are then assigned to predefined areas in the grid. They can be explicitly
// placed using coordinates through the grid-placement properties or implicitly placed into
// empty areas using auto-placement.
grid_container().for_each_child_of_type<Box>([&](Box& child_box) {
if (can_skip_is_anonymous_text_run(child_box))
return IterationDecision::Continue;
m_boxes_to_place.append(child_box);
return IterationDecision::Continue;
});
m_occupation_grid = OccupationGrid(column_count, row_count);
build_grid_areas();
// https://drafts.csswg.org/css-grid/#auto-placement-algo
// 8.5. Grid Item Placement Algorithm
// FIXME: 0. Generate anonymous grid items
// 1. Position anything that's not auto-positioned.
for (size_t i = 0; i < m_boxes_to_place.size(); i++) {
auto const& child_box = m_boxes_to_place[i];
if (is_auto_positioned_row(child_box->computed_values().grid_row_start(), child_box->computed_values().grid_row_end())
|| is_auto_positioned_column(child_box->computed_values().grid_column_start(), child_box->computed_values().grid_column_end()))
continue;
place_item_with_row_and_column_position(child_box);
m_boxes_to_place.remove(i);
i--;
}
// 2. Process the items locked to a given row.
// FIXME: Do "dense" packing
for (size_t i = 0; i < m_boxes_to_place.size(); i++) {
auto const& child_box = m_boxes_to_place[i];
if (is_auto_positioned_row(child_box->computed_values().grid_row_start(), child_box->computed_values().grid_row_end()))
continue;
place_item_with_row_position(child_box);
m_boxes_to_place.remove(i);
i--;
}
// 3. Determine the columns in the implicit grid.
// NOTE: "implicit grid" here is the same as the m_occupation_grid
// 3.1. Start with the columns from the explicit grid.
// NOTE: Done in step 1.
// 3.2. Among all the items with a definite column position (explicitly positioned items, items
// positioned in the previous step, and items not yet positioned but with a definite column) add
// columns to the beginning and end of the implicit grid as necessary to accommodate those items.
// NOTE: "Explicitly positioned items" and "items positioned in the previous step" done in step 1
// and 2, respectively. Adding columns for "items not yet positioned but with a definite column"
// will be done in step 4.
// 3.3. If the largest column span among all the items without a definite column position is larger
// than the width of the implicit grid, add columns to the end of the implicit grid to accommodate
// that column span.
for (auto const& child_box : m_boxes_to_place) {
int column_span = 1;
if (child_box->computed_values().grid_column_start().is_span())
column_span = child_box->computed_values().grid_column_start().raw_value();
else if (child_box->computed_values().grid_column_end().is_span())
column_span = child_box->computed_values().grid_column_end().raw_value();
if (column_span - 1 > m_occupation_grid.max_column_index())
m_occupation_grid.set_max_column_index(column_span - 1);
}
// 4. Position the remaining grid items.
// For each grid item that hasn't been positioned by the previous steps, in order-modified document
// order:
auto auto_placement_cursor_x = 0;
auto auto_placement_cursor_y = 0;
for (size_t i = 0; i < m_boxes_to_place.size(); i++) {
auto const& child_box = m_boxes_to_place[i];
// 4.1. For sparse packing:
// FIXME: no distinction made. See #4.2
// 4.1.1. If the item has a definite column position:
if (!is_auto_positioned_column(child_box->computed_values().grid_column_start(), child_box->computed_values().grid_column_end()))
place_item_with_column_position(child_box, auto_placement_cursor_x, auto_placement_cursor_y);
// 4.1.2. If the item has an automatic grid position in both axes:
else
place_item_with_no_declared_position(child_box, auto_placement_cursor_x, auto_placement_cursor_y);
m_boxes_to_place.remove(i);
i--;
// FIXME: 4.2. For dense packing:
}
// NOTE: When final implicit grid sizes are known, we can offset their positions so leftmost grid track has 0 index.
for (auto& item : m_grid_items) {
item.row = item.row - m_occupation_grid.min_row_index();
item.column = item.column - m_occupation_grid.min_column_index();
}
}
void GridFormattingContext::determine_grid_container_height()
{
CSSPixels total_y = 0;
for (auto& grid_row : m_grid_rows_and_gaps)
total_y += grid_row.base_size;
m_automatic_content_height = total_y;
}
void GridFormattingContext::resolve_grid_item_widths()
{
for (auto& item : m_grid_items) {
CSSPixels containing_block_width = containing_block_size_for_item(item, GridDimension::Column);
auto& box_state = m_state.get_mutable(item.box);
auto const& computed_values = item.box->computed_values();
auto const& computed_width = computed_values.width();
auto try_compute_width = [&](CSSPixels a_width) {
CSSPixels width = a_width;
// Auto margins absorb positive free space prior to alignment via the box alignment properties.
auto free_space_left_for_margins = containing_block_width - width - box_state.border_left - box_state.border_right - box_state.padding_left - box_state.padding_right - box_state.margin_left - box_state.margin_right;
if (computed_values.margin().left().is_auto() && computed_values.margin().right().is_auto()) {
box_state.margin_left = free_space_left_for_margins / 2;
box_state.margin_right = free_space_left_for_margins / 2;
} else if (computed_values.margin().left().is_auto()) {
box_state.margin_left = free_space_left_for_margins;
} else if (computed_values.margin().right().is_auto()) {
box_state.margin_right = free_space_left_for_margins;
} else if (computed_values.width().is_auto()) {
width += free_space_left_for_margins;
}
auto free_space_left_for_alignment = containing_block_width - a_width - box_state.border_left - box_state.border_right - box_state.padding_left - box_state.padding_right - box_state.margin_left - box_state.margin_right;
switch (computed_values.justify_self()) {
case CSS::JustifySelf::Normal:
case CSS::JustifySelf::Stretch:
return width;
case CSS::JustifySelf::Center:
box_state.margin_left += free_space_left_for_alignment / 2;
box_state.margin_right += free_space_left_for_alignment / 2;
return a_width;
case CSS::JustifySelf::Start:
case CSS::JustifySelf::FlexStart:
box_state.margin_right += free_space_left_for_alignment;
return a_width;
case CSS::JustifySelf::End:
case CSS::JustifySelf::FlexEnd:
box_state.margin_left += free_space_left_for_alignment;
return a_width;
default:
break;
}
return width;
};
CSSPixels used_width;
if (computed_width.is_auto()) {
used_width = try_compute_width(calculate_fit_content_width(item.box, get_available_space_for_item(item)));
} else if (computed_width.is_fit_content()) {
used_width = try_compute_width(calculate_fit_content_width(item.box, get_available_space_for_item(item)));
} else {
used_width = try_compute_width(computed_width.to_px(grid_container(), containing_block_width));
}
box_state.set_content_width(used_width);
}
}
void GridFormattingContext::resolve_grid_item_heights()
{
for (auto& item : m_grid_items) {
CSSPixels containing_block_height = containing_block_size_for_item(item, GridDimension::Row);
auto border_top = item.box->computed_values().border_top().width;
auto border_bottom = item.box->computed_values().border_bottom().width;
auto& box_state = m_state.get_mutable(item.box);
box_state.border_top = border_top;
box_state.border_bottom = border_bottom;
auto const& computed_height = item.box->computed_values().height();
auto used_height = computed_height.is_auto()
? (containing_block_height - box_state.margin_box_top() - box_state.margin_box_bottom())
: computed_height.to_px(grid_container(), containing_block_height);
box_state.set_content_height(used_height);
}
}
void GridFormattingContext::resolve_items_box_metrics(GridDimension const dimension)
{
for (auto& item : m_grid_items) {
auto& box_state = m_state.get_mutable(item.box);
auto& computed_values = item.box->computed_values();
if (dimension == GridDimension::Column) {
CSSPixels containing_block_width = containing_block_size_for_item(item, GridDimension::Column);
box_state.padding_right = computed_values.padding().right().to_px(grid_container(), containing_block_width);
box_state.padding_left = computed_values.padding().left().to_px(grid_container(), containing_block_width);
box_state.margin_right = computed_values.margin().right().to_px(grid_container(), containing_block_width);
box_state.margin_left = computed_values.margin().left().to_px(grid_container(), containing_block_width);
box_state.border_right = computed_values.border_right().width;
box_state.border_left = computed_values.border_left().width;
} else {
CSSPixels containing_block_height = containing_block_size_for_item(item, GridDimension::Row);
box_state.padding_top = computed_values.padding().top().to_px(grid_container(), containing_block_height);
box_state.padding_bottom = computed_values.padding().bottom().to_px(grid_container(), containing_block_height);
box_state.margin_top = computed_values.margin().top().to_px(grid_container(), containing_block_height);
box_state.margin_bottom = computed_values.margin().bottom().to_px(grid_container(), containing_block_height);
box_state.border_top = computed_values.border_top().width;
box_state.border_bottom = computed_values.border_bottom().width;
}
}
}
void GridFormattingContext::collapse_auto_fit_tracks_if_needed(GridDimension const dimension)
{
// https://www.w3.org/TR/css-grid-2/#auto-repeat
// The auto-fit keyword behaves the same as auto-fill, except that after grid item placement any
// empty repeated tracks are collapsed. An empty track is one with no in-flow grid items placed into
// or spanning across it. (This can result in all tracks being collapsed, if theyre all empty.)
auto const& grid_computed_values = grid_container().computed_values();
auto const& tracks_definition = dimension == GridDimension::Column ? grid_computed_values.grid_template_columns().track_list() : grid_computed_values.grid_template_rows().track_list();
auto& tracks = dimension == GridDimension::Column ? m_grid_columns : m_grid_rows;
if (tracks_definition.size() == 1 && tracks_definition.first().is_repeat() && tracks_definition.first().repeat().is_auto_fit()) {
for (size_t track_index = 0; track_index < tracks.size(); track_index++) {
if (m_occupation_grid.is_occupied(dimension == GridDimension::Column ? track_index : 0, dimension == GridDimension::Row ? track_index : 0))
continue;
// NOTE: A collapsed track is treated as having a fixed track sizing function of 0px
tracks[track_index].min_track_sizing_function = CSS::GridSize(CSS::Length::make_px(0));
tracks[track_index].max_track_sizing_function = CSS::GridSize(CSS::Length::make_px(0));
}
}
}
void GridFormattingContext::run(Box const& box, LayoutMode, AvailableSpace const& available_space)
{
m_available_space = available_space;
auto const& grid_computed_values = grid_container().computed_values();
// NOTE: We store explicit grid sizes to later use in determining the position of items with negative index.
m_explicit_columns_line_count = get_count_of_tracks(grid_computed_values.grid_template_columns().track_list(), available_space) + 1;
m_explicit_rows_line_count = get_count_of_tracks(grid_computed_values.grid_template_rows().track_list(), available_space) + 1;
place_grid_items(available_space);
initialize_grid_tracks_for_columns_and_rows(available_space);
initialize_gap_tracks(available_space);
collapse_auto_fit_tracks_if_needed(GridDimension::Column);
collapse_auto_fit_tracks_if_needed(GridDimension::Row);
for (auto& item : m_grid_items) {
auto& box_state = m_state.get_mutable(item.box);
auto& computed_values = item.box->computed_values();
// NOTE: As the containing blocks of grid items are created by implicit grid areas that are not present in the
// layout tree, the initial value of has_definite_width/height computed by LayoutState::UsedValues::set_node
// will be incorrect for anything other (auto, percentage, calculated) than fixed lengths.
// Therefor, it becomes necessary to reset this value to indefinite.
// TODO: Handle this in LayoutState::UsedValues::set_node
if (!computed_values.width().is_length())
box_state.set_indefinite_content_width();
if (!computed_values.height().is_length())
box_state.set_indefinite_content_height();
}
// Do the first pass of resolving grid items box metrics to compute values that are independent of a track width
resolve_items_box_metrics(GridDimension::Column);
run_track_sizing(available_space, GridDimension::Column);
// Do the second pass of resolving box metrics to compute values that depend on a track width
resolve_items_box_metrics(GridDimension::Column);
// Once the sizes of column tracks, which determine the widths of the grid areas forming the containing blocks
// for grid items, ara calculated, it becomes possible to determine the final widths of the grid items.
resolve_grid_item_widths();
// Do the first pass of resolving grid items box metrics to compute values that are independent of a track height
resolve_items_box_metrics(GridDimension::Row);
run_track_sizing(available_space, GridDimension::Row);
// Do the second pass of resolving box metrics to compute values that depend on a track height
resolve_items_box_metrics(GridDimension::Row);
resolve_grid_item_heights();
determine_grid_container_height();
if (available_space.height.is_intrinsic_sizing_constraint() || available_space.width.is_intrinsic_sizing_constraint()) {
determine_intrinsic_size_of_grid_container(available_space);
return;
}
auto layout_box = [&](int row_start, int row_end, int column_start, int column_end, Box const& child_box) -> void {
if (column_start < 0 || row_start < 0)
return;
auto& child_box_state = m_state.get_mutable(child_box);
CSSPixels x_start = 0;
CSSPixels x_end = 0;
CSSPixels y_start = 0;
CSSPixels y_end = 0;
for (int i = 0; i < column_start; i++)
x_start += m_grid_columns_and_gaps[i].base_size;
for (int i = 0; i < column_end; i++)
x_end += m_grid_columns_and_gaps[i].base_size;
for (int i = 0; i < row_start; i++)
y_start += m_grid_rows_and_gaps[i].base_size;
for (int i = 0; i < row_end; i++) {
y_end += m_grid_rows_and_gaps[i].base_size;
}
child_box_state.offset = {
x_start + child_box_state.border_left + child_box_state.padding_left + child_box_state.margin_left,
y_start + child_box_state.border_top + child_box_state.padding_top + child_box_state.margin_top
};
compute_inset(child_box);
auto available_space_for_children = AvailableSpace(AvailableSize::make_definite(child_box_state.content_width()), AvailableSize::make_definite(child_box_state.content_height()));
if (auto independent_formatting_context = layout_inside(child_box, LayoutMode::Normal, available_space_for_children))
independent_formatting_context->parent_context_did_dimension_child_root_box();
};
for (auto& grid_item : m_grid_items) {
auto resolved_row_span = box.computed_values().row_gap().is_auto() ? grid_item.row_span : grid_item.row_span * 2;
if (!box.computed_values().row_gap().is_auto() && grid_item.gap_adjusted_row(box) == 0)
resolved_row_span -= 1;
if (grid_item.gap_adjusted_row(box) + resolved_row_span > m_grid_rows.size())
resolved_row_span = m_grid_rows_and_gaps.size() - grid_item.gap_adjusted_row(box);
auto resolved_column_span = box.computed_values().column_gap().is_auto() ? grid_item.column_span : grid_item.column_span * 2;
if (!box.computed_values().column_gap().is_auto() && grid_item.gap_adjusted_column(box) == 0)
resolved_column_span -= 1;
if (grid_item.gap_adjusted_column(box) + resolved_column_span > m_grid_columns_and_gaps.size())
resolved_column_span = m_grid_columns_and_gaps.size() - grid_item.gap_adjusted_column(box);
layout_box(
grid_item.gap_adjusted_row(box),
grid_item.gap_adjusted_row(box) + resolved_row_span,
grid_item.gap_adjusted_column(box),
grid_item.gap_adjusted_column(box) + resolved_column_span,
grid_item.box);
}
}
void GridFormattingContext::determine_intrinsic_size_of_grid_container(AvailableSpace const& available_space)
{
// https://www.w3.org/TR/css-grid-1/#intrinsic-sizes
// The max-content size (min-content size) of a grid container is the sum of the grid containers track sizes
// (including gutters) in the appropriate axis, when the grid is sized under a max-content constraint (min-content constraint).
if (available_space.height.is_intrinsic_sizing_constraint()) {
CSSPixels grid_container_height = 0;
for (auto& track : m_grid_rows) {
grid_container_height += track.base_size;
}
m_state.get_mutable(grid_container()).set_content_height(grid_container_height);
}
if (available_space.width.is_intrinsic_sizing_constraint()) {
CSSPixels grid_container_width = 0;
for (auto& track : m_grid_columns) {
grid_container_width += track.base_size;
}
m_state.get_mutable(grid_container()).set_content_width(grid_container_width);
}
}
CSSPixels GridFormattingContext::automatic_content_width() const
{
return m_state.get(grid_container()).content_width();
}
CSSPixels GridFormattingContext::automatic_content_height() const
{
return m_automatic_content_height;
}
bool GridFormattingContext::is_auto_positioned_row(CSS::GridTrackPlacement const& grid_row_start, CSS::GridTrackPlacement const& grid_row_end) const
{
return is_auto_positioned_track(grid_row_start, grid_row_end);
}
bool GridFormattingContext::is_auto_positioned_column(CSS::GridTrackPlacement const& grid_column_start, CSS::GridTrackPlacement const& grid_column_end) const
{
return is_auto_positioned_track(grid_column_start, grid_column_end);
}
bool GridFormattingContext::is_auto_positioned_track(CSS::GridTrackPlacement const& grid_track_start, CSS::GridTrackPlacement const& grid_track_end) const
{
return grid_track_start.is_auto_positioned() && grid_track_end.is_auto_positioned();
}
AvailableSize GridFormattingContext::get_free_space(AvailableSpace const& available_space, GridDimension const dimension) const
{
// https://www.w3.org/TR/css-grid-2/#algo-terms
// free space: Equal to the available grid space minus the sum of the base sizes of all the grid
// tracks (including gutters), floored at zero. If available grid space is indefinite, the free
// space is indefinite as well.
auto& available_size = dimension == GridDimension::Column ? available_space.width : available_space.height;
auto& tracks = dimension == GridDimension::Column ? m_grid_columns_and_gaps : m_grid_rows_and_gaps;
if (available_size.is_definite()) {
CSSPixels sum_base_sizes = 0;
for (auto& track : tracks)
sum_base_sizes += track.base_size;
return AvailableSize::make_definite(max(CSSPixels(0), available_size.to_px() - sum_base_sizes));
}
return available_size;
}
int GridFormattingContext::get_line_index_by_line_name(String const& needle, CSS::GridTrackSizeList grid_track_size_list)
{
if (grid_track_size_list.track_list().size() == 0)
return -1;
auto repeated_tracks_count = 0;
for (size_t x = 0; x < grid_track_size_list.track_list().size(); x++) {
if (grid_track_size_list.track_list()[x].is_repeat()) {
// FIXME: Calculate amount of columns/rows if auto-fill/fit
if (!grid_track_size_list.track_list()[x].repeat().is_default())
return -1;
auto repeat = grid_track_size_list.track_list()[x].repeat().grid_track_size_list();
for (size_t y = 0; y < repeat.track_list().size(); y++) {
for (size_t z = 0; z < repeat.line_names()[y].size(); z++) {
if (repeat.line_names()[y][z] == needle)
return x + repeated_tracks_count;
repeated_tracks_count++;
}
}
} else {
for (size_t y = 0; y < grid_track_size_list.line_names()[x].size(); y++) {
if (grid_track_size_list.line_names()[x][y] == needle)
return x + repeated_tracks_count;
}
}
}
for (size_t y = 0; y < grid_track_size_list.line_names()[grid_track_size_list.track_list().size()].size(); y++) {
if (grid_track_size_list.line_names()[grid_track_size_list.track_list().size()][y] == needle)
return grid_track_size_list.track_list().size() + repeated_tracks_count;
}
return -1;
}
void OccupationGrid::set_occupied(int column_start, int column_end, int row_start, int row_end)
{
for (int row_index = row_start; row_index < row_end; row_index++) {
for (int column_index = column_start; column_index < column_end; column_index++) {
m_min_column_index = min(m_min_column_index, column_index);
m_max_column_index = max(m_max_column_index, column_index);
m_min_row_index = min(m_min_row_index, row_index);
m_max_row_index = max(m_max_row_index, row_index);
m_occupation_grid.set(GridPosition { .row = row_index, .column = column_index });
}
}
}
bool OccupationGrid::is_occupied(int column_index, int row_index) const
{
return m_occupation_grid.contains(GridPosition { row_index, column_index });
}
int GridItem::gap_adjusted_row(Box const& grid_box) const
{
return grid_box.computed_values().row_gap().is_auto() ? row : row * 2;
}
int GridItem::gap_adjusted_column(Box const& grid_box) const
{
return grid_box.computed_values().column_gap().is_auto() ? column : column * 2;
}
CSS::Size const& GridFormattingContext::get_item_preferred_size(GridItem const& item, GridDimension const dimension) const
{
if (dimension == GridDimension::Column)
return item.box->computed_values().width();
return item.box->computed_values().height();
}
CSSPixels GridFormattingContext::calculate_min_content_size(GridItem const& item, GridDimension const dimension) const
{
if (dimension == GridDimension::Column) {
return calculate_min_content_width(item.box);
} else {
return calculate_min_content_height(item.box, get_available_space_for_item(item).width);
}
}
CSSPixels GridFormattingContext::calculate_max_content_size(GridItem const& item, GridDimension const dimension) const
{
if (dimension == GridDimension::Column) {
return calculate_max_content_width(item.box);
} else {
return calculate_max_content_height(item.box, get_available_space_for_item(item).width);
}
}
CSSPixels GridFormattingContext::containing_block_size_for_item(GridItem const& item, GridDimension const dimension) const
{
CSSPixels containing_block_size = 0;
for_each_spanned_track_by_item(item, dimension, [&](GridTrack const& track) {
containing_block_size += track.base_size;
});
return containing_block_size;
}
AvailableSpace GridFormattingContext::get_available_space_for_item(GridItem const& item) const
{
auto& item_box_state = m_state.get(item.box);
AvailableSize available_width = item_box_state.has_definite_width() ? AvailableSize::make_definite(item_box_state.content_width()) : AvailableSize::make_indefinite();
AvailableSize available_height = item_box_state.has_definite_height() ? AvailableSize::make_definite(item_box_state.content_height()) : AvailableSize::make_indefinite();
return AvailableSpace(available_width, available_height);
}
CSSPixels GridFormattingContext::calculate_min_content_contribution(GridItem const& item, GridDimension const dimension) const
{
auto available_space_for_item = get_available_space_for_item(item);
auto should_treat_preferred_size_as_auto = [&] {
if (dimension == GridDimension::Column)
return should_treat_width_as_auto(item.box, available_space_for_item);
return should_treat_height_as_auto(item.box, available_space_for_item);
}();
if (should_treat_preferred_size_as_auto) {
return item.add_margin_box_sizes(calculate_min_content_size(item, dimension), dimension, m_state);
}
auto preferred_size = get_item_preferred_size(item, dimension);
auto containing_block_size = containing_block_size_for_item(item, dimension);
return item.add_margin_box_sizes(preferred_size.to_px(grid_container(), containing_block_size), dimension, m_state);
}
CSSPixels GridFormattingContext::calculate_max_content_contribution(GridItem const& item, GridDimension const dimension) const
{
auto available_space_for_item = get_available_space_for_item(item);
auto should_treat_preferred_size_as_auto = [&] {
if (dimension == GridDimension::Column)
return should_treat_width_as_auto(item.box, available_space_for_item);
return should_treat_height_as_auto(item.box, available_space_for_item);
}();
if (should_treat_preferred_size_as_auto) {
return item.add_margin_box_sizes(calculate_max_content_size(item, dimension), dimension, m_state);
}
auto preferred_size = get_item_preferred_size(item, dimension);
auto containing_block_size = containing_block_size_for_item(item, dimension);
return item.add_margin_box_sizes(preferred_size.to_px(grid_container(), containing_block_size), dimension, m_state);
}
CSSPixels GridFormattingContext::calculate_limited_min_content_contribution(GridItem const& item, GridDimension const dimension) const
{
// The limited min-content contribution of an item is its min-content contribution,
// limited by the max track sizing function (which could be the argument to a fit-content() track
// sizing function) if that is fixed and ultimately floored by its minimum contribution.
// FIXME: limit by max track sizing function
auto min_content_contribution = calculate_min_content_contribution(item, dimension);
auto minimum_contribution = calculate_minimum_contribution(item, dimension);
if (min_content_contribution < minimum_contribution)
return minimum_contribution;
return min_content_contribution;
}
CSSPixels GridFormattingContext::calculate_limited_max_content_contribution(GridItem const& item, GridDimension const dimension) const
{
// The limited max-content contribution of an item is its max-content contribution,
// limited by the max track sizing function (which could be the argument to a fit-content() track
// sizing function) if that is fixed and ultimately floored by its minimum contribution.
// FIXME: limit by max track sizing function
auto max_content_contribution = calculate_max_content_contribution(item, dimension);
auto minimum_contribution = calculate_minimum_contribution(item, dimension);
if (max_content_contribution < minimum_contribution)
return minimum_contribution;
return max_content_contribution;
}
CSS::Size const& GridFormattingContext::get_item_minimum_size(GridItem const& item, GridDimension const dimension) const
{
if (dimension == GridDimension::Column)
return item.box->computed_values().min_width();
return item.box->computed_values().min_height();
}
CSSPixels GridFormattingContext::content_size_suggestion(GridItem const& item, GridDimension const dimension) const
{
// The content size suggestion is the min-content size in the relevant axis
// FIXME: clamped, if it has a preferred aspect ratio, by any definite opposite-axis minimum and maximum sizes
// converted through the aspect ratio.
return calculate_min_content_size(item, dimension);
}
Optional<CSSPixels> GridFormattingContext::specified_size_suggestion(GridItem const& item, GridDimension const dimension) const
{
// https://www.w3.org/TR/css-grid-1/#specified-size-suggestion
// If the items preferred size in the relevant axis is definite, then the specified size suggestion is that size.
// It is otherwise undefined.
auto const& used_values = m_state.get(item.box);
auto has_definite_preferred_size = dimension == GridDimension::Column ? used_values.has_definite_width() : used_values.has_definite_height();
if (has_definite_preferred_size) {
// FIXME: consider margins, padding and borders because it is outer size.
auto containing_block_size = containing_block_size_for_item(item, dimension);
return get_item_preferred_size(item, dimension).to_px(item.box, containing_block_size);
}
return {};
}
CSSPixels GridFormattingContext::content_based_minimum_size(GridItem const& item, GridDimension const dimension) const
{
// https://www.w3.org/TR/css-grid-1/#content-based-minimum-size
// The content-based minimum size for a grid item in a given dimension is its specified size suggestion if it exists
if (auto specified_size_suggestion = this->specified_size_suggestion(item, dimension); specified_size_suggestion.has_value()) {
return specified_size_suggestion.value();
}
// FIXME: otherwise its transferred size suggestion if that exists
// else its content size suggestion
return content_size_suggestion(item, dimension);
}
CSSPixels GridFormattingContext::automatic_minimum_size(GridItem const& item, GridDimension const dimension) const
{
// To provide a more reasonable default minimum size for grid items, the used value of its automatic minimum size
// in a given axis is the content-based minimum size if all of the following are true:
// - it is not a scroll container
// - it spans at least one track in that axis whose min track sizing function is auto
// FIXME: - if it spans more than one track in that axis, none of those tracks are flexible
auto const& tracks = dimension == GridDimension::Column ? m_grid_columns : m_grid_rows;
auto item_track_index = item.raw_position(dimension);
// FIXME: Check all tracks spanned by an item
AvailableSize const& available_size = dimension == GridDimension::Column ? m_available_space->width : m_available_space->height;
auto item_spans_auto_tracks = tracks[item_track_index].min_track_sizing_function.is_auto(available_size);
if (item_spans_auto_tracks && !item.box->is_scroll_container()) {
return content_based_minimum_size(item, dimension);
}
// Otherwise, the automatic minimum size is zero, as usual.
return 0;
}
CSSPixels GridFormattingContext::calculate_minimum_contribution(GridItem const& item, GridDimension const dimension) const
{
// The minimum contribution of an item is the smallest outer size it can have.
// Specifically, if the items computed preferred size behaves as auto or depends on the size of its
// containing block in the relevant axis, its minimum contribution is the outer size that would
// result from assuming the items used minimum size as its preferred size; else the items minimum
// contribution is its min-content contribution. Because the minimum contribution often depends on
// the size of the items content, it is considered a type of intrinsic size contribution.
auto preferred_size = get_item_preferred_size(item, dimension);
auto should_treat_preferred_size_as_auto = [&] {
if (dimension == GridDimension::Column)
return should_treat_width_as_auto(item.box, get_available_space_for_item(item));
return should_treat_height_as_auto(item.box, get_available_space_for_item(item));
}();
if (should_treat_preferred_size_as_auto) {
auto minimum_size = get_item_minimum_size(item, dimension);
if (minimum_size.is_auto())
return item.add_margin_box_sizes(automatic_minimum_size(item, dimension), dimension, m_state);
auto containing_block_size = containing_block_size_for_item(item, dimension);
return item.add_margin_box_sizes(minimum_size.to_px(grid_container(), containing_block_size), dimension, m_state);
}
return calculate_min_content_contribution(item, dimension);
}
}
namespace AK {
template<>
struct Traits<Web::Layout::GridPosition> : public GenericTraits<Web::Layout::GridPosition> {
static unsigned hash(Web::Layout::GridPosition const& key) { return pair_int_hash(key.row, key.column); }
};
}
Reference in a new issue View git blame Copy permalink