ladybird/Userland/Libraries/LibWeb/Layout/FlexFormattingContext.h
Andreas Kling c8240e31a1 LibWeb: Implement basic intrinsic sizing algorithms for flex containers
This patch adds support for MinContent and MaxContent layout to FFC.
This means that an FFC can now calculate intrinsic sizes for the flex
container, to be used by the parent formatting context.

There are some FIXME's as usual, but this already works on basic things.
2022-04-06 11:31:08 +02:00

147 lines
5.7 KiB
C++

/*
* Copyright (c) 2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include <LibWeb/Layout/Box.h>
#include <LibWeb/Layout/FormattingContext.h>
namespace Web::Layout {
class FlexFormattingContext final : public FormattingContext {
public:
FlexFormattingContext(FormattingState&, Box const& flex_container, FormattingContext* parent);
~FlexFormattingContext();
virtual bool inhibits_floating() const override { return true; }
virtual void run(Box const&, LayoutMode) override;
Box const& flex_container() const { return context_box(); }
private:
void dump_items() const;
struct DirectionAgnosticMargins {
float main_before { 0 };
float main_after { 0 };
float cross_before { 0 };
float cross_after { 0 };
};
struct FlexItem {
Box& box;
float flex_base_size { 0 };
float hypothetical_main_size { 0 };
float hypothetical_cross_size { 0 };
float hypothetical_cross_size_with_margins() { return hypothetical_cross_size + margins.cross_before + margins.cross_after + borders.cross_after + borders.cross_before + padding.cross_after + padding.cross_before; }
float target_main_size { 0 };
bool frozen { false };
Optional<float> flex_factor {};
float scaled_flex_shrink_factor { 0 };
float max_content_flex_fraction { 0 };
float main_size { 0 };
float cross_size { 0 };
float main_offset { 0 };
float cross_offset { 0 };
DirectionAgnosticMargins margins {};
DirectionAgnosticMargins borders {};
DirectionAgnosticMargins padding {};
bool is_min_violation { false };
bool is_max_violation { false };
};
struct FlexLine {
Vector<FlexItem*> items;
float cross_size { 0 };
};
bool has_definite_main_size(Box const&) const;
bool has_definite_cross_size(Box const&) const;
float specified_main_size(Box const&) const;
float specified_cross_size(Box const&) const;
float resolved_definite_main_size(Box const&) const;
float resolved_definite_cross_size(Box const&) const;
bool has_main_min_size(Box const&) const;
bool has_cross_min_size(Box const&) const;
float specified_main_max_size(Box const&) const;
float specified_cross_max_size(Box const&) const;
float calculated_main_size(Box const&) const;
bool is_cross_auto(Box const&) const;
bool is_main_axis_margin_first_auto(Box const&) const;
bool is_main_axis_margin_second_auto(Box const&) const;
float specified_main_size_of_child_box(Box const& child_box) const;
float specified_main_min_size(Box const&) const;
float specified_cross_min_size(Box const&) const;
bool has_main_max_size(Box const&) const;
bool has_cross_max_size(Box const&) const;
float sum_of_margin_padding_border_in_main_axis(Box const&) const;
float determine_min_main_size_of_child(Box const& box);
void set_main_size(Box const&, float size);
void set_cross_size(Box const&, float size);
void set_offset(Box const&, float main_offset, float cross_offset);
void set_main_axis_first_margin(Box const&, float margin);
void set_main_axis_second_margin(Box const&, float margin);
void copy_dimensions_from_flex_items_to_boxes();
void generate_anonymous_flex_items();
void determine_available_main_and_cross_space(bool& main_is_constrained, bool& cross_is_constrained, float& main_min_size, float& main_max_size, float& cross_min_size, float& cross_max_size);
float calculate_indefinite_main_size(FlexItem const&);
void determine_flex_base_size_and_hypothetical_main_size(FlexItem&);
void determine_main_size_of_flex_container(bool main_is_constrained, float main_min_size, float main_max_size);
void collect_flex_items_into_flex_lines();
void resolve_flexible_lengths();
void determine_hypothetical_cross_size_of_item(FlexItem&);
void calculate_cross_size_of_each_flex_line(float cross_min_size, float cross_max_size);
void determine_used_cross_size_of_each_flex_item();
void distribute_any_remaining_free_space();
void align_all_flex_items_along_the_cross_axis();
void determine_flex_container_used_cross_size(float cross_min_size, float cross_max_size);
void align_all_flex_lines();
bool is_row_layout() const { return m_flex_direction == CSS::FlexDirection::Row || m_flex_direction == CSS::FlexDirection::RowReverse; }
bool is_single_line() const { return flex_container().computed_values().flex_wrap() == CSS::FlexWrap::Nowrap; }
bool is_direction_reverse() const { return m_flex_direction == CSS::FlexDirection::ColumnReverse || m_flex_direction == CSS::FlexDirection::RowReverse; }
void populate_specified_margins(FlexItem&, CSS::FlexDirection) const;
void determine_intrinsic_size_of_flex_container(LayoutMode);
[[nodiscard]] float calculate_intrinsic_main_size_of_flex_container(LayoutMode);
[[nodiscard]] float calculate_intrinsic_cross_size_of_flex_container(LayoutMode);
[[nodiscard]] float calculate_cross_min_content_contribution(FlexItem const&) const;
[[nodiscard]] float calculate_cross_max_content_contribution(FlexItem const&) const;
[[nodiscard]] float calculate_main_min_content_contribution(FlexItem const&) const;
[[nodiscard]] float calculate_main_max_content_contribution(FlexItem const&) const;
FormattingState::NodeState& m_flex_container_state;
Vector<FlexLine> m_flex_lines;
Vector<FlexItem> m_flex_items;
CSS::FlexDirection m_flex_direction {};
struct AvailableSpace {
Optional<float> main;
Optional<float> cross;
};
Optional<AvailableSpace> m_available_space;
};
}