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servo/components/layout/construct.rs
Patrick Walton 287fe3b3ab layout: Implement the correct hypothetical box behavior for 
absolutely-positioned elements declared with `display: inline`.

Although the computed `display` property of elements with `position:
absolute` is `block`, `position: absolute; display: inline` can still
behave differently from `position: absolute; display: block`. This is
because the hypothetical box for `position: absolute` can be at the
position it would have been if it had `display: inline`. CSS 2.1 §
10.3.7 describes this case in a parenthetical:

"The static-position containing block is the containing block of a
hypothetical box that would have been the first box of the element if
its specified 'position' value had been 'static' and its specified
'float' had been 'none'. (Note that due to the rules in section 9.7 this
hypothetical calculation might require also assuming a different
computed value for 'display'.)"

To handle this, I had to change both style computation and layout. For
the former, I added an internal property
`-servo-display-for-hypothetical-box`, which stores the `display` value
supplied by the author, before the computed value is calculated. Flow
construction now uses this value.

As for layout, implementing the proper behavior is tricky because the
position of an inline fragment in the inline direction cannot be
determined until height assignment, which is a parallelism hazard
because in parallel layout widths are computed before heights. However,
in this particular case we can avoid the parallelism hazard because the
inline direction of a hypothetical box only affects the layout if an
absolutely-positioned element is unconstrained in the inline direction.
Therefore, we can just lay out such absolutely-positioned elements with
a bogus inline position and fix it up once the true inline position of
the hypothetical box is computed. The name for this fix-up process is
"late computation of inline position" (and the corresponding fix-up for
the block position is called "late computation of block position").

This improves the header on /r/rust.
2014-10-01 18:34:53 -07:00

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
//! Creates flows and fragments from a DOM tree via a bottom-up, incremental traversal of the DOM.
//!
//! Each step of the traversal considers the node and existing flow, if there is one. If a node is
//! not dirty and an existing flow exists, then the traversal reuses that flow. Otherwise, it
//! proceeds to construct either a flow or a `ConstructionItem`. A construction item is a piece of
//! intermediate data that goes with a DOM node and hasn't found its "home" yet-maybe it's a box,
//! maybe it's an absolute or fixed position thing that hasn't found its containing block yet.
//! Construction items bubble up the tree from children to parents until they find their homes.
//!
//! TODO(pcwalton): There is no incremental reflow yet. This scheme requires that nodes either have
//! weak references to flows or that there be some mechanism to efficiently (O(1) time) "blow
//! apart" a flow tree and have the flows migrate "home" to their respective DOM nodes while we
//! perform flow tree construction. The precise mechanism for this will take some experimentation
//! to get right.
#![deny(unsafe_block)]
use css::node_style::StyledNode;
use block::BlockFlow;
use context::LayoutContext;
use floats::FloatKind;
use flow::{Flow, ImmutableFlowUtils, MutableOwnedFlowUtils};
use flow::{Descendants, AbsDescendants};
use flow;
use flow_ref::FlowRef;
use fragment::{Fragment, GenericFragment, IframeFragment, IframeFragmentInfo, ImageFragment};
use fragment::{ImageFragmentInfo, InlineAbsoluteHypotheticalFragment};
use fragment::{InlineAbsoluteHypotheticalFragmentInfo, InlineBlockFragment};
use fragment::{InlineBlockFragmentInfo, InputFragment, InputFragmentInfo, SpecificFragmentInfo};
use fragment::{TableCellFragment, TableColumnFragment, TableColumnFragmentInfo, TableFragment};
use fragment::{TableRowFragment, TableWrapperFragment, UnscannedTextFragment};
use fragment::{UnscannedTextFragmentInfo};
use inline::{InlineFragments, InlineFlow};
use parallel;
use table_wrapper::TableWrapperFlow;
use table::TableFlow;
use table_caption::TableCaptionFlow;
use table_colgroup::TableColGroupFlow;
use table_rowgroup::TableRowGroupFlow;
use table_row::TableRowFlow;
use table_cell::TableCellFlow;
use text::TextRunScanner;
use util::{LayoutDataAccess, OpaqueNodeMethods};
use wrapper::{PostorderNodeMutTraversal, TLayoutNode, ThreadSafeLayoutNode};
use wrapper::{Before, After, Normal};
use gfx::display_list::OpaqueNode;
use script::dom::element::{HTMLIFrameElementTypeId, HTMLImageElementTypeId};
use script::dom::element::{HTMLObjectElementTypeId, HTMLInputElementTypeId};
use script::dom::element::{HTMLTableColElementTypeId, HTMLTableDataCellElementTypeId};
use script::dom::element::{HTMLTableElementTypeId, HTMLTableHeaderCellElementTypeId};
use script::dom::element::{HTMLTableRowElementTypeId, HTMLTableSectionElementTypeId};
use script::dom::node::{CommentNodeTypeId, DoctypeNodeTypeId, DocumentFragmentNodeTypeId};
use script::dom::node::{DocumentNodeTypeId, ElementNodeTypeId, ProcessingInstructionNodeTypeId};
use script::dom::node::{TextNodeTypeId};
use script::dom::htmlobjectelement::is_image_data;
use std::mem;
use std::sync::atomics::Relaxed;
use style::ComputedValues;
use style::computed_values::{display, position, float};
use sync::Arc;
use url::Url;
/// The results of flow construction for a DOM node.
pub enum ConstructionResult {
/// This node contributes nothing at all (`display: none`). Alternately, this is what newly
/// created nodes have their `ConstructionResult` set to.
NoConstructionResult,
/// This node contributed a flow at the proper position in the tree.
/// Nothing more needs to be done for this node. It has bubbled up fixed
/// and absolute descendant flows that have a containing block above it.
FlowConstructionResult(FlowRef, AbsDescendants),
/// This node contributed some object or objects that will be needed to construct a proper flow
/// later up the tree, but these objects have not yet found their home.
ConstructionItemConstructionResult(ConstructionItem),
}
/// Represents the output of flow construction for a DOM node that has not yet resulted in a
/// complete flow. Construction items bubble up the tree until they find a `Flow` to be attached
/// to.
pub enum ConstructionItem {
/// Inline fragments and associated {ib} splits that have not yet found flows.
InlineFragmentsConstructionItem(InlineFragmentsConstructionResult),
/// Potentially ignorable whitespace.
WhitespaceConstructionItem(OpaqueNode, Arc<ComputedValues>),
/// TableColumn Fragment
TableColumnFragmentConstructionItem(Fragment),
}
/// Represents inline fragments and {ib} splits that are bubbling up from an inline.
pub struct InlineFragmentsConstructionResult {
/// Any {ib} splits that we're bubbling up.
pub splits: Vec<InlineBlockSplit>,
/// Any fragments that succeed the {ib} splits.
pub fragments: InlineFragments,
/// Any absolute descendants that we're bubbling up.
pub abs_descendants: AbsDescendants,
}
/// Represents an {ib} split that has not yet found the containing block that it belongs to. This
/// is somewhat tricky. An example may be helpful. For this DOM fragment:
///
/// ```html
/// <span>
/// A
/// <div>B</div>
/// C
/// </span>
/// ```
///
/// The resulting `ConstructionItem` for the outer `span` will be:
///
/// ```ignore
/// InlineFragmentsConstructionItem(Some(~[
/// InlineBlockSplit {
/// predecessor_fragments: ~[
/// A
/// ],
/// block: ~BlockFlow {
/// B
/// },
/// }),~[
/// C
/// ])
/// ```
pub struct InlineBlockSplit {
/// The inline fragments that precede the flow.
pub predecessors: InlineFragments,
/// The flow that caused this {ib} split.
pub flow: FlowRef,
}
/// Holds inline fragments that we're gathering for children of an inline node.
struct InlineFragmentsAccumulator {
/// The list of fragments.
fragments: InlineFragments,
/// Whether we've created a range to enclose all the fragments. This will be Some() if the outer node
/// is an inline and None otherwise.
enclosing_style: Option<Arc<ComputedValues>>,
}
impl InlineFragmentsAccumulator {
fn new() -> InlineFragmentsAccumulator {
InlineFragmentsAccumulator {
fragments: InlineFragments::new(),
enclosing_style: None,
}
}
fn from_inline_node(node: &ThreadSafeLayoutNode) -> InlineFragmentsAccumulator {
let fragments = InlineFragments::new();
InlineFragmentsAccumulator {
fragments: fragments,
enclosing_style: Some(node.style().clone()),
}
}
fn finish(self) -> InlineFragments {
let InlineFragmentsAccumulator {
fragments: mut fragments,
enclosing_style
} = self;
match enclosing_style {
Some(enclosing_style) => {
for frag in fragments.fragments.iter_mut() {
frag.add_inline_context_style(enclosing_style.clone());
}
}
None => {}
}
fragments
}
}
enum WhitespaceStrippingMode {
NoWhitespaceStripping,
StripWhitespaceFromStart,
StripWhitespaceFromEnd,
}
/// An object that knows how to create flows.
pub struct FlowConstructor<'a> {
/// The layout context.
pub layout_context: &'a LayoutContext<'a>,
}
impl<'a> FlowConstructor<'a> {
/// Creates a new flow constructor.
pub fn new<'a>(layout_context: &'a LayoutContext<'a>)
-> FlowConstructor<'a> {
FlowConstructor {
layout_context: layout_context,
}
}
/// Builds the `ImageFragmentInfo` for the given image. This is out of line to guide inlining.
fn build_fragment_info_for_image(&mut self, node: &ThreadSafeLayoutNode, url: Option<Url>)
-> SpecificFragmentInfo {
match url {
None => GenericFragment,
Some(url) => {
// FIXME(pcwalton): The fact that image fragments store the cache within them makes
// little sense to me.
ImageFragment(ImageFragmentInfo::new(node,
url,
self.layout_context
.shared
.image_cache
.clone()))
}
}
}
fn build_fragment_info_for_input(&mut self, node: &ThreadSafeLayoutNode) -> SpecificFragmentInfo {
//FIXME: would it make more sense to use HTMLInputElement::input_type instead of the raw
// value? definitely for string comparisons.
let elem = node.as_element();
let data = match elem.get_attr(&ns!(""), "type") {
Some("checkbox") | Some("radio") => None,
Some("button") | Some("submit") | Some("reset") =>
Some(node.get_input_value().len() as u32),
Some("file") => Some(node.get_input_size()),
_ => Some(node.get_input_size()),
};
data.map(|size| InputFragment(InputFragmentInfo { size: size }))
.unwrap_or(GenericFragment)
}
/// Builds specific `Fragment` info for the given node.
///
/// This does *not* construct the text for generated content (but, for generated content with
/// `display: block`, it does construct the generic fragment corresponding to the block).
/// Construction of the text fragment is done specially by `build_flow_using_children()` and
/// `build_fragments_for_replaced_inline_content()`.
pub fn build_specific_fragment_info_for_node(&mut self, node: &ThreadSafeLayoutNode)
-> SpecificFragmentInfo {
match node.type_id() {
Some(ElementNodeTypeId(HTMLIFrameElementTypeId)) => {
IframeFragment(IframeFragmentInfo::new(node))
}
Some(ElementNodeTypeId(HTMLImageElementTypeId)) => {
self.build_fragment_info_for_image(node, node.image_url())
}
Some(ElementNodeTypeId(HTMLInputElementTypeId)) => {
self.build_fragment_info_for_input(node)
}
Some(ElementNodeTypeId(HTMLObjectElementTypeId)) => {
let data = node.get_object_data();
self.build_fragment_info_for_image(node, data)
}
Some(ElementNodeTypeId(HTMLTableElementTypeId)) => TableWrapperFragment,
Some(ElementNodeTypeId(HTMLTableColElementTypeId)) => {
TableColumnFragment(TableColumnFragmentInfo::new(node))
}
Some(ElementNodeTypeId(HTMLTableDataCellElementTypeId)) |
Some(ElementNodeTypeId(HTMLTableHeaderCellElementTypeId)) => TableCellFragment,
Some(ElementNodeTypeId(HTMLTableRowElementTypeId)) |
Some(ElementNodeTypeId(HTMLTableSectionElementTypeId)) => TableRowFragment,
Some(TextNodeTypeId) => UnscannedTextFragment(UnscannedTextFragmentInfo::new(node)),
_ => {
// This includes pseudo-elements.
GenericFragment
}
}
}
/// Creates an inline flow from a set of inline fragments, then adds it as a child of the given
/// flow or pushes it onto the given flow list.
///
/// `#[inline(always)]` because this is performance critical and LLVM will not inline it
/// otherwise.
#[inline(always)]
fn flush_inline_fragments_to_flow_or_list(&mut self,
fragment_accumulator: InlineFragmentsAccumulator,
flow: &mut FlowRef,
flow_list: &mut Vec<FlowRef>,
whitespace_stripping: WhitespaceStrippingMode,
node: &ThreadSafeLayoutNode) {
let mut fragments = fragment_accumulator.finish();
if fragments.is_empty() {
return
};
match whitespace_stripping {
NoWhitespaceStripping => {}
StripWhitespaceFromStart => {
fragments.strip_ignorable_whitespace_from_start();
if fragments.is_empty() {
return
};
}
StripWhitespaceFromEnd => {
fragments.strip_ignorable_whitespace_from_end();
if fragments.is_empty() {
return
};
}
}
// Build a list of all the inline-block fragments before fragments is moved.
let mut inline_block_flows = vec!();
for f in fragments.fragments.iter() {
match f.specific {
InlineBlockFragment(ref info) => inline_block_flows.push(info.flow_ref.clone()),
InlineAbsoluteHypotheticalFragment(ref info) => {
inline_block_flows.push(info.flow_ref.clone())
}
_ => {}
}
}
let mut inline_flow_ref = FlowRef::new(box InlineFlow::from_fragments((*node).clone(),
fragments));
// Add all the inline-block fragments as children of the inline flow.
for inline_block_flow in inline_block_flows.iter() {
inline_flow_ref.add_new_child(inline_block_flow.clone());
}
{
let inline_flow = inline_flow_ref.get_mut().as_inline();
let (ascent, descent) =
inline_flow.compute_minimum_ascent_and_descent(self.layout_context.font_context(),
&**node.style());
inline_flow.minimum_block_size_above_baseline = ascent;
inline_flow.minimum_depth_below_baseline = descent;
TextRunScanner::new().scan_for_runs(self.layout_context.font_context(), inline_flow);
}
inline_flow_ref.finish(self.layout_context);
if flow.get().need_anonymous_flow(inline_flow_ref.get()) {
flow_list.push(inline_flow_ref)
} else {
flow.add_new_child(inline_flow_ref)
}
}
fn build_block_flow_using_construction_result_of_child(&mut self,
flow: &mut FlowRef,
consecutive_siblings: &mut Vec<FlowRef>,
node: &ThreadSafeLayoutNode,
kid: ThreadSafeLayoutNode,
inline_fragment_accumulator:
&mut InlineFragmentsAccumulator,
abs_descendants: &mut Descendants,
first_fragment: &mut bool) {
match kid.swap_out_construction_result() {
NoConstructionResult => {}
FlowConstructionResult(kid_flow, kid_abs_descendants) => {
// If kid_flow is TableCaptionFlow, kid_flow should be added under
// TableWrapperFlow.
if flow.get().is_table() && kid_flow.get().is_table_caption() {
kid.set_flow_construction_result(FlowConstructionResult(kid_flow,
Descendants::new()))
} else if flow.get().need_anonymous_flow(kid_flow.get()) {
consecutive_siblings.push(kid_flow)
} else {
// Flush any inline fragments that we were gathering up. This allows us to
// handle {ib} splits.
debug!("flushing {} inline box(es) to flow A",
inline_fragment_accumulator.fragments.len());
self.flush_inline_fragments_to_flow_or_list(
mem::replace(inline_fragment_accumulator,
InlineFragmentsAccumulator::new()),
flow,
consecutive_siblings,
StripWhitespaceFromStart,
node);
if !consecutive_siblings.is_empty() {
let consecutive_siblings = mem::replace(consecutive_siblings, vec!());
self.generate_anonymous_missing_child(consecutive_siblings, flow, node);
}
flow.add_new_child(kid_flow);
}
abs_descendants.push_descendants(kid_abs_descendants);
}
ConstructionItemConstructionResult(InlineFragmentsConstructionItem(
InlineFragmentsConstructionResult {
splits: splits,
fragments: successor_fragments,
abs_descendants: kid_abs_descendants,
})) => {
// Add any {ib} splits.
for split in splits.into_iter() {
// Pull apart the {ib} split object and push its predecessor fragments
// onto the list.
let InlineBlockSplit {
predecessors: predecessors,
flow: kid_flow
} = split;
inline_fragment_accumulator.fragments.push_all(predecessors);
// If this is the first fragment in flow, then strip ignorable
// whitespace per CSS 2.1 § 9.2.1.1.
let whitespace_stripping = if *first_fragment {
*first_fragment = false;
StripWhitespaceFromStart
} else {
NoWhitespaceStripping
};
// Flush any inline fragments that we were gathering up.
debug!("flushing {} inline box(es) to flow A",
inline_fragment_accumulator.fragments.len());
self.flush_inline_fragments_to_flow_or_list(
mem::replace(inline_fragment_accumulator,
InlineFragmentsAccumulator::new()),
flow,
consecutive_siblings,
whitespace_stripping,
node);
// Push the flow generated by the {ib} split onto our list of
// flows.
if flow.get().need_anonymous_flow(kid_flow.get()) {
consecutive_siblings.push(kid_flow)
} else {
flow.add_new_child(kid_flow)
}
}
// Add the fragments to the list we're maintaining.
inline_fragment_accumulator.fragments.push_all(successor_fragments);
abs_descendants.push_descendants(kid_abs_descendants);
}
ConstructionItemConstructionResult(WhitespaceConstructionItem(whitespace_node,
whitespace_style)) => {
// Add whitespace results. They will be stripped out later on when
// between block elements, and retained when between inline elements.
let fragment_info =
UnscannedTextFragment(UnscannedTextFragmentInfo::from_text(" ".to_string()));
let mut fragment = Fragment::from_opaque_node_and_style(whitespace_node,
whitespace_style,
fragment_info);
inline_fragment_accumulator.fragments.push(&mut fragment);
}
ConstructionItemConstructionResult(TableColumnFragmentConstructionItem(_)) => {
// TODO: Implement anonymous table objects for missing parents
// CSS 2.1 § 17.2.1, step 3-2
}
}
}
/// Build block flow for current node using information from children nodes.
///
/// Consume results from children and combine them, handling {ib} splits.
/// Block flows and inline flows thus created will become the children of
/// this block flow.
/// Also, deal with the absolute and fixed descendants bubbled up by
/// children nodes.
fn build_flow_for_block(&mut self, mut flow: FlowRef, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
// Gather up fragments for the inline flows we might need to create.
let mut inline_fragment_accumulator = InlineFragmentsAccumulator::new();
let mut consecutive_siblings = vec!();
let mut first_fragment = true;
// Special case: If this is generated content, then we need to initialize the accumulator
// with the fragment corresponding to that content.
if node.get_pseudo_element_type() != Normal ||
node.type_id() == Some(ElementNodeTypeId(HTMLInputElementTypeId)) {
let fragment_info = UnscannedTextFragment(UnscannedTextFragmentInfo::new(node));
let mut fragment = Fragment::new_from_specific_info(node, fragment_info);
inline_fragment_accumulator.fragments.push(&mut fragment);
first_fragment = false;
}
// List of absolute descendants, in tree order.
let mut abs_descendants = Descendants::new();
for kid in node.children() {
if kid.get_pseudo_element_type() != Normal {
self.process(&kid);
}
self.build_block_flow_using_construction_result_of_child(
&mut flow,
&mut consecutive_siblings,
node,
kid,
&mut inline_fragment_accumulator,
&mut abs_descendants,
&mut first_fragment);
}
// Perform a final flush of any inline fragments that we were gathering up to handle {ib}
// splits, after stripping ignorable whitespace.
self.flush_inline_fragments_to_flow_or_list(inline_fragment_accumulator,
&mut flow,
&mut consecutive_siblings,
StripWhitespaceFromEnd,
node);
if !consecutive_siblings.is_empty() {
self.generate_anonymous_missing_child(consecutive_siblings, &mut flow, node);
}
// The flow is done.
flow.finish(self.layout_context);
// Set up the absolute descendants.
let is_positioned = flow.get_mut().as_block().is_positioned();
let is_absolutely_positioned = flow.get_mut().as_block().is_absolutely_positioned();
if is_positioned {
// This is the containing block for all the absolute descendants.
flow.set_absolute_descendants(abs_descendants);
abs_descendants = Descendants::new();
if is_absolutely_positioned {
// This is now the only absolute flow in the subtree which hasn't yet
// reached its CB.
abs_descendants.push(flow.clone());
}
}
FlowConstructionResult(flow, abs_descendants)
}
/// Builds a flow for a node with `display: block`. This yields a `BlockFlow` with possibly
/// other `BlockFlow`s or `InlineFlow`s underneath it, depending on whether {ib} splits needed
/// to happen.
fn build_flow_for_nonfloated_block(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
let flow = box BlockFlow::from_node(self, node) as Box<Flow>;
self.build_flow_for_block(FlowRef::new(flow), node)
}
/// Builds the flow for a node with `float: {left|right}`. This yields a float `BlockFlow` with
/// a `BlockFlow` underneath it.
fn build_flow_for_floated_block(&mut self, node: &ThreadSafeLayoutNode, float_kind: FloatKind)
-> ConstructionResult {
let flow = box BlockFlow::float_from_node(self, node, float_kind) as Box<Flow>;
self.build_flow_for_block(FlowRef::new(flow), node)
}
/// Concatenates the fragments of kids, adding in our own borders/padding/margins if necessary.
/// Returns the `InlineFragmentsConstructionResult`, if any. There will be no
/// `InlineFragmentsConstructionResult` if this node consisted entirely of ignorable
/// whitespace.
fn build_fragments_for_nonreplaced_inline_content(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
let mut opt_inline_block_splits: Vec<InlineBlockSplit> = Vec::new();
let mut fragment_accumulator = InlineFragmentsAccumulator::from_inline_node(node);
let mut abs_descendants = Descendants::new();
// Concatenate all the fragments of our kids, creating {ib} splits as necessary.
for kid in node.children() {
if kid.get_pseudo_element_type() != Normal {
self.process(&kid);
}
match kid.swap_out_construction_result() {
NoConstructionResult => {}
FlowConstructionResult(flow, kid_abs_descendants) => {
// {ib} split. Flush the accumulator to our new split and make a new
// accumulator to hold any subsequent fragments we come across.
let split = InlineBlockSplit {
predecessors:
mem::replace(
&mut fragment_accumulator,
InlineFragmentsAccumulator::from_inline_node(node)).finish(),
flow: flow,
};
opt_inline_block_splits.push(split);
abs_descendants.push_descendants(kid_abs_descendants);
}
ConstructionItemConstructionResult(InlineFragmentsConstructionItem(
InlineFragmentsConstructionResult {
splits: splits,
fragments: successors,
abs_descendants: kid_abs_descendants,
})) => {
// Bubble up {ib} splits.
for split in splits.into_iter() {
let InlineBlockSplit {
predecessors: predecessors,
flow: kid_flow
} = split;
fragment_accumulator.fragments.push_all(predecessors);
let split = InlineBlockSplit {
predecessors:
mem::replace(&mut fragment_accumulator,
InlineFragmentsAccumulator::from_inline_node(node))
.finish(),
flow: kid_flow,
};
opt_inline_block_splits.push(split)
}
// Push residual fragments.
fragment_accumulator.fragments.push_all(successors);
abs_descendants.push_descendants(kid_abs_descendants);
}
ConstructionItemConstructionResult(WhitespaceConstructionItem(whitespace_node,
whitespace_style))
=> {
// Instantiate the whitespace fragment.
let fragment_info = UnscannedTextFragment(UnscannedTextFragmentInfo::from_text(" ".to_string()));
let mut fragment = Fragment::from_opaque_node_and_style(whitespace_node,
whitespace_style,
fragment_info);
fragment_accumulator.fragments.push(&mut fragment)
}
ConstructionItemConstructionResult(TableColumnFragmentConstructionItem(_)) => {
// TODO: Implement anonymous table objects for missing parents
// CSS 2.1 § 17.2.1, step 3-2
}
}
}
// Finally, make a new construction result.
if opt_inline_block_splits.len() > 0 || fragment_accumulator.fragments.len() > 0
|| abs_descendants.len() > 0 {
let construction_item = InlineFragmentsConstructionItem(
InlineFragmentsConstructionResult {
splits: opt_inline_block_splits,
fragments: fragment_accumulator.finish(),
abs_descendants: abs_descendants,
});
ConstructionItemConstructionResult(construction_item)
} else {
NoConstructionResult
}
}
/// Creates an `InlineFragmentsConstructionResult` for replaced content. Replaced content
/// doesn't render its children, so this just nukes a child's fragments and creates a
/// `Fragment`.
fn build_fragments_for_replaced_inline_content(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
for kid in node.children() {
kid.set_flow_construction_result(NoConstructionResult)
}
// If this node is ignorable whitespace, bail out now.
//
// FIXME(#2001, pcwalton): Don't do this if there's padding or borders.
if node.is_ignorable_whitespace() {
let opaque_node = OpaqueNodeMethods::from_thread_safe_layout_node(node);
return ConstructionItemConstructionResult(WhitespaceConstructionItem(
opaque_node,
node.style().clone()))
}
// If this is generated content, then we need to initialize the accumulator with the
// fragment corresponding to that content. Otherwise, just initialize with the ordinary
// fragment that needs to be generated for this inline node.
let mut fragment = if node.get_pseudo_element_type() != Normal {
let fragment_info = UnscannedTextFragment(UnscannedTextFragmentInfo::new(node));
Fragment::new_from_specific_info(node, fragment_info)
} else {
Fragment::new(self, node)
};
let mut fragments = InlineFragments::new();
fragments.push(&mut fragment);
let construction_item = InlineFragmentsConstructionItem(InlineFragmentsConstructionResult {
splits: Vec::new(),
fragments: fragments,
abs_descendants: Descendants::new(),
});
ConstructionItemConstructionResult(construction_item)
}
fn build_fragment_for_inline_block(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
let block_flow_result = self.build_flow_for_nonfloated_block(node);
let (block_flow, abs_descendants) = match block_flow_result {
FlowConstructionResult(block_flow, abs_descendants) => (block_flow, abs_descendants),
_ => unreachable!()
};
let fragment_info = InlineBlockFragment(InlineBlockFragmentInfo::new(block_flow));
let mut fragment = Fragment::new_from_specific_info(node, fragment_info);
let mut fragment_accumulator = InlineFragmentsAccumulator::from_inline_node(node);
fragment_accumulator.fragments.push(&mut fragment);
let construction_item = InlineFragmentsConstructionItem(InlineFragmentsConstructionResult {
splits: Vec::new(),
fragments: fragment_accumulator.finish(),
abs_descendants: abs_descendants,
});
ConstructionItemConstructionResult(construction_item)
}
/// This is an annoying case, because the computed `display` value is `block`, but the
/// hypothetical box is inline.
fn build_fragment_for_absolutely_positioned_inline(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
let block_flow_result = self.build_flow_for_nonfloated_block(node);
let (block_flow, abs_descendants) = match block_flow_result {
FlowConstructionResult(block_flow, abs_descendants) => (block_flow, abs_descendants),
_ => unreachable!()
};
let fragment_info = InlineAbsoluteHypotheticalFragment(
InlineAbsoluteHypotheticalFragmentInfo::new(block_flow));
let mut fragment = Fragment::new_from_specific_info(node, fragment_info);
let mut fragment_accumulator = InlineFragmentsAccumulator::from_inline_node(node);
fragment_accumulator.fragments.push(&mut fragment);
let construction_item = InlineFragmentsConstructionItem(InlineFragmentsConstructionResult {
splits: Vec::new(),
fragments: fragment_accumulator.finish(),
abs_descendants: abs_descendants,
});
ConstructionItemConstructionResult(construction_item)
}
/// Builds one or more fragments for a node with `display: inline`. This yields an
/// `InlineFragmentsConstructionResult`.
fn build_fragments_for_inline(&mut self, node: &ThreadSafeLayoutNode) -> ConstructionResult {
// Is this node replaced content?
if !node.is_replaced_content() {
// Go to a path that concatenates our kids' fragments.
self.build_fragments_for_nonreplaced_inline_content(node)
} else {
// Otherwise, just nuke our kids' fragments, create our fragment if any, and be done
// with it.
self.build_fragments_for_replaced_inline_content(node)
}
}
/// TableCaptionFlow is populated underneath TableWrapperFlow
fn place_table_caption_under_table_wrapper(&mut self,
table_wrapper_flow: &mut FlowRef,
node: &ThreadSafeLayoutNode) {
for kid in node.children() {
match kid.swap_out_construction_result() {
NoConstructionResult | ConstructionItemConstructionResult(_) => {}
FlowConstructionResult(kid_flow, _) => {
// Only kid flows with table-caption are matched here.
assert!(kid_flow.get().is_table_caption());
table_wrapper_flow.add_new_child(kid_flow);
}
}
}
}
/// Generates an anonymous table flow according to CSS 2.1 § 17.2.1, step 2.
/// If necessary, generate recursively another anonymous table flow.
fn generate_anonymous_missing_child(&mut self,
child_flows: Vec<FlowRef>,
flow: &mut FlowRef,
node: &ThreadSafeLayoutNode) {
let mut anonymous_flow = flow.get().generate_missing_child_flow(node);
let mut consecutive_siblings = vec!();
for kid_flow in child_flows.into_iter() {
if anonymous_flow.get().need_anonymous_flow(kid_flow.get()) {
consecutive_siblings.push(kid_flow);
continue;
}
if !consecutive_siblings.is_empty() {
self.generate_anonymous_missing_child(consecutive_siblings,
&mut anonymous_flow,
node);
consecutive_siblings = vec!();
}
anonymous_flow.add_new_child(kid_flow);
}
if !consecutive_siblings.is_empty() {
self.generate_anonymous_missing_child(consecutive_siblings, &mut anonymous_flow, node);
}
// The flow is done.
anonymous_flow.finish(self.layout_context);
flow.add_new_child(anonymous_flow);
}
/// Builds a flow for a node with `display: table`. This yields a `TableWrapperFlow` with possibly
/// other `TableCaptionFlow`s or `TableFlow`s underneath it.
fn build_flow_for_table_wrapper(&mut self, node: &ThreadSafeLayoutNode,
float_value: float::T) -> ConstructionResult {
let fragment = Fragment::new_from_specific_info(node, TableWrapperFragment);
let wrapper_flow = match float_value {
float::none => box TableWrapperFlow::from_node_and_fragment(node, fragment),
_ => {
let float_kind = FloatKind::from_property(float_value);
box TableWrapperFlow::float_from_node_and_fragment(node, fragment, float_kind)
}
};
let mut wrapper_flow = FlowRef::new(wrapper_flow as Box<Flow>);
let table_fragment = Fragment::new_from_specific_info(node, TableFragment);
let table_flow = box TableFlow::from_node_and_fragment(node, table_fragment);
let table_flow = FlowRef::new(table_flow as Box<Flow>);
// We first populate the TableFlow with other flows than TableCaptionFlow.
// We then populate the TableWrapperFlow with TableCaptionFlow, and attach
// the TableFlow to the TableWrapperFlow
let construction_result = self.build_flow_for_block(table_flow, node);
self.place_table_caption_under_table_wrapper(&mut wrapper_flow, node);
let mut abs_descendants = Descendants::new();
let mut fixed_descendants = Descendants::new();
// NOTE: The order of captions and table are not the same order as in the DOM tree.
// All caption blocks are placed before the table flow
match construction_result {
FlowConstructionResult(table_flow, table_abs_descendants) => {
wrapper_flow.add_new_child(table_flow);
abs_descendants.push_descendants(table_abs_descendants);
}
_ => {}
}
// The flow is done.
wrapper_flow.finish(self.layout_context);
let is_positioned = wrapper_flow.get_mut().as_block().is_positioned();
let is_fixed_positioned = wrapper_flow.get_mut().as_block().is_fixed();
let is_absolutely_positioned = wrapper_flow.get_mut()
.as_block()
.is_absolutely_positioned();
if is_positioned {
// This is the containing block for all the absolute descendants.
wrapper_flow.set_absolute_descendants(abs_descendants);
abs_descendants = Descendants::new();
if is_fixed_positioned {
// Send itself along with the other fixed descendants.
fixed_descendants.push(wrapper_flow.clone());
} else if is_absolutely_positioned {
// This is now the only absolute flow in the subtree which hasn't yet
// reached its containing block.
abs_descendants.push(wrapper_flow.clone());
}
}
FlowConstructionResult(wrapper_flow, abs_descendants)
}
/// Builds a flow for a node with `display: table-caption`. This yields a `TableCaptionFlow`
/// with possibly other `BlockFlow`s or `InlineFlow`s underneath it.
fn build_flow_for_table_caption(&mut self, node: &ThreadSafeLayoutNode) -> ConstructionResult {
let flow = box TableCaptionFlow::from_node(self, node) as Box<Flow>;
self.build_flow_for_block(FlowRef::new(flow), node)
}
/// Builds a flow for a node with `display: table-row-group`. This yields a `TableRowGroupFlow`
/// with possibly other `TableRowFlow`s underneath it.
fn build_flow_for_table_rowgroup(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
let fragment = Fragment::new_from_specific_info(node, TableRowFragment);
let flow = box TableRowGroupFlow::from_node_and_fragment(node, fragment);
let flow = flow as Box<Flow>;
self.build_flow_for_block(FlowRef::new(flow), node)
}
/// Builds a flow for a node with `display: table-row`. This yields a `TableRowFlow` with
/// possibly other `TableCellFlow`s underneath it.
fn build_flow_for_table_row(&mut self, node: &ThreadSafeLayoutNode) -> ConstructionResult {
let fragment = Fragment::new_from_specific_info(node, TableRowFragment);
let flow = box TableRowFlow::from_node_and_fragment(node, fragment) as Box<Flow>;
self.build_flow_for_block(FlowRef::new(flow), node)
}
/// Builds a flow for a node with `display: table-cell`. This yields a `TableCellFlow` with
/// possibly other `BlockFlow`s or `InlineFlow`s underneath it.
fn build_flow_for_table_cell(&mut self, node: &ThreadSafeLayoutNode) -> ConstructionResult {
let fragment = Fragment::new_from_specific_info(node, TableCellFragment);
let flow = box TableCellFlow::from_node_and_fragment(node, fragment) as Box<Flow>;
self.build_flow_for_block(FlowRef::new(flow), node)
}
/// Creates a fragment for a node with `display: table-column`.
fn build_fragments_for_table_column(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
// CSS 2.1 § 17.2.1. Treat all child fragments of a `table-column` as `display: none`.
for kid in node.children() {
kid.set_flow_construction_result(NoConstructionResult)
}
let specific = TableColumnFragment(TableColumnFragmentInfo::new(node));
let construction_item = TableColumnFragmentConstructionItem(
Fragment::new_from_specific_info(node, specific)
);
ConstructionItemConstructionResult(construction_item)
}
/// Builds a flow for a node with `display: table-column-group`.
/// This yields a `TableColGroupFlow`.
fn build_flow_for_table_colgroup(&mut self, node: &ThreadSafeLayoutNode)
-> ConstructionResult {
let fragment = Fragment::new_from_specific_info(
node,
TableColumnFragment(TableColumnFragmentInfo::new(node)));
let mut col_fragments = vec!();
for kid in node.children() {
// CSS 2.1 § 17.2.1. Treat all non-column child fragments of `table-column-group`
// as `display: none`.
match kid.swap_out_construction_result() {
ConstructionItemConstructionResult(TableColumnFragmentConstructionItem(
fragment)) => {
col_fragments.push(fragment);
}
_ => {}
}
}
if col_fragments.is_empty() {
debug!("add TableColumnFragment for empty colgroup");
let specific = TableColumnFragment(TableColumnFragmentInfo::new(node));
col_fragments.push(Fragment::new_from_specific_info(node, specific));
}
let flow = box TableColGroupFlow::from_node_and_fragments(node, fragment, col_fragments);
let mut flow = FlowRef::new(flow as Box<Flow>);
flow.finish(self.layout_context);
FlowConstructionResult(flow, Descendants::new())
}
}
impl<'a> PostorderNodeMutTraversal for FlowConstructor<'a> {
// Construct Flow based on 'display', 'position', and 'float' values.
//
// CSS 2.1 Section 9.7
//
// TODO: This should actually consult the table in that section to get the
// final computed value for 'display'.
fn process(&mut self, node: &ThreadSafeLayoutNode) -> bool {
// Get the `display` property for this node, and determine whether this node is floated.
let (display, float, positioning) = match node.type_id() {
None => {
// Pseudo-element.
let style = node.style();
let display = match node.get_pseudo_element_type() {
Normal => display::inline,
Before(display) => display,
After(display) => display,
};
(display, style.get_box().float, style.get_box().position)
}
Some(ElementNodeTypeId(_)) => {
let style = node.style();
let munged_display = if style.get_box()._servo_display_for_hypothetical_box ==
display::inline {
display::inline
} else {
style.get_box().display
};
(munged_display, style.get_box().float, style.get_box().position)
}
Some(TextNodeTypeId) => (display::inline, float::none, position::static_),
Some(CommentNodeTypeId) |
Some(DoctypeNodeTypeId) |
Some(DocumentFragmentNodeTypeId) |
Some(DocumentNodeTypeId) |
Some(ProcessingInstructionNodeTypeId) => {
(display::none, float::none, position::static_)
}
};
debug!("building flow for node: {:?} {:?}", display, float);
// Switch on display and floatedness.
match (display, float, positioning) {
// `display: none` contributes no flow construction result. Nuke the flow construction
// results of children.
(display::none, _, _) => {
for child in node.children() {
drop(child.swap_out_construction_result())
}
}
// Table items contribute table flow construction results.
(display::table, float_value, _) => {
let construction_result = self.build_flow_for_table_wrapper(node, float_value);
node.set_flow_construction_result(construction_result)
}
// Absolutely positioned elements will have computed value of
// `float` as 'none' and `display` as per the table.
// Only match here for block items. If an item is absolutely
// positioned, but inline we shouldn't try to construct a block
// flow here - instead, let it match the inline case
// below.
(display::block, _, position::absolute) | (_, _, position::fixed) => {
node.set_flow_construction_result(self.build_flow_for_nonfloated_block(node))
}
// Inline items that are absolutely-positioned contribute inline fragment construction
// results with a hypothetical fragment.
(display::inline, _, position::absolute) => {
let construction_result =
self.build_fragment_for_absolutely_positioned_inline(node);
node.set_flow_construction_result(construction_result)
}
// Inline items contribute inline fragment construction results.
//
// FIXME(pcwalton, #3307): This is not sufficient to handle floated generated content.
(display::inline, float::none, _) => {
let construction_result = self.build_fragments_for_inline(node);
node.set_flow_construction_result(construction_result)
}
// Inline-block items contribute inline fragment construction results.
(display::inline_block, float::none, _) => {
let construction_result = self.build_fragment_for_inline_block(node);
node.set_flow_construction_result(construction_result)
}
// Table items contribute table flow construction results.
(display::table_caption, _, _) => {
let construction_result = self.build_flow_for_table_caption(node);
node.set_flow_construction_result(construction_result)
}
// Table items contribute table flow construction results.
(display::table_column_group, _, _) => {
let construction_result = self.build_flow_for_table_colgroup(node);
node.set_flow_construction_result(construction_result)
}
// Table items contribute table flow construction results.
(display::table_column, _, _) => {
let construction_result = self.build_fragments_for_table_column(node);
node.set_flow_construction_result(construction_result)
}
// Table items contribute table flow construction results.
(display::table_row_group, _, _) | (display::table_header_group, _, _) |
(display::table_footer_group, _, _) => {
let construction_result = self.build_flow_for_table_rowgroup(node);
node.set_flow_construction_result(construction_result)
}
// Table items contribute table flow construction results.
(display::table_row, _, _) => {
let construction_result = self.build_flow_for_table_row(node);
node.set_flow_construction_result(construction_result)
}
// Table items contribute table flow construction results.
(display::table_cell, _, _) => {
let construction_result = self.build_flow_for_table_cell(node);
node.set_flow_construction_result(construction_result)
}
// Block flows that are not floated contribute block flow construction results.
//
// TODO(pcwalton): Make this only trigger for blocks and handle the other `display`
// properties separately.
(_, float::none, _) => {
node.set_flow_construction_result(self.build_flow_for_nonfloated_block(node))
}
// Floated flows contribute float flow construction results.
(_, float_value, _) => {
let float_kind = FloatKind::from_property(float_value);
node.set_flow_construction_result(
self.build_flow_for_floated_block(node, float_kind))
}
}
true
}
}
/// A utility trait with some useful methods for node queries.
trait NodeUtils {
/// Returns true if this node doesn't render its kids and false otherwise.
fn is_replaced_content(&self) -> bool;
/// Sets the construction result of a flow.
fn set_flow_construction_result(&self, result: ConstructionResult);
/// Replaces the flow construction result in a node with `NoConstructionResult` and returns the
/// old value.
fn swap_out_construction_result(&self) -> ConstructionResult;
}
impl<'ln> NodeUtils for ThreadSafeLayoutNode<'ln> {
fn is_replaced_content(&self) -> bool {
match self.type_id() {
Some(TextNodeTypeId) |
Some(ProcessingInstructionNodeTypeId) |
Some(CommentNodeTypeId) |
Some(DoctypeNodeTypeId) |
Some(DocumentFragmentNodeTypeId) |
Some(DocumentNodeTypeId) |
None |
Some(ElementNodeTypeId(HTMLImageElementTypeId)) => true,
Some(ElementNodeTypeId(HTMLObjectElementTypeId)) => self.has_object_data(),
Some(ElementNodeTypeId(_)) => false,
}
}
#[inline(always)]
fn set_flow_construction_result(&self, result: ConstructionResult) {
let mut layout_data_ref = self.mutate_layout_data();
match &mut *layout_data_ref {
&Some(ref mut layout_data) =>{
match self.get_pseudo_element_type() {
Before(_) => layout_data.data.before_flow_construction_result = result,
After(_) => layout_data.data.after_flow_construction_result = result,
Normal => layout_data.data.flow_construction_result = result,
}
},
&None => fail!("no layout data"),
}
}
#[inline(always)]
fn swap_out_construction_result(&self) -> ConstructionResult {
let mut layout_data_ref = self.mutate_layout_data();
match &mut *layout_data_ref {
&Some(ref mut layout_data) => {
match self.get_pseudo_element_type() {
Before(_) => {
mem::replace(&mut layout_data.data.before_flow_construction_result,
NoConstructionResult)
}
After(_) => {
mem::replace(&mut layout_data.data.after_flow_construction_result,
NoConstructionResult)
}
Normal => {
mem::replace(&mut layout_data.data.flow_construction_result,
NoConstructionResult)
}
}
}
&None => fail!("no layout data"),
}
}
}
/// Methods for interacting with HTMLObjectElement nodes
trait ObjectElement<'a> {
/// Returns None if this node is not matching attributes.
fn get_type_and_data(&self) -> (Option<&'a str>, Option<&'a str>);
/// Returns true if this node has object data that is correct uri.
fn has_object_data(&self) -> bool;
/// Returns the "data" attribute value parsed as a URL
fn get_object_data(&self) -> Option<Url>;
}
impl<'ln> ObjectElement<'ln> for ThreadSafeLayoutNode<'ln> {
fn get_type_and_data(&self) -> (Option<&'ln str>, Option<&'ln str>) {
let elem = self.as_element();
(elem.get_attr(&ns!(""), "type"), elem.get_attr(&ns!(""), "data"))
}
fn has_object_data(&self) -> bool {
match self.get_type_and_data() {
(None, Some(uri)) => is_image_data(uri),
_ => false
}
}
fn get_object_data(&self) -> Option<Url> {
match self.get_type_and_data() {
(None, Some(uri)) if is_image_data(uri) => Url::parse(uri).ok(),
_ => None
}
}
}
pub trait FlowConstructionUtils {
/// Adds a new flow as a child of this flow. Removes the flow from the given leaf set if
/// it's present.
fn add_new_child(&mut self, new_child: FlowRef);
/// Finishes a flow. Once a flow is finished, no more child flows or boxes may be added to it.
/// This will normally run the bubble-inline-sizes (minimum and preferred -- i.e. intrinsic -- inline-size)
/// calculation, unless the global `bubble_inline-sizes_separately` flag is on.
///
/// All flows must be finished at some point, or they will not have their intrinsic inline-sizes
/// properly computed. (This is not, however, a memory safety problem.)
fn finish(&mut self, context: &LayoutContext);
}
impl FlowConstructionUtils for FlowRef {
/// Adds a new flow as a child of this flow. Fails if this flow is marked as a leaf.
///
/// This must not be public because only the layout constructor can do this.
fn add_new_child(&mut self, mut new_child: FlowRef) {
{
let kid_base = flow::mut_base(new_child.get_mut());
kid_base.parallel.parent = parallel::mut_owned_flow_to_unsafe_flow(self);
}
let base = flow::mut_base(self.get_mut());
base.children.push_back(new_child);
let _ = base.parallel.children_count.fetch_add(1, Relaxed);
let _ = base.parallel.children_and_absolute_descendant_count.fetch_add(1, Relaxed);
}
/// Finishes a flow. Once a flow is finished, no more child flows or fragments may be added to
/// it. This will normally run the bubble-inline-sizes (minimum and preferred -- i.e. intrinsic --
/// inline-size) calculation, unless the global `bubble_inline-sizes_separately` flag is on.
///
/// All flows must be finished at some point, or they will not have their intrinsic inline-sizes
/// properly computed. (This is not, however, a memory safety problem.)
///
/// This must not be public because only the layout constructor can do this.
fn finish(&mut self, context: &LayoutContext) {
if !context.shared.opts.bubble_inline_sizes_separately {
self.get_mut().bubble_inline_sizes(context)
}
}
}
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