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/*
* Copyright (c) 2021, Matthew Olsson <mattco@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <LibPDF/CommonNames.h>
#include <LibPDF/Document.h>
#include <LibPDF/Parser.h>
namespace PDF {
String OutlineItem::to_string(int indent) const
{
auto indent_str = String::repeated(" ", indent + 1);
StringBuilder child_builder;
child_builder.append('[');
for (auto& child : children)
child_builder.appendff("{}\n", child.to_string(indent + 1));
child_builder.appendff("{}]", indent_str);
StringBuilder builder;
builder.append("OutlineItem {{\n");
builder.appendff("{}title={}\n", indent_str, title);
builder.appendff("{}count={}\n", indent_str, count);
builder.appendff("{}dest={}\n", indent_str, dest);
builder.appendff("{}color={}\n", indent_str, color);
builder.appendff("{}italic={}\n", indent_str, italic);
builder.appendff("{}bold={}\n", indent_str, bold);
builder.appendff("{}children={}\n", indent_str, child_builder.to_string());
builder.appendff("{}}}", String::repeated(" ", indent));
return builder.to_string();
}
RefPtr<Document> Document::create(ReadonlyBytes bytes)
{
auto parser = adopt_ref(*new Parser({}, bytes));
auto document = adopt_ref(*new Document(parser));
if (!parser->initialize())
return {};
document->m_catalog = parser->trailer()->get_dict(document, CommonNames::Root);
document->build_page_tree();
document->build_outline();
return document;
}
Document::Document(NonnullRefPtr<Parser> const& parser)
: m_parser(parser)
{
m_parser->set_document(this);
}
Value Document::get_or_load_value(u32 index)
{
auto value = get_value(index);
if (!value.has<Empty>()) // FIXME: Use Optional instead?
return value;
auto object = m_parser->parse_object_with_index(index);
m_values.set(index, object);
return object;
}
u32 Document::get_first_page_index() const
{
// FIXME: A PDF can have a different default first page, which
// should be fetched and returned here
return 0;
}
u32 Document::get_page_count() const
{
return m_page_object_indices.size();
}
Page Document::get_page(u32 index)
{
VERIFY(index < m_page_object_indices.size());
auto cached_page = m_pages.get(index);
if (cached_page.has_value())
return cached_page.value();
auto page_object_index = m_page_object_indices[index];
auto raw_page_object = resolve_to<DictObject>(get_or_load_value(page_object_index));
if (!raw_page_object->contains(CommonNames::Resources)) {
// This page inherits its resource dictionary
TODO();
}
auto resources = raw_page_object->get_dict(this, CommonNames::Resources);
auto contents = raw_page_object->get_object(this, CommonNames::Contents);
auto media_box_array = raw_page_object->get_array(this, CommonNames::MediaBox);
auto media_box = Rectangle {
media_box_array->at(0).to_float(),
media_box_array->at(1).to_float(),
media_box_array->at(2).to_float(),
media_box_array->at(3).to_float(),
};
auto crop_box = media_box;
if (raw_page_object->contains(CommonNames::CropBox)) {
auto crop_box_array = raw_page_object->get_array(this, CommonNames::CropBox);
crop_box = Rectangle {
crop_box_array->at(0).to_float(),
crop_box_array->at(1).to_float(),
crop_box_array->at(2).to_float(),
crop_box_array->at(3).to_float(),
};
}
float user_unit = 1.0f;
if (raw_page_object->contains(CommonNames::UserUnit))
user_unit = raw_page_object->get_value(CommonNames::UserUnit).to_float();
int rotate = 0;
if (raw_page_object->contains(CommonNames::Rotate)) {
rotate = raw_page_object->get_value(CommonNames::Rotate).get<int>();
VERIFY(rotate % 90 == 0);
}
Page page { move(resources), move(contents), media_box, crop_box, user_unit, rotate };
m_pages.set(index, page);
return page;
}
Value Document::resolve(Value const& value)
{
if (value.has<Reference>()) {
// FIXME: Surely indirect PDF objects can't contain another indirect PDF object,
// right? Unsure from the spec, but if they can, these return values would have
// to be wrapped with another resolve() call.
return get_or_load_value(value.as_ref_index());
}
if (!value.has<NonnullRefPtr<Object>>())
return value;
auto& obj = value.get<NonnullRefPtr<Object>>();
if (obj->is_indirect_value())
return static_ptr_cast<IndirectValue>(obj)->value();
return value;
}
bool Document::build_page_tree()
{
if (!m_catalog->contains(CommonNames::Pages))
return false;
auto page_tree = m_catalog->get_dict(this, CommonNames::Pages);
return add_page_tree_node_to_page_tree(page_tree);
}
bool Document::add_page_tree_node_to_page_tree(NonnullRefPtr<DictObject> const& page_tree)
{
if (!page_tree->contains(CommonNames::Kids) || !page_tree->contains(CommonNames::Count))
return false;
auto kids_array = page_tree->get_array(this, CommonNames::Kids);
auto page_count = page_tree->get(CommonNames::Count).value().get<int>();
if (static_cast<size_t>(page_count) != kids_array->elements().size()) {
// This page tree contains child page trees, so we recursively add
// these pages to the overall page tree
for (auto& value : *kids_array) {
auto reference_index = value.as_ref_index();
bool ok;
auto maybe_page_tree_node = m_parser->conditionally_parse_page_tree_node(reference_index, ok);
if (!ok)
return false;
if (maybe_page_tree_node) {
if (!add_page_tree_node_to_page_tree(maybe_page_tree_node.release_nonnull()))
return false;
} else {
m_page_object_indices.append(reference_index);
}
}
} else {
// We know all of the kids are leaf nodes
for (auto& value : *kids_array)
m_page_object_indices.append(value.as_ref_index());
}
return true;
}
void Document::build_outline()
{
if (!m_catalog->contains(CommonNames::Outlines))
return;
auto outline_dict = m_catalog->get_dict(this, CommonNames::Outlines);
if (!outline_dict->contains(CommonNames::First))
return;
if (!outline_dict->contains(CommonNames::Last))
return;
auto first_ref = outline_dict->get_value(CommonNames::First);
auto last_ref = outline_dict->get_value(CommonNames::Last);
auto children = build_outline_item_chain(first_ref, last_ref);
m_outline = adopt_ref(*new OutlineDict());
m_outline->children = move(children);
if (outline_dict->contains(CommonNames::Count))
m_outline->count = outline_dict->get_value(CommonNames::Count).get<int>();
}
NonnullRefPtr<OutlineItem> Document::build_outline_item(NonnullRefPtr<DictObject> const& outline_item_dict)
{
auto outline_item = adopt_ref(*new OutlineItem {});
if (outline_item_dict->contains(CommonNames::First)) {
VERIFY(outline_item_dict->contains(CommonNames::Last));
auto first_ref = outline_item_dict->get_value(CommonNames::First);
auto last_ref = outline_item_dict->get_value(CommonNames::Last);
auto children = build_outline_item_chain(first_ref, last_ref);
outline_item->children = move(children);
}
outline_item->title = outline_item_dict->get_string(this, CommonNames::Title)->string();
if (outline_item_dict->contains(CommonNames::Count))
outline_item->count = outline_item_dict->get_value(CommonNames::Count).get<int>();
if (outline_item_dict->contains(CommonNames::Dest)) {
auto dest_arr = outline_item_dict->get_array(this, CommonNames::Dest);
auto page_ref = dest_arr->at(0);
auto type_name = dest_arr->get_name_at(this, 1)->name();
Vector<float> parameters;
for (size_t i = 2; i < dest_arr->size(); i++)
parameters.append(dest_arr->at(i).to_float());
Destination::Type type;
if (type_name == CommonNames::XYZ) {
type = Destination::Type::XYZ;
} else if (type_name == CommonNames::Fit) {
type = Destination::Type::Fit;
} else if (type_name == CommonNames::FitH) {
type = Destination::Type::FitH;
} else if (type_name == CommonNames::FitV) {
type = Destination::Type::FitV;
} else if (type_name == CommonNames::FitR) {
type = Destination::Type::FitR;
} else if (type_name == CommonNames::FitB) {
type = Destination::Type::FitB;
} else if (type_name == CommonNames::FitBH) {
type = Destination::Type::FitBH;
} else if (type_name == CommonNames::FitBV) {
type = Destination::Type::FitBV;
} else {
VERIFY_NOT_REACHED();
}
outline_item->dest = Destination { type, page_ref, parameters };
}
if (outline_item_dict->contains(CommonNames::C)) {
auto color_array = outline_item_dict->get_array(this, CommonNames::C);
auto r = static_cast<int>(255.0f * color_array->at(0).get<float>());
auto g = static_cast<int>(255.0f * color_array->at(1).get<float>());
auto b = static_cast<int>(255.0f * color_array->at(2).get<float>());
outline_item->color = Color(r, g, b);
}
if (outline_item_dict->contains(CommonNames::F)) {
auto bitfield = outline_item_dict->get_value(CommonNames::F).get<int>();
outline_item->italic = bitfield & 0x1;
outline_item->bold = bitfield & 0x2;
}
return outline_item;
}
NonnullRefPtrVector<OutlineItem> Document::build_outline_item_chain(Value const& first_ref, Value const& last_ref)
{
VERIFY(first_ref.has<Reference>());
VERIFY(last_ref.has<Reference>());
NonnullRefPtrVector<OutlineItem> children;
auto first_dict = object_cast<DictObject>(
get_or_load_value(first_ref.as_ref_index()).get<NonnullRefPtr<Object>>());
auto first = build_outline_item(first_dict);
children.append(first);
auto current_child_dict = first_dict;
u32 current_child_index = first_ref.as_ref_index();
while (current_child_dict->contains(CommonNames::Next)) {
auto next_child_dict_ref = current_child_dict->get_value(CommonNames::Next);
current_child_index = next_child_dict_ref.as_ref_index();
auto next_child_dict = object_cast<DictObject>(get_or_load_value(current_child_index).get<NonnullRefPtr<Object>>());
auto next_child = build_outline_item(next_child_dict);
children.append(next_child);
current_child_dict = move(next_child_dict);
}
VERIFY(last_ref.as_ref_index() == current_child_index);
return children;
}
}
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