/*
* Copyright (c) 2021, Matthew Olsson <mattco@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/BitStream.h>
#include <AK/MemoryStream.h>
#include <AK/ScopeGuard.h>
#include <AK/TypeCasts.h>
#include <LibPDF/CommonNames.h>
#include <LibPDF/Document.h>
#include <LibPDF/Filter.h>
#include <LibPDF/Parser.h>
#include <LibTextCodec/Decoder.h>
#include <ctype.h>
namespace PDF {
template<typename T, typename... Args>
static NonnullRefPtr<T> make_object(Args... args) requires(IsBaseOf<Object, T>)
{
return adopt_ref(*new T(forward<Args>(args)...));
}
Vector<Command> Parser::parse_graphics_commands(ReadonlyBytes bytes)
{
auto parser = adopt_ref(*new Parser(bytes));
return parser->parse_graphics_commands();
}
Parser::Parser(Badge<Document>, ReadonlyBytes bytes)
: m_reader(bytes)
{
}
Parser::Parser(ReadonlyBytes bytes)
: m_reader(bytes)
{
}
void Parser::set_document(WeakPtr<Document> const& document)
{
m_document = document;
}
bool Parser::initialize()
{
if (!parse_header())
return {};
const auto result = initialize_linearization_dict();
if (result == LinearizationResult::Error)
return {};
if (result == LinearizationResult::NotLinearized)
return initialize_non_linearized_xref_table();
bool is_linearized = m_linearization_dictionary.has_value();
if (is_linearized) {
// The file may have been linearized at one point, but could have been updated afterwards,
// which means it is no longer a linearized PDF file.
is_linearized = m_linearization_dictionary.value().length_of_file == m_reader.bytes().size();
if (!is_linearized) {
// FIXME: The file shouldn't be treated as linearized, yet the xref tables are still
// split. This might take some tweaking to ensure correct behavior, which can be
// implemented later.
TODO();
}
}
if (is_linearized)
return initialize_linearized_xref_table();
return initialize_non_linearized_xref_table();
}
Value Parser::parse_object_with_index(u32 index)
{
VERIFY(m_xref_table->has_object(index));
auto byte_offset = m_xref_table->byte_offset_for_object(index);
m_reader.move_to(byte_offset);
auto indirect_value = parse_indirect_value();
VERIFY(indirect_value);
VERIFY(indirect_value->index() == index);
return indirect_value->value();
}
bool Parser::parse_header()
{
// FIXME: Do something with the version?
m_reader.set_reading_forwards();
if (m_reader.remaining() == 0)
return false;
m_reader.move_to(0);
if (m_reader.remaining() < 8 || !m_reader.matches("%PDF-"))
return false;
m_reader.move_by(5);
char major_ver = m_reader.read();
if (major_ver != '1' && major_ver != '2')
return false;
if (m_reader.read() != '.')
return false;
char minor_ver = m_reader.read();
if (minor_ver < '0' || minor_ver > '7')
return false;
consume_eol();
// Parse optional high-byte comment, which signifies a binary file
// FIXME: Do something with this?
auto comment = parse_comment();
if (!comment.is_empty()) {
auto binary = comment.length() >= 4;
if (binary) {
for (size_t i = 0; i < comment.length() && binary; i++)
binary = static_cast<u8>(comment[i]) > 128;
}
}
return true;
}
Parser::LinearizationResult Parser::initialize_linearization_dict()
{
// parse_header() is called immediately before this, so we are at the right location
auto dict_value = m_document->resolve(parse_indirect_value());
if (!dict_value.has<NonnullRefPtr<Object>>())
return LinearizationResult::Error;
auto dict_object = dict_value.get<NonnullRefPtr<Object>>();
if (!dict_object->is_dict())
return LinearizationResult::NotLinearized;
auto dict = object_cast<DictObject>(dict_object);
if (!dict->contains(CommonNames::Linearized))
return LinearizationResult::NotLinearized;
if (!dict->contains(CommonNames::L, CommonNames::H, CommonNames::O, CommonNames::E, CommonNames::N, CommonNames::T))
return LinearizationResult::Error;
auto length_of_file = dict->get_value(CommonNames::L);
auto hint_table = dict->get_value(CommonNames::H);
auto first_page_object_number = dict->get_value(CommonNames::O);
auto offset_of_first_page_end = dict->get_value(CommonNames::E);
auto number_of_pages = dict->get_value(CommonNames::N);
auto offset_of_main_xref_table = dict->get_value(CommonNames::T);
auto first_page = dict->get(CommonNames::P).value_or({});
// Validation
if (!length_of_file.has_u32()
|| !hint_table.has<NonnullRefPtr<Object>>()
|| !first_page_object_number.has_u32()
|| !number_of_pages.has_u16()
|| !offset_of_main_xref_table.has_u32()
|| (!first_page.has<Empty>() && !first_page.has_u32())) {
return LinearizationResult::Error;
}
auto hint_table_object = hint_table.get<NonnullRefPtr<Object>>();
if (!hint_table_object->is_array())
return LinearizationResult::Error;
auto hint_table_array = object_cast<ArrayObject>(hint_table_object);
auto hint_table_size = hint_table_array->size();
if (hint_table_size != 2 && hint_table_size != 4)
return LinearizationResult::Error;
auto primary_hint_stream_offset = hint_table_array->at(0);
auto primary_hint_stream_length = hint_table_array->at(1);
Value overflow_hint_stream_offset;
Value overflow_hint_stream_length;
if (hint_table_size == 4) {
overflow_hint_stream_offset = hint_table_array->at(2);
overflow_hint_stream_length = hint_table_array->at(3);
}
if (!primary_hint_stream_offset.has_u32()
|| !primary_hint_stream_length.has_u32()
|| (!overflow_hint_stream_offset.has<Empty>() && !overflow_hint_stream_offset.has_u32())
|| (!overflow_hint_stream_length.has<Empty>() && !overflow_hint_stream_length.has_u32())) {
return LinearizationResult::Error;
}
m_linearization_dictionary = LinearizationDictionary {
length_of_file.get_u32(),
primary_hint_stream_offset.get_u32(),
primary_hint_stream_length.get_u32(),
overflow_hint_stream_offset.has<Empty>() ? NumericLimits<u32>::max() : overflow_hint_stream_offset.get_u32(),
overflow_hint_stream_length.has<Empty>() ? NumericLimits<u32>::max() : overflow_hint_stream_length.get_u32(),
first_page_object_number.get_u32(),
offset_of_first_page_end.get_u32(),
number_of_pages.get_u16(),
offset_of_main_xref_table.get_u32(),
first_page.has<Empty>() ? NumericLimits<u32>::max() : first_page.get_u32(),
};
return LinearizationResult::Linearized;
}
bool Parser::initialize_linearized_xref_table()
{
// The linearization parameter dictionary has just been parsed, and the xref table
// comes immediately after it. We are in the correct spot.
if (!m_reader.matches("xref"))
return false;
m_xref_table = parse_xref_table();
if (!m_xref_table)
return false;
m_trailer = parse_file_trailer();
if (!m_trailer)
return false;
// Also parse the main xref table and merge into the first-page xref table. Note
// that we don't use the main xref table offset from the linearization dict because
// for some reason, it specified the offset of the whitespace after the object
// index start and length? So it's much easier to do it this way.
auto main_xref_table_offset = m_trailer->get_value(CommonNames::Prev).to_int();
m_reader.move_to(main_xref_table_offset);
auto main_xref_table = parse_xref_table();
if (!main_xref_table)
return false;
return m_xref_table->merge(move(*main_xref_table));
}
bool Parser::initialize_hint_tables()
{
auto linearization_dict = m_linearization_dictionary.value();
auto primary_offset = linearization_dict.primary_hint_stream_offset;
auto overflow_offset = linearization_dict.overflow_hint_stream_offset;
auto parse_hint_table = [&](size_t offset) -> RefPtr<StreamObject> {
m_reader.move_to(offset);
auto stream_indirect_value = parse_indirect_value();
if (!stream_indirect_value)
return {};
auto stream_value = stream_indirect_value->value();
if (!stream_value.has<NonnullRefPtr<Object>>())
return {};
auto stream_object = stream_value.get<NonnullRefPtr<Object>>();
if (!stream_object->is_stream())
return {};
return object_cast<StreamObject>(stream_object);
};
auto primary_hint_stream = parse_hint_table(primary_offset);
if (!primary_hint_stream)
return false;
RefPtr<StreamObject> overflow_hint_stream;
if (overflow_offset != NumericLimits<u32>::max())
overflow_hint_stream = parse_hint_table(overflow_offset);
ByteBuffer possible_merged_stream_buffer;
ReadonlyBytes hint_stream_bytes;
if (overflow_hint_stream) {
auto primary_size = primary_hint_stream->bytes().size();
auto overflow_size = overflow_hint_stream->bytes().size();
auto total_size = primary_size + overflow_size;
auto buffer_result = ByteBuffer::create_uninitialized(total_size);
if (!buffer_result.has_value())
return false;
possible_merged_stream_buffer = buffer_result.release_value();
auto ok = !possible_merged_stream_buffer.try_append(primary_hint_stream->bytes()).is_error();
ok = ok && !possible_merged_stream_buffer.try_append(overflow_hint_stream->bytes()).is_error();
if (!ok)
return false;
hint_stream_bytes = possible_merged_stream_buffer.bytes();
} else {
hint_stream_bytes = primary_hint_stream->bytes();
}
auto hint_table = parse_page_offset_hint_table(hint_stream_bytes);
if (!hint_table.has_value())
return false;
dbgln("hint table: {}", hint_table.value());
auto hint_table_entries = parse_all_page_offset_hint_table_entries(hint_table.value(), hint_stream_bytes);
if (!hint_table_entries.has_value())
return false;
auto entries = hint_table_entries.value();
dbgln("hint table entries size: {}", entries.size());
for (auto& entry : entries)
dbgln("{}", entry);
return true;
}
bool Parser::initialize_non_linearized_xref_table()
{
m_reader.move_to(m_reader.bytes().size() - 1);
if (!navigate_to_before_eof_marker())
return false;
if (!navigate_to_after_startxref())
return false;
if (m_reader.done())
return false;
m_reader.set_reading_forwards();
auto xref_offset_value = parse_number();
if (!xref_offset_value.has<int>())
return false;
auto xref_offset = xref_offset_value.get<int>();
m_reader.move_to(xref_offset);
m_xref_table = parse_xref_table();
if (!m_xref_table)
return false;
m_trailer = parse_file_trailer();
return m_trailer;
}
RefPtr<XRefTable> Parser::parse_xref_table()
{
if (!m_reader.matches("xref"))
return {};
m_reader.move_by(4);
if (!consume_eol())
return {};
auto table = adopt_ref(*new XRefTable());
while (true) {
if (m_reader.matches("trailer"))
return table;
Vector<XRefEntry> entries;
auto starting_index_value = parse_number();
auto starting_index = starting_index_value.get<int>();
auto object_count_value = parse_number();
auto object_count = object_count_value.get<int>();
for (int i = 0; i < object_count; i++) {
auto offset_string = String(m_reader.bytes().slice(m_reader.offset(), 10));
m_reader.move_by(10);
if (!consume(' '))
return {};
auto generation_string = String(m_reader.bytes().slice(m_reader.offset(), 5));
m_reader.move_by(5);
if (!consume(' '))
return {};
auto letter = m_reader.read();
if (letter != 'n' && letter != 'f')
return {};
// The line ending sequence can be one of the following:
// SP CR, SP LF, or CR LF
if (m_reader.matches(' ')) {
consume();
auto ch = consume();
if (ch != '\r' && ch != '\n')
return {};
} else {
if (!m_reader.matches("\r\n"))
return {};
m_reader.move_by(2);
}
auto offset = strtol(offset_string.characters(), nullptr, 10);
auto generation = strtol(generation_string.characters(), nullptr, 10);
entries.append({ offset, static_cast<u16>(generation), letter == 'n' });
}
table->add_section({ starting_index, object_count, entries });
}
}
RefPtr<DictObject> Parser::parse_file_trailer()
{
if (!m_reader.matches("trailer"))
return {};
m_reader.move_by(7);
consume_whitespace();
auto dict = parse_dict();
if (!dict)
return {};
if (!m_reader.matches("startxref"))
return {};
m_reader.move_by(9);
consume_whitespace();
m_reader.move_until([&](auto) { return matches_eol(); });
VERIFY(consume_eol());
if (!m_reader.matches("%%EOF"))
return {};
m_reader.move_by(5);
consume_whitespace();
return dict;
}
Optional<Parser::PageOffsetHintTable> Parser::parse_page_offset_hint_table(ReadonlyBytes hint_stream_bytes)
{
if (hint_stream_bytes.size() < sizeof(PageOffsetHintTable))
return {};
size_t offset = 0;
auto read_u32 = [&] {
u32 data = reinterpret_cast<const u32*>(hint_stream_bytes.data() + offset)[0];
offset += 4;
return AK::convert_between_host_and_big_endian(data);
};
auto read_u16 = [&] {
u16 data = reinterpret_cast<const u16*>(hint_stream_bytes.data() + offset)[0];
offset += 2;
return AK::convert_between_host_and_big_endian(data);
};
PageOffsetHintTable hint_table {
read_u32(),
read_u32(),
read_u16(),
read_u32(),
read_u16(),
read_u32(),
read_u16(),
read_u32(),
read_u16(),
read_u16(),
read_u16(),
read_u16(),
read_u16(),
};
// Verify that all of the bits_required_for_xyz fields are <= 32, since all of the numeric
// fields in PageOffsetHintTableEntry are u32
VERIFY(hint_table.bits_required_for_object_number <= 32);
VERIFY(hint_table.bits_required_for_page_length <= 32);
VERIFY(hint_table.bits_required_for_content_stream_offsets <= 32);
VERIFY(hint_table.bits_required_for_content_stream_length <= 32);
VERIFY(hint_table.bits_required_for_number_of_shared_obj_refs <= 32);
VERIFY(hint_table.bits_required_for_greatest_shared_obj_identifier <= 32);
VERIFY(hint_table.bits_required_for_fraction_numerator <= 32);
return hint_table;
}
Optional<Vector<Parser::PageOffsetHintTableEntry>> Parser::parse_all_page_offset_hint_table_entries(PageOffsetHintTable const& hint_table, ReadonlyBytes hint_stream_bytes)
{
InputMemoryStream input_stream(hint_stream_bytes);
input_stream.seek(sizeof(PageOffsetHintTable));
if (input_stream.has_any_error())
return {};
InputBitStream bit_stream(input_stream);
auto number_of_pages = m_linearization_dictionary.value().number_of_pages;
Vector<PageOffsetHintTableEntry> entries;
for (size_t i = 0; i < number_of_pages; i++)
entries.append(PageOffsetHintTableEntry {});
auto bits_required_for_object_number = hint_table.bits_required_for_object_number;
auto bits_required_for_page_length = hint_table.bits_required_for_page_length;
auto bits_required_for_content_stream_offsets = hint_table.bits_required_for_content_stream_offsets;
auto bits_required_for_content_stream_length = hint_table.bits_required_for_content_stream_length;
auto bits_required_for_number_of_shared_obj_refs = hint_table.bits_required_for_number_of_shared_obj_refs;
auto bits_required_for_greatest_shared_obj_identifier = hint_table.bits_required_for_greatest_shared_obj_identifier;
auto bits_required_for_fraction_numerator = hint_table.bits_required_for_fraction_numerator;
auto parse_int_entry = [&](u32 PageOffsetHintTableEntry::*field, u32 bit_size) {
if (bit_size <= 0)
return;
for (int i = 0; i < number_of_pages; i++) {
auto& entry = entries[i];
entry.*field = bit_stream.read_bits(bit_size);
}
};
auto parse_vector_entry = [&](Vector<u32> PageOffsetHintTableEntry::*field, u32 bit_size) {
if (bit_size <= 0)
return;
for (int page = 1; page < number_of_pages; page++) {
auto number_of_shared_objects = entries[page].number_of_shared_objects;
Vector<u32> items;
items.ensure_capacity(number_of_shared_objects);
for (size_t i = 0; i < number_of_shared_objects; i++)
items.unchecked_append(bit_stream.read_bits(bit_size));
entries[page].*field = move(items);
}
};
parse_int_entry(&PageOffsetHintTableEntry::objects_in_page_number, bits_required_for_object_number);
parse_int_entry(&PageOffsetHintTableEntry::page_length_number, bits_required_for_page_length);
parse_int_entry(&PageOffsetHintTableEntry::number_of_shared_objects, bits_required_for_number_of_shared_obj_refs);
parse_vector_entry(&PageOffsetHintTableEntry::shared_object_identifiers, bits_required_for_greatest_shared_obj_identifier);
parse_vector_entry(&PageOffsetHintTableEntry::shared_object_location_numerators, bits_required_for_fraction_numerator);
parse_int_entry(&PageOffsetHintTableEntry::page_content_stream_offset_number, bits_required_for_content_stream_offsets);
parse_int_entry(&PageOffsetHintTableEntry::page_content_stream_length_number, bits_required_for_content_stream_length);
return entries;
}
bool Parser::navigate_to_before_eof_marker()
{
m_reader.set_reading_backwards();
while (!m_reader.done()) {
m_reader.move_until([&](auto) { return matches_eol(); });
if (m_reader.done())
return false;
consume_eol();
if (!m_reader.matches("%%EOF"))
continue;
m_reader.move_by(5);
if (!matches_eol())
continue;
consume_eol();
return true;
}
return false;
}
bool Parser::navigate_to_after_startxref()
{
m_reader.set_reading_backwards();
while (!m_reader.done()) {
m_reader.move_until([&](auto) { return matches_eol(); });
auto offset = m_reader.offset() + 1;
consume_eol();
if (!m_reader.matches("startxref"))
continue;
m_reader.move_by(9);
if (!matches_eol())
continue;
m_reader.move_to(offset);
return true;
}
return false;
}
bool Parser::sloppy_is_linearized()
{
ScopeGuard guard([&] {
m_reader.move_to(0);
m_reader.set_reading_forwards();
});
auto limit = min(1024ul, m_reader.bytes().size() - 1);
m_reader.move_to(limit);
m_reader.set_reading_backwards();
while (!m_reader.done()) {
m_reader.move_until('/');
if (m_reader.matches("/Linearized"))
return true;
m_reader.move_by(1);
}
return false;
}
String Parser::parse_comment()
{
if (!m_reader.matches('%'))
return {};
consume();
auto comment_start_offset = m_reader.offset();
m_reader.move_until([&](auto) {
return matches_eol();
});
String str = StringView(m_reader.bytes().slice(comment_start_offset, m_reader.offset() - comment_start_offset));
consume_eol();
consume_whitespace();
return str;
}
Value Parser::parse_value()
{
parse_comment();
if (m_reader.matches("null")) {
m_reader.move_by(4);
consume_whitespace();
return Value(nullptr);
}
if (m_reader.matches("true")) {
m_reader.move_by(4);
consume_whitespace();
return Value(true);
}
if (m_reader.matches("false")) {
m_reader.move_by(5);
consume_whitespace();
return Value(false);
}
if (matches_number())
return parse_possible_indirect_value_or_ref();
if (m_reader.matches('/'))
return parse_name();
if (m_reader.matches("<<")) {
auto dict = parse_dict();
if (!dict)
return {};
if (m_reader.matches("stream"))
return parse_stream(dict.release_nonnull());
return dict;
}
if (m_reader.matches_any('(', '<'))
return parse_string();
if (m_reader.matches('['))
return parse_array();
dbgln("tried to parse value, but found char {} ({}) at offset {}", m_reader.peek(), static_cast<u8>(m_reader.peek()), m_reader.offset());
VERIFY_NOT_REACHED();
}
Value Parser::parse_possible_indirect_value_or_ref()
{
auto first_number = parse_number();
if (!first_number.has<int>() || !matches_number())
return first_number;
m_reader.save();
auto second_number = parse_number();
if (!second_number.has<int>()) {
m_reader.load();
return first_number;
}
if (m_reader.matches('R')) {
m_reader.discard();
consume();
consume_whitespace();
return Value(Reference(first_number.get<int>(), second_number.get<int>()));
}
if (m_reader.matches("obj")) {
m_reader.discard();
return parse_indirect_value(first_number.get<int>(), second_number.get<int>());
}
m_reader.load();
return first_number;
}
RefPtr<IndirectValue> Parser::parse_indirect_value(int index, int generation)
{
if (!m_reader.matches("obj"))
return {};
m_reader.move_by(3);
if (matches_eol())
consume_eol();
auto value = parse_value();
if (!m_reader.matches("endobj"))
return {};
consume(6);
consume_whitespace();
return make_object<IndirectValue>(index, generation, value);
}
RefPtr<IndirectValue> Parser::parse_indirect_value()
{
auto first_number = parse_number();
if (!first_number.has<int>())
return {};
auto second_number = parse_number();
if (!second_number.has<int>())
return {};
return parse_indirect_value(first_number.get<int>(), second_number.get<int>());
}
Value Parser::parse_number()
{
size_t start_offset = m_reader.offset();
bool is_float = false;
if (m_reader.matches('+') || m_reader.matches('-'))
consume();
while (!m_reader.done()) {
if (m_reader.matches('.')) {
if (is_float)
break;
is_float = true;
consume();
} else if (isdigit(m_reader.peek())) {
consume();
} else {
break;
}
}
consume_whitespace();
auto string = String(m_reader.bytes().slice(start_offset, m_reader.offset() - start_offset));
float f = strtof(string.characters(), nullptr);
if (is_float)
return Value(f);
VERIFY(floorf(f) == f);
return Value(static_cast<int>(f));
}
RefPtr<NameObject> Parser::parse_name()
{
if (!consume('/'))
return {};
StringBuilder builder;
while (true) {
if (!matches_regular_character())
break;
if (m_reader.matches('#')) {
int hex_value = 0;
for (int i = 0; i < 2; i++) {
auto ch = consume();
if (!isxdigit(ch))
return {};
hex_value *= 16;
if (ch <= '9') {
hex_value += ch - '0';
} else {
hex_value += ch - 'A' + 10;
}
}
builder.append(static_cast<char>(hex_value));
continue;
}
builder.append(consume());
}
consume_whitespace();
return make_object<NameObject>(builder.to_string());
}
RefPtr<StringObject> Parser::parse_string()
{
ScopeGuard guard([&] { consume_whitespace(); });
String string;
bool is_binary_string;
if (m_reader.matches('(')) {
string = parse_literal_string();
is_binary_string = false;
} else {
string = parse_hex_string();
is_binary_string = true;
}
if (string.is_null())
return {};
if (string.bytes().starts_with(Array<u8, 2> { 0xfe, 0xff })) {
// The string is encoded in UTF16-BE
string = TextCodec::decoder_for("utf-16be")->to_utf8(string.substring(2));
} else if (string.bytes().starts_with(Array<u8, 3> { 239, 187, 191 })) {
// The string is encoded in UTF-8. This is the default anyways, but if these bytes
// are explicitly included, we have to trim them
string = string.substring(3);
}
return make_object<StringObject>(string, is_binary_string);
}
String Parser::parse_literal_string()
{
if (!consume('('))
return {};
StringBuilder builder;
auto opened_parens = 0;
while (true) {
if (m_reader.matches('(')) {
opened_parens++;
builder.append(consume());
} else if (m_reader.matches(')')) {
consume();
if (opened_parens == 0)
break;
opened_parens--;
builder.append(')');
} else if (m_reader.matches('\\')) {
consume();
if (matches_eol()) {
consume_eol();
continue;
}
if (m_reader.done())
return {};
auto ch = consume();
switch (ch) {
case 'n':
builder.append('\n');
break;
case 'r':
builder.append('\r');
break;
case 't':
builder.append('\t');
break;
case 'b':
builder.append('\b');
break;
case 'f':
builder.append('\f');
break;
case '(':
builder.append('(');
break;
case ')':
builder.append(')');
break;
case '\\':
builder.append('\\');
break;
default: {
if (ch >= '0' && ch <= '7') {
int octal_value = ch - '0';
for (int i = 0; i < 2; i++) {
auto octal_ch = consume();
if (octal_ch < '0' || octal_ch > '7')
break;
octal_value = octal_value * 8 + (octal_ch - '0');
}
builder.append(static_cast<char>(octal_value));
} else {
builder.append(ch);
}
}
}
} else if (matches_eol()) {
consume_eol();
builder.append('\n');
} else {
builder.append(consume());
}
}
if (opened_parens != 0)
return {};
return builder.to_string();
}
String Parser::parse_hex_string()
{
if (!consume('<'))
return {};
StringBuilder builder;
while (true) {
if (m_reader.matches('>')) {
consume();
return builder.to_string();
} else {
int hex_value = 0;
for (int i = 0; i < 2; i++) {
auto ch = consume();
if (ch == '>') {
// The hex string contains an odd number of characters, and the last character
// is assumed to be '0'
consume();
hex_value *= 16;
builder.append(static_cast<char>(hex_value));
return builder.to_string();
}
if (!isxdigit(ch))
return {};
hex_value *= 16;
if (ch <= '9') {
hex_value += ch - '0';
} else {
hex_value += ch - 'A' + 10;
}
}
builder.append(static_cast<char>(hex_value));
}
}
}
RefPtr<ArrayObject> Parser::parse_array()
{
if (!consume('['))
return {};
consume_whitespace();
Vector<Value> values;
while (!m_reader.matches(']')) {
auto value = parse_value();
if (value.has<Empty>())
return {};
values.append(value);
}
if (!consume(']'))
return {};
consume_whitespace();
return make_object<ArrayObject>(values);
}
RefPtr<DictObject> Parser::parse_dict()
{
if (!consume('<') || !consume('<'))
return {};
consume_whitespace();
HashMap<FlyString, Value> map;
while (true) {
if (m_reader.matches(">>"))
break;
auto name = parse_name();
if (!name)
return {};
auto value = parse_value();
if (value.has<Empty>())
return {};
map.set(name->name(), value);
}
if (!consume('>') || !consume('>'))
return {};
consume_whitespace();
return make_object<DictObject>(map);
}
RefPtr<DictObject> Parser::conditionally_parse_page_tree_node(u32 object_index, bool& ok)
{
ok = true;
VERIFY(m_xref_table->has_object(object_index));
auto byte_offset = m_xref_table->byte_offset_for_object(object_index);
m_reader.move_to(byte_offset);
parse_number();
parse_number();
if (!m_reader.matches("obj")) {
ok = false;
return {};
}
m_reader.move_by(3);
consume_whitespace();
if (!consume('<') || !consume('<'))
return {};
consume_whitespace();
HashMap<FlyString, Value> map;
while (true) {
if (m_reader.matches(">>"))
break;
auto name = parse_name();
if (!name) {
ok = false;
return {};
}
auto name_string = name->name();
if (!name_string.is_one_of(CommonNames::Type, CommonNames::Parent, CommonNames::Kids, CommonNames::Count)) {
// This is a page, not a page tree node
return {};
}
auto value = parse_value();
if (value.has<Empty>()) {
ok = false;
return {};
}
if (name_string == CommonNames::Type) {
if (!value.has<NonnullRefPtr<Object>>())
return {};
auto type_object = value.get<NonnullRefPtr<Object>>();
if (!type_object->is_name())
return {};
auto type_name = object_cast<NameObject>(type_object);
if (type_name->name() != CommonNames::Pages)
return {};
}
map.set(name->name(), value);
}
if (!consume('>') || !consume('>'))
return {};
consume_whitespace();
return make_object<DictObject>(map);
}
RefPtr<StreamObject> Parser::parse_stream(NonnullRefPtr<DictObject> dict)
{
if (!m_reader.matches("stream"))
return {};
m_reader.move_by(6);
if (!consume_eol())
return {};
ReadonlyBytes bytes;
auto maybe_length = dict->get(CommonNames::Length);
if (maybe_length.has_value() && (!maybe_length->has<Reference>() || m_xref_table)) {
// The PDF writer has kindly provided us with the direct length of the stream
m_reader.save();
auto length = m_document->resolve_to<int>(maybe_length.value());
m_reader.load();
bytes = m_reader.bytes().slice(m_reader.offset(), length);
m_reader.move_by(length);
consume_whitespace();
} else {
// We have to look for the endstream keyword
auto stream_start = m_reader.offset();
while (true) {
m_reader.move_until([&](auto) { return matches_eol(); });
auto potential_stream_end = m_reader.offset();
consume_eol();
if (!m_reader.matches("endstream"))
continue;
bytes = m_reader.bytes().slice(stream_start, potential_stream_end - stream_start);
break;
}
}
m_reader.move_by(9);
consume_whitespace();
if (dict->contains(CommonNames::Filter)) {
auto filter_type = dict->get_name(m_document, CommonNames::Filter)->name();
auto maybe_bytes = Filter::decode(bytes, filter_type);
if (!maybe_bytes.has_value())
return {};
return make_object<EncodedStreamObject>(dict, move(maybe_bytes.value()));
}
return make_object<PlainTextStreamObject>(dict, bytes);
}
Vector<Command> Parser::parse_graphics_commands()
{
Vector<Command> commands;
Vector<Value> command_args;
constexpr static auto is_command_char = [](char ch) {
return isalpha(ch) || ch == '*' || ch == '\'';
};
while (!m_reader.done()) {
auto ch = m_reader.peek();
if (is_command_char(ch)) {
auto command_start = m_reader.offset();
while (is_command_char(ch)) {
consume();
if (m_reader.done())
break;
ch = m_reader.peek();
}
auto command_string = StringView(m_reader.bytes().slice(command_start, m_reader.offset() - command_start));
auto command_type = Command::command_type_from_symbol(command_string);
commands.append(Command(command_type, move(command_args)));
command_args = Vector<Value>();
consume_whitespace();
continue;
}
command_args.append(parse_value());
}
return commands;
}
bool Parser::matches_eol() const
{
return m_reader.matches_any(0xa, 0xd);
}
bool Parser::matches_whitespace() const
{
return matches_eol() || m_reader.matches_any(0, 0x9, 0xc, ' ');
}
bool Parser::matches_number() const
{
if (m_reader.done())
return false;
auto ch = m_reader.peek();
return isdigit(ch) || ch == '-' || ch == '+';
}
bool Parser::matches_delimiter() const
{
return m_reader.matches_any('(', ')', '<', '>', '[', ']', '{', '}', '/', '%');
}
bool Parser::matches_regular_character() const
{
return !matches_delimiter() && !matches_whitespace();
}
bool Parser::consume_eol()
{
if (m_reader.done()) {
return false;
}
if (m_reader.matches("\r\n")) {
consume(2);
return true;
}
auto consumed = consume();
return consumed == 0xd || consumed == 0xa;
}
bool Parser::consume_whitespace()
{
bool consumed = false;
while (matches_whitespace()) {
consumed = true;
consume();
}
return consumed;
}
char Parser::consume()
{
return m_reader.read();
}
void Parser::consume(int amount)
{
for (size_t i = 0; i < static_cast<size_t>(amount); i++)
consume();
}
bool Parser::consume(char ch)
{
return consume() == ch;
}
}
namespace AK {
template<>
struct Formatter<PDF::Parser::LinearizationDictionary> : Formatter<StringView> {
ErrorOr<void> format(FormatBuilder& format_builder, PDF::Parser::LinearizationDictionary const& dict)
{
StringBuilder builder;
builder.append("{\n");
builder.appendff(" length_of_file={}\n", dict.length_of_file);
builder.appendff(" primary_hint_stream_offset={}\n", dict.primary_hint_stream_offset);
builder.appendff(" primary_hint_stream_length={}\n", dict.primary_hint_stream_length);
builder.appendff(" overflow_hint_stream_offset={}\n", dict.overflow_hint_stream_offset);
builder.appendff(" overflow_hint_stream_length={}\n", dict.overflow_hint_stream_length);
builder.appendff(" first_page_object_number={}\n", dict.first_page_object_number);
builder.appendff(" offset_of_first_page_end={}\n", dict.offset_of_first_page_end);
builder.appendff(" number_of_pages={}\n", dict.number_of_pages);
builder.appendff(" offset_of_main_xref_table={}\n", dict.offset_of_main_xref_table);
builder.appendff(" first_page={}\n", dict.first_page);
builder.append('}');
return Formatter<StringView>::format(format_builder, builder.to_string());
}
};
template<>
struct Formatter<PDF::Parser::PageOffsetHintTable> : Formatter<StringView> {
ErrorOr<void> format(FormatBuilder& format_builder, PDF::Parser::PageOffsetHintTable const& table)
{
StringBuilder builder;
builder.append("{\n");
builder.appendff(" least_number_of_objects_in_a_page={}\n", table.least_number_of_objects_in_a_page);
builder.appendff(" location_of_first_page_object={}\n", table.location_of_first_page_object);
builder.appendff(" bits_required_for_object_number={}\n", table.bits_required_for_object_number);
builder.appendff(" least_length_of_a_page={}\n", table.least_length_of_a_page);
builder.appendff(" bits_required_for_page_length={}\n", table.bits_required_for_page_length);
builder.appendff(" least_offset_of_any_content_stream={}\n", table.least_offset_of_any_content_stream);
builder.appendff(" bits_required_for_content_stream_offsets={}\n", table.bits_required_for_content_stream_offsets);
builder.appendff(" least_content_stream_length={}\n", table.least_content_stream_length);
builder.appendff(" bits_required_for_content_stream_length={}\n", table.bits_required_for_content_stream_length);
builder.appendff(" bits_required_for_number_of_shared_obj_refs={}\n", table.bits_required_for_number_of_shared_obj_refs);
builder.appendff(" bits_required_for_greatest_shared_obj_identifier={}\n", table.bits_required_for_greatest_shared_obj_identifier);
builder.appendff(" bits_required_for_fraction_numerator={}\n", table.bits_required_for_fraction_numerator);
builder.appendff(" shared_object_reference_fraction_denominator={}\n", table.shared_object_reference_fraction_denominator);
builder.append('}');
return Formatter<StringView>::format(format_builder, builder.to_string());
}
};
template<>
struct Formatter<PDF::Parser::PageOffsetHintTableEntry> : Formatter<StringView> {
ErrorOr<void> format(FormatBuilder& format_builder, PDF::Parser::PageOffsetHintTableEntry const& entry)
{
StringBuilder builder;
builder.append("{\n");
builder.appendff(" objects_in_page_number={}\n", entry.objects_in_page_number);
builder.appendff(" page_length_number={}\n", entry.page_length_number);
builder.appendff(" number_of_shared_objects={}\n", entry.number_of_shared_objects);
builder.append(" shared_object_identifiers=[");
for (auto& identifier : entry.shared_object_identifiers)
builder.appendff(" {}", identifier);
builder.append(" ]\n");
builder.append(" shared_object_location_numerators=[");
for (auto& numerator : entry.shared_object_location_numerators)
builder.appendff(" {}", numerator);
builder.append(" ]\n");
builder.appendff(" page_content_stream_offset_number={}\n", entry.page_content_stream_offset_number);
builder.appendff(" page_content_stream_length_number={}\n", entry.page_content_stream_length_number);
builder.append('}');
return Formatter<StringView>::format(format_builder, builder.to_string());
}
};
}