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qpdf/libqpdf/QPDF_optimization.cc
2024-09-18 10:25:38 +01:00

493 lines
17 KiB
C++

// See the "Optimization" section of the manual.
#include <qpdf/assert_debug.h>
#include <qpdf/QPDF_private.hh>
#include <qpdf/QPDFExc.hh>
#include <qpdf/QPDFWriter_private.hh>
#include <qpdf/QPDF_Array.hh>
#include <qpdf/QPDF_Dictionary.hh>
#include <qpdf/QTC.hh>
QPDF::ObjUser::ObjUser() :
ou_type(ou_bad),
pageno(0)
{
}
QPDF::ObjUser::ObjUser(user_e type) :
ou_type(type),
pageno(0)
{
qpdf_assert_debug(type == ou_root);
}
QPDF::ObjUser::ObjUser(user_e type, int pageno) :
ou_type(type),
pageno(pageno)
{
qpdf_assert_debug((type == ou_page) || (type == ou_thumb));
}
QPDF::ObjUser::ObjUser(user_e type, std::string const& key) :
ou_type(type),
pageno(0),
key(key)
{
qpdf_assert_debug((type == ou_trailer_key) || (type == ou_root_key));
}
bool
QPDF::ObjUser::operator<(ObjUser const& rhs) const
{
if (this->ou_type < rhs.ou_type) {
return true;
} else if (this->ou_type == rhs.ou_type) {
if (this->pageno < rhs.pageno) {
return true;
} else if (this->pageno == rhs.pageno) {
return (this->key < rhs.key);
}
}
return false;
}
QPDF::UpdateObjectMapsFrame::UpdateObjectMapsFrame(
QPDF::ObjUser const& ou, QPDFObjectHandle oh, bool top) :
ou(ou),
oh(oh),
top(top)
{
}
void
QPDF::optimize(
std::map<int, int> const& object_stream_data,
bool allow_changes,
std::function<int(QPDFObjectHandle&)> skip_stream_parameters)
{
optimize_internal(object_stream_data, allow_changes, skip_stream_parameters);
}
void
QPDF::optimize(
QPDFWriter::ObjTable const& obj, std::function<int(QPDFObjectHandle&)> skip_stream_parameters)
{
optimize_internal(obj, true, skip_stream_parameters);
}
void
QPDF::optimize(QPDF::Xref_table const& xref)
{
optimize_internal(xref, false, nullptr);
}
template <typename T>
void
QPDF::optimize_internal(
T const& object_stream_data,
bool allow_changes,
std::function<int(QPDFObjectHandle&)> skip_stream_parameters)
{
if (!m->obj_user_to_objects.empty()) {
// already optimized
return;
}
// The PDF specification indicates that /Outlines is supposed to be an indirect reference. Force
// it to be so if it exists and is direct. (This has been seen in the wild.)
QPDFObjectHandle root = getRoot();
if (root.getKey("/Outlines").isDictionary()) {
QPDFObjectHandle outlines = root.getKey("/Outlines");
if (!outlines.isIndirect()) {
QTC::TC("qpdf", "QPDF_optimization indirect outlines");
root.replaceKey("/Outlines", makeIndirectObject(outlines));
}
}
// Traverse pages tree pushing all inherited resources down to the page level. This also
// initializes m->all_pages.
pushInheritedAttributesToPage(allow_changes, false);
// Traverse pages
int n = toI(m->all_pages.size());
for (int pageno = 0; pageno < n; ++pageno) {
updateObjectMaps(
ObjUser(ObjUser::ou_page, pageno),
m->all_pages.at(toS(pageno)),
skip_stream_parameters);
}
// Traverse document-level items
for (auto const& key: m->xref_table.trailer().getKeys()) {
if (key == "/Root") {
// handled separately
} else {
updateObjectMaps(
ObjUser(ObjUser::ou_trailer_key, key),
m->xref_table.trailer().getKey(key),
skip_stream_parameters);
}
}
for (auto const& key: root.getKeys()) {
// Technically, /I keys from /Thread dictionaries are supposed to be handled separately, but
// we are going to disregard that specification for now. There is loads of evidence that
// pdlin and Acrobat both disregard things like this from time to time, so this is almost
// certain not to cause any problems.
updateObjectMaps(
ObjUser(ObjUser::ou_root_key, key), root.getKey(key), skip_stream_parameters);
}
ObjUser root_ou = ObjUser(ObjUser::ou_root);
auto root_og = QPDFObjGen(root.getObjGen());
m->obj_user_to_objects[root_ou].insert(root_og);
m->object_to_obj_users[root_og].insert(root_ou);
filterCompressedObjects(object_stream_data);
}
void
QPDF::pushInheritedAttributesToPage()
{
// Public API should not have access to allow_changes.
pushInheritedAttributesToPage(true, false);
}
void
QPDF::pushInheritedAttributesToPage(bool allow_changes, bool warn_skipped_keys)
{
// Traverse pages tree pushing all inherited resources down to the page level.
// The record of whether we've done this is cleared by updateAllPagesCache(). If we're warning
// for skipped keys, re-traverse unconditionally.
if (m->pushed_inherited_attributes_to_pages && (!warn_skipped_keys)) {
return;
}
// Calling getAllPages() resolves any duplicated page objects, repairs broken nodes, and detects
// loops, so we don't have to do those activities here.
getAllPages();
// key_ancestors is a mapping of page attribute keys to a stack of Pages nodes that contain
// values for them.
std::map<std::string, std::vector<QPDFObjectHandle>> key_ancestors;
pushInheritedAttributesToPageInternal(
m->xref_table.trailer().getKey("/Root").getKey("/Pages"),
key_ancestors,
allow_changes,
warn_skipped_keys);
if (!key_ancestors.empty()) {
throw std::logic_error(
"key_ancestors not empty after pushing inherited attributes to pages");
}
m->pushed_inherited_attributes_to_pages = true;
m->ever_pushed_inherited_attributes_to_pages = true;
}
void
QPDF::pushInheritedAttributesToPageInternal(
QPDFObjectHandle cur_pages,
std::map<std::string, std::vector<QPDFObjectHandle>>& key_ancestors,
bool allow_changes,
bool warn_skipped_keys)
{
// Make a list of inheritable keys. Only the keys /MediaBox, /CropBox, /Resources, and /Rotate
// are inheritable attributes. Push this object onto the stack of pages nodes that have values
// for this attribute.
std::set<std::string> inheritable_keys;
for (auto const& key: cur_pages.getKeys()) {
if ((key == "/MediaBox") || (key == "/CropBox") || (key == "/Resources") ||
(key == "/Rotate")) {
if (!allow_changes) {
throw QPDFExc(
qpdf_e_internal,
m->file->getName(),
m->last_object_description,
m->file->getLastOffset(),
"optimize detected an inheritable attribute when called in no-change mode");
}
// This is an inheritable resource
inheritable_keys.insert(key);
QPDFObjectHandle oh = cur_pages.getKey(key);
QTC::TC("qpdf", "QPDF opt direct pages resource", oh.isIndirect() ? 0 : 1);
if (!oh.isIndirect()) {
if (!oh.isScalar()) {
// Replace shared direct object non-scalar resources with indirect objects to
// avoid copying large structures around.
cur_pages.replaceKey(key, makeIndirectObject(oh));
oh = cur_pages.getKey(key);
} else {
// It's okay to copy scalars.
QTC::TC("qpdf", "QPDF opt inherited scalar");
}
}
key_ancestors[key].push_back(oh);
if (key_ancestors[key].size() > 1) {
QTC::TC("qpdf", "QPDF opt key ancestors depth > 1");
}
// Remove this resource from this node. It will be reattached at the page level.
cur_pages.removeKey(key);
} else if (!((key == "/Type") || (key == "/Parent") || (key == "/Kids") ||
(key == "/Count"))) {
// Warn when flattening, but not if the key is at the top level (i.e. "/Parent" not
// set), as we don't change these; but flattening removes intermediate /Pages nodes.
if ((warn_skipped_keys) && (cur_pages.hasKey("/Parent"))) {
QTC::TC("qpdf", "QPDF unknown key not inherited");
setLastObjectDescription("Pages object", cur_pages.getObjGen());
warn(
qpdf_e_pages,
m->last_object_description,
0,
("Unknown key " + key +
" in /Pages object is being discarded as a result of flattening the /Pages "
"tree"));
}
}
}
// Process descendant nodes. This method does not perform loop detection because all code paths
// that lead here follow a call to getAllPages, which already throws an exception in the event
// of a loop in the pages tree.
for (auto& kid: cur_pages.getKey("/Kids").aitems()) {
if (kid.isDictionaryOfType("/Pages")) {
pushInheritedAttributesToPageInternal(
kid, key_ancestors, allow_changes, warn_skipped_keys);
} else {
// Add all available inheritable attributes not present in this object to this object.
for (auto const& iter: key_ancestors) {
std::string const& key = iter.first;
if (!kid.hasKey(key)) {
QTC::TC("qpdf", "QPDF opt resource inherited");
kid.replaceKey(key, iter.second.back());
} else {
QTC::TC("qpdf", "QPDF opt page resource hides ancestor");
}
}
}
}
// For each inheritable key, pop the stack. If the stack becomes empty, remove it from the map.
// That way, the invariant that the list of keys in key_ancestors is exactly those keys for
// which inheritable attributes are available.
if (!inheritable_keys.empty()) {
QTC::TC("qpdf", "QPDF opt inheritable keys");
for (auto const& key: inheritable_keys) {
key_ancestors[key].pop_back();
if (key_ancestors[key].empty()) {
QTC::TC("qpdf", "QPDF opt erase empty key ancestor");
key_ancestors.erase(key);
}
}
} else {
QTC::TC("qpdf", "QPDF opt no inheritable keys");
}
}
void
QPDF::updateObjectMaps(
ObjUser const& first_ou,
QPDFObjectHandle first_oh,
std::function<int(QPDFObjectHandle&)> skip_stream_parameters)
{
QPDFObjGen::set visited;
std::vector<UpdateObjectMapsFrame> pending;
pending.emplace_back(first_ou, first_oh, true);
// Traverse the object tree from this point taking care to avoid crossing page boundaries.
std::unique_ptr<ObjUser> thumb_ou;
while (!pending.empty()) {
auto cur = pending.back();
pending.pop_back();
bool is_page_node = false;
if (cur.oh.isDictionaryOfType("/Page")) {
is_page_node = true;
if (!cur.top) {
continue;
}
}
if (cur.oh.isIndirect()) {
QPDFObjGen og(cur.oh.getObjGen());
if (!visited.add(og)) {
QTC::TC("qpdf", "QPDF opt loop detected");
continue;
}
m->obj_user_to_objects[cur.ou].insert(og);
m->object_to_obj_users[og].insert(cur.ou);
}
if (cur.oh.isArray()) {
int n = cur.oh.getArrayNItems();
for (int i = 0; i < n; ++i) {
pending.emplace_back(cur.ou, cur.oh.getArrayItem(i), false);
}
} else if (cur.oh.isDictionary() || cur.oh.isStream()) {
QPDFObjectHandle dict = cur.oh;
bool is_stream = cur.oh.isStream();
int ssp = 0;
if (is_stream) {
dict = cur.oh.getDict();
if (skip_stream_parameters) {
ssp = skip_stream_parameters(cur.oh);
}
}
for (auto const& key: dict.getKeys()) {
if (is_page_node && (key == "/Thumb")) {
// Traverse page thumbnail dictionaries as a special case. There can only ever
// be one /Thumb key on a page, and we see at most one page node per call.
thumb_ou = std::make_unique<ObjUser>(ObjUser::ou_thumb, cur.ou.pageno);
pending.emplace_back(*thumb_ou, dict.getKey(key), false);
} else if (is_page_node && (key == "/Parent")) {
// Don't traverse back up the page tree
} else if (
((ssp >= 1) && (key == "/Length")) ||
((ssp >= 2) && ((key == "/Filter") || (key == "/DecodeParms")))) {
// Don't traverse into stream parameters that we are not going to write.
} else {
pending.emplace_back(cur.ou, dict.getKey(key), false);
}
}
}
}
}
void
QPDF::filterCompressedObjects(std::map<int, int> const& object_stream_data)
{
if (object_stream_data.empty()) {
return;
}
// Transform object_to_obj_users and obj_user_to_objects so that they refer only to uncompressed
// objects. If something is a user of a compressed object, then it is really a user of the
// object stream that contains it.
std::map<ObjUser, std::set<QPDFObjGen>> t_obj_user_to_objects;
std::map<QPDFObjGen, std::set<ObjUser>> t_object_to_obj_users;
for (auto const& i1: m->obj_user_to_objects) {
ObjUser const& ou = i1.first;
// Loop over objects.
for (auto const& og: i1.second) {
auto i2 = object_stream_data.find(og.getObj());
if (i2 == object_stream_data.end()) {
t_obj_user_to_objects[ou].insert(og);
} else {
t_obj_user_to_objects[ou].insert(QPDFObjGen(i2->second, 0));
}
}
}
for (auto const& i1: m->object_to_obj_users) {
QPDFObjGen const& og = i1.first;
// Loop over obj_users.
for (auto const& ou: i1.second) {
auto i2 = object_stream_data.find(og.getObj());
if (i2 == object_stream_data.end()) {
t_object_to_obj_users[og].insert(ou);
} else {
t_object_to_obj_users[QPDFObjGen(i2->second, 0)].insert(ou);
}
}
}
m->obj_user_to_objects = t_obj_user_to_objects;
m->object_to_obj_users = t_object_to_obj_users;
}
void
QPDF::filterCompressedObjects(QPDFWriter::ObjTable const& obj)
{
if (obj.getStreamsEmpty()) {
return;
}
// Transform object_to_obj_users and obj_user_to_objects so that they refer only to uncompressed
// objects. If something is a user of a compressed object, then it is really a user of the
// object stream that contains it.
std::map<ObjUser, std::set<QPDFObjGen>> t_obj_user_to_objects;
std::map<QPDFObjGen, std::set<ObjUser>> t_object_to_obj_users;
for (auto const& i1: m->obj_user_to_objects) {
ObjUser const& ou = i1.first;
// Loop over objects.
for (auto const& og: i1.second) {
if (obj.contains(og)) {
if (auto const& i2 = obj[og].object_stream; i2 <= 0) {
t_obj_user_to_objects[ou].insert(og);
} else {
t_obj_user_to_objects[ou].insert(QPDFObjGen(i2, 0));
}
}
}
}
for (auto const& i1: m->object_to_obj_users) {
QPDFObjGen const& og = i1.first;
if (obj.contains(og)) {
// Loop over obj_users.
for (auto const& ou: i1.second) {
if (auto i2 = obj[og].object_stream; i2 <= 0) {
t_object_to_obj_users[og].insert(ou);
} else {
t_object_to_obj_users[QPDFObjGen(i2, 0)].insert(ou);
}
}
}
}
m->obj_user_to_objects = t_obj_user_to_objects;
m->object_to_obj_users = t_object_to_obj_users;
}
void
QPDF::filterCompressedObjects(QPDF::Xref_table const& xref)
{
if (!xref.object_streams()) {
return;
}
// Transform object_to_obj_users and obj_user_to_objects so that they refer only to uncompressed
// objects. If something is a user of a compressed object, then it is really a user of the
// object stream that contains it.
std::map<ObjUser, std::set<QPDFObjGen>> t_obj_user_to_objects;
std::map<QPDFObjGen, std::set<ObjUser>> t_object_to_obj_users;
for (auto const& i1: m->obj_user_to_objects) {
ObjUser const& ou = i1.first;
// Loop over objects.
for (auto const& og: i1.second) {
if (auto stream = xref.stream_number(og.getObj())) {
t_obj_user_to_objects[ou].insert(QPDFObjGen(stream, 0));
} else {
t_obj_user_to_objects[ou].insert(og);
}
}
}
for (auto const& i1: m->object_to_obj_users) {
QPDFObjGen const& og = i1.first;
// Loop over obj_users.
for (auto const& ou: i1.second) {
if (auto stream = xref.stream_number(og.getObj())) {
t_object_to_obj_users[QPDFObjGen(stream, 0)].insert(ou);
} else {
t_object_to_obj_users[og].insert(ou);
}
}
}
m->obj_user_to_objects = t_obj_user_to_objects;
m->object_to_obj_users = t_object_to_obj_users;
}