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pdfium / pdfium / refs/heads/main / . / core / fpdfapi / parser / cpdf_document.cpp
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// Copyright 2014 The PDFium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
// Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com
#include "core/fpdfapi/parser/cpdf_document.h"
#include <algorithm>
#include <functional>
#include <optional>
#include <utility>
#include "core/fpdfapi/parser/cpdf_array.h"
#include "core/fpdfapi/parser/cpdf_dictionary.h"
#include "core/fpdfapi/parser/cpdf_linearized_header.h"
#include "core/fpdfapi/parser/cpdf_name.h"
#include "core/fpdfapi/parser/cpdf_null.h"
#include "core/fpdfapi/parser/cpdf_number.h"
#include "core/fpdfapi/parser/cpdf_parser.h"
#include "core/fpdfapi/parser/cpdf_read_validator.h"
#include "core/fpdfapi/parser/cpdf_reference.h"
#include "core/fpdfapi/parser/cpdf_stream.h"
#include "core/fpdfapi/parser/cpdf_stream_acc.h"
#include "core/fpdfapi/parser/fpdf_parser_utility.h"
#include "core/fxcodec/jbig2/JBig2_DocumentContext.h"
#include "core/fxcrt/check.h"
#include "core/fxcrt/check_op.h"
#include "core/fxcrt/containers/contains.h"
#include "core/fxcrt/fx_codepage.h"
#include "core/fxcrt/scoped_set_insertion.h"
#include "core/fxcrt/span.h"
#include "core/fxcrt/stl_util.h"
namespace {
const int kMaxPageLevel = 1024;
enum class NodeType : bool {
kBranch, // /Type /Pages, AKA page tree node.
kLeaf, // /Type /Page, AKA page object.
};
// Note that this function may modify `kid_dict` to correct PDF spec violations.
// Same reasoning as CountPages() below.
NodeType GetNodeType(RetainPtr<CPDF_Dictionary> kid_dict) {
const ByteString kid_type_value = kid_dict->GetNameFor("Type");
if (kid_type_value == "Pages") {
return NodeType::kBranch;
}
if (kid_type_value == "Page") {
return NodeType::kLeaf;
}
// Even though /Type is required for page tree nodes and page objects, PDFs
// may not have them or have the wrong type. Tolerate these errors and guess
// the type. Then fix the in-memory representation.
const bool has_kids = kid_dict->KeyExist("Kids");
kid_dict->SetNewFor<CPDF_Name>("Type", has_kids ? "Pages" : "Page");
return has_kids ? NodeType::kBranch : NodeType::kLeaf;
}
// Returns a value in the range [0, `CPDF_Document::kPageMaxNum`), or nullopt on
// error. Note that this function may modify `pages_dict` to correct PDF spec
// violations. By normalizing the in-memory representation, other code that
// reads the object do not have to deal with the same spec violations again.
// If the PDF gets saved, the saved copy will also be more spec-compliant.
std::optional<int> CountPages(
RetainPtr<CPDF_Dictionary> pages_dict,
std::set<RetainPtr<CPDF_Dictionary>>* visited_pages) {
// Required. See ISO 32000-1:2008 spec, table 29, but tolerate page tree nodes
// that violate the spec.
int count_from_dict = pages_dict->GetIntegerFor("Count");
if (count_from_dict > 0 && count_from_dict < CPDF_Document::kPageMaxNum) {
return count_from_dict;
}
RetainPtr<CPDF_Array> kids_array = pages_dict->GetMutableArrayFor("Kids");
if (!kids_array) {
return 0;
}
int count = 0;
for (size_t i = 0; i < kids_array->size(); i++) {
RetainPtr<CPDF_Dictionary> kid_dict = kids_array->GetMutableDictAt(i);
if (!kid_dict || pdfium::Contains(*visited_pages, kid_dict)) {
continue;
}
NodeType kid_type = GetNodeType(kid_dict);
if (kid_type == NodeType::kBranch) {
// Use |visited_pages| to help detect circular references of pages.
ScopedSetInsertion<RetainPtr<CPDF_Dictionary>> local_add(visited_pages,
kid_dict);
std::optional<int> local_count =
CountPages(std::move(kid_dict), visited_pages);
if (!local_count.has_value()) {
return std::nullopt; // Propagate error.
}
count += local_count.value();
} else {
CHECK_EQ(kid_type, NodeType::kLeaf);
count++;
}
if (count >= CPDF_Document::kPageMaxNum) {
return std::nullopt; // Error: too many pages.
}
}
// Fix the in-memory representation for page tree nodes that violate the spec.
pages_dict->SetNewFor<CPDF_Number>("Count", count);
return count;
}
int FindPageIndex(const CPDF_Dictionary* pNode,
uint32_t* skip_count,
uint32_t objnum,
int* index,
int level) {
if (!pNode->KeyExist("Kids")) {
if (objnum == pNode->GetObjNum())
return *index;
if (*skip_count != 0)
(*skip_count)--;
(*index)++;
return -1;
}
RetainPtr<const CPDF_Array> pKidList = pNode->GetArrayFor("Kids");
if (!pKidList)
return -1;
if (level >= kMaxPageLevel)
return -1;
size_t count = pNode->GetIntegerFor("Count");
if (count <= *skip_count) {
(*skip_count) -= count;
(*index) += count;
return -1;
}
if (count && count == pKidList->size()) {
for (size_t i = 0; i < count; i++) {
RetainPtr<const CPDF_Reference> pKid =
ToReference(pKidList->GetObjectAt(i));
if (pKid && pKid->GetRefObjNum() == objnum)
return static_cast<int>(*index + i);
}
}
for (size_t i = 0; i < pKidList->size(); i++) {
RetainPtr<const CPDF_Dictionary> pKid = pKidList->GetDictAt(i);
if (!pKid || pKid == pNode)
continue;
int found_index =
FindPageIndex(pKid.Get(), skip_count, objnum, index, level + 1);
if (found_index >= 0)
return found_index;
}
return -1;
}
} // namespace
CPDF_Document::CPDF_Document(std::unique_ptr<RenderDataIface> pRenderData,
std::unique_ptr<PageDataIface> pPageData)
: m_pDocRender(std::move(pRenderData)),
m_pDocPage(std::move(pPageData)),
m_StockFontClearer(m_pDocPage.get()) {
m_pDocRender->SetDocument(this);
m_pDocPage->SetDocument(this);
}
CPDF_Document::~CPDF_Document() {
// Be absolutely certain that |m_pExtension| is null before destroying
// the extension, to avoid re-entering it while being destroyed. clang
// seems to already do this for us, but the C++ standards seem to
// indicate the opposite.
m_pExtension.reset();
}
// static
bool CPDF_Document::IsValidPageObject(const CPDF_Object* obj) {
// See ISO 32000-1:2008 spec, table 30.
return ValidateDictType(ToDictionary(obj), "Page");
}
RetainPtr<CPDF_Object> CPDF_Document::ParseIndirectObject(uint32_t objnum) {
return m_pParser ? m_pParser->ParseIndirectObject(objnum) : nullptr;
}
bool CPDF_Document::TryInit() {
SetLastObjNum(m_pParser->GetLastObjNum());
RetainPtr<CPDF_Object> pRootObj =
GetOrParseIndirectObject(m_pParser->GetRootObjNum());
if (pRootObj)
m_pRootDict = pRootObj->GetMutableDict();
LoadPages();
return GetRoot() && GetPageCount() > 0;
}
CPDF_Parser::Error CPDF_Document::LoadDoc(
RetainPtr<IFX_SeekableReadStream> pFileAccess,
const ByteString& password) {
if (!m_pParser)
SetParser(std::make_unique<CPDF_Parser>(this));
return HandleLoadResult(
m_pParser->StartParse(std::move(pFileAccess), password));
}
CPDF_Parser::Error CPDF_Document::LoadLinearizedDoc(
RetainPtr<CPDF_ReadValidator> validator,
const ByteString& password) {
if (!m_pParser)
SetParser(std::make_unique<CPDF_Parser>(this));
return HandleLoadResult(
m_pParser->StartLinearizedParse(std::move(validator), password));
}
void CPDF_Document::LoadPages() {
const CPDF_LinearizedHeader* linearized_header =
m_pParser->GetLinearizedHeader();
if (!linearized_header) {
m_PageList.resize(RetrievePageCount());
return;
}
uint32_t objnum = linearized_header->GetFirstPageObjNum();
if (!IsValidPageObject(GetOrParseIndirectObject(objnum).Get())) {
m_PageList.resize(RetrievePageCount());
return;
}
uint32_t first_page_num = linearized_header->GetFirstPageNo();
uint32_t page_count = linearized_header->GetPageCount();
DCHECK(first_page_num < page_count);
m_PageList.resize(page_count);
m_PageList[first_page_num] = objnum;
}
RetainPtr<CPDF_Dictionary> CPDF_Document::TraversePDFPages(int iPage,
int* nPagesToGo,
size_t level) {
if (*nPagesToGo < 0 || m_bReachedMaxPageLevel)
return nullptr;
RetainPtr<CPDF_Dictionary> pPages = m_pTreeTraversal[level].first;
RetainPtr<CPDF_Array> pKidList = pPages->GetMutableArrayFor("Kids");
if (!pKidList) {
m_pTreeTraversal.pop_back();
if (*nPagesToGo != 1)
return nullptr;
m_PageList[iPage] = pPages->GetObjNum();
return pPages;
}
if (level >= kMaxPageLevel) {
m_pTreeTraversal.pop_back();
m_bReachedMaxPageLevel = true;
return nullptr;
}
RetainPtr<CPDF_Dictionary> page;
for (size_t i = m_pTreeTraversal[level].second; i < pKidList->size(); i++) {
if (*nPagesToGo == 0)
break;
pKidList->ConvertToIndirectObjectAt(i, this);
RetainPtr<CPDF_Dictionary> pKid = pKidList->GetMutableDictAt(i);
if (!pKid) {
(*nPagesToGo)--;
m_pTreeTraversal[level].second++;
continue;
}
if (pKid == pPages) {
m_pTreeTraversal[level].second++;
continue;
}
if (!pKid->KeyExist("Kids")) {
m_PageList[iPage - (*nPagesToGo) + 1] = pKid->GetObjNum();
(*nPagesToGo)--;
m_pTreeTraversal[level].second++;
if (*nPagesToGo == 0) {
page = std::move(pKid);
break;
}
} else {
// If the vector has size level+1, the child is not in yet
if (m_pTreeTraversal.size() == level + 1)
m_pTreeTraversal.emplace_back(std::move(pKid), 0);
// Now m_pTreeTraversal[level+1] should exist and be equal to pKid.
RetainPtr<CPDF_Dictionary> pPageKid =
TraversePDFPages(iPage, nPagesToGo, level + 1);
// Check if child was completely processed, i.e. it popped itself out
if (m_pTreeTraversal.size() == level + 1)
m_pTreeTraversal[level].second++;
// If child did not finish, no pages to go, or max level reached, end
if (m_pTreeTraversal.size() != level + 1 || *nPagesToGo == 0 ||
m_bReachedMaxPageLevel) {
page = std::move(pPageKid);
break;
}
}
}
if (m_pTreeTraversal[level].second == pKidList->size())
m_pTreeTraversal.pop_back();
return page;
}
void CPDF_Document::ResetTraversal() {
m_iNextPageToTraverse = 0;
m_bReachedMaxPageLevel = false;
m_pTreeTraversal.clear();
}
void CPDF_Document::SetParser(std::unique_ptr<CPDF_Parser> pParser) {
DCHECK(!m_pParser);
m_pParser = std::move(pParser);
}
CPDF_Parser::Error CPDF_Document::HandleLoadResult(CPDF_Parser::Error error) {
if (error == CPDF_Parser::SUCCESS)
m_bHasValidCrossReferenceTable = !m_pParser->xref_table_rebuilt();
return error;
}
RetainPtr<const CPDF_Dictionary> CPDF_Document::GetPagesDict() const {
const CPDF_Dictionary* pRoot = GetRoot();
return pRoot ? pRoot->GetDictFor("Pages") : nullptr;
}
RetainPtr<CPDF_Dictionary> CPDF_Document::GetMutablePagesDict() {
return pdfium::WrapRetain(
const_cast<CPDF_Dictionary*>(this->GetPagesDict().Get()));
}
bool CPDF_Document::IsPageLoaded(int iPage) const {
return !!m_PageList[iPage];
}
RetainPtr<const CPDF_Dictionary> CPDF_Document::GetPageDictionary(int iPage) {
if (!fxcrt::IndexInBounds(m_PageList, iPage))
return nullptr;
const uint32_t objnum = m_PageList[iPage];
if (objnum) {
RetainPtr<CPDF_Dictionary> result =
ToDictionary(GetOrParseIndirectObject(objnum));
if (result)
return result;
}
RetainPtr<CPDF_Dictionary> pPages = GetMutablePagesDict();
if (!pPages)
return nullptr;
if (m_pTreeTraversal.empty()) {
ResetTraversal();
m_pTreeTraversal.emplace_back(std::move(pPages), 0);
}
int nPagesToGo = iPage - m_iNextPageToTraverse + 1;
RetainPtr<CPDF_Dictionary> pPage = TraversePDFPages(iPage, &nPagesToGo, 0);
m_iNextPageToTraverse = iPage + 1;
return pPage;
}
RetainPtr<CPDF_Dictionary> CPDF_Document::GetMutablePageDictionary(int iPage) {
return pdfium::WrapRetain(
const_cast<CPDF_Dictionary*>(GetPageDictionary(iPage).Get()));
}
void CPDF_Document::SetPageObjNum(int iPage, uint32_t objNum) {
m_PageList[iPage] = objNum;
}
JBig2_DocumentContext* CPDF_Document::GetOrCreateCodecContext() {
if (!m_pCodecContext)
m_pCodecContext = std::make_unique<JBig2_DocumentContext>();
return m_pCodecContext.get();
}
RetainPtr<CPDF_Stream> CPDF_Document::CreateModifiedAPStream(
RetainPtr<CPDF_Dictionary> dict) {
auto stream = NewIndirect<CPDF_Stream>(std::move(dict));
m_ModifiedAPStreamIDs.insert(stream->GetObjNum());
return stream;
}
bool CPDF_Document::IsModifiedAPStream(const CPDF_Stream* stream) const {
return stream && pdfium::Contains(m_ModifiedAPStreamIDs, stream->GetObjNum());
}
int CPDF_Document::GetPageIndex(uint32_t objnum) {
uint32_t skip_count = 0;
bool bSkipped = false;
for (uint32_t i = 0; i < m_PageList.size(); ++i) {
if (m_PageList[i] == objnum)
return i;
if (!bSkipped && m_PageList[i] == 0) {
skip_count = i;
bSkipped = true;
}
}
RetainPtr<const CPDF_Dictionary> pPages = GetPagesDict();
if (!pPages)
return -1;
int start_index = 0;
int found_index = FindPageIndex(pPages, &skip_count, objnum, &start_index, 0);
// Corrupt page tree may yield out-of-range results.
if (!fxcrt::IndexInBounds(m_PageList, found_index))
return -1;
// Only update |m_PageList| when |objnum| points to a /Page object.
if (IsValidPageObject(GetOrParseIndirectObject(objnum).Get()))
m_PageList[found_index] = objnum;
return found_index;
}
int CPDF_Document::GetPageCount() const {
return fxcrt::CollectionSize<int>(m_PageList);
}
int CPDF_Document::RetrievePageCount() {
RetainPtr<CPDF_Dictionary> pPages = GetMutablePagesDict();
if (!pPages)
return 0;
if (!pPages->KeyExist("Kids"))
return 1;
std::set<RetainPtr<CPDF_Dictionary>> visited_pages = {pPages};
return CountPages(std::move(pPages), &visited_pages).value_or(0);
}
uint32_t CPDF_Document::GetUserPermissions(bool get_owner_perms) const {
return m_pParser ? m_pParser->GetPermissions(get_owner_perms) : 0;
}
RetainPtr<CPDF_StreamAcc> CPDF_Document::GetFontFileStreamAcc(
RetainPtr<const CPDF_Stream> pFontStream) {
return m_pDocPage->GetFontFileStreamAcc(std::move(pFontStream));
}
void CPDF_Document::MaybePurgeFontFileStreamAcc(
RetainPtr<CPDF_StreamAcc>&& pStreamAcc) {
if (m_pDocPage)
m_pDocPage->MaybePurgeFontFileStreamAcc(std::move(pStreamAcc));
}
void CPDF_Document::MaybePurgeImage(uint32_t objnum) {
if (m_pDocPage)
m_pDocPage->MaybePurgeImage(objnum);
}
void CPDF_Document::CreateNewDoc() {
DCHECK(!m_pRootDict);
DCHECK(!m_pInfoDict);
m_pRootDict = NewIndirect<CPDF_Dictionary>();
m_pRootDict->SetNewFor<CPDF_Name>("Type", "Catalog");
auto pPages = NewIndirect<CPDF_Dictionary>();
pPages->SetNewFor<CPDF_Name>("Type", "Pages");
pPages->SetNewFor<CPDF_Number>("Count", 0);
pPages->SetNewFor<CPDF_Array>("Kids");
m_pRootDict->SetNewFor<CPDF_Reference>("Pages", this, pPages->GetObjNum());
m_pInfoDict = NewIndirect<CPDF_Dictionary>();
}
RetainPtr<CPDF_Dictionary> CPDF_Document::CreateNewPage(int iPage) {
auto pDict = NewIndirect<CPDF_Dictionary>();
pDict->SetNewFor<CPDF_Name>("Type", "Page");
uint32_t dwObjNum = pDict->GetObjNum();
if (!InsertNewPage(iPage, pDict)) {
DeleteIndirectObject(dwObjNum);
return nullptr;
}
return pDict;
}
bool CPDF_Document::InsertDeletePDFPage(
RetainPtr<CPDF_Dictionary> pages_dict,
int pages_to_go,
RetainPtr<CPDF_Dictionary> page_dict,
bool is_insert,
std::set<RetainPtr<CPDF_Dictionary>>* visited) {
RetainPtr<CPDF_Array> kids_list = pages_dict->GetMutableArrayFor("Kids");
if (!kids_list) {
return false;
}
for (size_t i = 0; i < kids_list->size(); i++) {
RetainPtr<CPDF_Dictionary> kid_dict = kids_list->GetMutableDictAt(i);
NodeType kid_type = GetNodeType(kid_dict);
if (kid_type == NodeType::kLeaf) {
if (pages_to_go != 0) {
pages_to_go--;
continue;
}
if (is_insert) {
kids_list->InsertNewAt<CPDF_Reference>(i, this, page_dict->GetObjNum());
page_dict->SetNewFor<CPDF_Reference>("Parent", this,
pages_dict->GetObjNum());
} else {
kids_list->RemoveAt(i);
}
pages_dict->SetNewFor<CPDF_Number>(
"Count", pages_dict->GetIntegerFor("Count") + (is_insert ? 1 : -1));
ResetTraversal();
break;
}
CHECK_EQ(kid_type, NodeType::kBranch);
int page_count = kid_dict->GetIntegerFor("Count");
if (pages_to_go >= page_count) {
pages_to_go -= page_count;
continue;
}
if (pdfium::Contains(*visited, kid_dict)) {
return false;
}
ScopedSetInsertion<RetainPtr<CPDF_Dictionary>> insertion(visited, kid_dict);
if (!InsertDeletePDFPage(std::move(kid_dict), pages_to_go, page_dict,
is_insert, visited)) {
return false;
}
pages_dict->SetNewFor<CPDF_Number>(
"Count", pages_dict->GetIntegerFor("Count") + (is_insert ? 1 : -1));
break;
}
return true;
}
bool CPDF_Document::InsertNewPage(int iPage,
RetainPtr<CPDF_Dictionary> pPageDict) {
RetainPtr<CPDF_Dictionary> pRoot = GetMutableRoot();
if (!pRoot)
return false;
RetainPtr<CPDF_Dictionary> pPages = pRoot->GetMutableDictFor("Pages");
if (!pPages)
return false;
int nPages = GetPageCount();
if (iPage < 0 || iPage > nPages)
return false;
if (iPage == nPages) {
RetainPtr<CPDF_Array> pPagesList = pPages->GetOrCreateArrayFor("Kids");
pPagesList->AppendNew<CPDF_Reference>(this, pPageDict->GetObjNum());
pPages->SetNewFor<CPDF_Number>("Count", nPages + 1);
pPageDict->SetNewFor<CPDF_Reference>("Parent", this, pPages->GetObjNum());
ResetTraversal();
} else {
std::set<RetainPtr<CPDF_Dictionary>> stack = {pPages};
if (!InsertDeletePDFPage(std::move(pPages), iPage, pPageDict, true, &stack))
return false;
}
m_PageList.insert(m_PageList.begin() + iPage, pPageDict->GetObjNum());
return true;
}
RetainPtr<CPDF_Dictionary> CPDF_Document::GetInfo() {
if (m_pInfoDict)
return m_pInfoDict;
if (!m_pParser)
return nullptr;
uint32_t info_obj_num = m_pParser->GetInfoObjNum();
if (info_obj_num == 0)
return nullptr;
auto ref = pdfium::MakeRetain<CPDF_Reference>(this, info_obj_num);
m_pInfoDict = ToDictionary(ref->GetMutableDirect());
return m_pInfoDict;
}
RetainPtr<const CPDF_Array> CPDF_Document::GetFileIdentifier() const {
return m_pParser ? m_pParser->GetIDArray() : nullptr;
}
uint32_t CPDF_Document::DeletePage(int iPage) {
RetainPtr<CPDF_Dictionary> pPages = GetMutablePagesDict();
if (!pPages) {
return 0;
}
int nPages = pPages->GetIntegerFor("Count");
if (iPage < 0 || iPage >= nPages) {
return 0;
}
RetainPtr<const CPDF_Dictionary> page_dict = GetPageDictionary(iPage);
if (!page_dict) {
return 0;
}
std::set<RetainPtr<CPDF_Dictionary>> stack = {pPages};
if (!InsertDeletePDFPage(std::move(pPages), iPage, nullptr, false, &stack)) {
return 0;
}
m_PageList.erase(m_PageList.begin() + iPage);
return page_dict->GetObjNum();
}
void CPDF_Document::SetPageToNullObject(uint32_t page_obj_num) {
if (!page_obj_num || m_PageList.empty()) {
return;
}
// Load all pages so `m_PageList` has all the object numbers.
for (size_t i = 0; i < m_PageList.size(); ++i) {
GetPageDictionary(i);
}
if (pdfium::Contains(m_PageList, page_obj_num)) {
return;
}
// If `page_dict` is no longer in the page tree, replace it with an object of
// type null.
//
// Delete the object first from this container, so the conditional in the
// replacement call always evaluates to true.
DeleteIndirectObject(page_obj_num);
const bool replaced = ReplaceIndirectObjectIfHigherGeneration(
page_obj_num, pdfium::MakeRetain<CPDF_Null>());
CHECK(replaced);
}
void CPDF_Document::SetRootForTesting(RetainPtr<CPDF_Dictionary> root) {
m_pRootDict = std::move(root);
}
bool CPDF_Document::MovePages(pdfium::span<const int> page_indices,
int dest_page_index) {
const CPDF_Dictionary* pages = GetPagesDict();
const int num_pages_signed = pages ? pages->GetIntegerFor("Count") : 0;
if (num_pages_signed <= 0) {
return false;
}
const size_t num_pages = num_pages_signed;
// Check the number of pages is in range.
if (page_indices.empty() || page_indices.size() > num_pages) {
return false;
}
// Check that destination page index is in range.
if (dest_page_index < 0 ||
static_cast<size_t>(dest_page_index) > num_pages - page_indices.size()) {
return false;
}
// Check for if XFA is enabled.
Extension* extension = GetExtension();
if (extension && extension->ContainsExtensionForm()) {
// Don't manipulate XFA PDFs.
return false;
}
// Check for duplicate and out-of-range page indices
std::set<int> unique_page_indices;
// Store the pages that need to be moved. They'll be deleted then reinserted.
std::vector<RetainPtr<CPDF_Dictionary>> pages_to_move;
pages_to_move.reserve(page_indices.size());
// Store the page indices that will be deleted (and moved).
std::vector<int> page_indices_to_delete;
page_indices_to_delete.reserve(page_indices.size());
for (const int page_index : page_indices) {
bool inserted = unique_page_indices.insert(page_index).second;
if (!inserted) {
// Duplicate page index found
return false;
}
RetainPtr<CPDF_Dictionary> page = GetMutablePageDictionary(page_index);
if (!page) {
// Page not found, index might be out of range.
return false;
}
pages_to_move.push_back(std::move(page));
page_indices_to_delete.push_back(page_index);
}
// Sort the page indices to be deleted in descending order.
std::sort(page_indices_to_delete.begin(), page_indices_to_delete.end(),
std::greater<int>());
// Delete the pages in descending order.
if (extension) {
for (int page_index : page_indices_to_delete) {
extension->DeletePage(page_index);
}
} else {
for (int page_index : page_indices_to_delete) {
DeletePage(page_index);
}
}
// Insert the deleted pages back into the document at the destination page
// index.
for (size_t i = 0; i < pages_to_move.size(); ++i) {
if (!InsertNewPage(i + dest_page_index, pages_to_move[i])) {
// Fail in an indeterminate state.
return false;
}
}
return true;
}
void CPDF_Document::ResizePageListForTesting(size_t size) {
m_PageList.resize(size);
}
CPDF_Document::StockFontClearer::StockFontClearer(
CPDF_Document::PageDataIface* pPageData)
: m_pPageData(pPageData) {}
CPDF_Document::StockFontClearer::~StockFontClearer() {
m_pPageData->ClearStockFont();
}
CPDF_Document::PageDataIface::PageDataIface() = default;
CPDF_Document::PageDataIface::~PageDataIface() = default;
CPDF_Document::RenderDataIface::RenderDataIface() = default;
CPDF_Document::RenderDataIface::~RenderDataIface() = default;