core/fpdfapi/render/cpdf_pagerendercache.cpp - pdfium - Git at Google

 // Copyright 2016 PDFium Authors. All rights reserved.
 // 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/render/cpdf_pagerendercache.h"

 #include <algorithm>
 #include <vector>

 #include "core/fpdfapi/page/cpdf_page.h"
 #include "core/fpdfapi/render/cpdf_imagecacheentry.h"
 #include "core/fpdfapi/render/cpdf_renderstatus.h"

 namespace {

 struct CacheInfo {
   CacheInfo(uint32_t t, CPDF_Stream* stream) : time(t), pStream(stream) {}

   uint32_t time;
   CPDF_Stream* pStream;

   bool operator<(const CacheInfo& other) const { return time < other.time; }
 };

 }  // namespace

 CPDF_PageRenderCache::CPDF_PageRenderCache(CPDF_Page* pPage)
     : m_pPage(pPage),
       m_pCurImageCacheEntry(nullptr),
       m_nTimeCount(0),
       m_nCacheSize(0),
       m_bCurFindCache(false) {}

 CPDF_PageRenderCache::~CPDF_PageRenderCache() {
   for (const auto& it : m_ImageCache)
     delete it.second;
 }

 void CPDF_PageRenderCache::CacheOptimization(int32_t dwLimitCacheSize) {
   if (m_nCacheSize <= (uint32_t)dwLimitCacheSize)
     return;

   size_t nCount = m_ImageCache.size();
   std::vector<CacheInfo> cache_info;
   cache_info.reserve(nCount);
   for (const auto& it : m_ImageCache)
     cache_info.emplace_back(it.second->GetTimeCount(), it.second->GetStream());
   std::sort(cache_info.begin(), cache_info.end());

   // Check if time value is about to roll over and reset all entries.
   // The comparision is legal because uint32_t is an unsigned type.
   uint32_t nTimeCount = m_nTimeCount;
   if (nTimeCount + 1 < nTimeCount) {
     for (size_t i = 0; i < nCount; i++)
       m_ImageCache[cache_info[i].pStream]->m_dwTimeCount = i;
     m_nTimeCount = nCount;
   }

   size_t i = 0;
   while (i + 15 < nCount)
     ClearImageCacheEntry(cache_info[i++].pStream);

   while (i < nCount && m_nCacheSize > (uint32_t)dwLimitCacheSize)
     ClearImageCacheEntry(cache_info[i++].pStream);
 }

 void CPDF_PageRenderCache::ClearImageCacheEntry(CPDF_Stream* pStream) {
   auto it = m_ImageCache.find(pStream);
   if (it == m_ImageCache.end())
     return;

   m_nCacheSize -= it->second->EstimateSize();
   delete it->second;
   m_ImageCache.erase(it);
 }

 bool CPDF_PageRenderCache::StartGetCachedBitmap(
     CPDF_Stream* pStream,
     bool bStdCS,
     uint32_t GroupFamily,
     bool bLoadMask,
     CPDF_RenderStatus* pRenderStatus) {
   const auto it = m_ImageCache.find(pStream);
   m_bCurFindCache = it != m_ImageCache.end();
   if (m_bCurFindCache) {
     m_pCurImageCacheEntry = it->second;
   } else {
     m_pCurImageCacheEntry =
         new CPDF_ImageCacheEntry(m_pPage->m_pDocument, pStream);
   }
   int ret = m_pCurImageCacheEntry->StartGetCachedBitmap(
       pRenderStatus->m_pFormResource, m_pPage->m_pPageResources, bStdCS,
       GroupFamily, bLoadMask, pRenderStatus);
   if (ret == 2)
     return true;

   m_nTimeCount++;
   if (!m_bCurFindCache)
     m_ImageCache[pStream] = m_pCurImageCacheEntry;

   if (!ret)
     m_nCacheSize += m_pCurImageCacheEntry->EstimateSize();

   return false;
 }

 bool CPDF_PageRenderCache::Continue(IFX_Pause* pPause,
                                     CPDF_RenderStatus* pRenderStatus) {
   int ret = m_pCurImageCacheEntry->Continue(pPause, pRenderStatus);
   if (ret == 2)
     return true;

   m_nTimeCount++;
   if (!m_bCurFindCache)
     m_ImageCache[m_pCurImageCacheEntry->GetStream()] = m_pCurImageCacheEntry;
   if (!ret)
     m_nCacheSize += m_pCurImageCacheEntry->EstimateSize();
   return false;
 }

 void CPDF_PageRenderCache::ResetBitmap(
     CPDF_Stream* pStream,
     const CFX_RetainPtr<CFX_DIBitmap>& pBitmap) {
   CPDF_ImageCacheEntry* pEntry;
   const auto it = m_ImageCache.find(pStream);
   if (it == m_ImageCache.end()) {
     if (!pBitmap)
       return;

     pEntry = new CPDF_ImageCacheEntry(m_pPage->m_pDocument, pStream);
     m_ImageCache[pStream] = pEntry;
   } else {
     pEntry = it->second;
   }
   m_nCacheSize -= pEntry->EstimateSize();
   pEntry->Reset(pBitmap);
   m_nCacheSize += pEntry->EstimateSize();
 }
	// Copyright 2016 PDFium Authors. All rights reserved.
	// 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/render/cpdf_pagerendercache.h"

	#include <algorithm>
	#include <vector>

	#include "core/fpdfapi/page/cpdf_page.h"
	#include "core/fpdfapi/render/cpdf_imagecacheentry.h"
	#include "core/fpdfapi/render/cpdf_renderstatus.h"

	namespace {

	struct CacheInfo {
	CacheInfo(uint32_t t, CPDF_Stream* stream) : time(t), pStream(stream) {}

	uint32_t time;
	CPDF_Stream* pStream;

	bool operator<(const CacheInfo& other) const { return time < other.time; }
	};

	} // namespace

	CPDF_PageRenderCache::CPDF_PageRenderCache(CPDF_Page* pPage)
	: m_pPage(pPage),
	m_pCurImageCacheEntry(nullptr),
	m_nTimeCount(0),
	m_nCacheSize(0),
	m_bCurFindCache(false) {}

	CPDF_PageRenderCache::~CPDF_PageRenderCache() {
	for (const auto& it : m_ImageCache)
	delete it.second;
	}

	void CPDF_PageRenderCache::CacheOptimization(int32_t dwLimitCacheSize) {
	if (m_nCacheSize <= (uint32_t)dwLimitCacheSize)
	return;

	size_t nCount = m_ImageCache.size();
	std::vector<CacheInfo> cache_info;
	cache_info.reserve(nCount);
	for (const auto& it : m_ImageCache)
	cache_info.emplace_back(it.second->GetTimeCount(), it.second->GetStream());
	std::sort(cache_info.begin(), cache_info.end());

	// Check if time value is about to roll over and reset all entries.
	// The comparision is legal because uint32_t is an unsigned type.
	uint32_t nTimeCount = m_nTimeCount;
	if (nTimeCount + 1 < nTimeCount) {
	for (size_t i = 0; i < nCount; i++)
	m_ImageCache[cache_info[i].pStream]->m_dwTimeCount = i;
	m_nTimeCount = nCount;
	}

	size_t i = 0;
	while (i + 15 < nCount)
	ClearImageCacheEntry(cache_info[i++].pStream);

	while (i < nCount && m_nCacheSize > (uint32_t)dwLimitCacheSize)
	ClearImageCacheEntry(cache_info[i++].pStream);
	}

	void CPDF_PageRenderCache::ClearImageCacheEntry(CPDF_Stream* pStream) {
	auto it = m_ImageCache.find(pStream);
	if (it == m_ImageCache.end())
	return;

	m_nCacheSize -= it->second->EstimateSize();
	delete it->second;
	m_ImageCache.erase(it);
	}

	bool CPDF_PageRenderCache::StartGetCachedBitmap(
	CPDF_Stream* pStream,
	bool bStdCS,
	uint32_t GroupFamily,
	bool bLoadMask,
	CPDF_RenderStatus* pRenderStatus) {
	const auto it = m_ImageCache.find(pStream);
	m_bCurFindCache = it != m_ImageCache.end();
	if (m_bCurFindCache) {
	m_pCurImageCacheEntry = it->second;
	} else {
	m_pCurImageCacheEntry =
	new CPDF_ImageCacheEntry(m_pPage->m_pDocument, pStream);
	}
	int ret = m_pCurImageCacheEntry->StartGetCachedBitmap(
	pRenderStatus->m_pFormResource, m_pPage->m_pPageResources, bStdCS,
	GroupFamily, bLoadMask, pRenderStatus);
	if (ret == 2)
	return true;

	m_nTimeCount++;
	if (!m_bCurFindCache)
	m_ImageCache[pStream] = m_pCurImageCacheEntry;

	if (!ret)
	m_nCacheSize += m_pCurImageCacheEntry->EstimateSize();

	return false;
	}

	bool CPDF_PageRenderCache::Continue(IFX_Pause* pPause,
	CPDF_RenderStatus* pRenderStatus) {
	int ret = m_pCurImageCacheEntry->Continue(pPause, pRenderStatus);
	if (ret == 2)
	return true;

	m_nTimeCount++;
	if (!m_bCurFindCache)
	m_ImageCache[m_pCurImageCacheEntry->GetStream()] = m_pCurImageCacheEntry;
	if (!ret)
	m_nCacheSize += m_pCurImageCacheEntry->EstimateSize();
	return false;
	}

	void CPDF_PageRenderCache::ResetBitmap(
	CPDF_Stream* pStream,
	const CFX_RetainPtr<CFX_DIBitmap>& pBitmap) {
	CPDF_ImageCacheEntry* pEntry;
	const auto it = m_ImageCache.find(pStream);
	if (it == m_ImageCache.end()) {
	if (!pBitmap)
	return;

	pEntry = new CPDF_ImageCacheEntry(m_pPage->m_pDocument, pStream);
	m_ImageCache[pStream] = pEntry;
	} else {
	pEntry = it->second;
	}
	m_nCacheSize -= pEntry->EstimateSize();
	pEntry->Reset(pBitmap);
	m_nCacheSize += pEntry->EstimateSize();
	}