gecko-dev/image/imgLoader.cpp

3078 строки
107 KiB
C++

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
// Undefine windows version of LoadImage because our code uses that name.
#undef LoadImage
#include "imgLoader.h"
#include <algorithm>
#include <utility>
#include "DecoderFactory.h"
#include "Image.h"
#include "ImageLogging.h"
#include "ReferrerInfo.h"
#include "imgRequestProxy.h"
#include "mozilla/Attributes.h"
#include "mozilla/BasePrincipal.h"
#include "mozilla/ChaosMode.h"
#include "mozilla/ClearOnShutdown.h"
#include "mozilla/LoadInfo.h"
#include "mozilla/NullPrincipal.h"
#include "mozilla/Preferences.h"
#include "mozilla/StaticPrefs_image.h"
#include "mozilla/StaticPrefs_network.h"
#include "mozilla/dom/ContentParent.h"
#include "mozilla/dom/nsMixedContentBlocker.h"
#include "mozilla/image/ImageMemoryReporter.h"
#include "mozilla/layers/CompositorManagerChild.h"
#include "nsCOMPtr.h"
#include "nsCRT.h"
#include "nsContentPolicyUtils.h"
#include "nsContentUtils.h"
#include "nsIApplicationCache.h"
#include "nsIApplicationCacheContainer.h"
#include "nsIAsyncVerifyRedirectCallback.h"
#include "nsICacheInfoChannel.h"
#include "nsIChannelEventSink.h"
#include "nsIClassOfService.h"
#include "nsIFile.h"
#include "nsIFileURL.h"
#include "nsIHttpChannel.h"
#include "nsIInterfaceRequestor.h"
#include "nsIInterfaceRequestorUtils.h"
#include "nsIMemoryReporter.h"
#include "nsINetworkPredictor.h"
#include "nsIProgressEventSink.h"
#include "nsIProtocolHandler.h"
#include "nsImageModule.h"
#include "nsMimeTypes.h"
#include "nsNetCID.h"
#include "nsNetUtil.h"
#include "nsReadableUtils.h"
#include "nsStreamUtils.h"
#include "prtime.h"
// we want to explore making the document own the load group
// so we can associate the document URI with the load group.
// until this point, we have an evil hack:
#include "nsIHttpChannelInternal.h"
#include "nsILoadGroupChild.h"
#include "nsIDocShell.h"
using namespace mozilla;
using namespace mozilla::dom;
using namespace mozilla::image;
using namespace mozilla::net;
MOZ_DEFINE_MALLOC_SIZE_OF(ImagesMallocSizeOf)
class imgMemoryReporter final : public nsIMemoryReporter {
~imgMemoryReporter() = default;
public:
NS_DECL_ISUPPORTS
NS_IMETHOD CollectReports(nsIHandleReportCallback* aHandleReport,
nsISupports* aData, bool aAnonymize) override {
MOZ_ASSERT(NS_IsMainThread());
layers::CompositorManagerChild* manager =
mozilla::layers::CompositorManagerChild::GetInstance();
if (!manager || !StaticPrefs::image_mem_debug_reporting()) {
layers::SharedSurfacesMemoryReport sharedSurfaces;
FinishCollectReports(aHandleReport, aData, aAnonymize, sharedSurfaces);
return NS_OK;
}
RefPtr<imgMemoryReporter> self(this);
nsCOMPtr<nsIHandleReportCallback> handleReport(aHandleReport);
nsCOMPtr<nsISupports> data(aData);
manager->SendReportSharedSurfacesMemory(
[=](layers::SharedSurfacesMemoryReport aReport) {
self->FinishCollectReports(handleReport, data, aAnonymize, aReport);
},
[=](mozilla::ipc::ResponseRejectReason&& aReason) {
layers::SharedSurfacesMemoryReport sharedSurfaces;
self->FinishCollectReports(handleReport, data, aAnonymize,
sharedSurfaces);
});
return NS_OK;
}
void FinishCollectReports(
nsIHandleReportCallback* aHandleReport, nsISupports* aData,
bool aAnonymize, layers::SharedSurfacesMemoryReport& aSharedSurfaces) {
nsTArray<ImageMemoryCounter> chrome;
nsTArray<ImageMemoryCounter> content;
nsTArray<ImageMemoryCounter> uncached;
for (uint32_t i = 0; i < mKnownLoaders.Length(); i++) {
for (auto iter = mKnownLoaders[i]->mChromeCache.Iter(); !iter.Done();
iter.Next()) {
imgCacheEntry* entry = iter.UserData();
RefPtr<imgRequest> req = entry->GetRequest();
RecordCounterForRequest(req, &chrome, !entry->HasNoProxies());
}
for (auto iter = mKnownLoaders[i]->mCache.Iter(); !iter.Done();
iter.Next()) {
imgCacheEntry* entry = iter.UserData();
RefPtr<imgRequest> req = entry->GetRequest();
RecordCounterForRequest(req, &content, !entry->HasNoProxies());
}
MutexAutoLock lock(mKnownLoaders[i]->mUncachedImagesMutex);
for (auto iter = mKnownLoaders[i]->mUncachedImages.Iter(); !iter.Done();
iter.Next()) {
nsPtrHashKey<imgRequest>* entry = iter.Get();
RefPtr<imgRequest> req = entry->GetKey();
RecordCounterForRequest(req, &uncached, req->HasConsumers());
}
}
// Note that we only need to anonymize content image URIs.
ReportCounterArray(aHandleReport, aData, chrome, "images/chrome",
/* aAnonymize */ false, aSharedSurfaces);
ReportCounterArray(aHandleReport, aData, content, "images/content",
aAnonymize, aSharedSurfaces);
// Uncached images may be content or chrome, so anonymize them.
ReportCounterArray(aHandleReport, aData, uncached, "images/uncached",
aAnonymize, aSharedSurfaces);
// Report any shared surfaces that were not merged with the surface cache.
ImageMemoryReporter::ReportSharedSurfaces(aHandleReport, aData,
aSharedSurfaces);
nsCOMPtr<nsIMemoryReporterManager> imgr =
do_GetService("@mozilla.org/memory-reporter-manager;1");
if (imgr) {
imgr->EndReport();
}
}
static int64_t ImagesContentUsedUncompressedDistinguishedAmount() {
size_t n = 0;
for (uint32_t i = 0; i < imgLoader::sMemReporter->mKnownLoaders.Length();
i++) {
for (auto iter = imgLoader::sMemReporter->mKnownLoaders[i]->mCache.Iter();
!iter.Done(); iter.Next()) {
imgCacheEntry* entry = iter.UserData();
if (entry->HasNoProxies()) {
continue;
}
RefPtr<imgRequest> req = entry->GetRequest();
RefPtr<image::Image> image = req->GetImage();
if (!image) {
continue;
}
// Both this and EntryImageSizes measure
// images/content/raster/used/decoded memory. This function's
// measurement is secondary -- the result doesn't go in the "explicit"
// tree -- so we use moz_malloc_size_of instead of ImagesMallocSizeOf to
// prevent DMD from seeing it reported twice.
SizeOfState state(moz_malloc_size_of);
ImageMemoryCounter counter(req, image, state, /* aIsUsed = */ true);
n += counter.Values().DecodedHeap();
n += counter.Values().DecodedNonHeap();
}
}
return n;
}
void RegisterLoader(imgLoader* aLoader) {
mKnownLoaders.AppendElement(aLoader);
}
void UnregisterLoader(imgLoader* aLoader) {
mKnownLoaders.RemoveElement(aLoader);
}
private:
nsTArray<imgLoader*> mKnownLoaders;
struct MemoryTotal {
MemoryTotal& operator+=(const ImageMemoryCounter& aImageCounter) {
if (aImageCounter.Type() == imgIContainer::TYPE_RASTER) {
if (aImageCounter.IsUsed()) {
mUsedRasterCounter += aImageCounter.Values();
} else {
mUnusedRasterCounter += aImageCounter.Values();
}
} else if (aImageCounter.Type() == imgIContainer::TYPE_VECTOR) {
if (aImageCounter.IsUsed()) {
mUsedVectorCounter += aImageCounter.Values();
} else {
mUnusedVectorCounter += aImageCounter.Values();
}
} else if (aImageCounter.Type() == imgIContainer::TYPE_REQUEST) {
// Nothing to do, we did not get to the point of having an image.
} else {
MOZ_CRASH("Unexpected image type");
}
return *this;
}
const MemoryCounter& UsedRaster() const { return mUsedRasterCounter; }
const MemoryCounter& UnusedRaster() const { return mUnusedRasterCounter; }
const MemoryCounter& UsedVector() const { return mUsedVectorCounter; }
const MemoryCounter& UnusedVector() const { return mUnusedVectorCounter; }
private:
MemoryCounter mUsedRasterCounter;
MemoryCounter mUnusedRasterCounter;
MemoryCounter mUsedVectorCounter;
MemoryCounter mUnusedVectorCounter;
};
// Reports all images of a single kind, e.g. all used chrome images.
void ReportCounterArray(nsIHandleReportCallback* aHandleReport,
nsISupports* aData,
nsTArray<ImageMemoryCounter>& aCounterArray,
const char* aPathPrefix, bool aAnonymize,
layers::SharedSurfacesMemoryReport& aSharedSurfaces) {
MemoryTotal summaryTotal;
MemoryTotal nonNotableTotal;
// Report notable images, and compute total and non-notable aggregate sizes.
for (uint32_t i = 0; i < aCounterArray.Length(); i++) {
ImageMemoryCounter& counter = aCounterArray[i];
if (aAnonymize) {
counter.URI().Truncate();
counter.URI().AppendPrintf("<anonymized-%u>", i);
} else {
// The URI could be an extremely long data: URI. Truncate if needed.
static const size_t max = 256;
if (counter.URI().Length() > max) {
counter.URI().Truncate(max);
counter.URI().AppendLiteral(" (truncated)");
}
counter.URI().ReplaceChar('/', '\\');
}
summaryTotal += counter;
if (counter.IsNotable() || StaticPrefs::image_mem_debug_reporting()) {
ReportImage(aHandleReport, aData, aPathPrefix, counter,
aSharedSurfaces);
} else {
ImageMemoryReporter::TrimSharedSurfaces(counter, aSharedSurfaces);
nonNotableTotal += counter;
}
}
// Report non-notable images in aggregate.
ReportTotal(aHandleReport, aData, /* aExplicit = */ true, aPathPrefix,
"<non-notable images>/", nonNotableTotal);
// Report a summary in aggregate, outside of the explicit tree.
ReportTotal(aHandleReport, aData, /* aExplicit = */ false, aPathPrefix, "",
summaryTotal);
}
static void ReportImage(nsIHandleReportCallback* aHandleReport,
nsISupports* aData, const char* aPathPrefix,
const ImageMemoryCounter& aCounter,
layers::SharedSurfacesMemoryReport& aSharedSurfaces) {
nsAutoCString pathPrefix(NS_LITERAL_CSTRING("explicit/"));
pathPrefix.Append(aPathPrefix);
switch (aCounter.Type()) {
case imgIContainer::TYPE_RASTER:
pathPrefix.AppendLiteral("/raster/");
break;
case imgIContainer::TYPE_VECTOR:
pathPrefix.AppendLiteral("/vector/");
break;
case imgIContainer::TYPE_REQUEST:
pathPrefix.AppendLiteral("/request/");
break;
default:
pathPrefix.AppendLiteral("/unknown=");
pathPrefix.AppendInt(aCounter.Type());
pathPrefix.AppendLiteral("/");
break;
}
pathPrefix.Append(aCounter.IsUsed() ? "used/" : "unused/");
if (aCounter.IsValidating()) {
pathPrefix.AppendLiteral("validating/");
}
if (aCounter.HasError()) {
pathPrefix.AppendLiteral("err/");
}
pathPrefix.AppendLiteral("progress=");
pathPrefix.AppendInt(aCounter.Progress(), 16);
pathPrefix.AppendLiteral("/");
pathPrefix.AppendLiteral("image(");
pathPrefix.AppendInt(aCounter.IntrinsicSize().width);
pathPrefix.AppendLiteral("x");
pathPrefix.AppendInt(aCounter.IntrinsicSize().height);
pathPrefix.AppendLiteral(", ");
if (aCounter.URI().IsEmpty()) {
pathPrefix.AppendLiteral("<unknown URI>");
} else {
pathPrefix.Append(aCounter.URI());
}
pathPrefix.AppendLiteral(")/");
ReportSurfaces(aHandleReport, aData, pathPrefix, aCounter, aSharedSurfaces);
ReportSourceValue(aHandleReport, aData, pathPrefix, aCounter.Values());
}
static void ReportSurfaces(
nsIHandleReportCallback* aHandleReport, nsISupports* aData,
const nsACString& aPathPrefix, const ImageMemoryCounter& aCounter,
layers::SharedSurfacesMemoryReport& aSharedSurfaces) {
for (const SurfaceMemoryCounter& counter : aCounter.Surfaces()) {
nsAutoCString surfacePathPrefix(aPathPrefix);
if (counter.IsLocked()) {
surfacePathPrefix.AppendLiteral("locked/");
} else {
surfacePathPrefix.AppendLiteral("unlocked/");
}
if (counter.IsFactor2()) {
surfacePathPrefix.AppendLiteral("factor2/");
}
if (counter.CannotSubstitute()) {
surfacePathPrefix.AppendLiteral("cannot_substitute/");
}
surfacePathPrefix.AppendLiteral("surface(");
surfacePathPrefix.AppendInt(counter.Key().Size().width);
surfacePathPrefix.AppendLiteral("x");
surfacePathPrefix.AppendInt(counter.Key().Size().height);
if (!counter.IsFinished()) {
surfacePathPrefix.AppendLiteral(", incomplete");
}
if (counter.Values().ExternalHandles() > 0) {
surfacePathPrefix.AppendLiteral(", handles:");
surfacePathPrefix.AppendInt(
uint32_t(counter.Values().ExternalHandles()));
}
ImageMemoryReporter::AppendSharedSurfacePrefix(surfacePathPrefix, counter,
aSharedSurfaces);
if (counter.Type() == SurfaceMemoryCounterType::NORMAL) {
PlaybackType playback = counter.Key().Playback();
if (playback == PlaybackType::eAnimated) {
if (StaticPrefs::image_mem_debug_reporting()) {
surfacePathPrefix.AppendPrintf(
" (animation %4u)", uint32_t(counter.Values().FrameIndex()));
} else {
surfacePathPrefix.AppendLiteral(" (animation)");
}
}
if (counter.Key().Flags() != DefaultSurfaceFlags()) {
surfacePathPrefix.AppendLiteral(", flags:");
surfacePathPrefix.AppendInt(uint32_t(counter.Key().Flags()),
/* aRadix = */ 16);
}
if (counter.Key().SVGContext()) {
const SVGImageContext& context = counter.Key().SVGContext().ref();
surfacePathPrefix.AppendLiteral(", svgContext:[ ");
if (context.GetViewportSize()) {
const CSSIntSize& size = context.GetViewportSize().ref();
surfacePathPrefix.AppendLiteral("viewport=(");
surfacePathPrefix.AppendInt(size.width);
surfacePathPrefix.AppendLiteral("x");
surfacePathPrefix.AppendInt(size.height);
surfacePathPrefix.AppendLiteral(") ");
}
if (context.GetPreserveAspectRatio()) {
nsAutoString aspect;
context.GetPreserveAspectRatio()->ToString(aspect);
surfacePathPrefix.AppendLiteral("preserveAspectRatio=(");
LossyAppendUTF16toASCII(aspect, surfacePathPrefix);
surfacePathPrefix.AppendLiteral(") ");
}
if (context.GetContextPaint()) {
const SVGEmbeddingContextPaint* paint = context.GetContextPaint();
surfacePathPrefix.AppendLiteral("contextPaint=(");
if (paint->GetFill()) {
surfacePathPrefix.AppendLiteral(" fill=");
surfacePathPrefix.AppendInt(paint->GetFill()->ToABGR(), 16);
}
if (paint->GetFillOpacity()) {
surfacePathPrefix.AppendLiteral(" fillOpa=");
surfacePathPrefix.AppendFloat(paint->GetFillOpacity());
}
if (paint->GetStroke()) {
surfacePathPrefix.AppendLiteral(" stroke=");
surfacePathPrefix.AppendInt(paint->GetStroke()->ToABGR(), 16);
}
if (paint->GetStrokeOpacity()) {
surfacePathPrefix.AppendLiteral(" strokeOpa=");
surfacePathPrefix.AppendFloat(paint->GetStrokeOpacity());
}
surfacePathPrefix.AppendLiteral(" ) ");
}
surfacePathPrefix.AppendLiteral("]");
}
} else if (counter.Type() == SurfaceMemoryCounterType::COMPOSITING) {
surfacePathPrefix.AppendLiteral(", compositing frame");
} else if (counter.Type() == SurfaceMemoryCounterType::COMPOSITING_PREV) {
surfacePathPrefix.AppendLiteral(", compositing prev frame");
} else {
MOZ_ASSERT_UNREACHABLE("Unknown counter type");
}
surfacePathPrefix.AppendLiteral(")/");
ReportValues(aHandleReport, aData, surfacePathPrefix, counter.Values());
}
}
static void ReportTotal(nsIHandleReportCallback* aHandleReport,
nsISupports* aData, bool aExplicit,
const char* aPathPrefix, const char* aPathInfix,
const MemoryTotal& aTotal) {
nsAutoCString pathPrefix;
if (aExplicit) {
pathPrefix.AppendLiteral("explicit/");
}
pathPrefix.Append(aPathPrefix);
nsAutoCString rasterUsedPrefix(pathPrefix);
rasterUsedPrefix.AppendLiteral("/raster/used/");
rasterUsedPrefix.Append(aPathInfix);
ReportValues(aHandleReport, aData, rasterUsedPrefix, aTotal.UsedRaster());
nsAutoCString rasterUnusedPrefix(pathPrefix);
rasterUnusedPrefix.AppendLiteral("/raster/unused/");
rasterUnusedPrefix.Append(aPathInfix);
ReportValues(aHandleReport, aData, rasterUnusedPrefix,
aTotal.UnusedRaster());
nsAutoCString vectorUsedPrefix(pathPrefix);
vectorUsedPrefix.AppendLiteral("/vector/used/");
vectorUsedPrefix.Append(aPathInfix);
ReportValues(aHandleReport, aData, vectorUsedPrefix, aTotal.UsedVector());
nsAutoCString vectorUnusedPrefix(pathPrefix);
vectorUnusedPrefix.AppendLiteral("/vector/unused/");
vectorUnusedPrefix.Append(aPathInfix);
ReportValues(aHandleReport, aData, vectorUnusedPrefix,
aTotal.UnusedVector());
}
static void ReportValues(nsIHandleReportCallback* aHandleReport,
nsISupports* aData, const nsACString& aPathPrefix,
const MemoryCounter& aCounter) {
ReportSourceValue(aHandleReport, aData, aPathPrefix, aCounter);
ReportValue(aHandleReport, aData, KIND_HEAP, aPathPrefix, "decoded-heap",
"Decoded image data which is stored on the heap.",
aCounter.DecodedHeap());
ReportValue(aHandleReport, aData, KIND_NONHEAP, aPathPrefix,
"decoded-nonheap",
"Decoded image data which isn't stored on the heap.",
aCounter.DecodedNonHeap());
}
static void ReportSourceValue(nsIHandleReportCallback* aHandleReport,
nsISupports* aData,
const nsACString& aPathPrefix,
const MemoryCounter& aCounter) {
ReportValue(aHandleReport, aData, KIND_HEAP, aPathPrefix, "source",
"Raster image source data and vector image documents.",
aCounter.Source());
}
static void ReportValue(nsIHandleReportCallback* aHandleReport,
nsISupports* aData, int32_t aKind,
const nsACString& aPathPrefix,
const char* aPathSuffix, const char* aDescription,
size_t aValue) {
if (aValue == 0) {
return;
}
nsAutoCString desc(aDescription);
nsAutoCString path(aPathPrefix);
path.Append(aPathSuffix);
aHandleReport->Callback(EmptyCString(), path, aKind, UNITS_BYTES, aValue,
desc, aData);
}
static void RecordCounterForRequest(imgRequest* aRequest,
nsTArray<ImageMemoryCounter>* aArray,
bool aIsUsed) {
SizeOfState state(ImagesMallocSizeOf);
RefPtr<image::Image> image = aRequest->GetImage();
if (image) {
ImageMemoryCounter counter(aRequest, image, state, aIsUsed);
aArray->AppendElement(std::move(counter));
} else {
// We can at least record some information about the image from the
// request, and mark it as not knowing the image type yet.
ImageMemoryCounter counter(aRequest, state, aIsUsed);
aArray->AppendElement(std::move(counter));
}
}
};
NS_IMPL_ISUPPORTS(imgMemoryReporter, nsIMemoryReporter)
NS_IMPL_ISUPPORTS(nsProgressNotificationProxy, nsIProgressEventSink,
nsIChannelEventSink, nsIInterfaceRequestor)
NS_IMETHODIMP
nsProgressNotificationProxy::OnProgress(nsIRequest* request, nsISupports* ctxt,
int64_t progress, int64_t progressMax) {
nsCOMPtr<nsILoadGroup> loadGroup;
request->GetLoadGroup(getter_AddRefs(loadGroup));
nsCOMPtr<nsIProgressEventSink> target;
NS_QueryNotificationCallbacks(mOriginalCallbacks, loadGroup,
NS_GET_IID(nsIProgressEventSink),
getter_AddRefs(target));
if (!target) {
return NS_OK;
}
return target->OnProgress(mImageRequest, ctxt, progress, progressMax);
}
NS_IMETHODIMP
nsProgressNotificationProxy::OnStatus(nsIRequest* request, nsISupports* ctxt,
nsresult status,
const char16_t* statusArg) {
nsCOMPtr<nsILoadGroup> loadGroup;
request->GetLoadGroup(getter_AddRefs(loadGroup));
nsCOMPtr<nsIProgressEventSink> target;
NS_QueryNotificationCallbacks(mOriginalCallbacks, loadGroup,
NS_GET_IID(nsIProgressEventSink),
getter_AddRefs(target));
if (!target) {
return NS_OK;
}
return target->OnStatus(mImageRequest, ctxt, status, statusArg);
}
NS_IMETHODIMP
nsProgressNotificationProxy::AsyncOnChannelRedirect(
nsIChannel* oldChannel, nsIChannel* newChannel, uint32_t flags,
nsIAsyncVerifyRedirectCallback* cb) {
// Tell the original original callbacks about it too
nsCOMPtr<nsILoadGroup> loadGroup;
newChannel->GetLoadGroup(getter_AddRefs(loadGroup));
nsCOMPtr<nsIChannelEventSink> target;
NS_QueryNotificationCallbacks(mOriginalCallbacks, loadGroup,
NS_GET_IID(nsIChannelEventSink),
getter_AddRefs(target));
if (!target) {
cb->OnRedirectVerifyCallback(NS_OK);
return NS_OK;
}
// Delegate to |target| if set, reusing |cb|
return target->AsyncOnChannelRedirect(oldChannel, newChannel, flags, cb);
}
NS_IMETHODIMP
nsProgressNotificationProxy::GetInterface(const nsIID& iid, void** result) {
if (iid.Equals(NS_GET_IID(nsIProgressEventSink))) {
*result = static_cast<nsIProgressEventSink*>(this);
NS_ADDREF_THIS();
return NS_OK;
}
if (iid.Equals(NS_GET_IID(nsIChannelEventSink))) {
*result = static_cast<nsIChannelEventSink*>(this);
NS_ADDREF_THIS();
return NS_OK;
}
if (mOriginalCallbacks) {
return mOriginalCallbacks->GetInterface(iid, result);
}
return NS_NOINTERFACE;
}
static void NewRequestAndEntry(bool aForcePrincipalCheckForCacheEntry,
imgLoader* aLoader, const ImageCacheKey& aKey,
imgRequest** aRequest, imgCacheEntry** aEntry) {
RefPtr<imgRequest> request = new imgRequest(aLoader, aKey);
RefPtr<imgCacheEntry> entry =
new imgCacheEntry(aLoader, request, aForcePrincipalCheckForCacheEntry);
aLoader->AddToUncachedImages(request);
request.forget(aRequest);
entry.forget(aEntry);
}
static bool ShouldRevalidateEntry(imgCacheEntry* aEntry, nsLoadFlags aFlags,
bool aHasExpired) {
bool bValidateEntry = false;
if (aFlags & nsIRequest::LOAD_BYPASS_CACHE) {
return false;
}
if (aFlags & nsIRequest::VALIDATE_ALWAYS) {
bValidateEntry = true;
} else if (aEntry->GetMustValidate()) {
bValidateEntry = true;
} else if (aHasExpired) {
// The cache entry has expired... Determine whether the stale cache
// entry can be used without validation...
if (aFlags &
(nsIRequest::VALIDATE_NEVER | nsIRequest::VALIDATE_ONCE_PER_SESSION)) {
// VALIDATE_NEVER and VALIDATE_ONCE_PER_SESSION allow stale cache
// entries to be used unless they have been explicitly marked to
// indicate that revalidation is necessary.
bValidateEntry = false;
} else if (!(aFlags & nsIRequest::LOAD_FROM_CACHE)) {
// LOAD_FROM_CACHE allows a stale cache entry to be used... Otherwise,
// the entry must be revalidated.
bValidateEntry = true;
}
}
return bValidateEntry;
}
/* Call content policies on cached images that went through a redirect */
static bool ShouldLoadCachedImage(imgRequest* aImgRequest,
nsISupports* aLoadingContext,
nsIPrincipal* aTriggeringPrincipal,
nsContentPolicyType aPolicyType,
bool aSendCSPViolationReports) {
/* Call content policies on cached images - Bug 1082837
* Cached images are keyed off of the first uri in a redirect chain.
* Hence content policies don't get a chance to test the intermediate hops
* or the final desitnation. Here we test the final destination using
* mFinalURI off of the imgRequest and passing it into content policies.
* For Mixed Content Blocker, we do an additional check to determine if any
* of the intermediary hops went through an insecure redirect with the
* mHadInsecureRedirect flag
*/
bool insecureRedirect = aImgRequest->HadInsecureRedirect();
nsCOMPtr<nsIURI> contentLocation;
aImgRequest->GetFinalURI(getter_AddRefs(contentLocation));
nsresult rv;
nsCOMPtr<nsINode> requestingNode = do_QueryInterface(aLoadingContext);
nsCOMPtr<nsIPrincipal> loadingPrincipal =
requestingNode ? requestingNode->NodePrincipal() : aTriggeringPrincipal;
// If there is no context and also no triggeringPrincipal, then we use a fresh
// nullPrincipal as the loadingPrincipal because we can not create a loadinfo
// without a valid loadingPrincipal.
if (!loadingPrincipal) {
loadingPrincipal = NullPrincipal::CreateWithoutOriginAttributes();
}
nsCOMPtr<nsILoadInfo> secCheckLoadInfo = new LoadInfo(
loadingPrincipal, aTriggeringPrincipal, requestingNode,
nsILoadInfo::SEC_ONLY_FOR_EXPLICIT_CONTENTSEC_CHECK, aPolicyType);
secCheckLoadInfo->SetSendCSPViolationEvents(aSendCSPViolationReports);
int16_t decision = nsIContentPolicy::REJECT_REQUEST;
rv = NS_CheckContentLoadPolicy(contentLocation, secCheckLoadInfo,
EmptyCString(), // mime guess
&decision, nsContentUtils::GetContentPolicy());
if (NS_FAILED(rv) || !NS_CP_ACCEPTED(decision)) {
return false;
}
// We call all Content Policies above, but we also have to call mcb
// individually to check the intermediary redirect hops are secure.
if (insecureRedirect) {
// Bug 1314356: If the image ended up in the cache upgraded by HSTS and the
// page uses upgrade-inscure-requests it had an insecure redirect
// (http->https). We need to invalidate the image and reload it because
// mixed content blocker only bails if upgrade-insecure-requests is set on
// the doc and the resource load is http: which would result in an incorrect
// mixed content warning.
nsCOMPtr<nsIDocShell> docShell =
NS_CP_GetDocShellFromContext(aLoadingContext);
if (docShell) {
Document* document = docShell->GetDocument();
if (document && document->GetUpgradeInsecureRequests(false)) {
return false;
}
}
if (!aTriggeringPrincipal || !aTriggeringPrincipal->IsSystemPrincipal()) {
// Set the requestingLocation from the aTriggeringPrincipal.
nsCOMPtr<nsIURI> requestingLocation;
if (aTriggeringPrincipal) {
rv = aTriggeringPrincipal->GetURI(getter_AddRefs(requestingLocation));
NS_ENSURE_SUCCESS(rv, false);
}
// reset the decision for mixed content blocker check
decision = nsIContentPolicy::REJECT_REQUEST;
rv = nsMixedContentBlocker::ShouldLoad(
insecureRedirect, aPolicyType, contentLocation, requestingLocation,
aLoadingContext,
EmptyCString(), // mime guess
aTriggeringPrincipal, &decision);
if (NS_FAILED(rv) || !NS_CP_ACCEPTED(decision)) {
return false;
}
}
}
return true;
}
// Returns true if this request is compatible with the given CORS mode on the
// given loading principal, and false if the request may not be reused due
// to CORS. Also checks the Referrer Policy, since requests with different
// referrers/policies may generate different responses.
static bool ValidateSecurityInfo(imgRequest* request, bool forcePrincipalCheck,
int32_t corsmode,
nsIPrincipal* triggeringPrincipal,
nsISupports* aCX,
nsContentPolicyType aPolicyType,
nsIReferrerInfo* aReferrerInfo) {
// If the referrer policy doesn't match, we can't use this request.
// XXX: Note that we only validate referrer policy, not referrerInfo object.
// We should do with referrerInfo object, but it will cause us to use more
// resources in the common case (the same policies but different original
// referrers).
// XXX: this will return false if an image has different referrer attributes,
// i.e. we currently don't use the cached image but reload the image with
// the new referrer policy bug 1174921
ReferrerPolicy referrerPolicy = ReferrerPolicy::_empty;
if (aReferrerInfo) {
referrerPolicy = aReferrerInfo->ReferrerPolicy();
}
ReferrerPolicy requestReferrerPolicy = ReferrerPolicy::_empty;
if (request->GetReferrerInfo()) {
requestReferrerPolicy = request->GetReferrerInfo()->ReferrerPolicy();
}
if (referrerPolicy != requestReferrerPolicy) {
return false;
}
// If the entry's CORS mode doesn't match, or the CORS mode matches but the
// document principal isn't the same, we can't use this request.
if (request->GetCORSMode() != corsmode) {
return false;
}
if (request->GetCORSMode() != imgIRequest::CORS_NONE || forcePrincipalCheck) {
nsCOMPtr<nsIPrincipal> otherprincipal = request->GetTriggeringPrincipal();
// If we previously had a principal, but we don't now, we can't use this
// request.
if (otherprincipal && !triggeringPrincipal) {
return false;
}
if (otherprincipal && triggeringPrincipal) {
bool equals = false;
otherprincipal->Equals(triggeringPrincipal, &equals);
if (!equals) {
return false;
}
}
}
// Content Policy Check on Cached Images
return ShouldLoadCachedImage(request, aCX, triggeringPrincipal, aPolicyType,
/* aSendCSPViolationReports */ false);
}
static nsresult NewImageChannel(
nsIChannel** aResult,
// If aForcePrincipalCheckForCacheEntry is true, then we will
// force a principal check even when not using CORS before
// assuming we have a cache hit on a cache entry that we
// create for this channel. This is an out param that should
// be set to true if this channel ends up depending on
// aTriggeringPrincipal and false otherwise.
bool* aForcePrincipalCheckForCacheEntry, nsIURI* aURI,
nsIURI* aInitialDocumentURI, int32_t aCORSMode,
nsIReferrerInfo* aReferrerInfo, nsILoadGroup* aLoadGroup,
const nsCString& aAcceptHeader, nsLoadFlags aLoadFlags,
nsContentPolicyType aPolicyType, nsIPrincipal* aTriggeringPrincipal,
nsISupports* aRequestingContext, bool aRespectPrivacy) {
MOZ_ASSERT(aResult);
nsresult rv;
nsCOMPtr<nsIHttpChannel> newHttpChannel;
nsCOMPtr<nsIInterfaceRequestor> callbacks;
if (aLoadGroup) {
// Get the notification callbacks from the load group for the new channel.
//
// XXX: This is not exactly correct, because the network request could be
// referenced by multiple windows... However, the new channel needs
// something. So, using the 'first' notification callbacks is better
// than nothing...
//
aLoadGroup->GetNotificationCallbacks(getter_AddRefs(callbacks));
}
// Pass in a nullptr loadgroup because this is the underlying network
// request. This request may be referenced by several proxy image requests
// (possibly in different documents).
// If all of the proxy requests are canceled then this request should be
// canceled too.
//
nsCOMPtr<nsINode> requestingNode = do_QueryInterface(aRequestingContext);
nsSecurityFlags securityFlags =
aCORSMode == imgIRequest::CORS_NONE
? nsILoadInfo::SEC_ALLOW_CROSS_ORIGIN_DATA_INHERITS
: nsILoadInfo::SEC_REQUIRE_CORS_DATA_INHERITS;
if (aCORSMode == imgIRequest::CORS_ANONYMOUS) {
securityFlags |= nsILoadInfo::SEC_COOKIES_SAME_ORIGIN;
} else if (aCORSMode == imgIRequest::CORS_USE_CREDENTIALS) {
securityFlags |= nsILoadInfo::SEC_COOKIES_INCLUDE;
}
securityFlags |= nsILoadInfo::SEC_ALLOW_CHROME;
// Note we are calling NS_NewChannelWithTriggeringPrincipal() here with a
// node and a principal. This is for things like background images that are
// specified by user stylesheets, where the document is being styled, but
// the principal is that of the user stylesheet.
if (requestingNode && aTriggeringPrincipal) {
rv = NS_NewChannelWithTriggeringPrincipal(aResult, aURI, requestingNode,
aTriggeringPrincipal,
securityFlags, aPolicyType,
nullptr, // PerformanceStorage
nullptr, // loadGroup
callbacks, aLoadFlags);
if (NS_FAILED(rv)) {
return rv;
}
if (aPolicyType == nsIContentPolicy::TYPE_INTERNAL_IMAGE_FAVICON) {
// If this is a favicon loading, we will use the originAttributes from the
// triggeringPrincipal as the channel's originAttributes. This allows the
// favicon loading from XUL will use the correct originAttributes.
nsCOMPtr<nsILoadInfo> loadInfo = (*aResult)->LoadInfo();
rv = loadInfo->SetOriginAttributes(
aTriggeringPrincipal->OriginAttributesRef());
}
} else {
// either we are loading something inside a document, in which case
// we should always have a requestingNode, or we are loading something
// outside a document, in which case the triggeringPrincipal and
// triggeringPrincipal should always be the systemPrincipal.
// However, there are exceptions: one is Notifications which create a
// channel in the parent process in which case we can't get a
// requestingNode.
rv = NS_NewChannel(aResult, aURI, nsContentUtils::GetSystemPrincipal(),
securityFlags, aPolicyType,
nullptr, // nsICookieSettings
nullptr, // PerformanceStorage
nullptr, // loadGroup
callbacks, aLoadFlags);
if (NS_FAILED(rv)) {
return rv;
}
// Use the OriginAttributes from the loading principal, if one is available,
// and adjust the private browsing ID based on what kind of load the caller
// has asked us to perform.
OriginAttributes attrs;
if (aTriggeringPrincipal) {
attrs = aTriggeringPrincipal->OriginAttributesRef();
}
attrs.mPrivateBrowsingId = aRespectPrivacy ? 1 : 0;
nsCOMPtr<nsILoadInfo> loadInfo = (*aResult)->LoadInfo();
rv = loadInfo->SetOriginAttributes(attrs);
}
if (NS_FAILED(rv)) {
return rv;
}
// only inherit if we have a principal
*aForcePrincipalCheckForCacheEntry =
aTriggeringPrincipal && nsContentUtils::ChannelShouldInheritPrincipal(
aTriggeringPrincipal, aURI,
/* aInheritForAboutBlank */ false,
/* aForceInherit */ false);
// Initialize HTTP-specific attributes
newHttpChannel = do_QueryInterface(*aResult);
if (newHttpChannel) {
rv = newHttpChannel->SetRequestHeader(NS_LITERAL_CSTRING("Accept"),
aAcceptHeader, false);
MOZ_ASSERT(NS_SUCCEEDED(rv));
nsCOMPtr<nsIHttpChannelInternal> httpChannelInternal =
do_QueryInterface(newHttpChannel);
NS_ENSURE_TRUE(httpChannelInternal, NS_ERROR_UNEXPECTED);
rv = httpChannelInternal->SetDocumentURI(aInitialDocumentURI);
MOZ_ASSERT(NS_SUCCEEDED(rv));
if (aReferrerInfo) {
DebugOnly<nsresult> rv = newHttpChannel->SetReferrerInfo(aReferrerInfo);
MOZ_ASSERT(NS_SUCCEEDED(rv));
}
}
// Image channels are loaded by default with reduced priority.
nsCOMPtr<nsISupportsPriority> p = do_QueryInterface(*aResult);
if (p) {
uint32_t priority = nsISupportsPriority::PRIORITY_LOW;
if (aLoadFlags & nsIRequest::LOAD_BACKGROUND) {
++priority; // further reduce priority for background loads
}
p->AdjustPriority(priority);
}
// Create a new loadgroup for this new channel, using the old group as
// the parent. The indirection keeps the channel insulated from cancels,
// but does allow a way for this revalidation to be associated with at
// least one base load group for scheduling/caching purposes.
nsCOMPtr<nsILoadGroup> loadGroup = do_CreateInstance(NS_LOADGROUP_CONTRACTID);
nsCOMPtr<nsILoadGroupChild> childLoadGroup = do_QueryInterface(loadGroup);
if (childLoadGroup) {
childLoadGroup->SetParentLoadGroup(aLoadGroup);
}
(*aResult)->SetLoadGroup(loadGroup);
return NS_OK;
}
/* static */
uint32_t imgCacheEntry::SecondsFromPRTime(PRTime prTime) {
return uint32_t(int64_t(prTime) / int64_t(PR_USEC_PER_SEC));
}
imgCacheEntry::imgCacheEntry(imgLoader* loader, imgRequest* request,
bool forcePrincipalCheck)
: mLoader(loader),
mRequest(request),
mDataSize(0),
mTouchedTime(SecondsFromPRTime(PR_Now())),
mLoadTime(SecondsFromPRTime(PR_Now())),
mExpiryTime(0),
mMustValidate(false),
// We start off as evicted so we don't try to update the cache.
// PutIntoCache will set this to false.
mEvicted(true),
mHasNoProxies(true),
mForcePrincipalCheck(forcePrincipalCheck) {}
imgCacheEntry::~imgCacheEntry() {
LOG_FUNC(gImgLog, "imgCacheEntry::~imgCacheEntry()");
}
void imgCacheEntry::Touch(bool updateTime /* = true */) {
LOG_SCOPE(gImgLog, "imgCacheEntry::Touch");
if (updateTime) {
mTouchedTime = SecondsFromPRTime(PR_Now());
}
UpdateCache();
}
void imgCacheEntry::UpdateCache(int32_t diff /* = 0 */) {
// Don't update the cache if we've been removed from it or it doesn't care
// about our size or usage.
if (!Evicted() && HasNoProxies()) {
mLoader->CacheEntriesChanged(mRequest->IsChrome(), diff);
}
}
void imgCacheEntry::UpdateLoadTime() {
mLoadTime = SecondsFromPRTime(PR_Now());
}
void imgCacheEntry::SetHasNoProxies(bool hasNoProxies) {
if (MOZ_LOG_TEST(gImgLog, LogLevel::Debug)) {
if (hasNoProxies) {
LOG_FUNC_WITH_PARAM(gImgLog, "imgCacheEntry::SetHasNoProxies true", "uri",
mRequest->CacheKey().URI());
} else {
LOG_FUNC_WITH_PARAM(gImgLog, "imgCacheEntry::SetHasNoProxies false",
"uri", mRequest->CacheKey().URI());
}
}
mHasNoProxies = hasNoProxies;
}
imgCacheQueue::imgCacheQueue() : mDirty(false), mSize(0) {}
void imgCacheQueue::UpdateSize(int32_t diff) { mSize += diff; }
uint32_t imgCacheQueue::GetSize() const { return mSize; }
void imgCacheQueue::Remove(imgCacheEntry* entry) {
uint64_t index = mQueue.IndexOf(entry);
if (index == queueContainer::NoIndex) {
return;
}
mSize -= mQueue[index]->GetDataSize();
// If the queue is clean and this is the first entry,
// then we can efficiently remove the entry without
// dirtying the sort order.
if (!IsDirty() && index == 0) {
std::pop_heap(mQueue.begin(), mQueue.end(), imgLoader::CompareCacheEntries);
mQueue.RemoveLastElement();
return;
}
// Remove from the middle of the list. This potentially
// breaks the binary heap sort order.
mQueue.RemoveElementAt(index);
// If we only have one entry or the queue is empty, though,
// then the sort order is still effectively good. Simply
// refresh the list to clear the dirty flag.
if (mQueue.Length() <= 1) {
Refresh();
return;
}
// Otherwise we must mark the queue dirty and potentially
// trigger an expensive sort later.
MarkDirty();
}
void imgCacheQueue::Push(imgCacheEntry* entry) {
mSize += entry->GetDataSize();
RefPtr<imgCacheEntry> refptr(entry);
mQueue.AppendElement(std::move(refptr));
// If we're not dirty already, then we can efficiently add this to the
// binary heap immediately. This is only O(log n).
if (!IsDirty()) {
std::push_heap(mQueue.begin(), mQueue.end(),
imgLoader::CompareCacheEntries);
}
}
already_AddRefed<imgCacheEntry> imgCacheQueue::Pop() {
if (mQueue.IsEmpty()) {
return nullptr;
}
if (IsDirty()) {
Refresh();
}
std::pop_heap(mQueue.begin(), mQueue.end(), imgLoader::CompareCacheEntries);
RefPtr<imgCacheEntry> entry = mQueue.PopLastElement();
mSize -= entry->GetDataSize();
return entry.forget();
}
void imgCacheQueue::Refresh() {
// Resort the list. This is an O(3 * n) operation and best avoided
// if possible.
std::make_heap(mQueue.begin(), mQueue.end(), imgLoader::CompareCacheEntries);
mDirty = false;
}
void imgCacheQueue::MarkDirty() { mDirty = true; }
bool imgCacheQueue::IsDirty() { return mDirty; }
uint32_t imgCacheQueue::GetNumElements() const { return mQueue.Length(); }
bool imgCacheQueue::Contains(imgCacheEntry* aEntry) const {
return mQueue.Contains(aEntry);
}
imgCacheQueue::iterator imgCacheQueue::begin() { return mQueue.begin(); }
imgCacheQueue::const_iterator imgCacheQueue::begin() const {
return mQueue.begin();
}
imgCacheQueue::iterator imgCacheQueue::end() { return mQueue.end(); }
imgCacheQueue::const_iterator imgCacheQueue::end() const {
return mQueue.end();
}
nsresult imgLoader::CreateNewProxyForRequest(
imgRequest* aRequest, nsILoadGroup* aLoadGroup, Document* aLoadingDocument,
imgINotificationObserver* aObserver, nsLoadFlags aLoadFlags,
imgRequestProxy** _retval) {
LOG_SCOPE_WITH_PARAM(gImgLog, "imgLoader::CreateNewProxyForRequest",
"imgRequest", aRequest);
/* XXX If we move decoding onto separate threads, we should save off the
calling thread here and pass it off to |proxyRequest| so that it call
proxy calls to |aObserver|.
*/
RefPtr<imgRequestProxy> proxyRequest = new imgRequestProxy();
/* It is important to call |SetLoadFlags()| before calling |Init()| because
|Init()| adds the request to the loadgroup.
*/
proxyRequest->SetLoadFlags(aLoadFlags);
nsCOMPtr<nsIURI> uri;
aRequest->GetURI(getter_AddRefs(uri));
// init adds itself to imgRequest's list of observers
nsresult rv = proxyRequest->Init(aRequest, aLoadGroup, aLoadingDocument, uri,
aObserver);
if (NS_WARN_IF(NS_FAILED(rv))) {
return rv;
}
proxyRequest.forget(_retval);
return NS_OK;
}
class imgCacheExpirationTracker final
: public nsExpirationTracker<imgCacheEntry, 3> {
enum { TIMEOUT_SECONDS = 10 };
public:
imgCacheExpirationTracker();
protected:
void NotifyExpired(imgCacheEntry* entry) override;
};
imgCacheExpirationTracker::imgCacheExpirationTracker()
: nsExpirationTracker<imgCacheEntry, 3>(
TIMEOUT_SECONDS * 1000, "imgCacheExpirationTracker",
SystemGroup::EventTargetFor(TaskCategory::Other)) {}
void imgCacheExpirationTracker::NotifyExpired(imgCacheEntry* entry) {
// Hold on to a reference to this entry, because the expiration tracker
// mechanism doesn't.
RefPtr<imgCacheEntry> kungFuDeathGrip(entry);
if (MOZ_LOG_TEST(gImgLog, LogLevel::Debug)) {
RefPtr<imgRequest> req = entry->GetRequest();
if (req) {
LOG_FUNC_WITH_PARAM(gImgLog, "imgCacheExpirationTracker::NotifyExpired",
"entry", req->CacheKey().URI());
}
}
// We can be called multiple times on the same entry. Don't do work multiple
// times.
if (!entry->Evicted()) {
entry->Loader()->RemoveFromCache(entry);
}
entry->Loader()->VerifyCacheSizes();
}
///////////////////////////////////////////////////////////////////////////////
// imgLoader
///////////////////////////////////////////////////////////////////////////////
double imgLoader::sCacheTimeWeight;
uint32_t imgLoader::sCacheMaxSize;
imgMemoryReporter* imgLoader::sMemReporter;
NS_IMPL_ISUPPORTS(imgLoader, imgILoader, nsIContentSniffer, imgICache,
nsISupportsWeakReference, nsIObserver)
static imgLoader* gNormalLoader = nullptr;
static imgLoader* gPrivateBrowsingLoader = nullptr;
/* static */
already_AddRefed<imgLoader> imgLoader::CreateImageLoader() {
// In some cases, such as xpctests, XPCOM modules are not automatically
// initialized. We need to make sure that our module is initialized before
// we hand out imgLoader instances and code starts using them.
mozilla::image::EnsureModuleInitialized();
RefPtr<imgLoader> loader = new imgLoader();
loader->Init();
return loader.forget();
}
imgLoader* imgLoader::NormalLoader() {
if (!gNormalLoader) {
gNormalLoader = CreateImageLoader().take();
}
return gNormalLoader;
}
imgLoader* imgLoader::PrivateBrowsingLoader() {
if (!gPrivateBrowsingLoader) {
gPrivateBrowsingLoader = CreateImageLoader().take();
gPrivateBrowsingLoader->RespectPrivacyNotifications();
}
return gPrivateBrowsingLoader;
}
imgLoader::imgLoader()
: mUncachedImagesMutex("imgLoader::UncachedImages"),
mRespectPrivacy(false) {
sMemReporter->AddRef();
sMemReporter->RegisterLoader(this);
}
imgLoader::~imgLoader() {
ClearChromeImageCache();
ClearImageCache();
{
// If there are any of our imgRequest's left they are in the uncached
// images set, so clear their pointer to us.
MutexAutoLock lock(mUncachedImagesMutex);
for (auto iter = mUncachedImages.Iter(); !iter.Done(); iter.Next()) {
nsPtrHashKey<imgRequest>* entry = iter.Get();
RefPtr<imgRequest> req = entry->GetKey();
req->ClearLoader();
}
}
sMemReporter->UnregisterLoader(this);
sMemReporter->Release();
}
void imgLoader::VerifyCacheSizes() {
#ifdef DEBUG
if (!mCacheTracker) {
return;
}
uint32_t cachesize = mCache.Count() + mChromeCache.Count();
uint32_t queuesize =
mCacheQueue.GetNumElements() + mChromeCacheQueue.GetNumElements();
uint32_t trackersize = 0;
for (nsExpirationTracker<imgCacheEntry, 3>::Iterator it(mCacheTracker.get());
it.Next();) {
trackersize++;
}
MOZ_ASSERT(queuesize == trackersize, "Queue and tracker sizes out of sync!");
MOZ_ASSERT(queuesize <= cachesize, "Queue has more elements than cache!");
#endif
}
imgLoader::imgCacheTable& imgLoader::GetCache(bool aForChrome) {
return aForChrome ? mChromeCache : mCache;
}
imgLoader::imgCacheTable& imgLoader::GetCache(const ImageCacheKey& aKey) {
return GetCache(aKey.IsChrome());
}
imgCacheQueue& imgLoader::GetCacheQueue(bool aForChrome) {
return aForChrome ? mChromeCacheQueue : mCacheQueue;
}
imgCacheQueue& imgLoader::GetCacheQueue(const ImageCacheKey& aKey) {
return GetCacheQueue(aKey.IsChrome());
}
void imgLoader::GlobalInit() {
sCacheTimeWeight = StaticPrefs::image_cache_timeweight_AtStartup() / 1000.0;
int32_t cachesize = StaticPrefs::image_cache_size_AtStartup();
sCacheMaxSize = cachesize > 0 ? cachesize : 0;
sMemReporter = new imgMemoryReporter();
RegisterStrongAsyncMemoryReporter(sMemReporter);
RegisterImagesContentUsedUncompressedDistinguishedAmount(
imgMemoryReporter::ImagesContentUsedUncompressedDistinguishedAmount);
}
void imgLoader::ShutdownMemoryReporter() {
UnregisterImagesContentUsedUncompressedDistinguishedAmount();
UnregisterStrongMemoryReporter(sMemReporter);
}
nsresult imgLoader::InitCache() {
nsCOMPtr<nsIObserverService> os = mozilla::services::GetObserverService();
if (!os) {
return NS_ERROR_FAILURE;
}
os->AddObserver(this, "memory-pressure", false);
os->AddObserver(this, "chrome-flush-caches", false);
os->AddObserver(this, "last-pb-context-exited", false);
os->AddObserver(this, "profile-before-change", false);
os->AddObserver(this, "xpcom-shutdown", false);
mCacheTracker = MakeUnique<imgCacheExpirationTracker>();
return NS_OK;
}
nsresult imgLoader::Init() {
InitCache();
ReadAcceptHeaderPref();
Preferences::AddWeakObserver(this, "image.http.accept");
return NS_OK;
}
NS_IMETHODIMP
imgLoader::RespectPrivacyNotifications() {
mRespectPrivacy = true;
return NS_OK;
}
NS_IMETHODIMP
imgLoader::Observe(nsISupports* aSubject, const char* aTopic,
const char16_t* aData) {
// We listen for pref change notifications...
if (!strcmp(aTopic, NS_PREFBRANCH_PREFCHANGE_TOPIC_ID)) {
if (!NS_strcmp(aData, u"image.http.accept")) {
ReadAcceptHeaderPref();
}
} else if (strcmp(aTopic, "memory-pressure") == 0) {
MinimizeCaches();
} else if (strcmp(aTopic, "chrome-flush-caches") == 0) {
MinimizeCaches();
ClearChromeImageCache();
} else if (strcmp(aTopic, "last-pb-context-exited") == 0) {
if (mRespectPrivacy) {
ClearImageCache();
ClearChromeImageCache();
}
} else if (strcmp(aTopic, "profile-before-change") == 0) {
mCacheTracker = nullptr;
} else if (strcmp(aTopic, "xpcom-shutdown") == 0) {
mCacheTracker = nullptr;
ShutdownMemoryReporter();
} else {
// (Nothing else should bring us here)
MOZ_ASSERT(0, "Invalid topic received");
}
return NS_OK;
}
void imgLoader::ReadAcceptHeaderPref() {
nsAutoCString accept;
nsresult rv = Preferences::GetCString("image.http.accept", accept);
if (NS_SUCCEEDED(rv)) {
mAcceptHeader = accept;
} else {
mAcceptHeader =
IMAGE_PNG "," IMAGE_WILDCARD ";q=0.8," ANY_WILDCARD ";q=0.5";
}
}
NS_IMETHODIMP
imgLoader::ClearCache(bool chrome) {
if (XRE_IsParentProcess()) {
bool privateLoader = this == gPrivateBrowsingLoader;
for (auto* cp : ContentParent::AllProcesses(ContentParent::eLive)) {
Unused << cp->SendClearImageCache(privateLoader, chrome);
}
}
if (chrome) {
return ClearChromeImageCache();
}
return ClearImageCache();
}
NS_IMETHODIMP
imgLoader::RemoveEntriesFromPrincipal(nsIPrincipal* aPrincipal) {
nsAutoString origin;
nsresult rv = nsContentUtils::GetUTFOrigin(aPrincipal, origin);
if (NS_WARN_IF(NS_FAILED(rv))) {
return rv;
}
AutoTArray<RefPtr<imgCacheEntry>, 128> entriesToBeRemoved;
imgCacheTable& cache = GetCache(aPrincipal->IsSystemPrincipal());
for (auto iter = cache.Iter(); !iter.Done(); iter.Next()) {
auto& key = iter.Key();
if (key.OriginAttributesRef() !=
BasePrincipal::Cast(aPrincipal)->OriginAttributesRef()) {
continue;
}
nsAutoString imageOrigin;
nsresult rv = nsContentUtils::GetUTFOrigin(key.URI(), imageOrigin);
if (NS_WARN_IF(NS_FAILED(rv))) {
continue;
}
if (imageOrigin == origin) {
entriesToBeRemoved.AppendElement(iter.Data());
}
}
for (auto& entry : entriesToBeRemoved) {
if (!RemoveFromCache(entry)) {
NS_WARNING(
"Couldn't remove an entry from the cache in "
"RemoveEntriesFromPrincipal()\n");
}
}
return NS_OK;
}
NS_IMETHODIMP
imgLoader::RemoveEntry(nsIURI* aURI, Document* aDoc) {
if (aURI) {
OriginAttributes attrs;
if (aDoc) {
nsCOMPtr<nsIPrincipal> principal = aDoc->NodePrincipal();
if (principal) {
attrs = principal->OriginAttributesRef();
}
}
ImageCacheKey key(aURI, attrs, aDoc);
if (RemoveFromCache(key)) {
return NS_OK;
}
}
return NS_ERROR_NOT_AVAILABLE;
}
NS_IMETHODIMP
imgLoader::FindEntryProperties(nsIURI* uri, Document* aDoc,
nsIProperties** _retval) {
*_retval = nullptr;
OriginAttributes attrs;
if (aDoc) {
nsCOMPtr<nsIPrincipal> principal = aDoc->NodePrincipal();
if (principal) {
attrs = principal->OriginAttributesRef();
}
}
ImageCacheKey key(uri, attrs, aDoc);
imgCacheTable& cache = GetCache(key);
RefPtr<imgCacheEntry> entry;
if (cache.Get(key, getter_AddRefs(entry)) && entry) {
if (mCacheTracker && entry->HasNoProxies()) {
mCacheTracker->MarkUsed(entry);
}
RefPtr<imgRequest> request = entry->GetRequest();
if (request) {
nsCOMPtr<nsIProperties> properties = request->Properties();
properties.forget(_retval);
}
}
return NS_OK;
}
NS_IMETHODIMP_(void)
imgLoader::ClearCacheForControlledDocument(Document* aDoc) {
MOZ_ASSERT(aDoc);
AutoTArray<RefPtr<imgCacheEntry>, 128> entriesToBeRemoved;
imgCacheTable& cache = GetCache(false);
for (auto iter = cache.Iter(); !iter.Done(); iter.Next()) {
auto& key = iter.Key();
if (key.ControlledDocument() == aDoc) {
entriesToBeRemoved.AppendElement(iter.Data());
}
}
for (auto& entry : entriesToBeRemoved) {
if (!RemoveFromCache(entry)) {
NS_WARNING(
"Couldn't remove an entry from the cache in "
"ClearCacheForControlledDocument()\n");
}
}
}
void imgLoader::Shutdown() {
NS_IF_RELEASE(gNormalLoader);
gNormalLoader = nullptr;
NS_IF_RELEASE(gPrivateBrowsingLoader);
gPrivateBrowsingLoader = nullptr;
}
nsresult imgLoader::ClearChromeImageCache() {
return EvictEntries(mChromeCache);
}
nsresult imgLoader::ClearImageCache() { return EvictEntries(mCache); }
void imgLoader::MinimizeCaches() {
EvictEntries(mCacheQueue);
EvictEntries(mChromeCacheQueue);
}
bool imgLoader::PutIntoCache(const ImageCacheKey& aKey, imgCacheEntry* entry) {
imgCacheTable& cache = GetCache(aKey);
LOG_STATIC_FUNC_WITH_PARAM(gImgLog, "imgLoader::PutIntoCache", "uri",
aKey.URI());
// Check to see if this request already exists in the cache. If so, we'll
// replace the old version.
RefPtr<imgCacheEntry> tmpCacheEntry;
if (cache.Get(aKey, getter_AddRefs(tmpCacheEntry)) && tmpCacheEntry) {
MOZ_LOG(
gImgLog, LogLevel::Debug,
("[this=%p] imgLoader::PutIntoCache -- Element already in the cache",
nullptr));
RefPtr<imgRequest> tmpRequest = tmpCacheEntry->GetRequest();
// If it already exists, and we're putting the same key into the cache, we
// should remove the old version.
MOZ_LOG(gImgLog, LogLevel::Debug,
("[this=%p] imgLoader::PutIntoCache -- Replacing cached element",
nullptr));
RemoveFromCache(aKey);
} else {
MOZ_LOG(gImgLog, LogLevel::Debug,
("[this=%p] imgLoader::PutIntoCache --"
" Element NOT already in the cache",
nullptr));
}
cache.Put(aKey, entry);
// We can be called to resurrect an evicted entry.
if (entry->Evicted()) {
entry->SetEvicted(false);
}
// If we're resurrecting an entry with no proxies, put it back in the
// tracker and queue.
if (entry->HasNoProxies()) {
nsresult addrv = NS_OK;
if (mCacheTracker) {
addrv = mCacheTracker->AddObject(entry);
}
if (NS_SUCCEEDED(addrv)) {
imgCacheQueue& queue = GetCacheQueue(aKey);
queue.Push(entry);
}
}
RefPtr<imgRequest> request = entry->GetRequest();
request->SetIsInCache(true);
RemoveFromUncachedImages(request);
return true;
}
bool imgLoader::SetHasNoProxies(imgRequest* aRequest, imgCacheEntry* aEntry) {
LOG_STATIC_FUNC_WITH_PARAM(gImgLog, "imgLoader::SetHasNoProxies", "uri",
aRequest->CacheKey().URI());
aEntry->SetHasNoProxies(true);
if (aEntry->Evicted()) {
return false;
}
imgCacheQueue& queue = GetCacheQueue(aRequest->IsChrome());
nsresult addrv = NS_OK;
if (mCacheTracker) {
addrv = mCacheTracker->AddObject(aEntry);
}
if (NS_SUCCEEDED(addrv)) {
queue.Push(aEntry);
}
imgCacheTable& cache = GetCache(aRequest->IsChrome());
CheckCacheLimits(cache, queue);
return true;
}
bool imgLoader::SetHasProxies(imgRequest* aRequest) {
VerifyCacheSizes();
const ImageCacheKey& key = aRequest->CacheKey();
imgCacheTable& cache = GetCache(key);
LOG_STATIC_FUNC_WITH_PARAM(gImgLog, "imgLoader::SetHasProxies", "uri",
key.URI());
RefPtr<imgCacheEntry> entry;
if (cache.Get(key, getter_AddRefs(entry)) && entry) {
// Make sure the cache entry is for the right request
RefPtr<imgRequest> entryRequest = entry->GetRequest();
if (entryRequest == aRequest && entry->HasNoProxies()) {
imgCacheQueue& queue = GetCacheQueue(key);
queue.Remove(entry);
if (mCacheTracker) {
mCacheTracker->RemoveObject(entry);
}
entry->SetHasNoProxies(false);
return true;
}
}
return false;
}
void imgLoader::CacheEntriesChanged(bool aForChrome,
int32_t aSizeDiff /* = 0 */) {
imgCacheQueue& queue = GetCacheQueue(aForChrome);
// We only need to dirty the queue if there is any sorting
// taking place. Empty or single-entry lists can't become
// dirty.
if (queue.GetNumElements() > 1) {
queue.MarkDirty();
}
queue.UpdateSize(aSizeDiff);
}
void imgLoader::CheckCacheLimits(imgCacheTable& cache, imgCacheQueue& queue) {
if (queue.GetNumElements() == 0) {
NS_ASSERTION(queue.GetSize() == 0,
"imgLoader::CheckCacheLimits -- incorrect cache size");
}
// Remove entries from the cache until we're back at our desired max size.
while (queue.GetSize() > sCacheMaxSize) {
// Remove the first entry in the queue.
RefPtr<imgCacheEntry> entry(queue.Pop());
NS_ASSERTION(entry, "imgLoader::CheckCacheLimits -- NULL entry pointer");
if (MOZ_LOG_TEST(gImgLog, LogLevel::Debug)) {
RefPtr<imgRequest> req = entry->GetRequest();
if (req) {
LOG_STATIC_FUNC_WITH_PARAM(gImgLog, "imgLoader::CheckCacheLimits",
"entry", req->CacheKey().URI());
}
}
if (entry) {
// We just popped this entry from the queue, so pass AlreadyRemoved
// to avoid searching the queue again in RemoveFromCache.
RemoveFromCache(entry, QueueState::AlreadyRemoved);
}
}
}
bool imgLoader::ValidateRequestWithNewChannel(
imgRequest* request, nsIURI* aURI, nsIURI* aInitialDocumentURI,
nsIReferrerInfo* aReferrerInfo, nsILoadGroup* aLoadGroup,
imgINotificationObserver* aObserver, nsISupports* aCX,
Document* aLoadingDocument, uint64_t aInnerWindowId, nsLoadFlags aLoadFlags,
nsContentPolicyType aLoadPolicyType, imgRequestProxy** aProxyRequest,
nsIPrincipal* aTriggeringPrincipal, int32_t aCORSMode,
bool* aNewChannelCreated) {
// now we need to insert a new channel request object in between the real
// request and the proxy that basically delays loading the image until it
// gets a 304 or figures out that this needs to be a new request
nsresult rv;
// If we're currently in the middle of validating this request, just hand
// back a proxy to it; the required work will be done for us.
if (request->GetValidator()) {
rv = CreateNewProxyForRequest(request, aLoadGroup, aLoadingDocument,
aObserver, aLoadFlags, aProxyRequest);
if (NS_FAILED(rv)) {
return false;
}
if (*aProxyRequest) {
imgRequestProxy* proxy = static_cast<imgRequestProxy*>(*aProxyRequest);
// We will send notifications from imgCacheValidator::OnStartRequest().
// In the mean time, we must defer notifications because we are added to
// the imgRequest's proxy list, and we can get extra notifications
// resulting from methods such as StartDecoding(). See bug 579122.
proxy->MarkValidating();
// Attach the proxy without notifying
request->GetValidator()->AddProxy(proxy);
}
return NS_SUCCEEDED(rv);
}
// We will rely on Necko to cache this request when it's possible, and to
// tell imgCacheValidator::OnStartRequest whether the request came from its
// cache.
nsCOMPtr<nsIChannel> newChannel;
bool forcePrincipalCheck;
rv = NewImageChannel(getter_AddRefs(newChannel), &forcePrincipalCheck, aURI,
aInitialDocumentURI, aCORSMode, aReferrerInfo,
aLoadGroup, mAcceptHeader, aLoadFlags, aLoadPolicyType,
aTriggeringPrincipal, aCX, mRespectPrivacy);
if (NS_FAILED(rv)) {
return false;
}
if (aNewChannelCreated) {
*aNewChannelCreated = true;
}
RefPtr<imgRequestProxy> req;
rv = CreateNewProxyForRequest(request, aLoadGroup, aLoadingDocument,
aObserver, aLoadFlags, getter_AddRefs(req));
if (NS_FAILED(rv)) {
return false;
}
// Make sure that OnStatus/OnProgress calls have the right request set...
RefPtr<nsProgressNotificationProxy> progressproxy =
new nsProgressNotificationProxy(newChannel, req);
if (!progressproxy) {
return false;
}
RefPtr<imgCacheValidator> hvc = new imgCacheValidator(
progressproxy, this, request, aCX, aInnerWindowId, forcePrincipalCheck);
// Casting needed here to get past multiple inheritance.
nsCOMPtr<nsIStreamListener> listener =
do_QueryInterface(static_cast<nsIThreadRetargetableStreamListener*>(hvc));
NS_ENSURE_TRUE(listener, false);
// We must set the notification callbacks before setting up the
// CORS listener, because that's also interested inthe
// notification callbacks.
newChannel->SetNotificationCallbacks(hvc);
request->SetValidator(hvc);
// We will send notifications from imgCacheValidator::OnStartRequest().
// In the mean time, we must defer notifications because we are added to
// the imgRequest's proxy list, and we can get extra notifications
// resulting from methods such as StartDecoding(). See bug 579122.
req->MarkValidating();
// Add the proxy without notifying
hvc->AddProxy(req);
mozilla::net::PredictorLearn(aURI, aInitialDocumentURI,
nsINetworkPredictor::LEARN_LOAD_SUBRESOURCE,
aLoadGroup);
rv = newChannel->AsyncOpen(listener);
if (NS_WARN_IF(NS_FAILED(rv))) {
req->CancelAndForgetObserver(rv);
return false;
}
req.forget(aProxyRequest);
return true;
}
bool imgLoader::ValidateEntry(
imgCacheEntry* aEntry, nsIURI* aURI, nsIURI* aInitialDocumentURI,
nsIReferrerInfo* aReferrerInfo, nsILoadGroup* aLoadGroup,
imgINotificationObserver* aObserver, nsISupports* aCX,
Document* aLoadingDocument, nsLoadFlags aLoadFlags,
nsContentPolicyType aLoadPolicyType, bool aCanMakeNewChannel,
bool* aNewChannelCreated, imgRequestProxy** aProxyRequest,
nsIPrincipal* aTriggeringPrincipal, int32_t aCORSMode) {
LOG_SCOPE(gImgLog, "imgLoader::ValidateEntry");
// If the expiration time is zero, then the request has not gotten far enough
// to know when it will expire.
uint32_t expiryTime = aEntry->GetExpiryTime();
bool hasExpired = expiryTime != 0 &&
expiryTime <= imgCacheEntry::SecondsFromPRTime(PR_Now());
nsresult rv;
// Special treatment for file URLs - aEntry has expired if file has changed
nsCOMPtr<nsIFileURL> fileUrl(do_QueryInterface(aURI));
if (fileUrl) {
uint32_t lastModTime = aEntry->GetLoadTime();
nsCOMPtr<nsIFile> theFile;
rv = fileUrl->GetFile(getter_AddRefs(theFile));
if (NS_SUCCEEDED(rv)) {
PRTime fileLastMod;
rv = theFile->GetLastModifiedTime(&fileLastMod);
if (NS_SUCCEEDED(rv)) {
// nsIFile uses millisec, NSPR usec
fileLastMod *= 1000;
hasExpired =
imgCacheEntry::SecondsFromPRTime((PRTime)fileLastMod) > lastModTime;
}
}
}
RefPtr<imgRequest> request(aEntry->GetRequest());
if (!request) {
return false;
}
if (!ValidateSecurityInfo(request, aEntry->ForcePrincipalCheck(), aCORSMode,
aTriggeringPrincipal, aCX, aLoadPolicyType,
aReferrerInfo))
return false;
// data URIs are immutable and by their nature can't leak data, so we can
// just return true in that case. Doing so would mean that shift-reload
// doesn't reload data URI documents/images though (which is handy for
// debugging during gecko development) so we make an exception in that case.
nsAutoCString scheme;
aURI->GetScheme(scheme);
if (scheme.EqualsLiteral("data") &&
!(aLoadFlags & nsIRequest::LOAD_BYPASS_CACHE)) {
return true;
}
bool validateRequest = false;
// If the request's loadId is the same as the aCX, then it is ok to use
// this one because it has already been validated for this context.
//
// XXX: nullptr seems to be a 'special' key value that indicates that NO
// validation is required.
// XXX: we also check the window ID because the loadID() can return a reused
// pointer of a document. This can still happen for non-document image
// cache entries.
void* key = (void*)aCX;
nsCOMPtr<Document> doc = do_QueryInterface(aCX);
uint64_t innerWindowID = doc ? doc->InnerWindowID() : 0;
if (request->LoadId() != key || request->InnerWindowID() != innerWindowID) {
// If we would need to revalidate this entry, but we're being told to
// bypass the cache, we don't allow this entry to be used.
if (aLoadFlags & nsIRequest::LOAD_BYPASS_CACHE) {
return false;
}
if (MOZ_UNLIKELY(ChaosMode::isActive(ChaosFeature::ImageCache))) {
if (ChaosMode::randomUint32LessThan(4) < 1) {
return false;
}
}
// Determine whether the cache aEntry must be revalidated...
validateRequest = ShouldRevalidateEntry(aEntry, aLoadFlags, hasExpired);
MOZ_LOG(gImgLog, LogLevel::Debug,
("imgLoader::ValidateEntry validating cache entry. "
"validateRequest = %d",
validateRequest));
} else if (!key && MOZ_LOG_TEST(gImgLog, LogLevel::Debug)) {
MOZ_LOG(gImgLog, LogLevel::Debug,
("imgLoader::ValidateEntry BYPASSING cache validation for %s "
"because of NULL LoadID",
aURI->GetSpecOrDefault().get()));
}
// We can't use a cached request if it comes from a different
// application cache than this load is expecting.
nsCOMPtr<nsIApplicationCacheContainer> appCacheContainer;
nsCOMPtr<nsIApplicationCache> requestAppCache;
nsCOMPtr<nsIApplicationCache> groupAppCache;
if ((appCacheContainer = do_GetInterface(request->GetRequest()))) {
appCacheContainer->GetApplicationCache(getter_AddRefs(requestAppCache));
}
if ((appCacheContainer = do_QueryInterface(aLoadGroup))) {
appCacheContainer->GetApplicationCache(getter_AddRefs(groupAppCache));
}
if (requestAppCache != groupAppCache) {
MOZ_LOG(gImgLog, LogLevel::Debug,
("imgLoader::ValidateEntry - Unable to use cached imgRequest "
"[request=%p] because of mismatched application caches\n",
address_of(request)));
return false;
}
if (validateRequest && aCanMakeNewChannel) {
LOG_SCOPE(gImgLog, "imgLoader::ValidateRequest |cache hit| must validate");
return ValidateRequestWithNewChannel(
request, aURI, aInitialDocumentURI, aReferrerInfo, aLoadGroup,
aObserver, aCX, aLoadingDocument, innerWindowID, aLoadFlags,
aLoadPolicyType, aProxyRequest, aTriggeringPrincipal, aCORSMode,
aNewChannelCreated);
}
return !validateRequest;
}
bool imgLoader::RemoveFromCache(const ImageCacheKey& aKey) {
LOG_STATIC_FUNC_WITH_PARAM(gImgLog, "imgLoader::RemoveFromCache", "uri",
aKey.URI());
imgCacheTable& cache = GetCache(aKey);
imgCacheQueue& queue = GetCacheQueue(aKey);
RefPtr<imgCacheEntry> entry;
cache.Remove(aKey, getter_AddRefs(entry));
if (entry) {
MOZ_ASSERT(!entry->Evicted(), "Evicting an already-evicted cache entry!");
// Entries with no proxies are in the tracker.
if (entry->HasNoProxies()) {
if (mCacheTracker) {
mCacheTracker->RemoveObject(entry);
}
queue.Remove(entry);
}
entry->SetEvicted(true);
RefPtr<imgRequest> request = entry->GetRequest();
request->SetIsInCache(false);
AddToUncachedImages(request);
return true;
}
return false;
}
bool imgLoader::RemoveFromCache(imgCacheEntry* entry, QueueState aQueueState) {
LOG_STATIC_FUNC(gImgLog, "imgLoader::RemoveFromCache entry");
RefPtr<imgRequest> request = entry->GetRequest();
if (request) {
const ImageCacheKey& key = request->CacheKey();
imgCacheTable& cache = GetCache(key);
imgCacheQueue& queue = GetCacheQueue(key);
LOG_STATIC_FUNC_WITH_PARAM(gImgLog, "imgLoader::RemoveFromCache",
"entry's uri", key.URI());
cache.Remove(key);
if (entry->HasNoProxies()) {
LOG_STATIC_FUNC(gImgLog,
"imgLoader::RemoveFromCache removing from tracker");
if (mCacheTracker) {
mCacheTracker->RemoveObject(entry);
}
// Only search the queue to remove the entry if its possible it might
// be in the queue. If we know its not in the queue this would be
// wasted work.
MOZ_ASSERT_IF(aQueueState == QueueState::AlreadyRemoved,
!queue.Contains(entry));
if (aQueueState == QueueState::MaybeExists) {
queue.Remove(entry);
}
}
entry->SetEvicted(true);
request->SetIsInCache(false);
AddToUncachedImages(request);
return true;
}
return false;
}
nsresult imgLoader::EvictEntries(imgCacheTable& aCacheToClear) {
LOG_STATIC_FUNC(gImgLog, "imgLoader::EvictEntries table");
// We have to make a temporary, since RemoveFromCache removes the element
// from the queue, invalidating iterators.
nsTArray<RefPtr<imgCacheEntry> > entries;
for (auto iter = aCacheToClear.Iter(); !iter.Done(); iter.Next()) {
RefPtr<imgCacheEntry>& data = iter.Data();
entries.AppendElement(data);
}
for (uint32_t i = 0; i < entries.Length(); ++i) {
if (!RemoveFromCache(entries[i])) {
return NS_ERROR_FAILURE;
}
}
MOZ_ASSERT(aCacheToClear.Count() == 0);
return NS_OK;
}
nsresult imgLoader::EvictEntries(imgCacheQueue& aQueueToClear) {
LOG_STATIC_FUNC(gImgLog, "imgLoader::EvictEntries queue");
// We have to make a temporary, since RemoveFromCache removes the element
// from the queue, invalidating iterators.
nsTArray<RefPtr<imgCacheEntry> > entries(aQueueToClear.GetNumElements());
for (auto i = aQueueToClear.begin(); i != aQueueToClear.end(); ++i) {
entries.AppendElement(*i);
}
// Iterate in reverse order to minimize array copying.
for (auto& entry : entries) {
if (!RemoveFromCache(entry)) {
return NS_ERROR_FAILURE;
}
}
MOZ_ASSERT(aQueueToClear.GetNumElements() == 0);
return NS_OK;
}
void imgLoader::AddToUncachedImages(imgRequest* aRequest) {
MutexAutoLock lock(mUncachedImagesMutex);
mUncachedImages.PutEntry(aRequest);
}
void imgLoader::RemoveFromUncachedImages(imgRequest* aRequest) {
MutexAutoLock lock(mUncachedImagesMutex);
mUncachedImages.RemoveEntry(aRequest);
}
bool imgLoader::PreferLoadFromCache(nsIURI* aURI) const {
// If we are trying to load an image from a protocol that doesn't support
// caching (e.g. thumbnails via the moz-page-thumb:// protocol, or icons via
// the moz-extension:// protocol), load it directly from the cache to prevent
// re-decoding the image. See Bug 1373258.
// TODO: Bug 1406134
return aURI->SchemeIs("moz-page-thumb") || aURI->SchemeIs("moz-extension");
}
#define LOAD_FLAGS_CACHE_MASK \
(nsIRequest::LOAD_BYPASS_CACHE | nsIRequest::LOAD_FROM_CACHE)
#define LOAD_FLAGS_VALIDATE_MASK \
(nsIRequest::VALIDATE_ALWAYS | nsIRequest::VALIDATE_NEVER | \
nsIRequest::VALIDATE_ONCE_PER_SESSION)
NS_IMETHODIMP
imgLoader::LoadImageXPCOM(nsIURI* aURI, nsIURI* aInitialDocumentURI,
nsIReferrerInfo* aReferrerInfo,
nsIPrincipal* aTriggeringPrincipal,
nsILoadGroup* aLoadGroup,
imgINotificationObserver* aObserver, nsISupports* aCX,
nsLoadFlags aLoadFlags, nsISupports* aCacheKey,
nsContentPolicyType aContentPolicyType,
imgIRequest** _retval) {
// Optional parameter, so defaults to 0 (== TYPE_INVALID)
if (!aContentPolicyType) {
aContentPolicyType = nsIContentPolicy::TYPE_INTERNAL_IMAGE;
}
imgRequestProxy* proxy;
nsCOMPtr<nsINode> node = do_QueryInterface(aCX);
nsCOMPtr<Document> doc = do_QueryInterface(aCX);
nsresult rv =
LoadImage(aURI, aInitialDocumentURI, aReferrerInfo, aTriggeringPrincipal,
0, aLoadGroup, aObserver, node, doc, aLoadFlags, aCacheKey,
aContentPolicyType, EmptyString(),
/* aUseUrgentStartForChannel */ false, &proxy);
*_retval = proxy;
return rv;
}
nsresult imgLoader::LoadImage(
nsIURI* aURI, nsIURI* aInitialDocumentURI, nsIReferrerInfo* aReferrerInfo,
nsIPrincipal* aTriggeringPrincipal, uint64_t aRequestContextID,
nsILoadGroup* aLoadGroup, imgINotificationObserver* aObserver,
nsINode* aContext, Document* aLoadingDocument, nsLoadFlags aLoadFlags,
nsISupports* aCacheKey, nsContentPolicyType aContentPolicyType,
const nsAString& initiatorType, bool aUseUrgentStartForChannel,
imgRequestProxy** _retval) {
VerifyCacheSizes();
NS_ASSERTION(aURI, "imgLoader::LoadImage -- NULL URI pointer");
if (!aURI) {
return NS_ERROR_NULL_POINTER;
}
#ifdef MOZ_GECKO_PROFILER
AUTO_PROFILER_LABEL_DYNAMIC_NSCSTRING("imgLoader::LoadImage", NETWORK,
aURI->GetSpecOrDefault());
#endif
LOG_SCOPE_WITH_PARAM(gImgLog, "imgLoader::LoadImage", "aURI", aURI);
*_retval = nullptr;
RefPtr<imgRequest> request;
nsresult rv;
nsLoadFlags requestFlags = nsIRequest::LOAD_NORMAL;
#ifdef DEBUG
bool isPrivate = false;
if (aLoadingDocument) {
isPrivate = nsContentUtils::IsInPrivateBrowsing(aLoadingDocument);
} else if (aLoadGroup) {
isPrivate = nsContentUtils::IsInPrivateBrowsing(aLoadGroup);
}
MOZ_ASSERT(isPrivate == mRespectPrivacy);
if (aLoadingDocument) {
// The given load group should match that of the document if given. If
// that isn't the case, then we need to add more plumbing to ensure we
// block the document as well.
nsCOMPtr<nsILoadGroup> docLoadGroup =
aLoadingDocument->GetDocumentLoadGroup();
MOZ_ASSERT(docLoadGroup == aLoadGroup);
}
#endif
// Get the default load flags from the loadgroup (if possible)...
if (aLoadGroup) {
aLoadGroup->GetLoadFlags(&requestFlags);
if (PreferLoadFromCache(aURI)) {
requestFlags |= nsIRequest::LOAD_FROM_CACHE;
}
}
//
// Merge the default load flags with those passed in via aLoadFlags.
// Currently, *only* the caching, validation and background load flags
// are merged...
//
// The flags in aLoadFlags take precedence over the default flags!
//
if (aLoadFlags & LOAD_FLAGS_CACHE_MASK) {
// Override the default caching flags...
requestFlags = (requestFlags & ~LOAD_FLAGS_CACHE_MASK) |
(aLoadFlags & LOAD_FLAGS_CACHE_MASK);
}
if (aLoadFlags & LOAD_FLAGS_VALIDATE_MASK) {
// Override the default validation flags...
requestFlags = (requestFlags & ~LOAD_FLAGS_VALIDATE_MASK) |
(aLoadFlags & LOAD_FLAGS_VALIDATE_MASK);
}
if (aLoadFlags & nsIRequest::LOAD_BACKGROUND) {
// Propagate background loading...
requestFlags |= nsIRequest::LOAD_BACKGROUND;
}
int32_t corsmode = imgIRequest::CORS_NONE;
if (aLoadFlags & imgILoader::LOAD_CORS_ANONYMOUS) {
corsmode = imgIRequest::CORS_ANONYMOUS;
} else if (aLoadFlags & imgILoader::LOAD_CORS_USE_CREDENTIALS) {
corsmode = imgIRequest::CORS_USE_CREDENTIALS;
}
RefPtr<imgCacheEntry> entry;
// Look in the cache for our URI, and then validate it.
// XXX For now ignore aCacheKey. We will need it in the future
// for correctly dealing with image load requests that are a result
// of post data.
OriginAttributes attrs;
if (aTriggeringPrincipal) {
attrs = aTriggeringPrincipal->OriginAttributesRef();
}
ImageCacheKey key(aURI, attrs, aLoadingDocument);
imgCacheTable& cache = GetCache(key);
if (cache.Get(key, getter_AddRefs(entry)) && entry) {
bool newChannelCreated = false;
if (ValidateEntry(entry, aURI, aInitialDocumentURI, aReferrerInfo,
aLoadGroup, aObserver, ToSupports(aLoadingDocument),
aLoadingDocument, requestFlags, aContentPolicyType, true,
&newChannelCreated, _retval, aTriggeringPrincipal,
corsmode)) {
request = entry->GetRequest();
// If this entry has no proxies, its request has no reference to the
// entry.
if (entry->HasNoProxies()) {
LOG_FUNC_WITH_PARAM(gImgLog,
"imgLoader::LoadImage() adding proxyless entry",
"uri", key.URI());
MOZ_ASSERT(!request->HasCacheEntry(),
"Proxyless entry's request has cache entry!");
request->SetCacheEntry(entry);
if (mCacheTracker && entry->GetExpirationState()->IsTracked()) {
mCacheTracker->MarkUsed(entry);
}
}
entry->Touch();
if (!newChannelCreated) {
// This is ugly but it's needed to report CSP violations. We have 3
// scenarios:
// - we don't have cache. We are not in this if() stmt. A new channel is
// created and that triggers the CSP checks.
// - We have a cache entry and this is blocked by CSP directives.
DebugOnly<bool> shouldLoad =
ShouldLoadCachedImage(request, ToSupports(aLoadingDocument),
aTriggeringPrincipal, aContentPolicyType,
/* aSendCSPViolationReports */ true);
MOZ_ASSERT(shouldLoad);
}
} else {
// We can't use this entry. We'll try to load it off the network, and if
// successful, overwrite the old entry in the cache with a new one.
entry = nullptr;
}
}
// Keep the channel in this scope, so we can adjust its notificationCallbacks
// later when we create the proxy.
nsCOMPtr<nsIChannel> newChannel;
// If we didn't get a cache hit, we need to load from the network.
if (!request) {
LOG_SCOPE(gImgLog, "imgLoader::LoadImage |cache miss|");
bool forcePrincipalCheck;
rv = NewImageChannel(getter_AddRefs(newChannel), &forcePrincipalCheck, aURI,
aInitialDocumentURI, corsmode, aReferrerInfo,
aLoadGroup, mAcceptHeader, requestFlags,
aContentPolicyType, aTriggeringPrincipal, aContext,
mRespectPrivacy);
if (NS_FAILED(rv)) {
return NS_ERROR_FAILURE;
}
MOZ_ASSERT(NS_UsePrivateBrowsing(newChannel) == mRespectPrivacy);
NewRequestAndEntry(forcePrincipalCheck, this, key, getter_AddRefs(request),
getter_AddRefs(entry));
MOZ_LOG(gImgLog, LogLevel::Debug,
("[this=%p] imgLoader::LoadImage -- Created new imgRequest"
" [request=%p]\n",
this, request.get()));
nsCOMPtr<nsIClassOfService> cos(do_QueryInterface(newChannel));
if (cos) {
if (aUseUrgentStartForChannel) {
cos->AddClassFlags(nsIClassOfService::UrgentStart);
}
if (StaticPrefs::network_http_tailing_enabled() &&
aContentPolicyType == nsIContentPolicy::TYPE_INTERNAL_IMAGE_FAVICON) {
cos->AddClassFlags(nsIClassOfService::Throttleable |
nsIClassOfService::Tail);
nsCOMPtr<nsIHttpChannel> httpChannel(do_QueryInterface(newChannel));
if (httpChannel) {
Unused << httpChannel->SetRequestContextID(aRequestContextID);
}
}
}
nsCOMPtr<nsILoadGroup> channelLoadGroup;
newChannel->GetLoadGroup(getter_AddRefs(channelLoadGroup));
rv = request->Init(aURI, aURI, /* aHadInsecureRedirect = */ false,
channelLoadGroup, newChannel, entry,
ToSupports(aLoadingDocument), aTriggeringPrincipal,
corsmode, aReferrerInfo);
if (NS_FAILED(rv)) {
return NS_ERROR_FAILURE;
}
// Add the initiator type for this image load
nsCOMPtr<nsITimedChannel> timedChannel = do_QueryInterface(newChannel);
if (timedChannel) {
timedChannel->SetInitiatorType(initiatorType);
}
// create the proxy listener
nsCOMPtr<nsIStreamListener> listener = new ProxyListener(request.get());
MOZ_LOG(gImgLog, LogLevel::Debug,
("[this=%p] imgLoader::LoadImage -- Calling channel->AsyncOpen()\n",
this));
mozilla::net::PredictorLearn(aURI, aInitialDocumentURI,
nsINetworkPredictor::LEARN_LOAD_SUBRESOURCE,
aLoadGroup);
nsresult openRes = newChannel->AsyncOpen(listener);
if (NS_FAILED(openRes)) {
MOZ_LOG(
gImgLog, LogLevel::Debug,
("[this=%p] imgLoader::LoadImage -- AsyncOpen() failed: 0x%" PRIx32
"\n",
this, static_cast<uint32_t>(openRes)));
request->CancelAndAbort(openRes);
return openRes;
}
// Try to add the new request into the cache.
PutIntoCache(key, entry);
} else {
LOG_MSG_WITH_PARAM(gImgLog, "imgLoader::LoadImage |cache hit|", "request",
request);
}
// If we didn't get a proxy when validating the cache entry, we need to
// create one.
if (!*_retval) {
// ValidateEntry() has three return values: "Is valid," "might be valid --
// validating over network", and "not valid." If we don't have a _retval,
// we know ValidateEntry is not validating over the network, so it's safe
// to SetLoadId here because we know this request is valid for this context.
//
// Note, however, that this doesn't guarantee the behaviour we want (one
// URL maps to the same image on a page) if we load the same image in a
// different tab (see bug 528003), because its load id will get re-set, and
// that'll cause us to validate over the network.
request->SetLoadId(aLoadingDocument);
LOG_MSG(gImgLog, "imgLoader::LoadImage", "creating proxy request.");
rv = CreateNewProxyForRequest(request, aLoadGroup, aLoadingDocument,
aObserver, requestFlags, _retval);
if (NS_FAILED(rv)) {
return rv;
}
imgRequestProxy* proxy = *_retval;
// Make sure that OnStatus/OnProgress calls have the right request set, if
// we did create a channel here.
if (newChannel) {
nsCOMPtr<nsIInterfaceRequestor> requestor(
new nsProgressNotificationProxy(newChannel, proxy));
if (!requestor) {
return NS_ERROR_OUT_OF_MEMORY;
}
newChannel->SetNotificationCallbacks(requestor);
}
// Note that it's OK to add here even if the request is done. If it is,
// it'll send a OnStopRequest() to the proxy in imgRequestProxy::Notify and
// the proxy will be removed from the loadgroup.
proxy->AddToLoadGroup();
// If we're loading off the network, explicitly don't notify our proxy,
// because necko (or things called from necko, such as imgCacheValidator)
// are going to call our notifications asynchronously, and we can't make it
// further asynchronous because observers might rely on imagelib completing
// its work between the channel's OnStartRequest and OnStopRequest.
if (!newChannel) {
proxy->NotifyListener();
}
return rv;
}
NS_ASSERTION(*_retval, "imgLoader::LoadImage -- no return value");
return NS_OK;
}
NS_IMETHODIMP
imgLoader::LoadImageWithChannelXPCOM(nsIChannel* channel,
imgINotificationObserver* aObserver,
nsISupports* aCX,
nsIStreamListener** listener,
imgIRequest** _retval) {
nsresult result;
imgRequestProxy* proxy;
result = LoadImageWithChannel(channel, aObserver, aCX, listener, &proxy);
*_retval = proxy;
return result;
}
nsresult imgLoader::LoadImageWithChannel(nsIChannel* channel,
imgINotificationObserver* aObserver,
nsISupports* aCX,
nsIStreamListener** listener,
imgRequestProxy** _retval) {
NS_ASSERTION(channel,
"imgLoader::LoadImageWithChannel -- NULL channel pointer");
MOZ_ASSERT(NS_UsePrivateBrowsing(channel) == mRespectPrivacy);
LOG_SCOPE(gImgLog, "imgLoader::LoadImageWithChannel");
RefPtr<imgRequest> request;
nsCOMPtr<nsIURI> uri;
channel->GetURI(getter_AddRefs(uri));
nsCOMPtr<Document> doc = do_QueryInterface(aCX);
NS_ENSURE_TRUE(channel, NS_ERROR_FAILURE);
nsCOMPtr<nsILoadInfo> loadInfo = channel->LoadInfo();
OriginAttributes attrs = loadInfo->GetOriginAttributes();
ImageCacheKey key(uri, attrs, doc);
nsLoadFlags requestFlags = nsIRequest::LOAD_NORMAL;
channel->GetLoadFlags(&requestFlags);
if (PreferLoadFromCache(uri)) {
requestFlags |= nsIRequest::LOAD_FROM_CACHE;
}
RefPtr<imgCacheEntry> entry;
if (requestFlags & nsIRequest::LOAD_BYPASS_CACHE) {
RemoveFromCache(key);
} else {
// Look in the cache for our URI, and then validate it.
// XXX For now ignore aCacheKey. We will need it in the future
// for correctly dealing with image load requests that are a result
// of post data.
imgCacheTable& cache = GetCache(key);
if (cache.Get(key, getter_AddRefs(entry)) && entry) {
// We don't want to kick off another network load. So we ask
// ValidateEntry to only do validation without creating a new proxy. If
// it says that the entry isn't valid any more, we'll only use the entry
// we're getting if the channel is loading from the cache anyways.
//
// XXX -- should this be changed? it's pretty much verbatim from the old
// code, but seems nonsensical.
//
// Since aCanMakeNewChannel == false, we don't need to pass content policy
// type/principal/etc
nsCOMPtr<nsILoadInfo> loadInfo = channel->LoadInfo();
// if there is a loadInfo, use the right contentType, otherwise
// default to the internal image type
nsContentPolicyType policyType = loadInfo->InternalContentPolicyType();
if (ValidateEntry(entry, uri, nullptr, nullptr, nullptr, aObserver, aCX,
doc, requestFlags, policyType, false, nullptr, nullptr,
nullptr, imgIRequest::CORS_NONE)) {
request = entry->GetRequest();
} else {
nsCOMPtr<nsICacheInfoChannel> cacheChan(do_QueryInterface(channel));
bool bUseCacheCopy;
if (cacheChan) {
cacheChan->IsFromCache(&bUseCacheCopy);
} else {
bUseCacheCopy = false;
}
if (!bUseCacheCopy) {
entry = nullptr;
} else {
request = entry->GetRequest();
}
}
if (request && entry) {
// If this entry has no proxies, its request has no reference to
// the entry.
if (entry->HasNoProxies()) {
LOG_FUNC_WITH_PARAM(
gImgLog,
"imgLoader::LoadImageWithChannel() adding proxyless entry", "uri",
key.URI());
MOZ_ASSERT(!request->HasCacheEntry(),
"Proxyless entry's request has cache entry!");
request->SetCacheEntry(entry);
if (mCacheTracker && entry->GetExpirationState()->IsTracked()) {
mCacheTracker->MarkUsed(entry);
}
}
}
}
}
nsCOMPtr<nsILoadGroup> loadGroup;
channel->GetLoadGroup(getter_AddRefs(loadGroup));
#ifdef DEBUG
if (doc) {
// The load group of the channel should always match that of the
// document if given. If that isn't the case, then we need to add more
// plumbing to ensure we block the document as well.
nsCOMPtr<nsILoadGroup> docLoadGroup = doc->GetDocumentLoadGroup();
MOZ_ASSERT(docLoadGroup == loadGroup);
}
#endif
// Filter out any load flags not from nsIRequest
requestFlags &= nsIRequest::LOAD_REQUESTMASK;
nsresult rv = NS_OK;
if (request) {
// we have this in our cache already.. cancel the current (document) load
// this should fire an OnStopRequest
channel->Cancel(NS_ERROR_PARSED_DATA_CACHED);
*listener = nullptr; // give them back a null nsIStreamListener
rv = CreateNewProxyForRequest(request, loadGroup, doc, aObserver,
requestFlags, _retval);
static_cast<imgRequestProxy*>(*_retval)->NotifyListener();
} else {
// We use originalURI here to fulfil the imgIRequest contract on GetURI.
nsCOMPtr<nsIURI> originalURI;
channel->GetOriginalURI(getter_AddRefs(originalURI));
// XXX(seth): We should be able to just use |key| here, except that |key| is
// constructed above with the *current URI* and not the *original URI*. I'm
// pretty sure this is a bug, and it's preventing us from ever getting a
// cache hit in LoadImageWithChannel when redirects are involved.
ImageCacheKey originalURIKey(originalURI, attrs, doc);
// Default to doing a principal check because we don't know who
// started that load and whether their principal ended up being
// inherited on the channel.
NewRequestAndEntry(/* aForcePrincipalCheckForCacheEntry = */ true, this,
originalURIKey, getter_AddRefs(request),
getter_AddRefs(entry));
// No principal specified here, because we're not passed one.
// In LoadImageWithChannel, the redirects that may have been
// associated with this load would have gone through necko.
// We only have the final URI in ImageLib and hence don't know
// if the request went through insecure redirects. But if it did,
// the necko cache should have handled that (since all necko cache hits
// including the redirects will go through content policy). Hence, we
// can set aHadInsecureRedirect to false here.
rv = request->Init(originalURI, uri, /* aHadInsecureRedirect = */ false,
channel, channel, entry, aCX, nullptr,
imgIRequest::CORS_NONE, nullptr);
NS_ENSURE_SUCCESS(rv, rv);
RefPtr<ProxyListener> pl =
new ProxyListener(static_cast<nsIStreamListener*>(request.get()));
pl.forget(listener);
// Try to add the new request into the cache.
PutIntoCache(originalURIKey, entry);
rv = CreateNewProxyForRequest(request, loadGroup, doc, aObserver,
requestFlags, _retval);
// Explicitly don't notify our proxy, because we're loading off the
// network, and necko (or things called from necko, such as
// imgCacheValidator) are going to call our notifications asynchronously,
// and we can't make it further asynchronous because observers might rely
// on imagelib completing its work between the channel's OnStartRequest and
// OnStopRequest.
}
if (NS_FAILED(rv)) {
return rv;
}
(*_retval)->AddToLoadGroup();
return rv;
}
bool imgLoader::SupportImageWithMimeType(const char* aMimeType,
AcceptedMimeTypes aAccept
/* = AcceptedMimeTypes::IMAGES */) {
nsAutoCString mimeType(aMimeType);
ToLowerCase(mimeType);
if (aAccept == AcceptedMimeTypes::IMAGES_AND_DOCUMENTS &&
mimeType.EqualsLiteral("image/svg+xml")) {
return true;
}
DecoderType type = DecoderFactory::GetDecoderType(mimeType.get());
return type != DecoderType::UNKNOWN;
}
NS_IMETHODIMP
imgLoader::GetMIMETypeFromContent(nsIRequest* aRequest,
const uint8_t* aContents, uint32_t aLength,
nsACString& aContentType) {
return GetMimeTypeFromContent((const char*)aContents, aLength, aContentType);
}
/* static */
nsresult imgLoader::GetMimeTypeFromContent(const char* aContents,
uint32_t aLength,
nsACString& aContentType) {
/* Is it a GIF? */
if (aLength >= 6 &&
(!strncmp(aContents, "GIF87a", 6) || !strncmp(aContents, "GIF89a", 6))) {
aContentType.AssignLiteral(IMAGE_GIF);
/* or a PNG? */
} else if (aLength >= 8 && ((unsigned char)aContents[0] == 0x89 &&
(unsigned char)aContents[1] == 0x50 &&
(unsigned char)aContents[2] == 0x4E &&
(unsigned char)aContents[3] == 0x47 &&
(unsigned char)aContents[4] == 0x0D &&
(unsigned char)aContents[5] == 0x0A &&
(unsigned char)aContents[6] == 0x1A &&
(unsigned char)aContents[7] == 0x0A)) {
aContentType.AssignLiteral(IMAGE_PNG);
/* maybe a JPEG (JFIF)? */
/* JFIF files start with SOI APP0 but older files can start with SOI DQT
* so we test for SOI followed by any marker, i.e. FF D8 FF
* this will also work for SPIFF JPEG files if they appear in the future.
*
* (JFIF is 0XFF 0XD8 0XFF 0XE0 <skip 2> 0X4A 0X46 0X49 0X46 0X00)
*/
} else if (aLength >= 3 && ((unsigned char)aContents[0]) == 0xFF &&
((unsigned char)aContents[1]) == 0xD8 &&
((unsigned char)aContents[2]) == 0xFF) {
aContentType.AssignLiteral(IMAGE_JPEG);
/* or how about ART? */
/* ART begins with JG (4A 47). Major version offset 2.
* Minor version offset 3. Offset 4 must be nullptr.
*/
} else if (aLength >= 5 && ((unsigned char)aContents[0]) == 0x4a &&
((unsigned char)aContents[1]) == 0x47 &&
((unsigned char)aContents[4]) == 0x00) {
aContentType.AssignLiteral(IMAGE_ART);
} else if (aLength >= 2 && !strncmp(aContents, "BM", 2)) {
aContentType.AssignLiteral(IMAGE_BMP);
// ICOs always begin with a 2-byte 0 followed by a 2-byte 1.
// CURs begin with 2-byte 0 followed by 2-byte 2.
} else if (aLength >= 4 && (!memcmp(aContents, "\000\000\001\000", 4) ||
!memcmp(aContents, "\000\000\002\000", 4))) {
aContentType.AssignLiteral(IMAGE_ICO);
// WebPs always begin with RIFF, a 32-bit length, and WEBP.
} else if (aLength >= 12 && !memcmp(aContents, "RIFF", 4) &&
!memcmp(aContents + 8, "WEBP", 4)) {
aContentType.AssignLiteral(IMAGE_WEBP);
} else {
/* none of the above? I give up */
return NS_ERROR_NOT_AVAILABLE;
}
return NS_OK;
}
/**
* proxy stream listener class used to handle multipart/x-mixed-replace
*/
#include "nsIRequest.h"
#include "nsIStreamConverterService.h"
NS_IMPL_ISUPPORTS(ProxyListener, nsIStreamListener,
nsIThreadRetargetableStreamListener, nsIRequestObserver)
ProxyListener::ProxyListener(nsIStreamListener* dest) : mDestListener(dest) {
/* member initializers and constructor code */
}
ProxyListener::~ProxyListener() { /* destructor code */
}
/** nsIRequestObserver methods **/
NS_IMETHODIMP
ProxyListener::OnStartRequest(nsIRequest* aRequest) {
if (!mDestListener) {
return NS_ERROR_FAILURE;
}
nsCOMPtr<nsIChannel> channel(do_QueryInterface(aRequest));
if (channel) {
// We need to set the initiator type for the image load
nsCOMPtr<nsITimedChannel> timedChannel = do_QueryInterface(channel);
if (timedChannel) {
nsAutoString type;
timedChannel->GetInitiatorType(type);
if (type.IsEmpty()) {
timedChannel->SetInitiatorType(NS_LITERAL_STRING("img"));
}
}
nsAutoCString contentType;
nsresult rv = channel->GetContentType(contentType);
if (!contentType.IsEmpty()) {
/* If multipart/x-mixed-replace content, we'll insert a MIME decoder
in the pipeline to handle the content and pass it along to our
original listener.
*/
if (NS_LITERAL_CSTRING("multipart/x-mixed-replace").Equals(contentType)) {
nsCOMPtr<nsIStreamConverterService> convServ(
do_GetService("@mozilla.org/streamConverters;1", &rv));
if (NS_SUCCEEDED(rv)) {
nsCOMPtr<nsIStreamListener> toListener(mDestListener);
nsCOMPtr<nsIStreamListener> fromListener;
rv = convServ->AsyncConvertData("multipart/x-mixed-replace", "*/*",
toListener, nullptr,
getter_AddRefs(fromListener));
if (NS_SUCCEEDED(rv)) {
mDestListener = fromListener;
}
}
}
}
}
return mDestListener->OnStartRequest(aRequest);
}
NS_IMETHODIMP
ProxyListener::OnStopRequest(nsIRequest* aRequest, nsresult status) {
if (!mDestListener) {
return NS_ERROR_FAILURE;
}
return mDestListener->OnStopRequest(aRequest, status);
}
/** nsIStreamListener methods **/
NS_IMETHODIMP
ProxyListener::OnDataAvailable(nsIRequest* aRequest, nsIInputStream* inStr,
uint64_t sourceOffset, uint32_t count) {
if (!mDestListener) {
return NS_ERROR_FAILURE;
}
return mDestListener->OnDataAvailable(aRequest, inStr, sourceOffset, count);
}
/** nsThreadRetargetableStreamListener methods **/
NS_IMETHODIMP
ProxyListener::CheckListenerChain() {
NS_ASSERTION(NS_IsMainThread(), "Should be on the main thread!");
nsresult rv = NS_OK;
nsCOMPtr<nsIThreadRetargetableStreamListener> retargetableListener =
do_QueryInterface(mDestListener, &rv);
if (retargetableListener) {
rv = retargetableListener->CheckListenerChain();
}
MOZ_LOG(
gImgLog, LogLevel::Debug,
("ProxyListener::CheckListenerChain %s [this=%p listener=%p rv=%" PRIx32
"]",
(NS_SUCCEEDED(rv) ? "success" : "failure"), this,
(nsIStreamListener*)mDestListener, static_cast<uint32_t>(rv)));
return rv;
}
/**
* http validate class. check a channel for a 304
*/
NS_IMPL_ISUPPORTS(imgCacheValidator, nsIStreamListener, nsIRequestObserver,
nsIThreadRetargetableStreamListener, nsIChannelEventSink,
nsIInterfaceRequestor, nsIAsyncVerifyRedirectCallback)
imgCacheValidator::imgCacheValidator(nsProgressNotificationProxy* progress,
imgLoader* loader, imgRequest* request,
nsISupports* aContext,
uint64_t aInnerWindowId,
bool forcePrincipalCheckForCacheEntry)
: mProgressProxy(progress),
mRequest(request),
mContext(aContext),
mInnerWindowId(aInnerWindowId),
mImgLoader(loader),
mHadInsecureRedirect(false) {
NewRequestAndEntry(forcePrincipalCheckForCacheEntry, loader,
mRequest->CacheKey(), getter_AddRefs(mNewRequest),
getter_AddRefs(mNewEntry));
}
imgCacheValidator::~imgCacheValidator() {
if (mRequest) {
// If something went wrong, and we never unblocked the requests waiting on
// validation, now is our last chance. We will cancel the new request and
// switch the waiting proxies to it.
UpdateProxies(/* aCancelRequest */ true, /* aSyncNotify */ false);
}
}
void imgCacheValidator::AddProxy(imgRequestProxy* aProxy) {
// aProxy needs to be in the loadgroup since we're validating from
// the network.
aProxy->AddToLoadGroup();
mProxies.AppendElement(aProxy);
}
void imgCacheValidator::RemoveProxy(imgRequestProxy* aProxy) {
mProxies.RemoveElement(aProxy);
}
void imgCacheValidator::UpdateProxies(bool aCancelRequest, bool aSyncNotify) {
MOZ_ASSERT(mRequest);
// Clear the validator before updating the proxies. The notifications may
// clone an existing request, and its state could be inconsistent.
mRequest->SetValidator(nullptr);
mRequest = nullptr;
// If an error occurred, we will want to cancel the new request, and make the
// validating proxies point to it. Any proxies still bound to the original
// request which are not validating should remain untouched.
if (aCancelRequest) {
MOZ_ASSERT(mNewRequest);
mNewRequest->CancelAndAbort(NS_BINDING_ABORTED);
}
// We have finished validating the request, so we can safely take ownership
// of the proxy list. imgRequestProxy::SyncNotifyListener can mutate the list
// if imgRequestProxy::CancelAndForgetObserver is called by its owner. Note
// that any potential notifications should still be suppressed in
// imgRequestProxy::ChangeOwner because we haven't cleared the validating
// flag yet, and thus they will remain deferred.
AutoTArray<RefPtr<imgRequestProxy>, 4> proxies(std::move(mProxies));
for (auto& proxy : proxies) {
// First update the state of all proxies before notifying any of them
// to ensure a consistent state (e.g. in case the notification causes
// other proxies to be touched indirectly.)
MOZ_ASSERT(proxy->IsValidating());
MOZ_ASSERT(proxy->NotificationsDeferred(),
"Proxies waiting on cache validation should be "
"deferring notifications!");
if (mNewRequest) {
proxy->ChangeOwner(mNewRequest);
}
proxy->ClearValidating();
}
mNewRequest = nullptr;
mNewEntry = nullptr;
for (auto& proxy : proxies) {
if (aSyncNotify) {
// Notify synchronously, because the caller knows we are already in an
// asynchronously-called function (e.g. OnStartRequest).
proxy->SyncNotifyListener();
} else {
// Notify asynchronously, because the caller does not know our current
// call state (e.g. ~imgCacheValidator).
proxy->NotifyListener();
}
}
}
/** nsIRequestObserver methods **/
NS_IMETHODIMP
imgCacheValidator::OnStartRequest(nsIRequest* aRequest) {
// We may be holding on to a document, so ensure that it's released.
nsCOMPtr<nsISupports> context = mContext.forget();
// If for some reason we don't still have an existing request (probably
// because OnStartRequest got delivered more than once), just bail.
if (!mRequest) {
MOZ_ASSERT_UNREACHABLE("OnStartRequest delivered more than once?");
aRequest->Cancel(NS_BINDING_ABORTED);
return NS_ERROR_FAILURE;
}
// If this request is coming from cache and has the same URI as our
// imgRequest, the request all our proxies are pointing at is valid, and all
// we have to do is tell them to notify their listeners.
nsCOMPtr<nsICacheInfoChannel> cacheChan(do_QueryInterface(aRequest));
nsCOMPtr<nsIChannel> channel(do_QueryInterface(aRequest));
if (cacheChan && channel && !mRequest->CacheChanged(aRequest)) {
bool isFromCache = false;
cacheChan->IsFromCache(&isFromCache);
nsCOMPtr<nsIURI> channelURI;
channel->GetURI(getter_AddRefs(channelURI));
nsCOMPtr<nsIURI> finalURI;
mRequest->GetFinalURI(getter_AddRefs(finalURI));
bool sameURI = false;
if (channelURI && finalURI) {
channelURI->Equals(finalURI, &sameURI);
}
if (isFromCache && sameURI) {
// We don't need to load this any more.
aRequest->Cancel(NS_BINDING_ABORTED);
mNewRequest = nullptr;
// Clear the validator before updating the proxies. The notifications may
// clone an existing request, and its state could be inconsistent.
mRequest->SetLoadId(context);
mRequest->SetInnerWindowID(mInnerWindowId);
UpdateProxies(/* aCancelRequest */ false, /* aSyncNotify */ true);
return NS_OK;
}
}
// We can't load out of cache. We have to create a whole new request for the
// data that's coming in off the channel.
nsCOMPtr<nsIURI> uri;
mRequest->GetURI(getter_AddRefs(uri));
LOG_MSG_WITH_PARAM(gImgLog,
"imgCacheValidator::OnStartRequest creating new request",
"uri", uri);
int32_t corsmode = mRequest->GetCORSMode();
nsCOMPtr<nsIReferrerInfo> referrerInfo = mRequest->GetReferrerInfo();
nsCOMPtr<nsIPrincipal> triggeringPrincipal =
mRequest->GetTriggeringPrincipal();
// Doom the old request's cache entry
mRequest->RemoveFromCache();
// We use originalURI here to fulfil the imgIRequest contract on GetURI.
nsCOMPtr<nsIURI> originalURI;
channel->GetOriginalURI(getter_AddRefs(originalURI));
nsresult rv = mNewRequest->Init(originalURI, uri, mHadInsecureRedirect,
aRequest, channel, mNewEntry, context,
triggeringPrincipal, corsmode, referrerInfo);
if (NS_FAILED(rv)) {
UpdateProxies(/* aCancelRequest */ true, /* aSyncNotify */ true);
return rv;
}
mDestListener = new ProxyListener(mNewRequest);
// Try to add the new request into the cache. Note that the entry must be in
// the cache before the proxies' ownership changes, because adding a proxy
// changes the caching behaviour for imgRequests.
mImgLoader->PutIntoCache(mNewRequest->CacheKey(), mNewEntry);
UpdateProxies(/* aCancelRequest */ false, /* aSyncNotify */ true);
return mDestListener->OnStartRequest(aRequest);
}
NS_IMETHODIMP
imgCacheValidator::OnStopRequest(nsIRequest* aRequest, nsresult status) {
// Be sure we've released the document that we may have been holding on to.
mContext = nullptr;
if (!mDestListener) {
return NS_OK;
}
return mDestListener->OnStopRequest(aRequest, status);
}
/** nsIStreamListener methods **/
NS_IMETHODIMP
imgCacheValidator::OnDataAvailable(nsIRequest* aRequest, nsIInputStream* inStr,
uint64_t sourceOffset, uint32_t count) {
if (!mDestListener) {
// XXX see bug 113959
uint32_t _retval;
inStr->ReadSegments(NS_DiscardSegment, nullptr, count, &_retval);
return NS_OK;
}
return mDestListener->OnDataAvailable(aRequest, inStr, sourceOffset, count);
}
/** nsIThreadRetargetableStreamListener methods **/
NS_IMETHODIMP
imgCacheValidator::CheckListenerChain() {
NS_ASSERTION(NS_IsMainThread(), "Should be on the main thread!");
nsresult rv = NS_OK;
nsCOMPtr<nsIThreadRetargetableStreamListener> retargetableListener =
do_QueryInterface(mDestListener, &rv);
if (retargetableListener) {
rv = retargetableListener->CheckListenerChain();
}
MOZ_LOG(
gImgLog, LogLevel::Debug,
("[this=%p] imgCacheValidator::CheckListenerChain -- rv %" PRId32 "=%s",
this, static_cast<uint32_t>(rv),
NS_SUCCEEDED(rv) ? "succeeded" : "failed"));
return rv;
}
/** nsIInterfaceRequestor methods **/
NS_IMETHODIMP
imgCacheValidator::GetInterface(const nsIID& aIID, void** aResult) {
if (aIID.Equals(NS_GET_IID(nsIChannelEventSink))) {
return QueryInterface(aIID, aResult);
}
return mProgressProxy->GetInterface(aIID, aResult);
}
// These functions are materially the same as the same functions in imgRequest.
// We duplicate them because we're verifying whether cache loads are necessary,
// not unconditionally loading.
/** nsIChannelEventSink methods **/
NS_IMETHODIMP
imgCacheValidator::AsyncOnChannelRedirect(
nsIChannel* oldChannel, nsIChannel* newChannel, uint32_t flags,
nsIAsyncVerifyRedirectCallback* callback) {
// Note all cache information we get from the old channel.
mNewRequest->SetCacheValidation(mNewEntry, oldChannel);
// If the previous URI is a non-HTTPS URI, record that fact for later use by
// security code, which needs to know whether there is an insecure load at any
// point in the redirect chain.
nsCOMPtr<nsIURI> oldURI;
bool schemeLocal = false;
if (NS_FAILED(oldChannel->GetURI(getter_AddRefs(oldURI))) ||
NS_FAILED(NS_URIChainHasFlags(
oldURI, nsIProtocolHandler::URI_IS_LOCAL_RESOURCE, &schemeLocal)) ||
(!oldURI->SchemeIs("https") && !oldURI->SchemeIs("chrome") &&
!schemeLocal)) {
mHadInsecureRedirect = true;
}
// Prepare for callback
mRedirectCallback = callback;
mRedirectChannel = newChannel;
return mProgressProxy->AsyncOnChannelRedirect(oldChannel, newChannel, flags,
this);
}
NS_IMETHODIMP
imgCacheValidator::OnRedirectVerifyCallback(nsresult aResult) {
// If we've already been told to abort, just do so.
if (NS_FAILED(aResult)) {
mRedirectCallback->OnRedirectVerifyCallback(aResult);
mRedirectCallback = nullptr;
mRedirectChannel = nullptr;
return NS_OK;
}
// make sure we have a protocol that returns data rather than opens
// an external application, e.g. mailto:
nsCOMPtr<nsIURI> uri;
mRedirectChannel->GetURI(getter_AddRefs(uri));
bool doesNotReturnData = false;
NS_URIChainHasFlags(uri, nsIProtocolHandler::URI_DOES_NOT_RETURN_DATA,
&doesNotReturnData);
nsresult result = NS_OK;
if (doesNotReturnData) {
result = NS_ERROR_ABORT;
}
mRedirectCallback->OnRedirectVerifyCallback(result);
mRedirectCallback = nullptr;
mRedirectChannel = nullptr;
return NS_OK;
}