/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim:set ts=2 sw=2 sts=2 et cindent: */ /* 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/. */ #include "Box.h" #include "ByteStream.h" #include "mozilla/EndianUtils.h" #include "mozilla/Unused.h" #include namespace mozilla { // Limit reads to 32MiB max. // static const uint64_t Box::kMAX_BOX_READ = 32 * 1024 * 1024; // Returns the offset from the start of the body of a box of type |aType| // to the start of its first child. static uint32_t BoxOffset(AtomType aType) { const uint32_t FULLBOX_OFFSET = 4; if (aType == AtomType("mp4a") || aType == AtomType("enca")) { // AudioSampleEntry; ISO 14496-12, section 8.16 return 28; } else if (aType == AtomType("mp4v") || aType == AtomType("encv")) { // VideoSampleEntry; ISO 14496-12, section 8.16 return 78; } else if (aType == AtomType("stsd")) { // SampleDescriptionBox; ISO 14496-12, section 8.16 // This is a FullBox, and contains a |count| member before its child // boxes. return FULLBOX_OFFSET + 4; } return 0; } Box::Box(BoxContext* aContext, uint64_t aOffset, const Box* aParent) : mContext(aContext), mParent(aParent) { uint8_t header[8]; if (aOffset > INT64_MAX - sizeof(header)) { return; } MediaByteRange headerRange(aOffset, aOffset + sizeof(header)); if (mParent && !mParent->mRange.Contains(headerRange)) { return; } const MediaByteRange* byteRange; for (int i = 0;; i++) { if (i == mContext->mByteRanges.Length()) { return; } byteRange = static_cast(&mContext->mByteRanges[i]); if (byteRange->Contains(headerRange)) { break; } } size_t bytes; if (!mContext->mSource->CachedReadAt(aOffset, header, sizeof(header), &bytes) || bytes != sizeof(header)) { return; } uint64_t size = BigEndian::readUint32(header); if (size == 1) { uint8_t bigLength[8]; if (aOffset > INT64_MAX - sizeof(header) - sizeof(bigLength)) { return; } MediaByteRange bigLengthRange(headerRange.mEnd, headerRange.mEnd + sizeof(bigLength)); if ((mParent && !mParent->mRange.Contains(bigLengthRange)) || !byteRange->Contains(bigLengthRange) || !mContext->mSource->CachedReadAt(aOffset + sizeof(header), bigLength, sizeof(bigLength), &bytes) || bytes != sizeof(bigLength)) { return; } size = BigEndian::readUint64(bigLength); mBodyOffset = bigLengthRange.mEnd; } else if (size == 0) { // box extends to end of file. size = mContext->mByteRanges.LastInterval().mEnd - aOffset; mBodyOffset = headerRange.mEnd; } else { mBodyOffset = headerRange.mEnd; } if (size > INT64_MAX) { return; } int64_t end = static_cast(aOffset) + static_cast(size); if (end < static_cast(aOffset)) { // Overflowed. return; } mType = BigEndian::readUint32(&header[4]); mChildOffset = mBodyOffset + BoxOffset(mType); MediaByteRange boxRange(aOffset, end); if (mChildOffset > boxRange.mEnd || (mParent && !mParent->mRange.Contains(boxRange)) || !byteRange->Contains(boxRange)) { return; } mRange = boxRange; } Box::Box() : mContext(nullptr), mBodyOffset(0), mChildOffset(0), mParent(nullptr) {} Box Box::Next() const { MOZ_ASSERT(IsAvailable()); return Box(mContext, mRange.mEnd, mParent); } Box Box::FirstChild() const { MOZ_ASSERT(IsAvailable()); if (mChildOffset == mRange.mEnd) { return Box(); } return Box(mContext, mChildOffset, this); } nsTArray Box::ReadCompleteBox() const { const size_t length = mRange.mEnd - mRange.mStart; nsTArray out(length); out.SetLength(length); size_t bytesRead = 0; if (!mContext->mSource->CachedReadAt(mRange.mStart, out.Elements(), length, &bytesRead) || bytesRead != length) { // Byte ranges are being reported incorrectly NS_WARNING("Read failed in mozilla::Box::ReadCompleteBox()"); return nsTArray(0); } return out; } nsTArray Box::Read() const { nsTArray out; Unused << Read(&out, mRange); return out; } bool Box::Read(nsTArray* aDest, const MediaByteRange& aRange) const { int64_t length; if (!mContext->mSource->Length(&length)) { // The HTTP server didn't give us a length to work with. // Limit the read to kMAX_BOX_READ max. length = std::min(aRange.mEnd - mChildOffset, kMAX_BOX_READ); } else { length = aRange.mEnd - mChildOffset; } aDest->SetLength(length); size_t bytes; if (!mContext->mSource->CachedReadAt(mChildOffset, aDest->Elements(), aDest->Length(), &bytes) || bytes != aDest->Length()) { // Byte ranges are being reported incorrectly NS_WARNING("Read failed in mozilla::Box::Read()"); aDest->Clear(); return false; } return true; } ByteSlice Box::ReadAsSlice() { if (!mContext) { return ByteSlice{nullptr, 0}; } int64_t length; if (!mContext->mSource->Length(&length)) { // The HTTP server didn't give us a length to work with. // Limit the read to kMAX_BOX_READ max. length = std::min(mRange.mEnd - mChildOffset, kMAX_BOX_READ); } else { length = mRange.mEnd - mChildOffset; } const uint8_t* data = mContext->mSource->GetContiguousAccess(mChildOffset, length); if (data) { // We can direct access the underlying storage of the ByteStream. return ByteSlice{data, size_t(length)}; } uint8_t* p = mContext->mAllocator.Allocate(size_t(length)); size_t bytes; if (!mContext->mSource->CachedReadAt(mChildOffset, p, length, &bytes) || bytes != length) { // Byte ranges are being reported incorrectly NS_WARNING("Read failed in mozilla::Box::ReadAsSlice()"); return ByteSlice{nullptr, 0}; } return ByteSlice{p, size_t(length)}; } const size_t BLOCK_CAPACITY = 16 * 1024; uint8_t* BumpAllocator::Allocate(size_t aNumBytes) { if (aNumBytes > BLOCK_CAPACITY) { mBuffers.AppendElement(nsTArray(aNumBytes)); mBuffers.LastElement().SetLength(aNumBytes); return mBuffers.LastElement().Elements(); } for (nsTArray& buffer : mBuffers) { if (buffer.Length() + aNumBytes < BLOCK_CAPACITY) { size_t offset = buffer.Length(); buffer.SetLength(buffer.Length() + aNumBytes); return buffer.Elements() + offset; } } mBuffers.AppendElement(nsTArray(BLOCK_CAPACITY)); mBuffers.LastElement().SetLength(aNumBytes); return mBuffers.LastElement().Elements(); } } // namespace mozilla