third_party/perfetto/src/ipc/buffered_frame_deserializer.cc - cobalt - Git at Google

 /*
  * Copyright (C) 2017 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "src/ipc/buffered_frame_deserializer.h"

 #include <algorithm>
 #include <cinttypes>
 #include <type_traits>
 #include <utility>

 #include "perfetto/base/logging.h"
 #include "perfetto/ext/base/utils.h"

 #include "protos/perfetto/ipc/wire_protocol.gen.h"

 namespace perfetto {
 namespace ipc {

 namespace {

 // The header is just the number of bytes of the Frame protobuf message.
 constexpr size_t kHeaderSize = sizeof(uint32_t);
 }  // namespace

 BufferedFrameDeserializer::BufferedFrameDeserializer(size_t max_capacity)
     : capacity_(max_capacity) {
   PERFETTO_CHECK(max_capacity % base::GetSysPageSize() == 0);
   PERFETTO_CHECK(max_capacity >= base::GetSysPageSize());
 }

 BufferedFrameDeserializer::~BufferedFrameDeserializer() = default;

 BufferedFrameDeserializer::ReceiveBuffer
 BufferedFrameDeserializer::BeginReceive() {
   // Upon the first recv initialize the buffer to the max message size but
   // release the physical memory for all but the first page. The kernel will
   // automatically give us physical pages back as soon as we page-fault on them.
   if (!buf_.IsValid()) {
     PERFETTO_DCHECK(size_ == 0);
     // TODO(eseckler): Don't commit all of the buffer at once on Windows.
     buf_ = base::PagedMemory::Allocate(capacity_);

     // Surely we are going to use at least the first page, but we may not need
     // the rest for a bit.
     const auto page_size = base::GetSysPageSize();
     buf_.AdviseDontNeed(buf() + page_size, capacity_ - page_size);
   }

   PERFETTO_CHECK(capacity_ > size_);
   return ReceiveBuffer{buf() + size_, capacity_ - size_};
 }

 bool BufferedFrameDeserializer::EndReceive(size_t recv_size) {
   const auto page_size = base::GetSysPageSize();
   PERFETTO_CHECK(recv_size + size_ <= capacity_);
   size_ += recv_size;

   // At this point the contents buf_ can contain:
   // A) Only a fragment of the header (the size of the frame). E.g.,
   //    03 00 00 (the header is 4 bytes, one is missing).
   //
   // B) A header and a part of the frame. E.g.,
   //     05 00 00 00         11 22 33
   //    [ header, size=5 ]  [ Partial frame ]
   //
   // C) One or more complete header+frame. E.g.,
   //     05 00 00 00         11 22 33 44 55   03 00 00 00        AA BB CC
   //    [ header, size=5 ]  [ Whole frame ]  [ header, size=3 ] [ Whole frame ]
   //
   // D) Some complete header+frame(s) and a partial header or frame (C + A/B).
   //
   // C Is the more likely case and the one we are optimizing for. A, B, D can
   // happen because of the streaming nature of the socket.
   // The invariant of this function is that, when it returns, buf_ is either
   // empty (we drained all the complete frames) or starts with the header of the
   // next, still incomplete, frame.

   size_t consumed_size = 0;
   for (;;) {
     if (size_ < consumed_size + kHeaderSize)
       break;  // Case A, not enough data to read even the header.

     // Read the header into |payload_size|.
     uint32_t payload_size = 0;
     const char* rd_ptr = buf() + consumed_size;
     memcpy(base::AssumeLittleEndian(&payload_size), rd_ptr, kHeaderSize);

     // Saturate the |payload_size| to prevent overflows. The > capacity_ check
     // below will abort the parsing.
     size_t next_frame_size =
         std::min(static_cast<size_t>(payload_size), capacity_);
     next_frame_size += kHeaderSize;
     rd_ptr += kHeaderSize;

     if (size_ < consumed_size + next_frame_size) {
       // Case B. We got the header but not the whole frame.
       if (next_frame_size > capacity_) {
         // The caller is expected to shut down the socket and give up at this
         // point. If it doesn't do that and insists going on at some point it
         // will hit the capacity check in BeginReceive().
         PERFETTO_LOG("IPC Frame too large (size %zu)", next_frame_size);
         return false;
       }
       break;
     }

     // Case C. We got at least one header and whole frame.
     DecodeFrame(rd_ptr, payload_size);
     consumed_size += next_frame_size;
   }

   PERFETTO_DCHECK(consumed_size <= size_);
   if (consumed_size > 0) {
     // Shift out the consumed data from the buffer. In the typical case (C)
     // there is nothing to shift really, just setting size_ = 0 is enough.
     // Shifting is only for the (unlikely) case D.
     size_ -= consumed_size;
     if (size_ > 0) {
       // Case D. We consumed some frames but there is a leftover at the end of
       // the buffer. Shift out the consumed bytes, so that on the next round
       // |buf_| starts with the header of the next unconsumed frame.
       const char* move_begin = buf() + consumed_size;
       PERFETTO_CHECK(move_begin > buf());
       PERFETTO_CHECK(move_begin + size_ <= buf() + capacity_);
       memmove(buf(), move_begin, size_);
     }
     // If we just finished decoding a large frame that used more than one page,
     // release the extra memory in the buffer. Large frames should be quite
     // rare.
     if (consumed_size > page_size) {
       size_t size_rounded_up = (size_ / page_size + 1) * page_size;
       if (size_rounded_up < capacity_) {
         char* madvise_begin = buf() + size_rounded_up;
         const size_t madvise_size = capacity_ - size_rounded_up;
         PERFETTO_CHECK(madvise_begin > buf() + size_);
         PERFETTO_CHECK(madvise_begin + madvise_size <= buf() + capacity_);
         buf_.AdviseDontNeed(madvise_begin, madvise_size);
       }
     }
   }
   // At this point |size_| == 0 for case C, > 0 for cases A, B, D.
   return true;
 }

 std::unique_ptr<Frame> BufferedFrameDeserializer::PopNextFrame() {
   if (decoded_frames_.empty())
     return nullptr;
   std::unique_ptr<Frame> frame = std::move(decoded_frames_.front());
   decoded_frames_.pop_front();
   return frame;
 }

 void BufferedFrameDeserializer::DecodeFrame(const char* data, size_t size) {
   if (size == 0)
     return;
   std::unique_ptr<Frame> frame(new Frame);
   if (frame->ParseFromArray(data, size))
     decoded_frames_.push_back(std::move(frame));
 }

 // static
 std::string BufferedFrameDeserializer::Serialize(const Frame& frame) {
   std::vector<uint8_t> payload = frame.SerializeAsArray();
   const uint32_t payload_size = static_cast<uint32_t>(payload.size());
   std::string buf;
   buf.resize(kHeaderSize + payload_size);
   memcpy(&buf[0], base::AssumeLittleEndian(&payload_size), kHeaderSize);
   memcpy(&buf[kHeaderSize], payload.data(), payload.size());
   return buf;
 }

 }  // namespace ipc
 }  // namespace perfetto
	/*
	* Copyright (C) 2017 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "src/ipc/buffered_frame_deserializer.h"

	#include <algorithm>
	#include <cinttypes>
	#include <type_traits>
	#include <utility>

	#include "perfetto/base/logging.h"
	#include "perfetto/ext/base/utils.h"

	#include "protos/perfetto/ipc/wire_protocol.gen.h"

	namespace perfetto {
	namespace ipc {

	namespace {

	// The header is just the number of bytes of the Frame protobuf message.
	constexpr size_t kHeaderSize = sizeof(uint32_t);
	} // namespace

	BufferedFrameDeserializer::BufferedFrameDeserializer(size_t max_capacity)
	: capacity_(max_capacity) {
	PERFETTO_CHECK(max_capacity % base::GetSysPageSize() == 0);
	PERFETTO_CHECK(max_capacity >= base::GetSysPageSize());
	}

	BufferedFrameDeserializer::~BufferedFrameDeserializer() = default;

	BufferedFrameDeserializer::ReceiveBuffer
	BufferedFrameDeserializer::BeginReceive() {
	// Upon the first recv initialize the buffer to the max message size but
	// release the physical memory for all but the first page. The kernel will
	// automatically give us physical pages back as soon as we page-fault on them.
	if (!buf_.IsValid()) {
	PERFETTO_DCHECK(size_ == 0);
	// TODO(eseckler): Don't commit all of the buffer at once on Windows.
	buf_ = base::PagedMemory::Allocate(capacity_);

	// Surely we are going to use at least the first page, but we may not need
	// the rest for a bit.
	const auto page_size = base::GetSysPageSize();
	buf_.AdviseDontNeed(buf() + page_size, capacity_ - page_size);
	}

	PERFETTO_CHECK(capacity_ > size_);
	return ReceiveBuffer{buf() + size_, capacity_ - size_};
	}

	bool BufferedFrameDeserializer::EndReceive(size_t recv_size) {
	const auto page_size = base::GetSysPageSize();
	PERFETTO_CHECK(recv_size + size_ <= capacity_);
	size_ += recv_size;

	// At this point the contents buf_ can contain:
	// A) Only a fragment of the header (the size of the frame). E.g.,
	// 03 00 00 (the header is 4 bytes, one is missing).
	//
	// B) A header and a part of the frame. E.g.,
	// 05 00 00 00 11 22 33
	// [ header, size=5 ] [ Partial frame ]
	//
	// C) One or more complete header+frame. E.g.,
	// 05 00 00 00 11 22 33 44 55 03 00 00 00 AA BB CC
	// [ header, size=5 ] [ Whole frame ] [ header, size=3 ] [ Whole frame ]
	//
	// D) Some complete header+frame(s) and a partial header or frame (C + A/B).
	//
	// C Is the more likely case and the one we are optimizing for. A, B, D can
	// happen because of the streaming nature of the socket.
	// The invariant of this function is that, when it returns, buf_ is either
	// empty (we drained all the complete frames) or starts with the header of the
	// next, still incomplete, frame.

	size_t consumed_size = 0;
	for (;;) {
	if (size_ < consumed_size + kHeaderSize)
	break; // Case A, not enough data to read even the header.

	// Read the header into \|payload_size\|.
	uint32_t payload_size = 0;
	const char* rd_ptr = buf() + consumed_size;
	memcpy(base::AssumeLittleEndian(&payload_size), rd_ptr, kHeaderSize);

	// Saturate the \|payload_size\| to prevent overflows. The > capacity_ check
	// below will abort the parsing.
	size_t next_frame_size =
	std::min(static_cast<size_t>(payload_size), capacity_);
	next_frame_size += kHeaderSize;
	rd_ptr += kHeaderSize;

	if (size_ < consumed_size + next_frame_size) {
	// Case B. We got the header but not the whole frame.
	if (next_frame_size > capacity_) {
	// The caller is expected to shut down the socket and give up at this
	// point. If it doesn't do that and insists going on at some point it
	// will hit the capacity check in BeginReceive().
	PERFETTO_LOG("IPC Frame too large (size %zu)", next_frame_size);
	return false;
	}
	break;
	}

	// Case C. We got at least one header and whole frame.
	DecodeFrame(rd_ptr, payload_size);
	consumed_size += next_frame_size;
	}

	PERFETTO_DCHECK(consumed_size <= size_);
	if (consumed_size > 0) {
	// Shift out the consumed data from the buffer. In the typical case (C)
	// there is nothing to shift really, just setting size_ = 0 is enough.
	// Shifting is only for the (unlikely) case D.
	size_ -= consumed_size;
	if (size_ > 0) {
	// Case D. We consumed some frames but there is a leftover at the end of
	// the buffer. Shift out the consumed bytes, so that on the next round
	// \|buf_\| starts with the header of the next unconsumed frame.
	const char* move_begin = buf() + consumed_size;
	PERFETTO_CHECK(move_begin > buf());
	PERFETTO_CHECK(move_begin + size_ <= buf() + capacity_);
	memmove(buf(), move_begin, size_);
	}
	// If we just finished decoding a large frame that used more than one page,
	// release the extra memory in the buffer. Large frames should be quite
	// rare.
	if (consumed_size > page_size) {
	size_t size_rounded_up = (size_ / page_size + 1) * page_size;
	if (size_rounded_up < capacity_) {
	char* madvise_begin = buf() + size_rounded_up;
	const size_t madvise_size = capacity_ - size_rounded_up;
	PERFETTO_CHECK(madvise_begin > buf() + size_);
	PERFETTO_CHECK(madvise_begin + madvise_size <= buf() + capacity_);
	buf_.AdviseDontNeed(madvise_begin, madvise_size);
	}
	}
	}
	// At this point \|size_\| == 0 for case C, > 0 for cases A, B, D.
	return true;
	}

	std::unique_ptr<Frame> BufferedFrameDeserializer::PopNextFrame() {
	if (decoded_frames_.empty())
	return nullptr;
	std::unique_ptr<Frame> frame = std::move(decoded_frames_.front());
	decoded_frames_.pop_front();
	return frame;
	}

	void BufferedFrameDeserializer::DecodeFrame(const char* data, size_t size) {
	if (size == 0)
	return;
	std::unique_ptr<Frame> frame(new Frame);
	if (frame->ParseFromArray(data, size))
	decoded_frames_.push_back(std::move(frame));
	}

	// static
	std::string BufferedFrameDeserializer::Serialize(const Frame& frame) {
	std::vector<uint8_t> payload = frame.SerializeAsArray();
	const uint32_t payload_size = static_cast<uint32_t>(payload.size());
	std::string buf;
	buf.resize(kHeaderSize + payload_size);
	memcpy(&buf[0], base::AssumeLittleEndian(&payload_size), kHeaderSize);
	memcpy(&buf[kHeaderSize], payload.data(), payload.size());
	return buf;
	}

	} // namespace ipc
	} // namespace perfetto