http2/decoder/decode_buffer.h - quiche - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef QUICHE_HTTP2_DECODER_DECODE_BUFFER_H_
 #define QUICHE_HTTP2_DECODER_DECODE_BUFFER_H_

 // DecodeBuffer provides primitives for decoding various integer types found in
 // HTTP/2 frames. It wraps a byte array from which we can read and decode
 // serialized HTTP/2 frames, or parts thereof. DecodeBuffer is intended only for
 // stack allocation, where the caller is typically going to use the DecodeBuffer
 // instance as part of decoding the entire buffer before returning to its own
 // caller.

 #include <stddef.h>

 #include <algorithm>
 #include <cstdint>

 #include "absl/strings/string_view.h"
 #include "net/third_party/quiche/src/http2/platform/api/http2_logging.h"
 #include "net/third_party/quiche/src/common/platform/api/quiche_export.h"

 namespace http2 {
 class DecodeBufferSubset;

 class QUICHE_EXPORT_PRIVATE DecodeBuffer {
  public:
   DecodeBuffer(const char* buffer, size_t len)
       : buffer_(buffer), cursor_(buffer), beyond_(buffer + len) {
     DCHECK(buffer != nullptr);
     // We assume the decode buffers will typically be modest in size (i.e. often
     // a few KB, perhaps as high as 100KB). Let's make sure during testing that
     // we don't go very high, with 32MB selected rather arbitrarily.
     const size_t kMaxDecodeBufferLength = 1 << 25;
     DCHECK_LE(len, kMaxDecodeBufferLength);
   }
   explicit DecodeBuffer(absl::string_view s)
       : DecodeBuffer(s.data(), s.size()) {}
   // Constructor for character arrays, typically in tests. For example:
   //    const char input[] = { 0x11 };
   //    DecodeBuffer b(input);
   template <size_t N>
   explicit DecodeBuffer(const char (&buf)[N]) : DecodeBuffer(buf, N) {}

   DecodeBuffer(const DecodeBuffer&) = delete;
   DecodeBuffer operator=(const DecodeBuffer&) = delete;

   bool Empty() const { return cursor_ >= beyond_; }
   bool HasData() const { return cursor_ < beyond_; }
   size_t Remaining() const {
     DCHECK_LE(cursor_, beyond_);
     return beyond_ - cursor_;
   }
   size_t Offset() const { return cursor_ - buffer_; }
   size_t FullSize() const { return beyond_ - buffer_; }

   // Returns the minimum of the number of bytes remaining in this DecodeBuffer
   // and |length|, in support of determining how much of some structure/payload
   // is in this DecodeBuffer.
   size_t MinLengthRemaining(size_t length) const {
     return std::min(length, Remaining());
   }

   // For string decoding, returns a pointer to the next byte/char to be decoded.
   const char* cursor() const { return cursor_; }
   // Advances the cursor (pointer to the next byte/char to be decoded).
   void AdvanceCursor(size_t amount) {
     DCHECK_LE(amount, Remaining());  // Need at least that much remaining.
     DCHECK_EQ(subset_, nullptr) << "Access via subset only when present.";
     cursor_ += amount;
   }

   // Only call methods starting "Decode" when there is enough input remaining.
   char DecodeChar() {
     DCHECK_LE(1u, Remaining());  // Need at least one byte remaining.
     DCHECK_EQ(subset_, nullptr) << "Access via subset only when present.";
     return *cursor_++;
   }

   uint8_t DecodeUInt8();
   uint16_t DecodeUInt16();
   uint32_t DecodeUInt24();

   // For 31-bit unsigned integers, where the 32nd bit is reserved for future
   // use (i.e. the high-bit of the first byte of the encoding); examples:
   // the Stream Id in a frame header or the Window Size Increment in a
   // WINDOW_UPDATE frame.
   uint32_t DecodeUInt31();

   uint32_t DecodeUInt32();

  protected:
 #ifndef NDEBUG
   // These are part of validating during tests that there is at most one
   // DecodeBufferSubset instance at a time for any DecodeBuffer instance.
   void set_subset_of_base(DecodeBuffer* base, const DecodeBufferSubset* subset);
   void clear_subset_of_base(DecodeBuffer* base,
                             const DecodeBufferSubset* subset);
 #endif

  private:
 #ifndef NDEBUG
   void set_subset(const DecodeBufferSubset* subset);
   void clear_subset(const DecodeBufferSubset* subset);
 #endif

   // Prevent heap allocation of DecodeBuffer.
   static void* operator new(size_t s);
   static void* operator new[](size_t s);
   static void operator delete(void* p);
   static void operator delete[](void* p);

   const char* const buffer_;
   const char* cursor_;
   const char* const beyond_;
   const DecodeBufferSubset* subset_ = nullptr;  // Used for DCHECKs.
 };

 // DecodeBufferSubset is used when decoding a known sized chunk of data, which
 // starts at base->cursor(), and continues for subset_len, which may be
 // entirely in |base|, or may extend beyond it (hence the MinLengthRemaining
 // in the constructor).
 // There are two benefits to using DecodeBufferSubset: it ensures that the
 // cursor of |base| is advanced when the subset's destructor runs, and it
 // ensures that the consumer of the subset can't go beyond the subset which
 // it is intended to decode.
 // There must be only a single DecodeBufferSubset at a time for a base
 // DecodeBuffer, though they can be nested (i.e. a DecodeBufferSubset's
 // base may itself be a DecodeBufferSubset). This avoids the AdvanceCursor
 // being called erroneously.
 class QUICHE_EXPORT_PRIVATE DecodeBufferSubset : public DecodeBuffer {
  public:
   DecodeBufferSubset(DecodeBuffer* base, size_t subset_len)
       : DecodeBuffer(base->cursor(), base->MinLengthRemaining(subset_len)),
         base_buffer_(base) {
 #ifndef NDEBUG
     DebugSetup();
 #endif
   }

   DecodeBufferSubset(const DecodeBufferSubset&) = delete;
   DecodeBufferSubset operator=(const DecodeBufferSubset&) = delete;

   ~DecodeBufferSubset() {
     size_t offset = Offset();
 #ifndef NDEBUG
     DebugTearDown();
 #endif
     base_buffer_->AdvanceCursor(offset);
   }

  private:
   DecodeBuffer* const base_buffer_;
 #ifndef NDEBUG
   size_t start_base_offset_;  // Used for DCHECKs.
   size_t max_base_offset_;    // Used for DCHECKs.

   void DebugSetup();
   void DebugTearDown();
 #endif
 };

 }  // namespace http2

 #endif  // QUICHE_HTTP2_DECODER_DECODE_BUFFER_H_
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef QUICHE_HTTP2_DECODER_DECODE_BUFFER_H_
	#define QUICHE_HTTP2_DECODER_DECODE_BUFFER_H_

	// DecodeBuffer provides primitives for decoding various integer types found in
	// HTTP/2 frames. It wraps a byte array from which we can read and decode
	// serialized HTTP/2 frames, or parts thereof. DecodeBuffer is intended only for
	// stack allocation, where the caller is typically going to use the DecodeBuffer
	// instance as part of decoding the entire buffer before returning to its own
	// caller.

	#include <stddef.h>

	#include <algorithm>
	#include <cstdint>

	#include "absl/strings/string_view.h"
	#include "net/third_party/quiche/src/http2/platform/api/http2_logging.h"
	#include "net/third_party/quiche/src/common/platform/api/quiche_export.h"

	namespace http2 {
	class DecodeBufferSubset;

	class QUICHE_EXPORT_PRIVATE DecodeBuffer {
	public:
	DecodeBuffer(const char* buffer, size_t len)
	: buffer_(buffer), cursor_(buffer), beyond_(buffer + len) {
	DCHECK(buffer != nullptr);
	// We assume the decode buffers will typically be modest in size (i.e. often
	// a few KB, perhaps as high as 100KB). Let's make sure during testing that
	// we don't go very high, with 32MB selected rather arbitrarily.
	const size_t kMaxDecodeBufferLength = 1 << 25;
	DCHECK_LE(len, kMaxDecodeBufferLength);
	}
	explicit DecodeBuffer(absl::string_view s)
	: DecodeBuffer(s.data(), s.size()) {}
	// Constructor for character arrays, typically in tests. For example:
	// const char input[] = { 0x11 };
	// DecodeBuffer b(input);
	template <size_t N>
	explicit DecodeBuffer(const char (&buf)[N]) : DecodeBuffer(buf, N) {}

	DecodeBuffer(const DecodeBuffer&) = delete;
	DecodeBuffer operator=(const DecodeBuffer&) = delete;

	bool Empty() const { return cursor_ >= beyond_; }
	bool HasData() const { return cursor_ < beyond_; }
	size_t Remaining() const {
	DCHECK_LE(cursor_, beyond_);
	return beyond_ - cursor_;
	}
	size_t Offset() const { return cursor_ - buffer_; }
	size_t FullSize() const { return beyond_ - buffer_; }

	// Returns the minimum of the number of bytes remaining in this DecodeBuffer
	// and \|length\|, in support of determining how much of some structure/payload
	// is in this DecodeBuffer.
	size_t MinLengthRemaining(size_t length) const {
	return std::min(length, Remaining());
	}

	// For string decoding, returns a pointer to the next byte/char to be decoded.
	const char* cursor() const { return cursor_; }
	// Advances the cursor (pointer to the next byte/char to be decoded).
	void AdvanceCursor(size_t amount) {
	DCHECK_LE(amount, Remaining()); // Need at least that much remaining.
	DCHECK_EQ(subset_, nullptr) << "Access via subset only when present.";
	cursor_ += amount;
	}

	// Only call methods starting "Decode" when there is enough input remaining.
	char DecodeChar() {
	DCHECK_LE(1u, Remaining()); // Need at least one byte remaining.
	DCHECK_EQ(subset_, nullptr) << "Access via subset only when present.";
	return *cursor_++;
	}

	uint8_t DecodeUInt8();
	uint16_t DecodeUInt16();
	uint32_t DecodeUInt24();

	// For 31-bit unsigned integers, where the 32nd bit is reserved for future
	// use (i.e. the high-bit of the first byte of the encoding); examples:
	// the Stream Id in a frame header or the Window Size Increment in a
	// WINDOW_UPDATE frame.
	uint32_t DecodeUInt31();

	uint32_t DecodeUInt32();

	protected:
	#ifndef NDEBUG
	// These are part of validating during tests that there is at most one
	// DecodeBufferSubset instance at a time for any DecodeBuffer instance.
	void set_subset_of_base(DecodeBuffer* base, const DecodeBufferSubset* subset);
	void clear_subset_of_base(DecodeBuffer* base,
	const DecodeBufferSubset* subset);
	#endif

	private:
	#ifndef NDEBUG
	void set_subset(const DecodeBufferSubset* subset);
	void clear_subset(const DecodeBufferSubset* subset);
	#endif

	// Prevent heap allocation of DecodeBuffer.
	static void* operator new(size_t s);
	static void* operator new[](size_t s);
	static void operator delete(void* p);
	static void operator delete[](void* p);

	const char* const buffer_;
	const char* cursor_;
	const char* const beyond_;
	const DecodeBufferSubset* subset_ = nullptr; // Used for DCHECKs.
	};

	// DecodeBufferSubset is used when decoding a known sized chunk of data, which
	// starts at base->cursor(), and continues for subset_len, which may be
	// entirely in \|base\|, or may extend beyond it (hence the MinLengthRemaining
	// in the constructor).
	// There are two benefits to using DecodeBufferSubset: it ensures that the
	// cursor of \|base\| is advanced when the subset's destructor runs, and it
	// ensures that the consumer of the subset can't go beyond the subset which
	// it is intended to decode.
	// There must be only a single DecodeBufferSubset at a time for a base
	// DecodeBuffer, though they can be nested (i.e. a DecodeBufferSubset's
	// base may itself be a DecodeBufferSubset). This avoids the AdvanceCursor
	// being called erroneously.
	class QUICHE_EXPORT_PRIVATE DecodeBufferSubset : public DecodeBuffer {
	public:
	DecodeBufferSubset(DecodeBuffer* base, size_t subset_len)
	: DecodeBuffer(base->cursor(), base->MinLengthRemaining(subset_len)),
	base_buffer_(base) {
	#ifndef NDEBUG
	DebugSetup();
	#endif
	}

	DecodeBufferSubset(const DecodeBufferSubset&) = delete;
	DecodeBufferSubset operator=(const DecodeBufferSubset&) = delete;

	~DecodeBufferSubset() {
	size_t offset = Offset();
	#ifndef NDEBUG
	DebugTearDown();
	#endif
	base_buffer_->AdvanceCursor(offset);
	}

	private:
	DecodeBuffer* const base_buffer_;
	#ifndef NDEBUG
	size_t start_base_offset_; // Used for DCHECKs.
	size_t max_base_offset_; // Used for DCHECKs.

	void DebugSetup();
	void DebugTearDown();
	#endif
	};

	} // namespace http2

	#endif // QUICHE_HTTP2_DECODER_DECODE_BUFFER_H_