src/wasm/decoder.h - platform/external/v8 - Git at Google

 // Copyright 2015 the V8 project 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 V8_WASM_DECODER_H_
 #define V8_WASM_DECODER_H_

 #include <memory>

 #include "src/base/compiler-specific.h"
 #include "src/flags.h"
 #include "src/signature.h"
 #include "src/utils.h"
 #include "src/wasm/wasm-result.h"
 #include "src/zone/zone-containers.h"

 namespace v8 {
 namespace internal {
 namespace wasm {

 #if DEBUG
 #define TRACE(...)                                    \
   do {                                                \
     if (FLAG_trace_wasm_decoder) PrintF(__VA_ARGS__); \
   } while (false)
 #else
 #define TRACE(...)
 #endif

 // A helper utility to decode bytes, integers, fields, varints, etc, from
 // a buffer of bytes.
 class Decoder {
  public:
   Decoder(const byte* start, const byte* end)
       : start_(start),
         pc_(start),
         end_(end),
         error_pc_(nullptr),
         error_pt_(nullptr) {}
   Decoder(const byte* start, const byte* pc, const byte* end)
       : start_(start),
         pc_(pc),
         end_(end),
         error_pc_(nullptr),
         error_pt_(nullptr) {}

   virtual ~Decoder() {}

   inline bool check(const byte* base, unsigned offset, unsigned length,
                     const char* msg) {
     DCHECK_GE(base, start_);
     if ((base + offset + length) > end_) {
       error(base, base + offset, "%s", msg);
       return false;
     }
     return true;
   }

   // Reads a single 8-bit byte, reporting an error if out of bounds.
   inline uint8_t checked_read_u8(const byte* base, unsigned offset,
                                  const char* msg = "expected 1 byte") {
     return check(base, offset, 1, msg) ? base[offset] : 0;
   }

   // Reads 16-bit word, reporting an error if out of bounds.
   inline uint16_t checked_read_u16(const byte* base, unsigned offset,
                                    const char* msg = "expected 2 bytes") {
     return check(base, offset, 2, msg) ? read_u16(base + offset) : 0;
   }

   // Reads 32-bit word, reporting an error if out of bounds.
   inline uint32_t checked_read_u32(const byte* base, unsigned offset,
                                    const char* msg = "expected 4 bytes") {
     return check(base, offset, 4, msg) ? read_u32(base + offset) : 0;
   }

   // Reads 64-bit word, reporting an error if out of bounds.
   inline uint64_t checked_read_u64(const byte* base, unsigned offset,
                                    const char* msg = "expected 8 bytes") {
     return check(base, offset, 8, msg) ? read_u64(base + offset) : 0;
   }

   // Reads a variable-length unsigned integer (little endian).
   uint32_t checked_read_u32v(const byte* base, unsigned offset,
                              unsigned* length,
                              const char* msg = "expected LEB32") {
     return checked_read_leb<uint32_t, false>(base, offset, length, msg);
   }

   // Reads a variable-length signed integer (little endian).
   int32_t checked_read_i32v(const byte* base, unsigned offset, unsigned* length,
                             const char* msg = "expected SLEB32") {
     uint32_t result =
         checked_read_leb<uint32_t, true>(base, offset, length, msg);
     if (*length == 5) return bit_cast<int32_t>(result);
     if (*length > 0) {
       int shift = 32 - 7 * *length;
       // Perform sign extension.
       return bit_cast<int32_t>(result << shift) >> shift;
     }
     return 0;
   }

   // Reads a variable-length unsigned integer (little endian).
   uint64_t checked_read_u64v(const byte* base, unsigned offset,
                              unsigned* length,
                              const char* msg = "expected LEB64") {
     return checked_read_leb<uint64_t, false>(base, offset, length, msg);
   }

   // Reads a variable-length signed integer (little endian).
   int64_t checked_read_i64v(const byte* base, unsigned offset, unsigned* length,
                             const char* msg = "expected SLEB64") {
     uint64_t result =
         checked_read_leb<uint64_t, true>(base, offset, length, msg);
     if (*length == 10) return bit_cast<int64_t>(result);
     if (*length > 0) {
       int shift = 64 - 7 * *length;
       // Perform sign extension.
       return bit_cast<int64_t>(result << shift) >> shift;
     }
     return 0;
   }

   // Reads a single 16-bit unsigned integer (little endian).
   inline uint16_t read_u16(const byte* ptr) {
     DCHECK(ptr >= start_ && (ptr + 2) <= end_);
     return ReadLittleEndianValue<uint16_t>(ptr);
   }

   // Reads a single 32-bit unsigned integer (little endian).
   inline uint32_t read_u32(const byte* ptr) {
     DCHECK(ptr >= start_ && (ptr + 4) <= end_);
     return ReadLittleEndianValue<uint32_t>(ptr);
   }

   // Reads a single 64-bit unsigned integer (little endian).
   inline uint64_t read_u64(const byte* ptr) {
     DCHECK(ptr >= start_ && (ptr + 8) <= end_);
     return ReadLittleEndianValue<uint64_t>(ptr);
   }

   // Reads a 8-bit unsigned integer (byte) and advances {pc_}.
   uint8_t consume_u8(const char* name = nullptr) {
     TRACE("  +%d  %-20s: ", static_cast<int>(pc_ - start_),
           name ? name : "uint8_t");
     if (checkAvailable(1)) {
       byte val = *(pc_++);
       TRACE("%02x = %d\n", val, val);
       return val;
     }
     return traceOffEnd<uint8_t>();
   }

   // Reads a 16-bit unsigned integer (little endian) and advances {pc_}.
   uint16_t consume_u16(const char* name = nullptr) {
     TRACE("  +%d  %-20s: ", static_cast<int>(pc_ - start_),
           name ? name : "uint16_t");
     if (checkAvailable(2)) {
       uint16_t val = read_u16(pc_);
       TRACE("%02x %02x = %d\n", pc_[0], pc_[1], val);
       pc_ += 2;
       return val;
     }
     return traceOffEnd<uint16_t>();
   }

   // Reads a single 32-bit unsigned integer (little endian) and advances {pc_}.
   uint32_t consume_u32(const char* name = nullptr) {
     TRACE("  +%d  %-20s: ", static_cast<int>(pc_ - start_),
           name ? name : "uint32_t");
     if (checkAvailable(4)) {
       uint32_t val = read_u32(pc_);
       TRACE("%02x %02x %02x %02x = %u\n", pc_[0], pc_[1], pc_[2], pc_[3], val);
       pc_ += 4;
       return val;
     }
     return traceOffEnd<uint32_t>();
   }

   // Reads a LEB128 variable-length unsigned 32-bit integer and advances {pc_}.
   uint32_t consume_u32v(const char* name = nullptr) {
     return consume_leb<uint32_t, false>(name);
   }

   // Reads a LEB128 variable-length signed 32-bit integer and advances {pc_}.
   int32_t consume_i32v(const char* name = nullptr) {
     return consume_leb<int32_t, true>(name);
   }

   // Consume {size} bytes and send them to the bit bucket, advancing {pc_}.
   void consume_bytes(uint32_t size, const char* name = "skip") {
 #if DEBUG
     if (name) {
       // Only trace if the name is not null.
       TRACE("  +%d  %-20s: %d bytes\n", static_cast<int>(pc_ - start_), name,
             size);
     }
 #endif
     if (checkAvailable(size)) {
       pc_ += size;
     } else {
       pc_ = end_;
     }
   }

   // Check that at least {size} bytes exist between {pc_} and {end_}.
   bool checkAvailable(int size) {
     intptr_t pc_overflow_value = std::numeric_limits<intptr_t>::max() - size;
     if (size < 0 || (intptr_t)pc_ > pc_overflow_value) {
       error(pc_, nullptr, "reading %d bytes would underflow/overflow", size);
       return false;
     } else if (pc_ < start_ || end_ < (pc_ + size)) {
       error(pc_, nullptr, "expected %d bytes, fell off end", size);
       return false;
     } else {
       return true;
     }
   }

   void error(const char* msg) { error(pc_, nullptr, "%s", msg); }

   void error(const byte* pc, const char* msg) { error(pc, nullptr, "%s", msg); }

   // Sets internal error state.
   void PRINTF_FORMAT(4, 5)
       error(const byte* pc, const byte* pt, const char* format, ...) {
     if (ok()) {
 #if DEBUG
       if (FLAG_wasm_break_on_decoder_error) {
         base::OS::DebugBreak();
       }
 #endif
       const int kMaxErrorMsg = 256;
       char* buffer = new char[kMaxErrorMsg];
       va_list arguments;
       va_start(arguments, format);
       base::OS::VSNPrintF(buffer, kMaxErrorMsg - 1, format, arguments);
       va_end(arguments);
       error_msg_.reset(buffer);
       error_pc_ = pc;
       error_pt_ = pt;
       onFirstError();
     }
   }

   // Behavior triggered on first error, overridden in subclasses.
   virtual void onFirstError() {}

   // Debugging helper to print bytes up to the end.
   template <typename T>
   T traceOffEnd() {
     T t = 0;
     for (const byte* ptr = pc_; ptr < end_; ptr++) {
       TRACE("%02x ", *ptr);
     }
     TRACE("<end>\n");
     pc_ = end_;
     return t;
   }

   // Converts the given value to a {Result}, copying the error if necessary.
   template <typename T>
   Result<T> toResult(T val) {
     Result<T> result;
     if (failed()) {
       TRACE("Result error: %s\n", error_msg_.get());
       result.error_code = kError;
       result.start = start_;
       result.error_pc = error_pc_;
       result.error_pt = error_pt_;
       // transfer ownership of the error to the result.
       result.error_msg.reset(error_msg_.release());
     } else {
       result.error_code = kSuccess;
     }
     result.val = std::move(val);
     return result;
   }

   // Resets the boundaries of this decoder.
   void Reset(const byte* start, const byte* end) {
     start_ = start;
     pc_ = start;
     end_ = end;
     error_pc_ = nullptr;
     error_pt_ = nullptr;
     error_msg_.reset();
   }

   bool ok() const { return error_msg_ == nullptr; }
   bool failed() const { return !ok(); }
   bool more() const { return pc_ < end_; }

   const byte* start() const { return start_; }
   const byte* pc() const { return pc_; }
   uint32_t pc_offset() const { return static_cast<uint32_t>(pc_ - start_); }
   const byte* end() const { return end_; }

  protected:
   const byte* start_;
   const byte* pc_;
   const byte* end_;
   const byte* error_pc_;
   const byte* error_pt_;
   std::unique_ptr<char[]> error_msg_;

  private:
   template <typename IntType, bool is_signed>
   IntType checked_read_leb(const byte* base, unsigned offset, unsigned* length,
                            const char* msg) {
     if (!check(base, offset, 1, msg)) {
       *length = 0;
       return 0;
     }

     const int kMaxLength = (sizeof(IntType) * 8 + 6) / 7;
     const byte* ptr = base + offset;
     const byte* end = ptr + kMaxLength;
     if (end > end_) end = end_;
     int shift = 0;
     byte b = 0;
     IntType result = 0;
     while (ptr < end) {
       b = *ptr++;
       result = result | (static_cast<IntType>(b & 0x7F) << shift);
       if ((b & 0x80) == 0) break;
       shift += 7;
     }
     DCHECK_LE(ptr - (base + offset), kMaxLength);
     *length = static_cast<unsigned>(ptr - (base + offset));
     if (ptr == end) {
       // Check there are no bits set beyond the bitwidth of {IntType}.
       const int kExtraBits = (1 + kMaxLength * 7) - (sizeof(IntType) * 8);
       const byte kExtraBitsMask =
           static_cast<byte>((0xFF << (8 - kExtraBits)) & 0xFF);
       int extra_bits_value;
       if (is_signed) {
         // A signed-LEB128 must sign-extend the final byte, excluding its
         // most-signifcant bit. e.g. for a 32-bit LEB128:
         //   kExtraBits = 4
         //   kExtraBitsMask = 0xf0
         // If b is 0x0f, the value is negative, so extra_bits_value is 0x70.
         // If b is 0x03, the value is positive, so extra_bits_value is 0x00.
         extra_bits_value = (static_cast<int8_t>(b << kExtraBits) >> 8) &
                            kExtraBitsMask & ~0x80;
       } else {
         extra_bits_value = 0;
       }
       if (*length == kMaxLength && (b & kExtraBitsMask) != extra_bits_value) {
         error(base, ptr, "extra bits in varint");
         return 0;
       }
       if ((b & 0x80) != 0) {
         error(base, ptr, "%s", msg);
         return 0;
       }
     }
     return result;
   }

   template <typename IntType, bool is_signed>
   IntType consume_leb(const char* name = nullptr) {
     TRACE("  +%d  %-20s: ", static_cast<int>(pc_ - start_),
           name ? name : "varint");
     if (checkAvailable(1)) {
       const int kMaxLength = (sizeof(IntType) * 8 + 6) / 7;
       const byte* pos = pc_;
       const byte* end = pc_ + kMaxLength;
       if (end > end_) end = end_;

       IntType result = 0;
       int shift = 0;
       byte b = 0;
       while (pc_ < end) {
         b = *pc_++;
         TRACE("%02x ", b);
         result = result | (static_cast<IntType>(b & 0x7F) << shift);
         shift += 7;
         if ((b & 0x80) == 0) break;
       }

       int length = static_cast<int>(pc_ - pos);
       if (pc_ == end && (b & 0x80)) {
         TRACE("\n");
         error(pc_ - 1, "varint too large");
       } else if (length == 0) {
         TRACE("\n");
         error(pc_, "varint of length 0");
       } else if (is_signed) {
         if (length < kMaxLength) {
           int sign_ext_shift = 8 * sizeof(IntType) - shift;
           // Perform sign extension.
           result = (result << sign_ext_shift) >> sign_ext_shift;
         }
         TRACE("= %" PRIi64 "\n", static_cast<int64_t>(result));
       } else {
         TRACE("= %" PRIu64 "\n", static_cast<uint64_t>(result));
       }
       return result;
     }
     return traceOffEnd<uint32_t>();
   }
 };

 #undef TRACE
 }  // namespace wasm
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_WASM_DECODER_H_
	// Copyright 2015 the V8 project 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 V8_WASM_DECODER_H_
	#define V8_WASM_DECODER_H_

	#include <memory>

	#include "src/base/compiler-specific.h"
	#include "src/flags.h"
	#include "src/signature.h"
	#include "src/utils.h"
	#include "src/wasm/wasm-result.h"
	#include "src/zone/zone-containers.h"

	namespace v8 {
	namespace internal {
	namespace wasm {

	#if DEBUG
	#define TRACE(...) \
	do { \
	if (FLAG_trace_wasm_decoder) PrintF(__VA_ARGS__); \
	} while (false)
	#else
	#define TRACE(...)
	#endif

	// A helper utility to decode bytes, integers, fields, varints, etc, from
	// a buffer of bytes.
	class Decoder {
	public:
	Decoder(const byte* start, const byte* end)
	: start_(start),
	pc_(start),
	end_(end),
	error_pc_(nullptr),
	error_pt_(nullptr) {}
	Decoder(const byte* start, const byte* pc, const byte* end)
	: start_(start),
	pc_(pc),
	end_(end),
	error_pc_(nullptr),
	error_pt_(nullptr) {}

	virtual ~Decoder() {}

	inline bool check(const byte* base, unsigned offset, unsigned length,
	const char* msg) {
	DCHECK_GE(base, start_);
	if ((base + offset + length) > end_) {
	error(base, base + offset, "%s", msg);
	return false;
	}
	return true;
	}

	// Reads a single 8-bit byte, reporting an error if out of bounds.
	inline uint8_t checked_read_u8(const byte* base, unsigned offset,
	const char* msg = "expected 1 byte") {
	return check(base, offset, 1, msg) ? base[offset] : 0;
	}

	// Reads 16-bit word, reporting an error if out of bounds.
	inline uint16_t checked_read_u16(const byte* base, unsigned offset,
	const char* msg = "expected 2 bytes") {
	return check(base, offset, 2, msg) ? read_u16(base + offset) : 0;
	}

	// Reads 32-bit word, reporting an error if out of bounds.
	inline uint32_t checked_read_u32(const byte* base, unsigned offset,
	const char* msg = "expected 4 bytes") {
	return check(base, offset, 4, msg) ? read_u32(base + offset) : 0;
	}

	// Reads 64-bit word, reporting an error if out of bounds.
	inline uint64_t checked_read_u64(const byte* base, unsigned offset,
	const char* msg = "expected 8 bytes") {
	return check(base, offset, 8, msg) ? read_u64(base + offset) : 0;
	}

	// Reads a variable-length unsigned integer (little endian).
	uint32_t checked_read_u32v(const byte* base, unsigned offset,
	unsigned* length,
	const char* msg = "expected LEB32") {
	return checked_read_leb<uint32_t, false>(base, offset, length, msg);
	}

	// Reads a variable-length signed integer (little endian).
	int32_t checked_read_i32v(const byte* base, unsigned offset, unsigned* length,
	const char* msg = "expected SLEB32") {
	uint32_t result =
	checked_read_leb<uint32_t, true>(base, offset, length, msg);
	if (*length == 5) return bit_cast<int32_t>(result);
	if (*length > 0) {
	int shift = 32 - 7 * *length;
	// Perform sign extension.
	return bit_cast<int32_t>(result << shift) >> shift;
	}
	return 0;
	}

	// Reads a variable-length unsigned integer (little endian).
	uint64_t checked_read_u64v(const byte* base, unsigned offset,
	unsigned* length,
	const char* msg = "expected LEB64") {
	return checked_read_leb<uint64_t, false>(base, offset, length, msg);
	}

	// Reads a variable-length signed integer (little endian).
	int64_t checked_read_i64v(const byte* base, unsigned offset, unsigned* length,
	const char* msg = "expected SLEB64") {
	uint64_t result =
	checked_read_leb<uint64_t, true>(base, offset, length, msg);
	if (*length == 10) return bit_cast<int64_t>(result);
	if (*length > 0) {
	int shift = 64 - 7 * *length;
	// Perform sign extension.
	return bit_cast<int64_t>(result << shift) >> shift;
	}
	return 0;
	}

	// Reads a single 16-bit unsigned integer (little endian).
	inline uint16_t read_u16(const byte* ptr) {
	DCHECK(ptr >= start_ && (ptr + 2) <= end_);
	return ReadLittleEndianValue<uint16_t>(ptr);
	}

	// Reads a single 32-bit unsigned integer (little endian).
	inline uint32_t read_u32(const byte* ptr) {
	DCHECK(ptr >= start_ && (ptr + 4) <= end_);
	return ReadLittleEndianValue<uint32_t>(ptr);
	}

	// Reads a single 64-bit unsigned integer (little endian).
	inline uint64_t read_u64(const byte* ptr) {
	DCHECK(ptr >= start_ && (ptr + 8) <= end_);
	return ReadLittleEndianValue<uint64_t>(ptr);
	}

	// Reads a 8-bit unsigned integer (byte) and advances {pc_}.
	uint8_t consume_u8(const char* name = nullptr) {
	TRACE(" +%d %-20s: ", static_cast<int>(pc_ - start_),
	name ? name : "uint8_t");
	if (checkAvailable(1)) {
	byte val = *(pc_++);
	TRACE("%02x = %d\n", val, val);
	return val;
	}
	return traceOffEnd<uint8_t>();
	}

	// Reads a 16-bit unsigned integer (little endian) and advances {pc_}.
	uint16_t consume_u16(const char* name = nullptr) {
	TRACE(" +%d %-20s: ", static_cast<int>(pc_ - start_),
	name ? name : "uint16_t");
	if (checkAvailable(2)) {
	uint16_t val = read_u16(pc_);
	TRACE("%02x %02x = %d\n", pc_[0], pc_[1], val);
	pc_ += 2;
	return val;
	}
	return traceOffEnd<uint16_t>();
	}

	// Reads a single 32-bit unsigned integer (little endian) and advances {pc_}.
	uint32_t consume_u32(const char* name = nullptr) {
	TRACE(" +%d %-20s: ", static_cast<int>(pc_ - start_),
	name ? name : "uint32_t");
	if (checkAvailable(4)) {
	uint32_t val = read_u32(pc_);
	TRACE("%02x %02x %02x %02x = %u\n", pc_[0], pc_[1], pc_[2], pc_[3], val);
	pc_ += 4;
	return val;
	}
	return traceOffEnd<uint32_t>();
	}

	// Reads a LEB128 variable-length unsigned 32-bit integer and advances {pc_}.
	uint32_t consume_u32v(const char* name = nullptr) {
	return consume_leb<uint32_t, false>(name);
	}

	// Reads a LEB128 variable-length signed 32-bit integer and advances {pc_}.
	int32_t consume_i32v(const char* name = nullptr) {
	return consume_leb<int32_t, true>(name);
	}

	// Consume {size} bytes and send them to the bit bucket, advancing {pc_}.
	void consume_bytes(uint32_t size, const char* name = "skip") {
	#if DEBUG
	if (name) {
	// Only trace if the name is not null.
	TRACE(" +%d %-20s: %d bytes\n", static_cast<int>(pc_ - start_), name,
	size);
	}
	#endif
	if (checkAvailable(size)) {
	pc_ += size;
	} else {
	pc_ = end_;
	}
	}

	// Check that at least {size} bytes exist between {pc_} and {end_}.
	bool checkAvailable(int size) {
	intptr_t pc_overflow_value = std::numeric_limits<intptr_t>::max() - size;
	if (size < 0 \|\| (intptr_t)pc_ > pc_overflow_value) {
	error(pc_, nullptr, "reading %d bytes would underflow/overflow", size);
	return false;
	} else if (pc_ < start_ \|\| end_ < (pc_ + size)) {
	error(pc_, nullptr, "expected %d bytes, fell off end", size);
	return false;
	} else {
	return true;
	}
	}

	void error(const char* msg) { error(pc_, nullptr, "%s", msg); }

	void error(const byte* pc, const char* msg) { error(pc, nullptr, "%s", msg); }

	// Sets internal error state.
	void PRINTF_FORMAT(4, 5)
	error(const byte* pc, const byte* pt, const char* format, ...) {
	if (ok()) {
	#if DEBUG
	if (FLAG_wasm_break_on_decoder_error) {
	base::OS::DebugBreak();
	}
	#endif
	const int kMaxErrorMsg = 256;
	char* buffer = new char[kMaxErrorMsg];
	va_list arguments;
	va_start(arguments, format);
	base::OS::VSNPrintF(buffer, kMaxErrorMsg - 1, format, arguments);
	va_end(arguments);
	error_msg_.reset(buffer);
	error_pc_ = pc;
	error_pt_ = pt;
	onFirstError();
	}
	}

	// Behavior triggered on first error, overridden in subclasses.
	virtual void onFirstError() {}

	// Debugging helper to print bytes up to the end.
	template <typename T>
	T traceOffEnd() {
	T t = 0;
	for (const byte* ptr = pc_; ptr < end_; ptr++) {
	TRACE("%02x ", *ptr);
	}
	TRACE("<end>\n");
	pc_ = end_;
	return t;
	}

	// Converts the given value to a {Result}, copying the error if necessary.
	template <typename T>
	Result<T> toResult(T val) {
	Result<T> result;
	if (failed()) {
	TRACE("Result error: %s\n", error_msg_.get());
	result.error_code = kError;
	result.start = start_;
	result.error_pc = error_pc_;
	result.error_pt = error_pt_;
	// transfer ownership of the error to the result.
	result.error_msg.reset(error_msg_.release());
	} else {
	result.error_code = kSuccess;
	}
	result.val = std::move(val);
	return result;
	}

	// Resets the boundaries of this decoder.
	void Reset(const byte* start, const byte* end) {
	start_ = start;
	pc_ = start;
	end_ = end;
	error_pc_ = nullptr;
	error_pt_ = nullptr;
	error_msg_.reset();
	}

	bool ok() const { return error_msg_ == nullptr; }
	bool failed() const { return !ok(); }
	bool more() const { return pc_ < end_; }

	const byte* start() const { return start_; }
	const byte* pc() const { return pc_; }
	uint32_t pc_offset() const { return static_cast<uint32_t>(pc_ - start_); }
	const byte* end() const { return end_; }

	protected:
	const byte* start_;
	const byte* pc_;
	const byte* end_;
	const byte* error_pc_;
	const byte* error_pt_;
	std::unique_ptr<char[]> error_msg_;

	private:
	template <typename IntType, bool is_signed>
	IntType checked_read_leb(const byte* base, unsigned offset, unsigned* length,
	const char* msg) {
	if (!check(base, offset, 1, msg)) {
	*length = 0;
	return 0;
	}

	const int kMaxLength = (sizeof(IntType) * 8 + 6) / 7;
	const byte* ptr = base + offset;
	const byte* end = ptr + kMaxLength;
	if (end > end_) end = end_;
	int shift = 0;
	byte b = 0;
	IntType result = 0;
	while (ptr < end) {
	b = *ptr++;
	result = result \| (static_cast<IntType>(b & 0x7F) << shift);
	if ((b & 0x80) == 0) break;
	shift += 7;
	}
	DCHECK_LE(ptr - (base + offset), kMaxLength);
	*length = static_cast<unsigned>(ptr - (base + offset));
	if (ptr == end) {
	// Check there are no bits set beyond the bitwidth of {IntType}.
	const int kExtraBits = (1 + kMaxLength * 7) - (sizeof(IntType) * 8);
	const byte kExtraBitsMask =
	static_cast<byte>((0xFF << (8 - kExtraBits)) & 0xFF);
	int extra_bits_value;
	if (is_signed) {
	// A signed-LEB128 must sign-extend the final byte, excluding its
	// most-signifcant bit. e.g. for a 32-bit LEB128:
	// kExtraBits = 4
	// kExtraBitsMask = 0xf0
	// If b is 0x0f, the value is negative, so extra_bits_value is 0x70.
	// If b is 0x03, the value is positive, so extra_bits_value is 0x00.
	extra_bits_value = (static_cast<int8_t>(b << kExtraBits) >> 8) &
	kExtraBitsMask & ~0x80;
	} else {
	extra_bits_value = 0;
	}
	if (*length == kMaxLength && (b & kExtraBitsMask) != extra_bits_value) {
	error(base, ptr, "extra bits in varint");
	return 0;
	}
	if ((b & 0x80) != 0) {
	error(base, ptr, "%s", msg);
	return 0;
	}
	}
	return result;
	}

	template <typename IntType, bool is_signed>
	IntType consume_leb(const char* name = nullptr) {
	TRACE(" +%d %-20s: ", static_cast<int>(pc_ - start_),
	name ? name : "varint");
	if (checkAvailable(1)) {
	const int kMaxLength = (sizeof(IntType) * 8 + 6) / 7;
	const byte* pos = pc_;
	const byte* end = pc_ + kMaxLength;
	if (end > end_) end = end_;

	IntType result = 0;
	int shift = 0;
	byte b = 0;
	while (pc_ < end) {
	b = *pc_++;
	TRACE("%02x ", b);
	result = result \| (static_cast<IntType>(b & 0x7F) << shift);
	shift += 7;
	if ((b & 0x80) == 0) break;
	}

	int length = static_cast<int>(pc_ - pos);
	if (pc_ == end && (b & 0x80)) {
	TRACE("\n");
	error(pc_ - 1, "varint too large");
	} else if (length == 0) {
	TRACE("\n");
	error(pc_, "varint of length 0");
	} else if (is_signed) {
	if (length < kMaxLength) {
	int sign_ext_shift = 8 * sizeof(IntType) - shift;
	// Perform sign extension.
	result = (result << sign_ext_shift) >> sign_ext_shift;
	}
	TRACE("= %" PRIi64 "\n", static_cast<int64_t>(result));
	} else {
	TRACE("= %" PRIu64 "\n", static_cast<uint64_t>(result));
	}
	return result;
	}
	return traceOffEnd<uint32_t>();
	}
	};

	#undef TRACE
	} // namespace wasm
	} // namespace internal
	} // namespace v8

	#endif // V8_WASM_DECODER_H_