src/addrcache.cc - external/github.com/google/open-vcdiff - Git at Google

 // Copyright 2007 The open-vcdiff Authors. All Rights Reserved.
 //
 // 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.
 //
 // Implementation of the Address Cache and Address Encoding
 // algorithms described in sections 5.1 - 5.4 of RFC 3284 -
 // The VCDIFF Generic Differencing and Compression Data Format.
 // The RFC text can be found at http://www.faqs.org/rfcs/rfc3284.html
 //
 // Assumptions:
 //   * The VCDAddress type is large enough to hold any offset within
 //     the source and target windows.  The limit (for int32_t) is 2^31-1 bytes.
 //     The source (dictionary) should not approach this size limit;
 //     to compress a target file that is larger than
 //     INT_MAX - (dictionary size) bytes, the encoder must
 //     break it up into multiple target windows.

 #include <config.h>
 #include "addrcache.h"
 #include "logging.h"
 #include "varint_bigendian.h"
 #include "vcdiff_defs.h"  // RESULT_ERROR

 namespace open_vcdiff {

 // The constructor does not initialize near_addresses_ and same_addresses_.
 // Therefore, Init() must be called before any other method can be used.
 //
 // Arguments:
 //   near_cache_size: Size of the NEAR cache (number of 4-byte integers)
 //   same_cache_size: Size of the SAME cache (number of blocks of
 //                                            256 4-byte integers per block)
 //     Because the mode is expressed as a byte value,
 //     near_cache_size + same_cache_size should not exceed 254.
 //
 VCDiffAddressCache::VCDiffAddressCache(unsigned char near_cache_size,
                                        unsigned char same_cache_size)
     : near_cache_size_(near_cache_size),
       same_cache_size_(same_cache_size),
       next_slot_(0) { }

 VCDiffAddressCache::VCDiffAddressCache()
     : near_cache_size_(kDefaultNearCacheSize),
       same_cache_size_(kDefaultSameCacheSize),
       next_slot_(0) { }

 // Sets up data structures needed to call other methods.  Operations that may
 // fail at runtime (for example, validating the provided near_cache_size_ and
 // same_cache_size_ parameters against their maximum allowed values) are
 // confined to this routine in order to guarantee that the class constructor
 // will never fail.  Other methods (except the destructor) cannot be invoked
 // until this method has been called successfully.  After the object has been
 // initialized and used, Init() can be called again to reset it to its initial
 // state.
 //
 // Return value: "true" if initialization succeeded, "false" if it failed.
 //     No other method except the destructor may be invoked if this function
 //     returns false.  The caller is responsible for checking the return value
 //     and providing an exit path in case of error.
 //
 bool VCDiffAddressCache::Init() {
   // The mode is expressed as a byte value, so there is only room for 256 modes,
   // including the two non-cached modes (SELF and HERE).  Do not allow a larger
   // number of modes to be defined.
   if ((near_cache_size_ + same_cache_size_) > VCD_MAX_MODES - 2) {
     VCD_ERROR << "Using near cache size " << static_cast<int>(near_cache_size_)
               << " and same cache size " << static_cast<int>(same_cache_size_)
               << " would exceed maximum number of COPY modes ("
               << VCD_MAX_MODES << ")" << VCD_ENDL;
     return false;
   }
   if (near_cache_size_ > 0) {
     near_addresses_.assign(near_cache_size_, 0);
   }
   if (same_cache_size_ > 0) {
     same_addresses_.assign(same_cache_size_ * 256, 0);
   }
   next_slot_ = 0;  // in case Init() is called a second time to reinit
   return true;
 }

 // This method will be called whenever an address is calculated for an
 // encoded or decoded COPY instruction, and will update the contents
 // of the SAME and NEAR caches.  It is vital that the use of
 // UpdateCache (called cache_update in the RFC examples) exactly match
 // the RFC standard, and that the same caching logic be used in the
 // decoder as in the encoder, in order for the decoded addresses to
 // match.
 //
 // Argument:
 //   address: This must be a valid address between 0 and
 //       (source window size + target window size).  It is assumed that
 //       these bounds have been checked before calling UpdateCache.
 //
 void VCDiffAddressCache::UpdateCache(VCDAddress address) {
   if (near_cache_size_ > 0) {
     near_addresses_[next_slot_] = address;
     next_slot_ = (next_slot_ + 1) % near_cache_size_;
   }
   if (same_cache_size_ > 0) {
     same_addresses_[address % (same_cache_size_ * 256)] = address;
   }
 }

 // Determines the address mode that yields the most compact encoding
 // of the given address value, writes the encoded address into the
 // address stream, and returns the mode used.  The most compact encoding
 // is found by looking for the numerically lowest encoded address.
 // The Init() function must already have been called.
 //
 // Arguments:
 //   address: The address to be encoded.  Must be a non-negative integer
 //       between 0 and (here_address - 1).
 //   here_address: The current location in the target data (i.e., the
 //       position just after the last encoded value.)  Must be non-negative.
 //   encoded_addr: Points to an VCDAddress that will be replaced
 //       with the encoded representation of address.
 //       If WriteAddressAsVarintForMode returns true when passed
 //       the return value, then encoded_addr should be written
 //       into the delta file as a variable-length integer (Varint);
 //       otherwise, it should be written as a byte (unsigned char).
 //
 // Return value: A mode value between 0 and 255.  The mode will tell
 //       how to interpret the next value in the address stream.
 //       The values 0 and 1 correspond to SELF and HERE addressing.
 //
 // The function is guaranteed to succeed unless the conditions on the arguments
 // have not been met, in which case a VCD_DFATAL message will be produced,
 // 0 will be returned, and *encoded_addr will be replaced with 0.
 //
 unsigned char VCDiffAddressCache::EncodeAddress(VCDAddress address,
                                                 VCDAddress here_address,
                                                 VCDAddress* encoded_addr) {
   if (address < 0) {
     VCD_DFATAL << "EncodeAddress was passed a negative address: "
                << address << VCD_ENDL;
     *encoded_addr = 0;
     return 0;
   }
   if (address >= here_address) {
     VCD_DFATAL << "EncodeAddress was called with address (" << address
                << ") < here_address (" << here_address << ")" << VCD_ENDL;
     *encoded_addr = 0;
     return 0;
   }
   // Try using the SAME cache.  This method, if available, always
   // results in the smallest encoding and takes priority over other modes.
   if (same_cache_size() > 0) {
     const VCDAddress same_cache_pos =
         address % (same_cache_size() * 256);
     if (SameAddress(same_cache_pos) == address) {
       // This is the only mode for which an single byte will be written
       // to the address stream instead of a variable-length integer.
       UpdateCache(address);
       *encoded_addr = same_cache_pos % 256;
       return FirstSameMode() +
           static_cast<unsigned char>(same_cache_pos / 256);  // SAME mode
     }
   }

   // Try SELF mode
   unsigned char best_mode = VCD_SELF_MODE;
   VCDAddress best_encoded_address = address;

   // Try HERE mode
   {
     const VCDAddress here_encoded_address = here_address - address;
     if (here_encoded_address < best_encoded_address) {
       best_mode = VCD_HERE_MODE;
       best_encoded_address = here_encoded_address;
     }
   }

   // Try using the NEAR cache
   for (unsigned char i = 0; i < near_cache_size(); ++i) {
     const VCDAddress near_encoded_address = address - NearAddress(i);
     if ((near_encoded_address >= 0) &&
         (near_encoded_address < best_encoded_address)) {
       best_mode = FirstNearMode() + i;
       best_encoded_address = near_encoded_address;
     }
   }

   UpdateCache(address);
   *encoded_addr = best_encoded_address;
   return best_mode;
 }

 // Increments *byte_pointer and returns the byte it pointed to before the
 // increment.  The caller must check bounds to ensure that *byte_pointer
 // points to a valid address in memory.
 static unsigned char ParseByte(const char** byte_pointer) {
   unsigned char byte_value = static_cast<unsigned char>(**byte_pointer);
   ++(*byte_pointer);
   return byte_value;
 }

 // Checks the given decoded address for validity.  Returns true if the
 // address is valid; otherwise, prints an error message to the log and
 // returns false.
 static bool IsDecodedAddressValid(VCDAddress decoded_address,
                                   VCDAddress here_address) {
   if (decoded_address < 0) {
     VCD_ERROR << "Decoded address " << decoded_address << " is invalid"
               << VCD_ENDL;
     return false;
   } else if (decoded_address >= here_address) {
     VCD_ERROR << "Decoded address (" << decoded_address
               << ") is beyond location in target file (" << here_address
               << ")" << VCD_ENDL;
     return false;
   }
   return true;
 }

 // Interprets the next value in the address_stream using the provided mode,
 // which may need to access the SAME or NEAR address cache.  Returns the
 // decoded address.
 // The Init() function must already have been called.
 //
 // Arguments:
 //   here_address: The current location in the source + target data (i.e., the
 //       location into which the COPY instruction will copy.)  By definition,
 //       all addresses between 0 and (here_address - 1) are valid, and
 //       any other address is invalid.
 //   mode: A byte value between 0 and (near_cache_size_ + same_cache_size_ + 1)
 //       which tells how to interpret the next value in the address stream.
 //       The values 0 and 1 correspond to SELF and HERE addressing.
 //       The validity of "mode" should already have been checked before
 //       calling this function.
 //   address_stream: Points to a pointer holding the position
 //       in the "Addresses section for COPYs" part of the input data.
 //       That section must already have been uncompressed
 //       using a secondary decompressor (if necessary.)
 //       This is an IN/OUT argument; the value of *address_stream will be
 //       incremented by the size of an integer, or (if the SAME cache
 //       was used) by the size of a byte (1).
 //   address_stream_end: Points to the position just after the end of
 //       the address stream buffer.  All addresses between *address_stream
 //       and address_stream_end should contain valid address data.
 //
 // Return value: If the input conditions were met, and the address section
 //     of the input data contains properly encoded addresses that match
 //     the instructions section, then an integer between 0 and here_address - 1
 //     will be returned, representing the address from which data should
 //     be copied from the source or target window into the output stream.
 //     If an invalid address value is found in address_stream, then
 //     RESULT_ERROR will be returned.  If the limit address_stream_end
 //     is reached before the address can be decoded, then
 //     RESULT_END_OF_DATA will be returned.  If more streamed data
 //     is expected, this means that the consumer should block and wait
 //     for more data before continuing to decode.  If no more data is expected,
 //     this return value signals an error condition.
 //
 VCDAddress VCDiffAddressCache::DecodeAddress(VCDAddress here_address,
                                              unsigned char mode,
                                              const char** address_stream,
                                              const char* address_stream_end) {
   if (here_address < 0) {
     VCD_DFATAL << "DecodeAddress was passed a negative value"
                   " for here_address: " << here_address << VCD_ENDL;
     return RESULT_ERROR;
   }
   const char* new_address_pos = *address_stream;
   if (new_address_pos >= address_stream_end) {
     return RESULT_END_OF_DATA;
   }
   VCDAddress decoded_address;
   if (IsSameMode(mode)) {
     // SAME mode expects a byte value as the encoded address
     unsigned char encoded_address = ParseByte(&new_address_pos);
     decoded_address = DecodeSameAddress(mode, encoded_address);
   } else {
     // All modes except SAME mode expect a VarintBE as the encoded address
     int32_t encoded_address = VarintBE<int32_t>::Parse(address_stream_end,
                                                        &new_address_pos);
     switch (encoded_address) {
       case RESULT_ERROR:
         VCD_ERROR << "Found invalid variable-length integer "
                      "as encoded address value" << VCD_ENDL;
         return RESULT_ERROR;
       case RESULT_END_OF_DATA:
         return RESULT_END_OF_DATA;
       default:
         break;
     }
     if (IsSelfMode(mode)) {
       decoded_address = DecodeSelfAddress(encoded_address);
     } else if (IsHereMode(mode)) {
       decoded_address = DecodeHereAddress(encoded_address, here_address);
     } else if (IsNearMode(mode)) {
       decoded_address = DecodeNearAddress(mode, encoded_address);
     } else {
       VCD_DFATAL << "Invalid mode value (" << static_cast<int>(mode)
                  << ") passed to DecodeAddress; maximum mode value = "
                  << static_cast<int>(LastMode()) << VCD_ENDL;
       return RESULT_ERROR;
     }
   }
   // Check for an out-of-bounds address (corrupt/malicious data)
   if (!IsDecodedAddressValid(decoded_address, here_address)) {
     return RESULT_ERROR;
   }
   *address_stream = new_address_pos;
   UpdateCache(decoded_address);
   return decoded_address;
 }

 }  // namespace open_vcdiff
	// Copyright 2007 The open-vcdiff Authors. All Rights Reserved.
	//
	// 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.
	//
	// Implementation of the Address Cache and Address Encoding
	// algorithms described in sections 5.1 - 5.4 of RFC 3284 -
	// The VCDIFF Generic Differencing and Compression Data Format.
	// The RFC text can be found at http://www.faqs.org/rfcs/rfc3284.html
	//
	// Assumptions:
	// * The VCDAddress type is large enough to hold any offset within
	// the source and target windows. The limit (for int32_t) is 2^31-1 bytes.
	// The source (dictionary) should not approach this size limit;
	// to compress a target file that is larger than
	// INT_MAX - (dictionary size) bytes, the encoder must
	// break it up into multiple target windows.

	#include <config.h>
	#include "addrcache.h"
	#include "logging.h"
	#include "varint_bigendian.h"
	#include "vcdiff_defs.h" // RESULT_ERROR

	namespace open_vcdiff {

	// The constructor does not initialize near_addresses_ and same_addresses_.
	// Therefore, Init() must be called before any other method can be used.
	//
	// Arguments:
	// near_cache_size: Size of the NEAR cache (number of 4-byte integers)
	// same_cache_size: Size of the SAME cache (number of blocks of
	// 256 4-byte integers per block)
	// Because the mode is expressed as a byte value,
	// near_cache_size + same_cache_size should not exceed 254.
	//
	VCDiffAddressCache::VCDiffAddressCache(unsigned char near_cache_size,
	unsigned char same_cache_size)
	: near_cache_size_(near_cache_size),
	same_cache_size_(same_cache_size),
	next_slot_(0) { }

	VCDiffAddressCache::VCDiffAddressCache()
	: near_cache_size_(kDefaultNearCacheSize),
	same_cache_size_(kDefaultSameCacheSize),
	next_slot_(0) { }

	// Sets up data structures needed to call other methods. Operations that may
	// fail at runtime (for example, validating the provided near_cache_size_ and
	// same_cache_size_ parameters against their maximum allowed values) are
	// confined to this routine in order to guarantee that the class constructor
	// will never fail. Other methods (except the destructor) cannot be invoked
	// until this method has been called successfully. After the object has been
	// initialized and used, Init() can be called again to reset it to its initial
	// state.
	//
	// Return value: "true" if initialization succeeded, "false" if it failed.
	// No other method except the destructor may be invoked if this function
	// returns false. The caller is responsible for checking the return value
	// and providing an exit path in case of error.
	//
	bool VCDiffAddressCache::Init() {
	// The mode is expressed as a byte value, so there is only room for 256 modes,
	// including the two non-cached modes (SELF and HERE). Do not allow a larger
	// number of modes to be defined.
	if ((near_cache_size_ + same_cache_size_) > VCD_MAX_MODES - 2) {
	VCD_ERROR << "Using near cache size " << static_cast<int>(near_cache_size_)
	<< " and same cache size " << static_cast<int>(same_cache_size_)
	<< " would exceed maximum number of COPY modes ("
	<< VCD_MAX_MODES << ")" << VCD_ENDL;
	return false;
	}
	if (near_cache_size_ > 0) {
	near_addresses_.assign(near_cache_size_, 0);
	}
	if (same_cache_size_ > 0) {
	same_addresses_.assign(same_cache_size_ * 256, 0);
	}
	next_slot_ = 0; // in case Init() is called a second time to reinit
	return true;
	}

	// This method will be called whenever an address is calculated for an
	// encoded or decoded COPY instruction, and will update the contents
	// of the SAME and NEAR caches. It is vital that the use of
	// UpdateCache (called cache_update in the RFC examples) exactly match
	// the RFC standard, and that the same caching logic be used in the
	// decoder as in the encoder, in order for the decoded addresses to
	// match.
	//
	// Argument:
	// address: This must be a valid address between 0 and
	// (source window size + target window size). It is assumed that
	// these bounds have been checked before calling UpdateCache.
	//
	void VCDiffAddressCache::UpdateCache(VCDAddress address) {
	if (near_cache_size_ > 0) {
	near_addresses_[next_slot_] = address;
	next_slot_ = (next_slot_ + 1) % near_cache_size_;
	}
	if (same_cache_size_ > 0) {
	same_addresses_[address % (same_cache_size_ * 256)] = address;
	}
	}

	// Determines the address mode that yields the most compact encoding
	// of the given address value, writes the encoded address into the
	// address stream, and returns the mode used. The most compact encoding
	// is found by looking for the numerically lowest encoded address.
	// The Init() function must already have been called.
	//
	// Arguments:
	// address: The address to be encoded. Must be a non-negative integer
	// between 0 and (here_address - 1).
	// here_address: The current location in the target data (i.e., the
	// position just after the last encoded value.) Must be non-negative.
	// encoded_addr: Points to an VCDAddress that will be replaced
	// with the encoded representation of address.
	// If WriteAddressAsVarintForMode returns true when passed
	// the return value, then encoded_addr should be written
	// into the delta file as a variable-length integer (Varint);
	// otherwise, it should be written as a byte (unsigned char).
	//
	// Return value: A mode value between 0 and 255. The mode will tell
	// how to interpret the next value in the address stream.
	// The values 0 and 1 correspond to SELF and HERE addressing.
	//
	// The function is guaranteed to succeed unless the conditions on the arguments
	// have not been met, in which case a VCD_DFATAL message will be produced,
	// 0 will be returned, and *encoded_addr will be replaced with 0.
	//
	unsigned char VCDiffAddressCache::EncodeAddress(VCDAddress address,
	VCDAddress here_address,
	VCDAddress* encoded_addr) {
	if (address < 0) {
	VCD_DFATAL << "EncodeAddress was passed a negative address: "
	<< address << VCD_ENDL;
	*encoded_addr = 0;
	return 0;
	}
	if (address >= here_address) {
	VCD_DFATAL << "EncodeAddress was called with address (" << address
	<< ") < here_address (" << here_address << ")" << VCD_ENDL;
	*encoded_addr = 0;
	return 0;
	}
	// Try using the SAME cache. This method, if available, always
	// results in the smallest encoding and takes priority over other modes.
	if (same_cache_size() > 0) {
	const VCDAddress same_cache_pos =
	address % (same_cache_size() * 256);
	if (SameAddress(same_cache_pos) == address) {
	// This is the only mode for which an single byte will be written
	// to the address stream instead of a variable-length integer.
	UpdateCache(address);
	*encoded_addr = same_cache_pos % 256;
	return FirstSameMode() +
	static_cast<unsigned char>(same_cache_pos / 256); // SAME mode
	}
	}

	// Try SELF mode
	unsigned char best_mode = VCD_SELF_MODE;
	VCDAddress best_encoded_address = address;

	// Try HERE mode
	{
	const VCDAddress here_encoded_address = here_address - address;
	if (here_encoded_address < best_encoded_address) {
	best_mode = VCD_HERE_MODE;
	best_encoded_address = here_encoded_address;
	}
	}

	// Try using the NEAR cache
	for (unsigned char i = 0; i < near_cache_size(); ++i) {
	const VCDAddress near_encoded_address = address - NearAddress(i);
	if ((near_encoded_address >= 0) &&
	(near_encoded_address < best_encoded_address)) {
	best_mode = FirstNearMode() + i;
	best_encoded_address = near_encoded_address;
	}
	}

	UpdateCache(address);
	*encoded_addr = best_encoded_address;
	return best_mode;
	}

	// Increments *byte_pointer and returns the byte it pointed to before the
	// increment. The caller must check bounds to ensure that *byte_pointer
	// points to a valid address in memory.
	static unsigned char ParseByte(const char** byte_pointer) {
	unsigned char byte_value = static_cast<unsigned char>(**byte_pointer);
	++(*byte_pointer);
	return byte_value;
	}

	// Checks the given decoded address for validity. Returns true if the
	// address is valid; otherwise, prints an error message to the log and
	// returns false.
	static bool IsDecodedAddressValid(VCDAddress decoded_address,
	VCDAddress here_address) {
	if (decoded_address < 0) {
	VCD_ERROR << "Decoded address " << decoded_address << " is invalid"
	<< VCD_ENDL;
	return false;
	} else if (decoded_address >= here_address) {
	VCD_ERROR << "Decoded address (" << decoded_address
	<< ") is beyond location in target file (" << here_address
	<< ")" << VCD_ENDL;
	return false;
	}
	return true;
	}

	// Interprets the next value in the address_stream using the provided mode,
	// which may need to access the SAME or NEAR address cache. Returns the
	// decoded address.
	// The Init() function must already have been called.
	//
	// Arguments:
	// here_address: The current location in the source + target data (i.e., the
	// location into which the COPY instruction will copy.) By definition,
	// all addresses between 0 and (here_address - 1) are valid, and
	// any other address is invalid.
	// mode: A byte value between 0 and (near_cache_size_ + same_cache_size_ + 1)
	// which tells how to interpret the next value in the address stream.
	// The values 0 and 1 correspond to SELF and HERE addressing.
	// The validity of "mode" should already have been checked before
	// calling this function.
	// address_stream: Points to a pointer holding the position
	// in the "Addresses section for COPYs" part of the input data.
	// That section must already have been uncompressed
	// using a secondary decompressor (if necessary.)
	// This is an IN/OUT argument; the value of *address_stream will be
	// incremented by the size of an integer, or (if the SAME cache
	// was used) by the size of a byte (1).
	// address_stream_end: Points to the position just after the end of
	// the address stream buffer. All addresses between *address_stream
	// and address_stream_end should contain valid address data.
	//
	// Return value: If the input conditions were met, and the address section
	// of the input data contains properly encoded addresses that match
	// the instructions section, then an integer between 0 and here_address - 1
	// will be returned, representing the address from which data should
	// be copied from the source or target window into the output stream.
	// If an invalid address value is found in address_stream, then
	// RESULT_ERROR will be returned. If the limit address_stream_end
	// is reached before the address can be decoded, then
	// RESULT_END_OF_DATA will be returned. If more streamed data
	// is expected, this means that the consumer should block and wait
	// for more data before continuing to decode. If no more data is expected,
	// this return value signals an error condition.
	//
	VCDAddress VCDiffAddressCache::DecodeAddress(VCDAddress here_address,
	unsigned char mode,
	const char** address_stream,
	const char* address_stream_end) {
	if (here_address < 0) {
	VCD_DFATAL << "DecodeAddress was passed a negative value"
	" for here_address: " << here_address << VCD_ENDL;
	return RESULT_ERROR;
	}
	const char* new_address_pos = *address_stream;
	if (new_address_pos >= address_stream_end) {
	return RESULT_END_OF_DATA;
	}
	VCDAddress decoded_address;
	if (IsSameMode(mode)) {
	// SAME mode expects a byte value as the encoded address
	unsigned char encoded_address = ParseByte(&new_address_pos);
	decoded_address = DecodeSameAddress(mode, encoded_address);
	} else {
	// All modes except SAME mode expect a VarintBE as the encoded address
	int32_t encoded_address = VarintBE<int32_t>::Parse(address_stream_end,
	&new_address_pos);
	switch (encoded_address) {
	case RESULT_ERROR:
	VCD_ERROR << "Found invalid variable-length integer "
	"as encoded address value" << VCD_ENDL;
	return RESULT_ERROR;
	case RESULT_END_OF_DATA:
	return RESULT_END_OF_DATA;
	default:
	break;
	}
	if (IsSelfMode(mode)) {
	decoded_address = DecodeSelfAddress(encoded_address);
	} else if (IsHereMode(mode)) {
	decoded_address = DecodeHereAddress(encoded_address, here_address);
	} else if (IsNearMode(mode)) {
	decoded_address = DecodeNearAddress(mode, encoded_address);
	} else {
	VCD_DFATAL << "Invalid mode value (" << static_cast<int>(mode)
	<< ") passed to DecodeAddress; maximum mode value = "
	<< static_cast<int>(LastMode()) << VCD_ENDL;
	return RESULT_ERROR;
	}
	}
	// Check for an out-of-bounds address (corrupt/malicious data)
	if (!IsDecodedAddressValid(decoded_address, here_address)) {
	return RESULT_ERROR;
	}
	*address_stream = new_address_pos;
	UpdateCache(decoded_address);
	return decoded_address;
	}

	} // namespace open_vcdiff