// Copyright 2007 Google Inc. // Author: Lincoln Smith // // 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 #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(int near_cache_size, int 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. We do a separate sanity check for // near_cache_size_ and same_cache_size_ because adding them together can // cause an integer overflow if each is set to, say, INT_MAX. if ((near_cache_size_ > (VCD_MAX_MODES - 2)) || (near_cache_size_ < 0)) { VCD_ERROR << "Near cache size " << near_cache_size_ << " is invalid" << VCD_ENDL; return false; } if ((same_cache_size_ > (VCD_MAX_MODES - 2)) || (same_cache_size_ < 0)) { VCD_ERROR << "Same cache size " << same_cache_size_ << " is invalid" << VCD_ENDL; return false; } if ((near_cache_size_ + same_cache_size_) > VCD_MAX_MODES - 2) { VCD_ERROR << "Using near cache size " << near_cache_size_ << " and same cache size " << 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() + (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 (int 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(**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::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(mode) << ") passed to DecodeAddress; maximum mode value = " << static_cast(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