src/rolling_hash.h - platform/external/open-vcdiff - Git at Google

 // Copyright 2007, 2008 Google Inc.
 // Authors: Jeff Dean, Sanjay Ghemawat, 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.

 #ifndef OPEN_VCDIFF_ROLLING_HASH_H_
 #define OPEN_VCDIFF_ROLLING_HASH_H_

 #include <config.h>
 #include <stdint.h>  // uint32_t
 #include "compile_assert.h"
 #include "logging.h"

 namespace open_vcdiff {

 // Rabin-Karp hasher module -- this is a faster version with different
 // constants, so it's not quite Rabin-Karp fingerprinting, but its behavior is
 // close enough for most applications.

 // Definitions common to all hash window sizes.
 class RollingHashUtil {
  public:
   // Multiplier for incremental hashing.  The compiler should be smart enough to
   // convert (val * kMult) into ((val << 8) + val).
   static const uint32_t kMult = 257;

   // All hashes are returned modulo "kBase".  Current implementation requires
   // kBase <= 2^32/kMult to avoid overflow.  Also, kBase must be a power of two
   // so that we can compute modulus efficiently.
   static const uint32_t kBase = (1 << 23);

   // Returns operand % kBase, assuming that kBase is a power of two.
   static inline uint32_t ModBase(uint32_t operand) {
     return operand & (kBase - 1);
   }

   // Given an unsigned integer "operand", returns an unsigned integer "result"
   // such that
   //     result < kBase
   // and
   //     ModBase(operand + result) == 0
   static inline uint32_t FindModBaseInverse(uint32_t operand) {
     // The subtraction (0 - operand) produces an unsigned underflow for any
     // operand except 0.  The underflow results in a (very large) unsigned
     // number.  Binary subtraction is used instead of unary negation because
     // some compilers (e.g. Visual Studio 7+) produce a warning if an unsigned
     // value is negated.
     //
     // The C++ mod operation (operand % kBase) may produce different results for
     // different compilers if operand is negative.  That is not a problem in
     // this case, since all numbers used are unsigned, and ModBase does its work
     // using bitwise arithmetic rather than the % operator.
     return ModBase(uint32_t(0) - operand);
   }

   // Here's the heart of the hash algorithm.  Start with a partial_hash value of
   // 0, and run this HashStep once against each byte in the data window to be
   // hashed.  The result will be the hash value for the entire data window.  The
   // Hash() function, below, does exactly this, albeit with some refinements.
   static inline uint32_t HashStep(uint32_t partial_hash,
                                   unsigned char next_byte) {
     return ModBase((partial_hash * kMult) + next_byte);
   }

   // Use this function to start computing a new hash value based on the first
   // two bytes in the window.  It is equivalent to calling
   //     HashStep(HashStep(0, ptr[0]), ptr[1])
   // but takes advantage of the fact that the maximum value of
   // (ptr[0] * kMult) + ptr[1] is not large enough to exceed kBase, thus
   // avoiding an unnecessary ModBase operation.
   static inline uint32_t HashFirstTwoBytes(const char* ptr) {
     return (static_cast<unsigned char>(ptr[0]) * kMult)
         + static_cast<unsigned char>(ptr[1]);
   }
  private:
   // Making these private avoids copy constructor and assignment operator.
   // No objects of this type should be constructed.
   RollingHashUtil();
   RollingHashUtil(const RollingHashUtil&);  // NOLINT
   void operator=(const RollingHashUtil&);
 };

 // window_size must be >= 2.
 template<int window_size>
 class RollingHash {
  public:
   // Perform global initialization that is required in order to instantiate a
   // RollingHash.  This function *must* be called (preferably on startup) by any
   // program that uses a RollingHash.  It is harmless to call this function more
   // than once.  It is not thread-safe, but calling it from two different
   // threads at the same time can only cause a memory leak, not incorrect
   // behavior.  Make sure to call it before spawning any threads that could use
   // RollingHash.
   static void Init();

   // Initialize hasher to maintain a window of the specified size.  You need an
   // instance of this type to use UpdateHash(), but Hash() does not depend on
   // remove_table_, so it is static.
   RollingHash() {
     if (!remove_table_) {
       VCD_DFATAL << "RollingHash object instantiated"
                     " before calling RollingHash::Init()" << VCD_ENDL;
     }
   }

   // Compute a hash of the window "ptr[0, window_size - 1]".
   static uint32_t Hash(const char* ptr) {
     uint32_t h = RollingHashUtil::HashFirstTwoBytes(ptr);
     for (int i = 2; i < window_size; ++i) {
       h = RollingHashUtil::HashStep(h, ptr[i]);
     }
     return h;
   }

   // Update a hash by removing the oldest byte and adding a new byte.
   //
   // UpdateHash takes the hash value of buffer[0] ... buffer[window_size -1]
   // along with the value of buffer[0] (the "old_first_byte" argument)
   // and the value of buffer[window_size] (the "new_last_byte" argument).
   // It quickly computes the hash value of buffer[1] ... buffer[window_size]
   // without having to run Hash() on the entire window.
   //
   // The larger the window, the more advantage comes from using UpdateHash()
   // (which runs in time independent of window_size) instead of Hash().
   // Each time window_size doubles, the time to execute Hash() also doubles,
   // while the time to execute UpdateHash() remains constant.  Empirical tests
   // have borne out this statement.
   uint32_t UpdateHash(uint32_t old_hash,
                       const char old_first_byte,
                       const char new_last_byte) const {
     uint32_t partial_hash = RemoveFirstByteFromHash(old_hash, old_first_byte);
     return RollingHashUtil::HashStep(partial_hash, new_last_byte);
   }

  protected:
   // Given a full hash value for buffer[0] ... buffer[window_size -1], plus the
   // value of the first byte buffer[0], this function returns a *partial* hash
   // value for buffer[1] ... buffer[window_size -1].  See the comments in
   // Init(), below, for a description of how the contents of remove_table_ are
   // computed.
   static uint32_t RemoveFirstByteFromHash(uint32_t full_hash,
                                           unsigned char first_byte) {
     return RollingHashUtil::ModBase(full_hash + remove_table_[first_byte]);
   }

  private:
   // We keep a table that maps from any byte "b" to
   //    (- b * pow(kMult, window_size - 1)) % kBase
   static const uint32_t* remove_table_;
 };

 // For each window_size, fill a 256-entry table such that
 //        the hash value of buffer[0] ... buffer[window_size - 1]
 //      + remove_table_[buffer[0]]
 //     == the hash value of buffer[1] ... buffer[window_size - 1]
 // See the comments in Init(), below, for a description of how the contents of
 // remove_table_ are computed.
 template<int window_size>
 const uint32_t* RollingHash<window_size>::remove_table_ = NULL;

 // Init() checks to make sure that the static object remove_table_ has been
 // initialized; if not, it does the considerable work of populating it.  Once
 // it's ready, the table can be used for any number of RollingHash objects of
 // the same window_size.
 //
 template<int window_size>
 void RollingHash<window_size>::Init() {
   VCD_COMPILE_ASSERT(window_size >= 2,
                      RollingHash_window_size_must_be_at_least_2);
   if (remove_table_ == NULL) {
     // The new object is placed into a local pointer instead of directly into
     // remove_table_, for two reasons:
     //   1. remove_table_ is a pointer to const.  The table is populated using
     //      the non-const local pointer and then assigned to the global const
     //      pointer once it's ready.
     //   2. No other thread will ever see remove_table_ pointing to a
     //      partially-initialized table.  If two threads happen to call Init()
     //      at the same time, two tables with the same contents may be created
     //      (causing a memory leak), but the results will be consistent
     //      no matter which of the two tables is used.
     uint32_t* new_remove_table = new uint32_t[256];
     // Compute multiplier.  Concisely, it is:
     //     pow(kMult, (window_size - 1)) % kBase,
     // but we compute the power in integer form.
     uint32_t multiplier = 1;
     for (int i = 0; i < window_size - 1; ++i) {
       multiplier =
           RollingHashUtil::ModBase(multiplier * RollingHashUtil::kMult);
     }
     // For each character removed_byte, compute
     //     remove_table_[removed_byte] ==
     //         (- (removed_byte * pow(kMult, (window_size - 1)))) % kBase
     // where the power operator "pow" is taken in integer form.
     //
     // If you take a hash value fp representing the hash of
     //     buffer[0] ... buffer[window_size - 1]
     // and add the value of remove_table_[buffer[0]] to it, the result will be
     // a partial hash value for
     //     buffer[1] ... buffer[window_size - 1]
     // that is to say, it no longer includes buffer[0].
     //
     // The following byte at buffer[window_size] can then be merged with this
     // partial hash value to arrive quickly at the hash value for a window that
     // has advanced by one byte, to
     //     buffer[1] ... buffer[window_size]
     // In fact, that is precisely what happens in UpdateHash, above.
     uint32_t byte_times_multiplier = 0;
     for (int removed_byte = 0; removed_byte < 256; ++removed_byte) {
       new_remove_table[removed_byte] =
           RollingHashUtil::FindModBaseInverse(byte_times_multiplier);
       // Iteratively adding the multiplier in this loop is equivalent to
       // computing (removed_byte * multiplier), and is faster
       byte_times_multiplier =
           RollingHashUtil::ModBase(byte_times_multiplier + multiplier);
     }
     remove_table_ = new_remove_table;
   }
 }

 }  // namespace open_vcdiff

 #endif  // OPEN_VCDIFF_ROLLING_HASH_H_
	// Copyright 2007, 2008 Google Inc.
	// Authors: Jeff Dean, Sanjay Ghemawat, 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.

	#ifndef OPEN_VCDIFF_ROLLING_HASH_H_
	#define OPEN_VCDIFF_ROLLING_HASH_H_

	#include <config.h>
	#include <stdint.h> // uint32_t
	#include "compile_assert.h"
	#include "logging.h"

	namespace open_vcdiff {

	// Rabin-Karp hasher module -- this is a faster version with different
	// constants, so it's not quite Rabin-Karp fingerprinting, but its behavior is
	// close enough for most applications.

	// Definitions common to all hash window sizes.
	class RollingHashUtil {
	public:
	// Multiplier for incremental hashing. The compiler should be smart enough to
	// convert (val * kMult) into ((val << 8) + val).
	static const uint32_t kMult = 257;

	// All hashes are returned modulo "kBase". Current implementation requires
	// kBase <= 2^32/kMult to avoid overflow. Also, kBase must be a power of two
	// so that we can compute modulus efficiently.
	static const uint32_t kBase = (1 << 23);

	// Returns operand % kBase, assuming that kBase is a power of two.
	static inline uint32_t ModBase(uint32_t operand) {
	return operand & (kBase - 1);
	}

	// Given an unsigned integer "operand", returns an unsigned integer "result"
	// such that
	// result < kBase
	// and
	// ModBase(operand + result) == 0
	static inline uint32_t FindModBaseInverse(uint32_t operand) {
	// The subtraction (0 - operand) produces an unsigned underflow for any
	// operand except 0. The underflow results in a (very large) unsigned
	// number. Binary subtraction is used instead of unary negation because
	// some compilers (e.g. Visual Studio 7+) produce a warning if an unsigned
	// value is negated.
	//
	// The C++ mod operation (operand % kBase) may produce different results for
	// different compilers if operand is negative. That is not a problem in
	// this case, since all numbers used are unsigned, and ModBase does its work
	// using bitwise arithmetic rather than the % operator.
	return ModBase(uint32_t(0) - operand);
	}

	// Here's the heart of the hash algorithm. Start with a partial_hash value of
	// 0, and run this HashStep once against each byte in the data window to be
	// hashed. The result will be the hash value for the entire data window. The
	// Hash() function, below, does exactly this, albeit with some refinements.
	static inline uint32_t HashStep(uint32_t partial_hash,
	unsigned char next_byte) {
	return ModBase((partial_hash * kMult) + next_byte);
	}

	// Use this function to start computing a new hash value based on the first
	// two bytes in the window. It is equivalent to calling
	// HashStep(HashStep(0, ptr[0]), ptr[1])
	// but takes advantage of the fact that the maximum value of
	// (ptr[0] * kMult) + ptr[1] is not large enough to exceed kBase, thus
	// avoiding an unnecessary ModBase operation.
	static inline uint32_t HashFirstTwoBytes(const char* ptr) {
	return (static_cast<unsigned char>(ptr[0]) * kMult)
	+ static_cast<unsigned char>(ptr[1]);
	}
	private:
	// Making these private avoids copy constructor and assignment operator.
	// No objects of this type should be constructed.
	RollingHashUtil();
	RollingHashUtil(const RollingHashUtil&); // NOLINT
	void operator=(const RollingHashUtil&);
	};

	// window_size must be >= 2.
	template<int window_size>
	class RollingHash {
	public:
	// Perform global initialization that is required in order to instantiate a
	// RollingHash. This function must be called (preferably on startup) by any
	// program that uses a RollingHash. It is harmless to call this function more
	// than once. It is not thread-safe, but calling it from two different
	// threads at the same time can only cause a memory leak, not incorrect
	// behavior. Make sure to call it before spawning any threads that could use
	// RollingHash.
	static void Init();

	// Initialize hasher to maintain a window of the specified size. You need an
	// instance of this type to use UpdateHash(), but Hash() does not depend on
	// remove_table_, so it is static.
	RollingHash() {
	if (!remove_table_) {
	VCD_DFATAL << "RollingHash object instantiated"
	" before calling RollingHash::Init()" << VCD_ENDL;
	}
	}

	// Compute a hash of the window "ptr[0, window_size - 1]".
	static uint32_t Hash(const char* ptr) {
	uint32_t h = RollingHashUtil::HashFirstTwoBytes(ptr);
	for (int i = 2; i < window_size; ++i) {
	h = RollingHashUtil::HashStep(h, ptr[i]);
	}
	return h;
	}

	// Update a hash by removing the oldest byte and adding a new byte.
	//
	// UpdateHash takes the hash value of buffer[0] ... buffer[window_size -1]
	// along with the value of buffer[0] (the "old_first_byte" argument)
	// and the value of buffer[window_size] (the "new_last_byte" argument).
	// It quickly computes the hash value of buffer[1] ... buffer[window_size]
	// without having to run Hash() on the entire window.
	//
	// The larger the window, the more advantage comes from using UpdateHash()
	// (which runs in time independent of window_size) instead of Hash().
	// Each time window_size doubles, the time to execute Hash() also doubles,
	// while the time to execute UpdateHash() remains constant. Empirical tests
	// have borne out this statement.
	uint32_t UpdateHash(uint32_t old_hash,
	const char old_first_byte,
	const char new_last_byte) const {
	uint32_t partial_hash = RemoveFirstByteFromHash(old_hash, old_first_byte);
	return RollingHashUtil::HashStep(partial_hash, new_last_byte);
	}

	protected:
	// Given a full hash value for buffer[0] ... buffer[window_size -1], plus the
	// value of the first byte buffer[0], this function returns a partial hash
	// value for buffer[1] ... buffer[window_size -1]. See the comments in
	// Init(), below, for a description of how the contents of remove_table_ are
	// computed.
	static uint32_t RemoveFirstByteFromHash(uint32_t full_hash,
	unsigned char first_byte) {
	return RollingHashUtil::ModBase(full_hash + remove_table_[first_byte]);
	}

	private:
	// We keep a table that maps from any byte "b" to
	// (- b * pow(kMult, window_size - 1)) % kBase
	static const uint32_t* remove_table_;
	};

	// For each window_size, fill a 256-entry table such that
	// the hash value of buffer[0] ... buffer[window_size - 1]
	// + remove_table_[buffer[0]]
	// == the hash value of buffer[1] ... buffer[window_size - 1]
	// See the comments in Init(), below, for a description of how the contents of
	// remove_table_ are computed.
	template<int window_size>
	const uint32_t* RollingHash<window_size>::remove_table_ = NULL;

	// Init() checks to make sure that the static object remove_table_ has been
	// initialized; if not, it does the considerable work of populating it. Once
	// it's ready, the table can be used for any number of RollingHash objects of
	// the same window_size.
	//
	template<int window_size>
	void RollingHash<window_size>::Init() {
	VCD_COMPILE_ASSERT(window_size >= 2,
	RollingHash_window_size_must_be_at_least_2);
	if (remove_table_ == NULL) {
	// The new object is placed into a local pointer instead of directly into
	// remove_table_, for two reasons:
	// 1. remove_table_ is a pointer to const. The table is populated using
	// the non-const local pointer and then assigned to the global const
	// pointer once it's ready.
	// 2. No other thread will ever see remove_table_ pointing to a
	// partially-initialized table. If two threads happen to call Init()
	// at the same time, two tables with the same contents may be created
	// (causing a memory leak), but the results will be consistent
	// no matter which of the two tables is used.
	uint32_t* new_remove_table = new uint32_t[256];
	// Compute multiplier. Concisely, it is:
	// pow(kMult, (window_size - 1)) % kBase,
	// but we compute the power in integer form.
	uint32_t multiplier = 1;
	for (int i = 0; i < window_size - 1; ++i) {
	multiplier =
	RollingHashUtil::ModBase(multiplier * RollingHashUtil::kMult);
	}
	// For each character removed_byte, compute
	// remove_table_[removed_byte] ==
	// (- (removed_byte * pow(kMult, (window_size - 1)))) % kBase
	// where the power operator "pow" is taken in integer form.
	//
	// If you take a hash value fp representing the hash of
	// buffer[0] ... buffer[window_size - 1]
	// and add the value of remove_table_[buffer[0]] to it, the result will be
	// a partial hash value for
	// buffer[1] ... buffer[window_size - 1]
	// that is to say, it no longer includes buffer[0].
	//
	// The following byte at buffer[window_size] can then be merged with this
	// partial hash value to arrive quickly at the hash value for a window that
	// has advanced by one byte, to
	// buffer[1] ... buffer[window_size]
	// In fact, that is precisely what happens in UpdateHash, above.
	uint32_t byte_times_multiplier = 0;
	for (int removed_byte = 0; removed_byte < 256; ++removed_byte) {
	new_remove_table[removed_byte] =
	RollingHashUtil::FindModBaseInverse(byte_times_multiplier);
	// Iteratively adding the multiplier in this loop is equivalent to
	// computing (removed_byte * multiplier), and is faster
	byte_times_multiplier =
	RollingHashUtil::ModBase(byte_times_multiplier + multiplier);
	}
	remove_table_ = new_remove_table;
	}
	}

	} // namespace open_vcdiff

	#endif // OPEN_VCDIFF_ROLLING_HASH_H_