core/SkChecksum.h - platform/external/chromium_org/third_party/skia/include - Git at Google

 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkChecksum_DEFINED
 #define SkChecksum_DEFINED

 #include "SkTypes.h"

 /**
  *  Computes a 32bit checksum from a blob of 32bit aligned data. This is meant
  *  to be very very fast, as it is used internally by the font cache, in
  *  conjuction with the entire raw key. This algorithm does not generate
  *  unique values as well as others (e.g. MD5) but it performs much faster.
  *  Skia's use cases can survive non-unique values (since the entire key is
  *  always available). Clients should only be used in circumstances where speed
  *  over uniqueness is at a premium.
  */
 class SkChecksum : SkNoncopyable {
 private:
     /*
      *  Our Rotate and Mash helpers are meant to automatically do the right
      *  thing depending if sizeof(uintptr_t) is 4 or 8.
      */
     enum {
         ROTR = 17,
         ROTL = sizeof(uintptr_t) * 8 - ROTR,
         HALFBITS = sizeof(uintptr_t) * 4
     };

     static inline uintptr_t Mash(uintptr_t total, uintptr_t value) {
         return ((total >> ROTR) | (total << ROTL)) ^ value;
     }

 public:

     /**
      * Calculate 32-bit Murmur hash (murmur3).
      * This should take 2-3x longer than SkChecksum::Compute, but is a considerably better hash.
      * See en.wikipedia.org/wiki/MurmurHash.
      *
      *  @param data Memory address of the data block to be processed. Must be 32-bit aligned.
      *  @param size Size of the data block in bytes. Must be a multiple of 4.
      *  @param seed Initial hash seed. (optional)
      *  @return hash result
      */
     static uint32_t Murmur3(const uint32_t* data, size_t bytes, uint32_t seed=0) {
         SkASSERT(SkIsAlign4(bytes));
         const size_t words = bytes/4;

         uint32_t hash = seed;
         for (size_t i = 0; i < words; i++) {
             uint32_t k = data[i];
             k *= 0xcc9e2d51;
             k = (k << 15) | (k >> 17);
             k *= 0x1b873593;

             hash ^= k;
             hash = (hash << 13) | (hash >> 19);
             hash *= 5;
             hash += 0xe6546b64;
         }
         hash ^= bytes;
         hash ^= hash >> 16;
         hash *= 0x85ebca6b;
         hash ^= hash >> 13;
         hash *= 0xc2b2ae35;
         hash ^= hash >> 16;
         return hash;
     }

     /**
      *  Compute a 32-bit checksum for a given data block
      *
      *  WARNING: this algorithm is tuned for efficiency, not backward/forward
      *  compatibility.  It may change at any time, so a checksum generated with
      *  one version of the Skia code may not match a checksum generated with
      *  a different version of the Skia code.
      *
      *  @param data Memory address of the data block to be processed. Must be
      *              32-bit aligned.
      *  @param size Size of the data block in bytes. Must be a multiple of 4.
      *  @return checksum result
      */
     static uint32_t Compute(const uint32_t* data, size_t size) {
         SkASSERT(SkIsAlign4(size));

         /*
          *  We want to let the compiler use 32bit or 64bit addressing and math
          *  so we use uintptr_t as our magic type. This makes the code a little
          *  more obscure (we can't hard-code 32 or 64 anywhere, but have to use
          *  sizeof()).
          */
         uintptr_t result = 0;
         const uintptr_t* ptr = reinterpret_cast<const uintptr_t*>(data);

         /*
          *  count the number of quad element chunks. This takes into account
          *  if we're on a 32bit or 64bit arch, since we use sizeof(uintptr_t)
          *  to compute how much to shift-down the size.
          */
         size_t n4 = size / (sizeof(uintptr_t) << 2);
         for (size_t i = 0; i < n4; ++i) {
             result = Mash(result, *ptr++);
             result = Mash(result, *ptr++);
             result = Mash(result, *ptr++);
             result = Mash(result, *ptr++);
         }
         size &= ((sizeof(uintptr_t) << 2) - 1);

         data = reinterpret_cast<const uint32_t*>(ptr);
         const uint32_t* stop = data + (size >> 2);
         while (data < stop) {
             result = Mash(result, *data++);
         }

         /*
          *  smash us down to 32bits if we were 64. Note that when uintptr_t is
          *  32bits, this code-path should go away, but I still got a warning
          *  when I wrote
          *      result ^= result >> 32;
          *  since >>32 is undefined for 32bit ints, hence the wacky HALFBITS
          *  define.
          */
         if (8 == sizeof(result)) {
             result ^= result >> HALFBITS;
         }
         return static_cast<uint32_t>(result);
     }
 };

 #endif
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkChecksum_DEFINED
	#define SkChecksum_DEFINED

	#include "SkTypes.h"

	/**
	* Computes a 32bit checksum from a blob of 32bit aligned data. This is meant
	* to be very very fast, as it is used internally by the font cache, in
	* conjuction with the entire raw key. This algorithm does not generate
	* unique values as well as others (e.g. MD5) but it performs much faster.
	* Skia's use cases can survive non-unique values (since the entire key is
	* always available). Clients should only be used in circumstances where speed
	* over uniqueness is at a premium.
	*/
	class SkChecksum : SkNoncopyable {
	private:
	/*
	* Our Rotate and Mash helpers are meant to automatically do the right
	* thing depending if sizeof(uintptr_t) is 4 or 8.
	*/
	enum {
	ROTR = 17,
	ROTL = sizeof(uintptr_t) * 8 - ROTR,
	HALFBITS = sizeof(uintptr_t) * 4
	};

	static inline uintptr_t Mash(uintptr_t total, uintptr_t value) {
	return ((total >> ROTR) \| (total << ROTL)) ^ value;
	}

	public:

	/**
	* Calculate 32-bit Murmur hash (murmur3).
	* This should take 2-3x longer than SkChecksum::Compute, but is a considerably better hash.
	* See en.wikipedia.org/wiki/MurmurHash.
	*
	* @param data Memory address of the data block to be processed. Must be 32-bit aligned.
	* @param size Size of the data block in bytes. Must be a multiple of 4.
	* @param seed Initial hash seed. (optional)
	* @return hash result
	*/
	static uint32_t Murmur3(const uint32_t* data, size_t bytes, uint32_t seed=0) {
	SkASSERT(SkIsAlign4(bytes));
	const size_t words = bytes/4;

	uint32_t hash = seed;
	for (size_t i = 0; i < words; i++) {
	uint32_t k = data[i];
	k *= 0xcc9e2d51;
	k = (k << 15) \| (k >> 17);
	k *= 0x1b873593;

	hash ^= k;
	hash = (hash << 13) \| (hash >> 19);
	hash *= 5;
	hash += 0xe6546b64;
	}
	hash ^= bytes;
	hash ^= hash >> 16;
	hash *= 0x85ebca6b;
	hash ^= hash >> 13;
	hash *= 0xc2b2ae35;
	hash ^= hash >> 16;
	return hash;
	}

	/**
	* Compute a 32-bit checksum for a given data block
	*
	* WARNING: this algorithm is tuned for efficiency, not backward/forward
	* compatibility. It may change at any time, so a checksum generated with
	* one version of the Skia code may not match a checksum generated with
	* a different version of the Skia code.
	*
	* @param data Memory address of the data block to be processed. Must be
	* 32-bit aligned.
	* @param size Size of the data block in bytes. Must be a multiple of 4.
	* @return checksum result
	*/
	static uint32_t Compute(const uint32_t* data, size_t size) {
	SkASSERT(SkIsAlign4(size));

	/*
	* We want to let the compiler use 32bit or 64bit addressing and math
	* so we use uintptr_t as our magic type. This makes the code a little
	* more obscure (we can't hard-code 32 or 64 anywhere, but have to use
	* sizeof()).
	*/
	uintptr_t result = 0;
	const uintptr_t* ptr = reinterpret_cast<const uintptr_t*>(data);

	/*
	* count the number of quad element chunks. This takes into account
	* if we're on a 32bit or 64bit arch, since we use sizeof(uintptr_t)
	* to compute how much to shift-down the size.
	*/
	size_t n4 = size / (sizeof(uintptr_t) << 2);
	for (size_t i = 0; i < n4; ++i) {
	result = Mash(result, *ptr++);
	result = Mash(result, *ptr++);
	result = Mash(result, *ptr++);
	result = Mash(result, *ptr++);
	}
	size &= ((sizeof(uintptr_t) << 2) - 1);

	data = reinterpret_cast<const uint32_t*>(ptr);
	const uint32_t* stop = data + (size >> 2);
	while (data < stop) {
	result = Mash(result, *data++);
	}

	/*
	* smash us down to 32bits if we were 64. Note that when uintptr_t is
	* 32bits, this code-path should go away, but I still got a warning
	* when I wrote
	* result ^= result >> 32;
	* since >>32 is undefined for 32bit ints, hence the wacky HALFBITS
	* define.
	*/
	if (8 == sizeof(result)) {
	result ^= result >> HALFBITS;
	}
	return static_cast<uint32_t>(result);
	}
	};

	#endif