diffcore-delta.c - git - Git at Google

 #include "cache.h"
 #include "diff.h"
 #include "diffcore.h"

 /*
  * Idea here is very simple.
  *
  * Almost all data we are interested in are text, but sometimes we have
  * to deal with binary data.  So we cut them into chunks delimited by
  * LF byte, or 64-byte sequence, whichever comes first, and hash them.
  *
  * For those chunks, if the source buffer has more instances of it
  * than the destination buffer, that means the difference are the
  * number of bytes not copied from source to destination.  If the
  * counts are the same, everything was copied from source to
  * destination.  If the destination has more, everything was copied,
  * and destination added more.
  *
  * We are doing an approximation so we do not really have to waste
  * memory by actually storing the sequence.  We just hash them into
  * somewhere around 2^16 hashbuckets and count the occurrences.
  */

 /* Wild guess at the initial hash size */
 #define INITIAL_HASH_SIZE 9

 /* We leave more room in smaller hash but do not let it
  * grow to have unused hole too much.
  */
 #define INITIAL_FREE(sz_log2) ((1<<(sz_log2))*(sz_log2-3)/(sz_log2))

 /* A prime rather carefully chosen between 2^16..2^17, so that
  * HASHBASE < INITIAL_FREE(17).  We want to keep the maximum hashtable
  * size under the current 2<<17 maximum, which can hold this many
  * different values before overflowing to hashtable of size 2<<18.
  */
 #define HASHBASE 107927

 struct spanhash {
 	unsigned int hashval;
 	unsigned int cnt;
 };
 struct spanhash_top {
 	int alloc_log2;
 	int free;
 	struct spanhash data[FLEX_ARRAY];
 };

 static struct spanhash_top *spanhash_rehash(struct spanhash_top *orig)
 {
 	struct spanhash_top *new_spanhash;
 	int i;
 	int osz = 1 << orig->alloc_log2;
 	int sz = osz << 1;

 	new_spanhash = xmalloc(st_add(sizeof(*orig),
 			     st_mult(sizeof(struct spanhash), sz)));
 	new_spanhash->alloc_log2 = orig->alloc_log2 + 1;
 	new_spanhash->free = INITIAL_FREE(new_spanhash->alloc_log2);
 	memset(new_spanhash->data, 0, sizeof(struct spanhash) * sz);
 	for (i = 0; i < osz; i++) {
 		struct spanhash *o = &(orig->data[i]);
 		int bucket;
 		if (!o->cnt)
 			continue;
 		bucket = o->hashval & (sz - 1);
 		while (1) {
 			struct spanhash *h = &(new_spanhash->data[bucket++]);
 			if (!h->cnt) {
 				h->hashval = o->hashval;
 				h->cnt = o->cnt;
 				new_spanhash->free--;
 				break;
 			}
 			if (sz <= bucket)
 				bucket = 0;
 		}
 	}
 	free(orig);
 	return new_spanhash;
 }

 static struct spanhash_top *add_spanhash(struct spanhash_top *top,
 					 unsigned int hashval, int cnt)
 {
 	int bucket, lim;
 	struct spanhash *h;

 	lim = (1 << top->alloc_log2);
 	bucket = hashval & (lim - 1);
 	while (1) {
 		h = &(top->data[bucket++]);
 		if (!h->cnt) {
 			h->hashval = hashval;
 			h->cnt = cnt;
 			top->free--;
 			if (top->free < 0)
 				return spanhash_rehash(top);
 			return top;
 		}
 		if (h->hashval == hashval) {
 			h->cnt += cnt;
 			return top;
 		}
 		if (lim <= bucket)
 			bucket = 0;
 	}
 }

 static int spanhash_cmp(const void *a_, const void *b_)
 {
 	const struct spanhash *a = a_;
 	const struct spanhash *b = b_;

 	/* A count of zero compares at the end.. */
 	if (!a->cnt)
 		return !b->cnt ? 0 : 1;
 	if (!b->cnt)
 		return -1;
 	return a->hashval < b->hashval ? -1 :
 		a->hashval > b->hashval ? 1 : 0;
 }

 static struct spanhash_top *hash_chars(struct repository *r,
 				       struct diff_filespec *one)
 {
 	int i, n;
 	unsigned int accum1, accum2, hashval;
 	struct spanhash_top *hash;
 	unsigned char *buf = one->data;
 	unsigned int sz = one->size;
 	int is_text = !diff_filespec_is_binary(r, one);

 	i = INITIAL_HASH_SIZE;
 	hash = xmalloc(st_add(sizeof(*hash),
 			      st_mult(sizeof(struct spanhash), 1<<i)));
 	hash->alloc_log2 = i;
 	hash->free = INITIAL_FREE(i);
 	memset(hash->data, 0, sizeof(struct spanhash) * (1<<i));

 	n = 0;
 	accum1 = accum2 = 0;
 	while (sz) {
 		unsigned int c = *buf++;
 		unsigned int old_1 = accum1;
 		sz--;

 		/* Ignore CR in CRLF sequence if text */
 		if (is_text && c == '\r' && sz && *buf == '\n')
 			continue;

 		accum1 = (accum1 << 7) ^ (accum2 >> 25);
 		accum2 = (accum2 << 7) ^ (old_1 >> 25);
 		accum1 += c;
 		if (++n < 64 && c != '\n')
 			continue;
 		hashval = (accum1 + accum2 * 0x61) % HASHBASE;
 		hash = add_spanhash(hash, hashval, n);
 		n = 0;
 		accum1 = accum2 = 0;
 	}
 	QSORT(hash->data, 1ul << hash->alloc_log2, spanhash_cmp);
 	return hash;
 }

 int diffcore_count_changes(struct repository *r,
 			   struct diff_filespec *src,
 			   struct diff_filespec *dst,
 			   void **src_count_p,
 			   void **dst_count_p,
 			   unsigned long *src_copied,
 			   unsigned long *literal_added)
 {
 	struct spanhash *s, *d;
 	struct spanhash_top *src_count, *dst_count;
 	unsigned long sc, la;

 	src_count = dst_count = NULL;
 	if (src_count_p)
 		src_count = *src_count_p;
 	if (!src_count) {
 		src_count = hash_chars(r, src);
 		if (src_count_p)
 			*src_count_p = src_count;
 	}
 	if (dst_count_p)
 		dst_count = *dst_count_p;
 	if (!dst_count) {
 		dst_count = hash_chars(r, dst);
 		if (dst_count_p)
 			*dst_count_p = dst_count;
 	}
 	sc = la = 0;

 	s = src_count->data;
 	d = dst_count->data;
 	for (;;) {
 		unsigned dst_cnt, src_cnt;
 		if (!s->cnt)
 			break; /* we checked all in src */
 		while (d->cnt) {
 			if (d->hashval >= s->hashval)
 				break;
 			la += d->cnt;
 			d++;
 		}
 		src_cnt = s->cnt;
 		dst_cnt = 0;
 		if (d->cnt && d->hashval == s->hashval) {
 			dst_cnt = d->cnt;
 			d++;
 		}
 		if (src_cnt < dst_cnt) {
 			la += dst_cnt - src_cnt;
 			sc += src_cnt;
 		}
 		else
 			sc += dst_cnt;
 		s++;
 	}
 	while (d->cnt) {
 		la += d->cnt;
 		d++;
 	}

 	if (!src_count_p)
 		free(src_count);
 	if (!dst_count_p)
 		free(dst_count);
 	*src_copied = sc;
 	*literal_added = la;
 	return 0;
 }
	#include "cache.h"
	#include "diff.h"
	#include "diffcore.h"

	/*
	* Idea here is very simple.
	*
	* Almost all data we are interested in are text, but sometimes we have
	* to deal with binary data. So we cut them into chunks delimited by
	* LF byte, or 64-byte sequence, whichever comes first, and hash them.
	*
	* For those chunks, if the source buffer has more instances of it
	* than the destination buffer, that means the difference are the
	* number of bytes not copied from source to destination. If the
	* counts are the same, everything was copied from source to
	* destination. If the destination has more, everything was copied,
	* and destination added more.
	*
	* We are doing an approximation so we do not really have to waste
	* memory by actually storing the sequence. We just hash them into
	* somewhere around 2^16 hashbuckets and count the occurrences.
	*/

	/* Wild guess at the initial hash size */
	#define INITIAL_HASH_SIZE 9

	/* We leave more room in smaller hash but do not let it
	* grow to have unused hole too much.
	*/
	#define INITIAL_FREE(sz_log2) ((1<<(sz_log2))*(sz_log2-3)/(sz_log2))

	/* A prime rather carefully chosen between 2^16..2^17, so that
	* HASHBASE < INITIAL_FREE(17). We want to keep the maximum hashtable
	* size under the current 2<<17 maximum, which can hold this many
	* different values before overflowing to hashtable of size 2<<18.
	*/
	#define HASHBASE 107927

	struct spanhash {
	unsigned int hashval;
	unsigned int cnt;
	};
	struct spanhash_top {
	int alloc_log2;
	int free;
	struct spanhash data[FLEX_ARRAY];
	};

	static struct spanhash_top spanhash_rehash(struct spanhash_top orig)
	{
	struct spanhash_top *new_spanhash;
	int i;
	int osz = 1 << orig->alloc_log2;
	int sz = osz << 1;

	new_spanhash = xmalloc(st_add(sizeof(*orig),
	st_mult(sizeof(struct spanhash), sz)));
	new_spanhash->alloc_log2 = orig->alloc_log2 + 1;
	new_spanhash->free = INITIAL_FREE(new_spanhash->alloc_log2);
	memset(new_spanhash->data, 0, sizeof(struct spanhash) * sz);
	for (i = 0; i < osz; i++) {
	struct spanhash *o = &(orig->data[i]);
	int bucket;
	if (!o->cnt)
	continue;
	bucket = o->hashval & (sz - 1);
	while (1) {
	struct spanhash *h = &(new_spanhash->data[bucket++]);
	if (!h->cnt) {
	h->hashval = o->hashval;
	h->cnt = o->cnt;
	new_spanhash->free--;
	break;
	}
	if (sz <= bucket)
	bucket = 0;
	}
	}
	free(orig);
	return new_spanhash;
	}

	static struct spanhash_top add_spanhash(struct spanhash_top top,
	unsigned int hashval, int cnt)
	{
	int bucket, lim;
	struct spanhash *h;

	lim = (1 << top->alloc_log2);
	bucket = hashval & (lim - 1);
	while (1) {
	h = &(top->data[bucket++]);
	if (!h->cnt) {
	h->hashval = hashval;
	h->cnt = cnt;
	top->free--;
	if (top->free < 0)
	return spanhash_rehash(top);
	return top;
	}
	if (h->hashval == hashval) {
	h->cnt += cnt;
	return top;
	}
	if (lim <= bucket)
	bucket = 0;
	}
	}

	static int spanhash_cmp(const void a_, const void b_)
	{
	const struct spanhash *a = a_;
	const struct spanhash *b = b_;

	/* A count of zero compares at the end.. */
	if (!a->cnt)
	return !b->cnt ? 0 : 1;
	if (!b->cnt)
	return -1;
	return a->hashval < b->hashval ? -1 :
	a->hashval > b->hashval ? 1 : 0;
	}

	static struct spanhash_top hash_chars(struct repository r,
	struct diff_filespec *one)
	{
	int i, n;
	unsigned int accum1, accum2, hashval;
	struct spanhash_top *hash;
	unsigned char *buf = one->data;
	unsigned int sz = one->size;
	int is_text = !diff_filespec_is_binary(r, one);

	i = INITIAL_HASH_SIZE;
	hash = xmalloc(st_add(sizeof(*hash),
	st_mult(sizeof(struct spanhash), 1<<i)));
	hash->alloc_log2 = i;
	hash->free = INITIAL_FREE(i);
	memset(hash->data, 0, sizeof(struct spanhash) * (1<<i));

	n = 0;
	accum1 = accum2 = 0;
	while (sz) {
	unsigned int c = *buf++;
	unsigned int old_1 = accum1;
	sz--;

	/* Ignore CR in CRLF sequence if text */
	if (is_text && c == '\r' && sz && *buf == '\n')
	continue;

	accum1 = (accum1 << 7) ^ (accum2 >> 25);
	accum2 = (accum2 << 7) ^ (old_1 >> 25);
	accum1 += c;
	if (++n < 64 && c != '\n')
	continue;
	hashval = (accum1 + accum2 * 0x61) % HASHBASE;
	hash = add_spanhash(hash, hashval, n);
	n = 0;
	accum1 = accum2 = 0;
	}
	QSORT(hash->data, 1ul << hash->alloc_log2, spanhash_cmp);
	return hash;
	}

	int diffcore_count_changes(struct repository *r,
	struct diff_filespec *src,
	struct diff_filespec *dst,
	void **src_count_p,
	void **dst_count_p,
	unsigned long *src_copied,
	unsigned long *literal_added)
	{
	struct spanhash s, d;
	struct spanhash_top src_count, dst_count;
	unsigned long sc, la;

	src_count = dst_count = NULL;
	if (src_count_p)
	src_count = *src_count_p;
	if (!src_count) {
	src_count = hash_chars(r, src);
	if (src_count_p)
	*src_count_p = src_count;
	}
	if (dst_count_p)
	dst_count = *dst_count_p;
	if (!dst_count) {
	dst_count = hash_chars(r, dst);
	if (dst_count_p)
	*dst_count_p = dst_count;
	}
	sc = la = 0;

	s = src_count->data;
	d = dst_count->data;
	for (;;) {
	unsigned dst_cnt, src_cnt;
	if (!s->cnt)
	break; /* we checked all in src */
	while (d->cnt) {
	if (d->hashval >= s->hashval)
	break;
	la += d->cnt;
	d++;
	}
	src_cnt = s->cnt;
	dst_cnt = 0;
	if (d->cnt && d->hashval == s->hashval) {
	dst_cnt = d->cnt;
	d++;
	}
	if (src_cnt < dst_cnt) {
	la += dst_cnt - src_cnt;
	sc += src_cnt;
	}
	else
	sc += dst_cnt;
	s++;
	}
	while (d->cnt) {
	la += d->cnt;
	d++;
	}

	if (!src_count_p)
	free(src_count);
	if (!dst_count_p)
	free(dst_count);
	*src_copied = sc;
	*literal_added = la;
	return 0;
	}