mariadb/ha/ha0storage.c

/******************************************************
Hash storage.
Provides a data structure that stores chunks of data in
its own storage, avoiding duplicates.

(c) 2007 Innobase Oy

Created September 22, 2007 Vasil Dimov
*******************************************************/

#include "univ.i"
#include "ha0storage.h"
#include "hash0hash.h"
#include "mem0mem.h"
#include "ut0rnd.h"

#ifdef UNIV_NONINL
#include "ha0storage.ic"
#endif

/***********************************************************************
Retrieves a data from a storage. If it is present, a pointer to the
stored copy of data is returned, otherwise NULL is returned. */
static
const void*
ha_storage_get(
/*===========*/
	ha_storage_t*	storage,	/* in: hash storage */
	const void*	data,		/* in: data to check for */
	ulint		data_len)	/* in: data length */
{
	ha_storage_node_t*	node;
	ulint			fold;

	/* avoid repetitive calls to ut_fold_binary() in the HASH_SEARCH
	macro */
	fold = ut_fold_binary(data, data_len);

#define IS_FOUND	\
	node->data_len == data_len && memcmp(node->data, data, data_len) == 0

	HASH_SEARCH(
		next,			/* node->"next" */
		storage->hash,		/* the hash table */
		fold,			/* key */
		ha_storage_node_t*,	/* type of node->next */
		node,			/* auxiliary variable */
		IS_FOUND);		/* search criteria */

	if (node == NULL) {

		return(NULL);
	}
	/* else */

	return(node->data);
}

/***********************************************************************
Copies data into the storage and returns a pointer to the copy. If the
same data chunk is already present, then pointer to it is returned.
Data chunks are considered to be equal if len1 == len2 and
memcmp(data1, data2, len1) == 0. If "data" is not present (and thus
data_len bytes need to be allocated) and the size of storage is going to
become more than "memlim" then "data" is not added and NULL is returned.
To disable this behavior "memlim" can be set to 0, which stands for
"no limit". */
UNIV_INTERN
const void*
ha_storage_put_memlim(
/*==================*/
	ha_storage_t*	storage,	/* in/out: hash storage */
	const void*	data,		/* in: data to store */
	ulint		data_len,	/* in: data length */
	ulint		memlim)		/* in: memory limit to obey */
{
	void*			raw;
	ha_storage_node_t*	node;
	const void*		data_copy;
	ulint			fold;

	/* check if data chunk is already present */
	data_copy = ha_storage_get(storage, data, data_len);
	if (data_copy != NULL) {

		return(data_copy);
	}

	/* not present */

	/* check if we are allowed to allocate data_len bytes */
	if (memlim > 0
	    && ha_storage_get_size(storage) + data_len > memlim) {

		return(NULL);
	}

	/* we put the auxiliary node struct and the data itself in one
	continuous block */
	raw = mem_heap_alloc(storage->heap,
			     sizeof(ha_storage_node_t) + data_len);

	node = (ha_storage_node_t*) raw;
	data_copy = (byte*) raw + sizeof(*node);

	memcpy((byte*) raw + sizeof(*node), data, data_len);

	node->data_len = data_len;
	node->data = data_copy;

	/* avoid repetitive calls to ut_fold_binary() in the HASH_INSERT
	macro */
	fold = ut_fold_binary(data, data_len);

	HASH_INSERT(
		ha_storage_node_t,	/* type used in the hash chain */
		next,			/* node->"next" */
		storage->hash,		/* the hash table */
		fold,			/* key */
		node);			/* add this data to the hash */

	/* the output should not be changed because it will spoil the
	hash table */
	return(data_copy);
}

#ifdef UNIV_COMPILE_TEST_FUNCS

void
test_ha_storage()
{
	ha_storage_t*	storage;
	char		buf[1024];
	int		i;
	const void*	stored[256];
	const void*	p;

	storage = ha_storage_create(0, 0);

	for (i = 0; i < 256; i++) {

		memset(buf, i, sizeof(buf));
		stored[i] = ha_storage_put(storage, buf, sizeof(buf));
	}

	//ha_storage_empty(&storage);

	for (i = 255; i >= 0; i--) {

		memset(buf, i, sizeof(buf));
		p = ha_storage_put(storage, buf, sizeof(buf));

		if (p != stored[i]) {

			fprintf(stderr, "ha_storage_put() returned %p "
				"instead of %p, i=%d\n", p, stored[i], i);
			return;
		}
	}

	fprintf(stderr, "all ok\n");

	ha_storage_free(storage);
}

#endif /* UNIV_COMPILE_TEST_FUNCS */
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00			`/******************************************************`
			`Hash storage.`
			`Provides a data structure that stores chunks of data in`
			`its own storage, avoiding duplicates.`

			`(c) 2007 Innobase Oy`

			`Created September 22, 2007 Vasil Dimov`
			`*******************************************************/`

			`#include "univ.i"`
			`#include "ha0storage.h"`
			`#include "hash0hash.h"`
			`#include "mem0mem.h"`
			`#include "ut0rnd.h"`

			`#ifdef UNIV_NONINL`
			`#include "ha0storage.ic"`
			`#endif`

			`/***********************************************************************`
			`Retrieves a data from a storage. If it is present, a pointer to the`
			`stored copy of data is returned, otherwise NULL is returned. */`
			`static`
branches/zip: Add const qualifier to the value returned by ha_storage_put(). It must not be changed as this will invalidate the hash. 2007-09-28 15:40:12 +02:00			`const void*`
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00			`ha_storage_get(`
			`/===========/`
			`ha_storage_t* storage, /* in: hash storage */`
			`const void* data, /* in: data to check for */`
			`ulint data_len) /* in: data length */`
			`{`
			`ha_storage_node_t* node;`
			`ulint fold;`

			`/* avoid repetitive calls to ut_fold_binary() in the HASH_SEARCH`
			`macro */`
			`fold = ut_fold_binary(data, data_len);`

			`#define IS_FOUND \`
			`node->data_len == data_len && memcmp(node->data, data, data_len) == 0`

			`HASH_SEARCH(`
			`next, /* node->"next" */`
			`storage->hash, /* the hash table */`
			`fold, /* key */`
			`ha_storage_node_t, / type of node->next */`
			`node, /* auxiliary variable */`
			`IS_FOUND); /* search criteria */`

			`if (node == NULL) {`

			`return(NULL);`
			`}`
			`/* else */`

			`return(node->data);`
			`}`

			`/***********************************************************************`
			`Copies data into the storage and returns a pointer to the copy. If the`
			`same data chunk is already present, then pointer to it is returned.`
			`Data chunks are considered to be equal if len1 == len2 and`
branches/zip: Implement a limit on the memory used by the INNODB_TRX, INNODB_LOCKS and INNODB_LOCK_WAITS tables. The maximum allowed memory is defined with the macro TRX_I_S_MEM_LIMIT. Approved by: Marko (via IM) 2007-11-16 14:12:13 +01:00			`memcmp(data1, data2, len1) == 0. If "data" is not present (and thus`
			`data_len bytes need to be allocated) and the size of storage is going to`
			`become more than "memlim" then "data" is not added and NULL is returned.`
			`To disable this behavior "memlim" can be set to 0, which stands for`
			`"no limit". */`
branches/zip: Introduce UNIV_INTERN, a linkage specifier for InnoDB-global symbols. Use it for all definitions of non-static variables and functions. lexyy.c, make_flex.sh: Declare yylex as UNIV_INTERN, not static. It is referenced from pars0grm.c. Actually, according to nm .libs/ha_innodb.so\|grep -w '[ABCE-TVXYZ]' the following symbols are still global: * The vtable for class ha_innodb * pars0grm.c: The function yyparse() and the variables yychar, yylval, yynerrs The required changes to the Bison-generated file pars0grm.c will be addressed in a separate commit, which will add a script similar to make_flex.sh. The class ha_innodb is renamed from class ha_innobase by a #define. Thus, there will be no clash with the builtin InnoDB. However, there will be some overhead for invoking virtual methods of class ha_innodb. Ideas for making the vtable hidden are welcome. -fvisibility=hidden is not available in GCC 3. 2008-02-06 15:17:36 +01:00			`UNIV_INTERN`
branches/zip: Add const qualifier to the value returned by ha_storage_put(). It must not be changed as this will invalidate the hash. 2007-09-28 15:40:12 +02:00			`const void*`
branches/zip: Implement a limit on the memory used by the INNODB_TRX, INNODB_LOCKS and INNODB_LOCK_WAITS tables. The maximum allowed memory is defined with the macro TRX_I_S_MEM_LIMIT. Approved by: Marko (via IM) 2007-11-16 14:12:13 +01:00			`ha_storage_put_memlim(`
			`/==================/`
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00			`ha_storage_t* storage, /* in/out: hash storage */`
			`const void* data, /* in: data to store */`
branches/zip: Implement a limit on the memory used by the INNODB_TRX, INNODB_LOCKS and INNODB_LOCK_WAITS tables. The maximum allowed memory is defined with the macro TRX_I_S_MEM_LIMIT. Approved by: Marko (via IM) 2007-11-16 14:12:13 +01:00			`ulint data_len, /* in: data length */`
			`ulint memlim) /* in: memory limit to obey */`
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00			`{`
			`void* raw;`
			`ha_storage_node_t* node;`
branches/zip: Add const qualifier to the value returned by ha_storage_put(). It must not be changed as this will invalidate the hash. 2007-09-28 15:40:12 +02:00			`const void* data_copy;`
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00			`ulint fold;`

			`/* check if data chunk is already present */`
			`data_copy = ha_storage_get(storage, data, data_len);`
			`if (data_copy != NULL) {`

			`return(data_copy);`
			`}`

branches/zip: Implement a limit on the memory used by the INNODB_TRX, INNODB_LOCKS and INNODB_LOCK_WAITS tables. The maximum allowed memory is defined with the macro TRX_I_S_MEM_LIMIT. Approved by: Marko (via IM) 2007-11-16 14:12:13 +01:00			`/* not present */`

			`/* check if we are allowed to allocate data_len bytes */`
			`if (memlim > 0`
			`&& ha_storage_get_size(storage) + data_len > memlim) {`

			`return(NULL);`
			`}`
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00
			`/* we put the auxiliary node struct and the data itself in one`
			`continuous block */`
			`raw = mem_heap_alloc(storage->heap,`
			`sizeof(ha_storage_node_t) + data_len);`

			`node = (ha_storage_node_t*) raw;`
			`data_copy = (byte) raw + sizeof(node);`

branches/zip: Add const qualifier to the value returned by ha_storage_put(). It must not be changed as this will invalidate the hash. 2007-09-28 15:40:12 +02:00			`memcpy((byte) raw + sizeof(node), data, data_len);`
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00
			`node->data_len = data_len;`
			`node->data = data_copy;`

			`/* avoid repetitive calls to ut_fold_binary() in the HASH_INSERT`
			`macro */`
			`fold = ut_fold_binary(data, data_len);`

			`HASH_INSERT(`
			`ha_storage_node_t, /* type used in the hash chain */`
			`next, /* node->"next" */`
			`storage->hash, /* the hash table */`
			`fold, /* key */`
			`node); /* add this data to the hash */`

branches/zip: Add const qualifier to the value returned by ha_storage_put(). It must not be changed as this will invalidate the hash. 2007-09-28 15:40:12 +02:00			`/* the output should not be changed because it will spoil the`
			`hash table */`
branches/zip: Add a type that stores chunks of data in its own storage and avoids duplicates. Supported methods: ha_storage_create() Allocates new storage object. ha_storage_put() Copies a given data chunk into the storage and returns pointer to the copy. If the data chunk is already present, a pointer to the existing object is returned and the given data chunk is not copied. ha_storage_empty() Clears (empties) the storage from all data chunks that are stored in it. ha_storage_free() Destroys a storage object. Opposite to ha_storage_create(). Approved by: Marko 2007-09-24 14:21:29 +02:00			`return(data_copy);`
			`}`
branches/zip: Implement a limit on the memory used by the INNODB_TRX, INNODB_LOCKS and INNODB_LOCK_WAITS tables. The maximum allowed memory is defined with the macro TRX_I_S_MEM_LIMIT. Approved by: Marko (via IM) 2007-11-16 14:12:13 +01:00
			`#ifdef UNIV_COMPILE_TEST_FUNCS`

			`void`
			`test_ha_storage()`
			`{`
			`ha_storage_t* storage;`
			`char buf[1024];`
			`int i;`
			`const void* stored[256];`
			`const void* p;`

			`storage = ha_storage_create(0, 0);`

			`for (i = 0; i < 256; i++) {`

			`memset(buf, i, sizeof(buf));`
			`stored[i] = ha_storage_put(storage, buf, sizeof(buf));`
			`}`

			`//ha_storage_empty(&storage);`

			`for (i = 255; i >= 0; i--) {`

			`memset(buf, i, sizeof(buf));`
			`p = ha_storage_put(storage, buf, sizeof(buf));`

			`if (p != stored[i]) {`

			`fprintf(stderr, "ha_storage_put() returned %p "`
			`"instead of %p, i=%d\n", p, stored[i], i);`
			`return;`
			`}`
			`}`

			`fprintf(stderr, "all ok\n");`

			`ha_storage_free(storage);`
			`}`

			`#endif /* UNIV_COMPILE_TEST_FUNCS */`