xref: /titanic_44/usr/src/cmd/sendmail/db/include/lock.h (revision 2b4a78020b9c38d1b95e2f3fefa6d6e4be382d1f)
1 /*-
2  * See the file LICENSE for redistribution information.
3  *
4  * Copyright (c) 1996, 1997, 1998
5  *	Sleepycat Software.  All rights reserved.
6  *
7  *	@(#)lock.h	10.17 (Sleepycat) 1/3/99
8  */
9 
10 typedef struct __db_lockobj	DB_LOCKOBJ;
11 
12 #define DB_DEFAULT_LOCK_FILE	"__db_lock.share"
13 
14 #ifndef DB_LOCK_DEFAULT_N
15 #define DB_LOCK_DEFAULT_N	5000	/* Default # of locks in region. */
16 #endif
17 
18 /*
19  * The locker id space is divided between the transaction manager and the lock
20  * manager.  Lockid's start at 0 and go to DB_LOCK_MAXID.  Txn Id's start at
21  * DB_LOCK_MAXID + 1 and go up to TXN_INVALID.
22  */
23 #define DB_LOCK_MAXID		0x7fffffff
24 
25 /* Check for region catastrophic shutdown. */
26 #define	LOCK_PANIC_CHECK(lt) {						\
27 	if ((lt)->region->hdr.panic)					\
28 		return (DB_RUNRECOVERY);				\
29 }
30 
31 /*
32  * The lock region consists of:
33  *	The DB_LOCKREGION structure (sizeof(DB_LOCKREGION)).
34  *	The conflict matrix of nmodes * nmodes bytes (nmodes * nmodes).
35  *	The hash table for object lookup (hashsize * sizeof(DB_OBJ *)).
36  *	The locks themselves (maxlocks * sizeof(struct __db_lock).
37  *	The objects being locked (maxlocks * sizeof(DB_OBJ)).
38  *	String space to represent the DBTs that are the objects being locked.
39  */
40 struct __db_lockregion {
41 	RLAYOUT		hdr;		/* Shared region header. */
42 	u_int32_t	magic;		/* lock magic number */
43 	u_int32_t	version;	/* version number */
44 	u_int32_t	id;		/* unique id generator */
45 	u_int32_t	need_dd;	/* flag for deadlock detector */
46 	u_int32_t	detect;		/* run dd on every conflict */
47 	SH_TAILQ_HEAD(lock_header) free_locks;	/* free lock header */
48 	SH_TAILQ_HEAD(obj_header) free_objs;	/* free obj header */
49 	u_int32_t	maxlocks;	/* maximum number of locks in table */
50 	u_int32_t	table_size;	/* size of hash table */
51 	u_int32_t	nmodes;		/* number of lock modes */
52 	u_int32_t	numobjs;	/* number of objects */
53 	u_int32_t	nlockers;	/* number of lockers */
54 	size_t		increment;	/* how much to grow region */
55 	size_t		hash_off;	/* offset of hash table */
56 	size_t		mem_off;	/* offset of memory region */
57 	size_t		mem_bytes;	/* number of bytes in memory region */
58 	u_int32_t	nconflicts;	/* number of lock conflicts */
59 	u_int32_t	nrequests;	/* number of lock gets */
60 	u_int32_t	nreleases;	/* number of lock puts */
61 	u_int32_t	ndeadlocks;	/* number of deadlocks */
62 };
63 
64 /* Macros to lock/unlock the region. */
65 #define	LOCK_LOCKREGION(lt)						\
66 	(void)__db_mutex_lock(&(lt)->region->hdr.lock, (lt)->reginfo.fd)
67 #define	UNLOCK_LOCKREGION(lt)						\
68 	(void)__db_mutex_unlock(&(lt)->region->hdr.lock, (lt)->reginfo.fd)
69 
70 /*
71  * Since we will be keeping DBTs in shared memory, we need the equivalent
72  * of a DBT that will work in shared memory.
73  */
74 typedef struct __sh_dbt {
75 	u_int32_t size;
76 	ssize_t off;
77 } SH_DBT;
78 
79 #define SH_DBT_PTR(p)	((void *)(((u_int8_t *)(p)) + (p)->off))
80 
81 struct __db_lockobj {
82 	SH_DBT	lockobj;		/* Identifies object locked. */
83 	SH_TAILQ_ENTRY links;		/* Links for free list. */
84 	union {
85 		SH_TAILQ_HEAD(_wait) _waiters;	/* List of waiting locks. */
86 		u_int32_t	_dd_id;		/* Deadlock detector id. */
87 	} wlinks;
88 	union {
89 		SH_LIST_HEAD(_held) _heldby;	/* Locks held by this locker. */
90 		SH_TAILQ_HEAD(_hold) _holders;	/* List of held locks. */
91 	} dlinks;
92 #define	DB_LOCK_OBJTYPE		1
93 #define	DB_LOCK_LOCKER		2
94 					/* Allocate room in the object to
95 					 * hold typical DB lock structures
96 					 * so that we do not have to
97 					 * allocate them from shalloc. */
98 	u_int8_t objdata[sizeof(struct __db_ilock)];
99 	u_int8_t type;			/* Real object or locker id. */
100 };
101 
102 #define dd_id	wlinks._dd_id
103 #define	waiters	wlinks._waiters
104 #define	holders	dlinks._holders
105 #define	heldby	dlinks._heldby
106 
107 /*
108  * The lock table is the per-process cookie returned from a lock_open call.
109  */
110 struct __db_locktab {
111 	DB_ENV		*dbenv;		/* Environment. */
112 	REGINFO		 reginfo;	/* Region information. */
113 	DB_LOCKREGION	*region;	/* Address of shared memory region. */
114 	DB_HASHTAB 	*hashtab; 	/* Beginning of hash table. */
115 	void		*mem;		/* Beginning of string space. */
116 	u_int8_t 	*conflicts;	/* Pointer to conflict matrix. */
117 };
118 
119 /* Test for conflicts. */
120 #define CONFLICTS(T, HELD, WANTED) \
121 	T->conflicts[HELD * T->region->nmodes + WANTED]
122 
123 /*
124  * Resources in the lock region.  Used to indicate which resource
125  * is running low when we need to grow the region.
126  */
127 typedef enum {
128 	DB_LOCK_MEM, DB_LOCK_OBJ, DB_LOCK_LOCK
129 } db_resource_t;
130 
131 struct __db_lock {
132 	/*
133 	 * Wait on mutex to wait on lock.  You reference your own mutex with
134 	 * ID 0 and others reference your mutex with ID 1.
135 	 */
136 	db_mutex_t	mutex;
137 
138 	u_int32_t	holder;		/* Who holds this lock. */
139 	SH_TAILQ_ENTRY	links;		/* Free or holder/waiter list. */
140 	SH_LIST_ENTRY	locker_links;	/* List of locks held by a locker. */
141 	u_int32_t	refcount;	/* Reference count the lock. */
142 	db_lockmode_t	mode;		/* What sort of lock. */
143 	ssize_t		obj;		/* Relative offset of object struct. */
144 	size_t		txnoff;		/* Offset of holding transaction. */
145 	db_status_t	status;		/* Status of this lock. */
146 };
147 
148 /*
149  * This is a serious layering violation.  To support nested transactions, we
150  * need to be able to tell that a lock is held by a transaction (as opposed to
151  * some other locker) and to be able to traverse the parent/descendent chain.
152  * In order to do this, each lock held by a transaction maintains a reference
153  * to the shared memory transaction structure so it can be accessed during lock
154  * promotion.  As the structure is in shared memory, we cannot store a pointer
155  * to it, so we use the offset within the region.  As nothing lives at region
156  * offset 0, we use that to indicate that there is no transaction associated
157  * with the current lock.
158  */
159 #define TXN_IS_HOLDING(L)	((L)->txnoff != 0 /* INVALID_REG_OFFSET */)
160 
161 /*
162  * We cannot return pointers to the user (else we cannot easily grow regions),
163  * so we return offsets in the region.  These must be converted to and from
164  * regular pointers.  Always use the macros below.
165  */
166 #define OFFSET_TO_LOCK(lt, off)	\
167 	((struct __db_lock *)((u_int8_t *)((lt)->region) + (off)))
168 #define LOCK_TO_OFFSET(lt, lock) \
169 	((size_t)((u_int8_t *)(lock) - (u_int8_t *)lt->region))
170 #define OFFSET_TO_OBJ(lt, off)	\
171 	((DB_LOCKOBJ *)((u_int8_t *)((lt)->region) + (off)))
172 #define OBJ_TO_OFFSET(lt, obj) \
173 	((size_t)((u_int8_t *)(obj) - (u_int8_t *)lt->region))
174 
175 /*
176  * The lock header contains the region structure and the conflict matrix.
177  * Aligned to a large boundary because we don't know what the underlying
178  * type of the hash table elements are.
179  */
180 #define LOCK_HASH_ALIGN	8
181 #define LOCK_HEADER_SIZE(M)	\
182 	((size_t)(sizeof(DB_LOCKREGION) + ALIGN((M * M), LOCK_HASH_ALIGN)))
183 
184 /*
185  * For the full region, we need to add the locks, the objects, the hash table
186  * and the string space (which is 16 bytes per lock).
187  */
188 #define STRING_SIZE(N) (16 * N)
189 
190 #define LOCK_REGION_SIZE(M, N, H)					\
191 	(ALIGN(LOCK_HEADER_SIZE(M) +					\
192 	(H) * sizeof(DB_HASHTAB), MUTEX_ALIGNMENT) +			\
193 	(N) * ALIGN(sizeof(struct __db_lock), MUTEX_ALIGNMENT) +	\
194 	ALIGN((N) * sizeof(DB_LOCKOBJ), sizeof(size_t)) +		\
195 	ALIGN(STRING_SIZE(N), sizeof(size_t)))
196 
197 #include "lock_ext.h"
198