/** @file mdb.c * @brief memory-mapped database library * * A Btree-based database management library modeled loosely on the * BerkeleyDB API, but much simplified. */ /* * Copyright 2011 Howard Chu, Symas Corp. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted only as authorized by the OpenLDAP * Public License. * * A copy of this license is available in the file LICENSE in the * top-level directory of the distribution or, alternatively, at * . * * This code is derived from btree.c written by Martin Hedenfalk. * * Copyright (c) 2009, 2010 Martin Hedenfalk * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #ifdef _WIN32 #include #else #include #include #ifdef HAVE_SYS_FILE_H #include #endif #include #endif #include #include #include #include #include #include #include #include #include #ifndef _WIN32 #include #endif #include "mdb.h" #include "midl.h" /** @defgroup internal MDB Internals * @{ */ /** @defgroup compat Windows Compatibility Macros * A bunch of macros to minimize the amount of platform-specific ifdefs * needed throughout the rest of the code. When the features this library * needs are similar enough to POSIX to be hidden in a one-or-two line * replacement, this macro approach is used. * @{ */ #ifdef _WIN32 #define pthread_t DWORD #define pthread_mutex_t HANDLE #define pthread_key_t DWORD #define pthread_self() GetCurrentThreadId() #define pthread_key_create(x,y) (*(x) = TlsAlloc()) #define pthread_key_delete(x) TlsFree(x) #define pthread_getspecific(x) TlsGetValue(x) #define pthread_setspecific(x,y) TlsSetValue(x,y) #define pthread_mutex_unlock(x) ReleaseMutex(x) #define pthread_mutex_lock(x) WaitForSingleObject(x, INFINITE) #define LOCK_MUTEX_R(env) pthread_mutex_lock((env)->me_rmutex) #define UNLOCK_MUTEX_R(env) pthread_mutex_unlock((env)->me_rmutex) #define LOCK_MUTEX_W(env) pthread_mutex_lock((env)->me_wmutex) #define UNLOCK_MUTEX_W(env) pthread_mutex_unlock((env)->me_wmutex) #define getpid() GetCurrentProcessId() #define fdatasync(fd) (!FlushFileBuffers(fd)) #define ErrCode() GetLastError() #define GET_PAGESIZE(x) {SYSTEM_INFO si; GetSystemInfo(&si); (x) = si.dwPageSize;} #define close(fd) CloseHandle(fd) #define munmap(ptr,len) UnmapViewOfFile(ptr) #else /** Lock the reader mutex. */ #define LOCK_MUTEX_R(env) pthread_mutex_lock(&(env)->me_txns->mti_mutex) /** Unlock the reader mutex. */ #define UNLOCK_MUTEX_R(env) pthread_mutex_unlock(&(env)->me_txns->mti_mutex) /** Lock the writer mutex. * Only a single write transaction is allowed at a time. Other writers * will block waiting for this mutex. */ #define LOCK_MUTEX_W(env) pthread_mutex_lock(&(env)->me_txns->mti_wmutex) /** Unlock the writer mutex. */ #define UNLOCK_MUTEX_W(env) pthread_mutex_unlock(&(env)->me_txns->mti_wmutex) /** Get the error code for the last failed system function. */ #define ErrCode() errno /** An abstraction for a file handle. * On POSIX systems file handles are small integers. On Windows * they're opaque pointers. */ #define HANDLE int /** A value for an invalid file handle. * Mainly used to initialize file variables and signify that they are * unused. */ #define INVALID_HANDLE_VALUE (-1) /** Get the size of a memory page for the system. * This is the basic size that the platform's memory manager uses, and is * fundamental to the use of memory-mapped files. */ #define GET_PAGESIZE(x) ((x) = sysconf(_SC_PAGE_SIZE)) #endif /** @} */ #ifndef _WIN32 /** A flag for opening a file and requesting synchronous data writes. * This is only used when writing a meta page. It's not strictly needed; * we could just do a normal write and then immediately perform a flush. * But if this flag is available it saves us an extra system call. * * @note If O_DSYNC is undefined but exists in /usr/include, * preferably set some compiler flag to get the definition. * Otherwise compile with the less efficient -DMDB_DSYNC=O_SYNC. */ #ifndef MDB_DSYNC # define MDB_DSYNC O_DSYNC #endif #endif /** A page number in the database. * Note that 64 bit page numbers are overkill, since pages themselves * already represent 12-13 bits of addressable memory, and the OS will * always limit applications to a maximum of 63 bits of address space. * * @note In the #MDB_node structure, we only store 48 bits of this value, * which thus limits us to only 60 bits of addressable data. */ typedef ULONG pgno_t; /** @defgroup debug Debug Macros * @{ */ #ifndef DEBUG /** Enable debug output. * Set this to 1 for copious tracing. Set to 2 to add dumps of all IDLs * read from and written to the database (used for free space management). */ #define DEBUG 0 #endif #if !(__STDC_VERSION__ >= 199901L || defined(__GNUC__)) # define DPRINTF (void) /* Vararg macros may be unsupported */ #elif DEBUG /** Print a debug message with printf formatting. */ # define DPRINTF(fmt, ...) /**< Requires 2 or more args */ \ fprintf(stderr, "%s:%d:(%p) " fmt "\n", __func__, __LINE__, pthread_self(), __VA_ARGS__) #else # define DPRINTF(fmt, ...) ((void) 0) #endif /** Print a debug string. * The string is printed literally, with no format processing. */ #define DPUTS(arg) DPRINTF("%s", arg) /** @} */ /** A default memory page size. * The actual size is platform-dependent, but we use this for * boot-strapping. We probably should not be using this any more. * The #GET_PAGESIZE() macro is used to get the actual size. * * Note that we don't currently support Huge pages. On Linux, * regular data files cannot use Huge pages, and in general * Huge pages aren't actually pageable. We rely on the OS * demand-pager to read our data and page it out when memory * pressure from other processes is high. So until OSs have * actual paging support for Huge pages, they're not viable. */ #define PAGESIZE 4096 /** The minimum number of keys required in a database page. * Setting this to a larger value will place a smaller bound on the * maximum size of a data item. Data items larger than this size will * be pushed into overflow pages instead of being stored directly in * the B-tree node. This value used to default to 4. With a page size * of 4096 bytes that meant that any item larger than 1024 bytes would * go into an overflow page. That also meant that on average 2-3KB of * each overflow page was wasted space. The value cannot be lower than * 2 because then there would no longer be a tree structure. With this * value, items larger than 2KB will go into overflow pages, and on * average only 1KB will be wasted. */ #define MDB_MINKEYS 2 /** A stamp that identifies a file as an MDB file. * There's nothing special about this value other than that it is easily * recognizable, and it will reflect any byte order mismatches. */ #define MDB_MAGIC 0xBEEFC0DE /** The version number for a database's file format. */ #define MDB_VERSION 1 /** The maximum size of a key in the database. * While data items have essentially unbounded size, we require that * keys all fit onto a regular page. This limit could be raised a bit * further if needed; to something just under #PAGESIZE / #MDB_MINKEYS. */ #define MAXKEYSIZE 511 #if DEBUG /** A key buffer. * @ingroup debug * This is used for printing a hex dump of a key's contents. */ #define DKBUF char kbuf[(MAXKEYSIZE*2+1)] /** Display a key in hex. * @ingroup debug * Invoke a function to display a key in hex. */ #define DKEY(x) mdb_dkey(x, kbuf) #else #define DKBUF #define DKEY(x) #endif /** @defgroup lazylock Lazy Locking * Macros for locks that are't actually needed. * The DB view is always consistent because all writes are wrapped in * the wmutex. Finer-grained locks aren't necessary. * @{ */ #ifndef LAZY_LOCKS /** Use lazy locking. I.e., don't lock these accesses at all. */ #define LAZY_LOCKS 1 #endif #if LAZY_LOCKS /** Grab the reader lock */ #define LAZY_MUTEX_LOCK(x) /** Release the reader lock */ #define LAZY_MUTEX_UNLOCK(x) /** Release the DB table reader/writer lock */ #define LAZY_RWLOCK_UNLOCK(x) /** Grab the DB table write lock */ #define LAZY_RWLOCK_WRLOCK(x) /** Grab the DB table read lock */ #define LAZY_RWLOCK_RDLOCK(x) /** Declare the DB table rwlock */ #define LAZY_RWLOCK_DEF(x) /** Initialize the DB table rwlock */ #define LAZY_RWLOCK_INIT(x,y) /** Destroy the DB table rwlock */ #define LAZY_RWLOCK_DESTROY(x) #else #define LAZY_MUTEX_LOCK(x) pthread_mutex_lock(x) #define LAZY_MUTEX_UNLOCK(x) pthread_mutex_unlock(x) #define LAZY_RWLOCK_UNLOCK(x) pthread_rwlock_unlock(x) #define LAZY_RWLOCK_WRLOCK(x) pthread_rwlock_wrlock(x) #define LAZY_RWLOCK_RDLOCK(x) pthread_rwlock_rdlock(x) #define LAZY_RWLOCK_DEF(x) pthread_rwlock_t x #define LAZY_RWLOCK_INIT(x,y) pthread_rwlock_init(x,y) #define LAZY_RWLOCK_DESTROY(x) pthread_rwlock_destroy(x) #endif /** @} */ /** An invalid page number. * Mainly used to denote an empty tree. */ #define P_INVALID (~0UL) /** Test if a flag \b f is set in a flag word \b w. */ #define F_ISSET(w, f) (((w) & (f)) == (f)) /** Used for offsets within a single page. * Since memory pages are typically 4 or 8KB in size, 12-13 bits, * this is plenty. */ typedef uint16_t indx_t; /** Default size of memory map. * This is certainly too small for any actual applications. Apps should always set * the size explicitly using #mdb_env_set_mapsize(). */ #define DEFAULT_MAPSIZE 1048576 /** @defgroup readers Reader Lock Table * Readers don't acquire any locks for their data access. Instead, they * simply record their transaction ID in the reader table. The reader * mutex is needed just to find an empty slot in the reader table. The * slot's address is saved in thread-specific data so that subsequent read * transactions started by the same thread need no further locking to proceed. * * Since the database uses multi-version concurrency control, readers don't * actually need any locking. This table is used to keep track of which * readers are using data from which old transactions, so that we'll know * when a particular old transaction is no longer in use. Old transactions * that have discarded any data pages can then have those pages reclaimed * for use by a later write transaction. * * The lock table is constructed such that reader slots are aligned with the * processor's cache line size. Any slot is only ever used by one thread. * This alignment guarantees that there will be no contention or cache * thrashing as threads update their own slot info, and also eliminates * any need for locking when accessing a slot. * * A writer thread will scan every slot in the table to determine the oldest * outstanding reader transaction. Any freed pages older than this will be * reclaimed by the writer. The writer doesn't use any locks when scanning * this table. This means that there's no guarantee that the writer will * see the most up-to-date reader info, but that's not required for correct * operation - all we need is to know the upper bound on the oldest reader, * we don't care at all about the newest reader. So the only consequence of * reading stale information here is that old pages might hang around a * while longer before being reclaimed. That's actually good anyway, because * the longer we delay reclaiming old pages, the more likely it is that a * string of contiguous pages can be found after coalescing old pages from * many old transactions together. * * @todo We don't actually do such coalescing yet, we grab pages from one * old transaction at a time. * @{ */ /** Number of slots in the reader table. * This value was chosen somewhat arbitrarily. 126 readers plus a * couple mutexes fit exactly into 8KB on my development machine. * Applications should set the table size using #mdb_env_set_maxreaders(). */ #define DEFAULT_READERS 126 /** The size of a CPU cache line in bytes. We want our lock structures * aligned to this size to avoid false cache line sharing in the * lock table. * This value works for most CPUs. For Itanium this should be 128. */ #ifndef CACHELINE #define CACHELINE 64 #endif /** The information we store in a single slot of the reader table. * In addition to a transaction ID, we also record the process and * thread ID that owns a slot, so that we can detect stale information, * e.g. threads or processes that went away without cleaning up. * @note We currently don't check for stale records. We simply re-init * the table when we know that we're the only process opening the * lock file. */ typedef struct MDB_rxbody { /** The current Transaction ID when this transaction began. * Multiple readers that start at the same time will probably have the * same ID here. Again, it's not important to exclude them from * anything; all we need to know is which version of the DB they * started from so we can avoid overwriting any data used in that * particular version. */ ULONG mrb_txnid; /** The process ID of the process owning this reader txn. */ pid_t mrb_pid; /** The thread ID of the thread owning this txn. */ pthread_t mrb_tid; } MDB_rxbody; /** The actual reader record, with cacheline padding. */ typedef struct MDB_reader { union { MDB_rxbody mrx; /** shorthand for mrb_txnid */ #define mr_txnid mru.mrx.mrb_txnid #define mr_pid mru.mrx.mrb_pid #define mr_tid mru.mrx.mrb_tid /** cache line alignment */ char pad[(sizeof(MDB_rxbody)+CACHELINE-1) & ~(CACHELINE-1)]; } mru; } MDB_reader; /** The header for the reader table. * The table resides in a memory-mapped file. (This is a different file * than is used for the main database.) * * For POSIX the actual mutexes reside in the shared memory of this * mapped file. On Windows, mutexes are named objects allocated by the * kernel; we store the mutex names in this mapped file so that other * processes can grab them. This same approach will also be used on * MacOSX/Darwin (using named semaphores) since MacOSX doesn't support * process-shared POSIX mutexes. */ typedef struct MDB_txbody { /** Stamp identifying this as an MDB lock file. It must be set * to #MDB_MAGIC. */ uint32_t mtb_magic; /** Version number of this lock file. Must be set to #MDB_VERSION. */ uint32_t mtb_version; #ifdef _WIN32 char mtb_rmname[32]; #else /** Mutex protecting access to this table. * This is the reader lock that #LOCK_MUTEX_R acquires. */ pthread_mutex_t mtb_mutex; #endif /** The ID of the last transaction committed to the database. * This is recorded here only for convenience; the value can always * be determined by reading the main database meta pages. */ ULONG mtb_txnid; /** The number of slots that have been used in the reader table. * This always records the maximum count, it is not decremented * when readers release their slots. */ uint32_t mtb_numreaders; /** The ID of the most recent meta page in the database. * This is recorded here only for convenience; the value can always * be determined by reading the main database meta pages. */ uint32_t mtb_me_toggle; } MDB_txbody; /** The actual reader table definition. */ typedef struct MDB_txninfo { union { MDB_txbody mtb; #define mti_magic mt1.mtb.mtb_magic #define mti_version mt1.mtb.mtb_version #define mti_mutex mt1.mtb.mtb_mutex #define mti_rmname mt1.mtb.mtb_rmname #define mti_txnid mt1.mtb.mtb_txnid #define mti_numreaders mt1.mtb.mtb_numreaders #define mti_me_toggle mt1.mtb.mtb_me_toggle char pad[(sizeof(MDB_txbody)+CACHELINE-1) & ~(CACHELINE-1)]; } mt1; union { #ifdef _WIN32 char mt2_wmname[32]; #define mti_wmname mt2.mt2_wmname #else pthread_mutex_t mt2_wmutex; #define mti_wmutex mt2.mt2_wmutex #endif char pad[(sizeof(pthread_mutex_t)+CACHELINE-1) & ~(CACHELINE-1)]; } mt2; MDB_reader mti_readers[1]; } MDB_txninfo; /** @} */ /** Common header for all page types. * Overflow pages occupy a number of contiguous pages with no * headers on any page after the first. */ typedef struct MDB_page { #define mp_pgno mp_p.p_pgno #define mp_next mp_p.p_next union padded { pgno_t p_pgno; /**< page number */ void * p_next; /**< for in-memory list of freed structs */ } mp_p; #define P_BRANCH 0x01 /**< branch page */ #define P_LEAF 0x02 /**< leaf page */ #define P_OVERFLOW 0x04 /**< overflow page */ #define P_META 0x08 /**< meta page */ #define P_DIRTY 0x10 /**< dirty page */ #define P_LEAF2 0x20 /**< for #MDB_DUPFIXED records */ uint32_t mp_flags; #define mp_lower mp_pb.pb.pb_lower #define mp_upper mp_pb.pb.pb_upper #define mp_pages mp_pb.pb_pages union page_bounds { struct { indx_t pb_lower; /**< lower bound of free space */ indx_t pb_upper; /**< upper bound of free space */ } pb; uint32_t pb_pages; /**< number of overflow pages */ } mp_pb; indx_t mp_ptrs[1]; /**< dynamic size */ } MDB_page; /** Size of the page header, excluding dynamic data at the end */ #define PAGEHDRSZ ((unsigned) offsetof(MDB_page, mp_ptrs)) /** Address of first usable data byte in a page, after the header */ #define METADATA(p) ((void *)((char *)(p) + PAGEHDRSZ)) /** Number of nodes on a page */ #define NUMKEYS(p) (((p)->mp_lower - PAGEHDRSZ) >> 1) /** The amount of space remaining in the page */ #define SIZELEFT(p) (indx_t)((p)->mp_upper - (p)->mp_lower) /** The percentage of space used in the page, in tenths of a percent. */ #define PAGEFILL(env, p) (1000L * ((env)->me_psize - PAGEHDRSZ - SIZELEFT(p)) / \ ((env)->me_psize - PAGEHDRSZ)) /** The minimum page fill factor, in tenths of a percent. * Pages emptier than this are candidates for merging. */ #define FILL_THRESHOLD 250 /** Test if a page is a leaf page */ #define IS_LEAF(p) F_ISSET((p)->mp_flags, P_LEAF) /** Test if a page is a LEAF2 page */ #define IS_LEAF2(p) F_ISSET((p)->mp_flags, P_LEAF2) /** Test if a page is a branch page */ #define IS_BRANCH(p) F_ISSET((p)->mp_flags, P_BRANCH) /** Test if a page is an overflow page */ #define IS_OVERFLOW(p) F_ISSET((p)->mp_flags, P_OVERFLOW) /** The number of overflow pages needed to store the given size. */ #define OVPAGES(size, psize) ((PAGEHDRSZ-1 + (size)) / (psize) + 1) /** Header for a single key/data pair within a page. * We guarantee 2-byte alignment for nodes. */ typedef struct MDB_node { /** lo and hi are used for data size on leaf nodes and for * child pgno on branch nodes. On 64 bit platforms, flags * is also used for pgno. (branch nodes ignore flags) */ unsigned short mn_lo; unsigned short mn_hi; /**< part of dsize or pgno */ unsigned short mn_flags; /**< flags for special node types */ #define F_BIGDATA 0x01 /**< data put on overflow page */ #define F_SUBDATA 0x02 /**< data is a sub-database */ #define F_DUPDATA 0x04 /**< data has duplicates */ unsigned short mn_ksize; /**< key size */ char mn_data[1]; /**< key and data are appended here */ } MDB_node; /** Size of the node header, excluding dynamic data at the end */ #define NODESIZE offsetof(MDB_node, mn_data) /** Size of a node in a branch page with a given key. * This is just the node header plus the key, there is no data. */ #define INDXSIZE(k) (NODESIZE + ((k) == NULL ? 0 : (k)->mv_size)) /** Size of a node in a leaf page with a given key and data. * This is node header plus key plus data size. */ #define LEAFSIZE(k, d) (NODESIZE + (k)->mv_size + (d)->mv_size) /** Address of node \b i in page \b p */ #define NODEPTR(p, i) ((MDB_node *)((char *)(p) + (p)->mp_ptrs[i])) /** Address of the key for the node */ #define NODEKEY(node) (void *)((node)->mn_data) /** Address of the data for a node */ #define NODEDATA(node) (void *)((char *)(node)->mn_data + (node)->mn_ksize) /** Get the page number pointed to by a branch node */ #if LONG_MAX == 0x7fffffff #define NODEPGNO(node) ((node)->mn_lo | ((node)->mn_hi << 16)) /** Set the page number in a branch node */ #define SETPGNO(node,pgno) do { \ (node)->mn_lo = (pgno) & 0xffff; (node)->mn_hi = (pgno) >> 16;} while(0) #else #define NODEPGNO(node) ((node)->mn_lo | ((node)->mn_hi << 16) | ((unsigned long)(node)->mn_flags << 32)) /** Set the page number in a branch node */ #define SETPGNO(node,pgno) do { \ (node)->mn_lo = (pgno) & 0xffff; (node)->mn_hi = (pgno) >> 16; \ (node)->mn_flags = (pgno) >> 32; } while(0) #endif /** Get the size of the data in a leaf node */ #define NODEDSZ(node) ((node)->mn_lo | ((unsigned)(node)->mn_hi << 16)) /** Set the size of the data for a leaf node */ #define SETDSZ(node,size) do { \ (node)->mn_lo = (size) & 0xffff; (node)->mn_hi = (size) >> 16;} while(0) /** The size of a key in a node */ #define NODEKSZ(node) ((node)->mn_ksize) /** The address of a key in a LEAF2 page. * LEAF2 pages are used for #MDB_DUPFIXED sorted-duplicate sub-DBs. * There are no node headers, keys are stored contiguously. */ #define LEAF2KEY(p, i, ks) ((char *)(p) + PAGEHDRSZ + ((i)*(ks))) /** Set the \b node's key into \b key, if requested. */ #define MDB_SET_KEY(node, key) { if ((key) != NULL) { \ (key)->mv_size = NODEKSZ(node); (key)->mv_data = NODEKEY(node); } } /** Information about a single database in the environment. */ typedef struct MDB_db { uint32_t md_pad; /**< also ksize for LEAF2 pages */ uint16_t md_flags; /**< @ref mdb_open */ uint16_t md_depth; /**< depth of this tree */ ULONG md_branch_pages; /**< number of internal pages */ ULONG md_leaf_pages; /**< number of leaf pages */ ULONG md_overflow_pages; /**< number of overflow pages */ ULONG md_entries; /**< number of data items */ pgno_t md_root; /**< the root page of this tree */ } MDB_db; /** Handle for the DB used to track free pages. */ #define FREE_DBI 0 /** Handle for the default DB. */ #define MAIN_DBI 1 /** Meta page content. */ typedef struct MDB_meta { /** Stamp identifying this as an MDB data file. It must be set * to #MDB_MAGIC. */ uint32_t mm_magic; /** Version number of this lock file. Must be set to #MDB_VERSION. */ uint32_t mm_version; void *mm_address; /**< address for fixed mapping */ size_t mm_mapsize; /**< size of mmap region */ MDB_db mm_dbs[2]; /**< first is free space, 2nd is main db */ /** The size of pages used in this DB */ #define mm_psize mm_dbs[0].md_pad /** Any persistent environment flags. @ref mdb_env */ #define mm_flags mm_dbs[0].md_flags pgno_t mm_last_pg; /**< last used page in file */ ULONG mm_txnid; /**< txnid that committed this page */ } MDB_meta; /** Auxiliary DB info. * The information here is mostly static/read-only. There is * only a single copy of this record in the environment. * The \b md_dirty flag is not read-only, but only a write * transaction can ever update it, and only write transactions * need to worry about it. */ typedef struct MDB_dbx { MDB_val md_name; /**< name of the database */ MDB_cmp_func *md_cmp; /**< function for comparing keys */ MDB_cmp_func *md_dcmp; /**< function for comparing data items */ MDB_rel_func *md_rel; /**< user relocate function */ MDB_dbi md_parent; /**< parent DB of a sub-DB */ unsigned int md_dirty; /**< TRUE if DB was written in this txn */ } MDB_dbx; /** A database transaction. * Every operation requires a transaction handle. */ struct MDB_txn { pgno_t mt_next_pgno; /**< next unallocated page */ /** The ID of this transaction. IDs are integers incrementing from 1. * Only committed write transactions increment the ID. If a transaction * aborts, the ID may be re-used by the next writer. */ ULONG mt_txnid; MDB_env *mt_env; /**< the DB environment */ /** The list of pages that became unused during this transaction. * This is an #IDL. */ pgno_t *mt_free_pgs; union { ID2L dirty_list; /**< modified pages */ MDB_reader *reader; /**< this thread's slot in the reader table */ } mt_u; /** Array of records for each DB known in the environment. */ MDB_dbx *mt_dbxs; /** Array of MDB_db records for each known DB */ MDB_db *mt_dbs; /** Number of DB records in use. This number only ever increments; * we don't decrement it when individual DB handles are closed. */ unsigned int mt_numdbs; #define MDB_TXN_RDONLY 0x01 /**< read-only transaction */ #define MDB_TXN_ERROR 0x02 /**< an error has occurred */ unsigned int mt_flags; /** Tracks which of the two meta pages was used at the start * of this transaction. */ unsigned int mt_toggle; }; /** Enough space for 2^32 nodes with minimum of 2 keys per node. I.e., plenty. * At 4 keys per node, enough for 2^64 nodes, so there's probably no need to * raise this on a 64 bit machine. */ #define CURSOR_STACK 32 struct MDB_xcursor; /** Cursors are used for all DB operations */ struct MDB_cursor { /** Context used for databases with #MDB_DUPSORT, otherwise NULL */ struct MDB_xcursor *mc_xcursor; /** The transaction that owns this cursor */ MDB_txn *mc_txn; /** The database handle this cursor operates on */ MDB_dbi mc_dbi; unsigned short mc_snum; /**< number of pushed pages */ unsigned short mc_top; /**< index of top page, mc_snum-1 */ unsigned int mc_flags; #define C_INITIALIZED 0x01 /**< cursor has been initialized and is valid */ #define C_EOF 0x02 /**< No more data */ #define C_XDIRTY 0x04 /**< @deprecated mc_xcursor needs to be flushed */ MDB_page *mc_pg[CURSOR_STACK]; /**< stack of pushed pages */ indx_t mc_ki[CURSOR_STACK]; /**< stack of page indices */ }; /** Context for sorted-dup records. * We could have gone to a fully recursive design, with arbitrarily * deep nesting of sub-databases. But for now we only handle these * levels - main DB, optional sub-DB, sorted-duplicate DB. */ typedef struct MDB_xcursor { /** A sub-cursor for traversing the Dup DB */ MDB_cursor mx_cursor; /** A fake transaction struct for pointing to our own table * of DB info. */ MDB_txn mx_txn; /** Our private DB information tables. Slots 0 and 1 are always * copies of the corresponding slots in the main transaction. These * hold the FREEDB and MAINDB, respectively. If the main cursor is * on a sub-database, that will be copied to slot 2, and the duplicate * database info will be in slot 3. If the main cursor is on the MAINDB * then the duplicate DB info will be in slot 2 and slot 3 will be unused. */ MDB_dbx mx_dbxs[4]; /** MDB_db table */ MDB_db mx_dbs[4]; } MDB_xcursor; /** A set of pages freed by an earlier transaction. */ typedef struct MDB_oldpages { /** Usually we only read one record from the FREEDB at a time, but * in case we read more, this will chain them together. */ struct MDB_oldpages *mo_next; /** The ID of the transaction in which these pages were freed. */ ULONG mo_txnid; /** An #IDL of the pages */ pgno_t mo_pages[1]; /* dynamic */ } MDB_oldpages; /** The database environment. */ struct MDB_env { HANDLE me_fd; /**< The main data file */ HANDLE me_lfd; /**< The lock file */ HANDLE me_mfd; /**< just for writing the meta pages */ /** Failed to update the meta page. Probably an I/O error. */ #define MDB_FATAL_ERROR 0x80000000U uint32_t me_flags; uint32_t me_extrapad; /**< unused for now */ unsigned int me_maxreaders; /**< size of the reader table */ unsigned int me_numdbs; /**< number of DBs opened */ unsigned int me_maxdbs; /**< size of the DB table */ char *me_path; /**< path to the DB files */ char *me_map; /**< the memory map of the data file */ MDB_txninfo *me_txns; /**< the memory map of the lock file */ MDB_meta *me_metas[2]; /**< pointers to the two meta pages */ MDB_txn *me_txn; /**< current write transaction */ size_t me_mapsize; /**< size of the data memory map */ off_t me_size; /**< current file size */ pgno_t me_maxpg; /**< me_mapsize / me_psize */ unsigned int me_psize; /**< size of a page, from #GET_PAGESIZE */ unsigned int me_db_toggle; /**< which DB table is current */ MDB_dbx *me_dbxs; /**< array of static DB info */ MDB_db *me_dbs[2]; /**< two arrays of MDB_db info */ MDB_oldpages *me_pghead; /**< list of old page records */ pthread_key_t me_txkey; /**< thread-key for readers */ MDB_page *me_dpages; /**< list of malloc'd blocks for re-use */ /** IDL of pages that became unused in a write txn */ pgno_t me_free_pgs[MDB_IDL_UM_SIZE]; /** ID2L of pages that were written during a write txn */ ID2 me_dirty_list[MDB_IDL_UM_SIZE]; /** rwlock for the DB tables, if #LAZY_LOCKS is false */ LAZY_RWLOCK_DEF(me_dblock); #ifdef _WIN32 HANDLE me_rmutex; /* Windows mutexes don't reside in shared mem */ HANDLE me_wmutex; #endif }; /** max number of pages to commit in one writev() call */ #define MDB_COMMIT_PAGES 64 static MDB_page *mdb_alloc_page(MDB_cursor *mc, int num); static int mdb_touch(MDB_cursor *mc); static int mdb_search_page_root(MDB_cursor *mc, MDB_val *key, int modify); static int mdb_search_page(MDB_cursor *mc, MDB_val *key, int modify); static int mdb_env_read_header(MDB_env *env, MDB_meta *meta); static int mdb_env_read_meta(MDB_env *env, int *which); static int mdb_env_write_meta(MDB_txn *txn); static int mdb_get_page(MDB_txn *txn, pgno_t pgno, MDB_page **mp); static MDB_node *mdb_search_node(MDB_cursor *mc, MDB_val *key, int *exactp); static int mdb_add_node(MDB_cursor *mc, indx_t indx, MDB_val *key, MDB_val *data, pgno_t pgno, uint8_t flags); static void mdb_del_node(MDB_page *mp, indx_t indx, int ksize); static int mdb_del0(MDB_cursor *mc, MDB_node *leaf); static int mdb_read_data(MDB_txn *txn, MDB_node *leaf, MDB_val *data); static int mdb_rebalance(MDB_cursor *mc); static int mdb_update_key(MDB_page *mp, indx_t indx, MDB_val *key); static int mdb_move_node(MDB_cursor *csrc, MDB_cursor *cdst); static int mdb_merge(MDB_cursor *csrc, MDB_cursor *cdst); static int mdb_split(MDB_cursor *mc, MDB_val *newkey, MDB_val *newdata, pgno_t newpgno); static MDB_page *mdb_new_page(MDB_cursor *mc, uint32_t flags, int num); static void cursor_pop_page(MDB_cursor *mc); static int cursor_push_page(MDB_cursor *mc, MDB_page *mp); static int mdb_sibling(MDB_cursor *mc, int move_right); static int mdb_cursor_next(MDB_cursor *mc, MDB_val *key, MDB_val *data, MDB_cursor_op op); static int mdb_cursor_prev(MDB_cursor *mc, MDB_val *key, MDB_val *data, MDB_cursor_op op); static int mdb_cursor_set(MDB_cursor *mc, MDB_val *key, MDB_val *data, MDB_cursor_op op, int *exactp); static int mdb_cursor_first(MDB_cursor *mc, MDB_val *key, MDB_val *data); static int mdb_cursor_last(MDB_cursor *mc, MDB_val *key, MDB_val *data); static void mdb_xcursor_init0(MDB_cursor *mc); static void mdb_xcursor_init1(MDB_cursor *mc, MDB_node *node); static void mdb_xcursor_init2(MDB_cursor *mc); static void mdb_xcursor_fini(MDB_cursor *mc); static size_t mdb_leaf_size(MDB_env *env, MDB_val *key, MDB_val *data); static size_t mdb_branch_size(MDB_env *env, MDB_val *key); static void mdb_default_cmp(MDB_txn *txn, MDB_dbi dbi); /** @cond */ static MDB_cmp_func memncmp, memnrcmp, intcmp, cintcmp; /** @endcond */ #ifdef _WIN32 static SECURITY_DESCRIPTOR mdb_null_sd; static SECURITY_ATTRIBUTES mdb_all_sa; static int mdb_sec_inited; #endif /** Return the library version info. */ char * mdb_version(int *major, int *minor, int *patch) { if (major) *major = MDB_VERSION_MAJOR; if (minor) *minor = MDB_VERSION_MINOR; if (patch) *patch = MDB_VERSION_PATCH; return MDB_VERSION_STRING; } /** Table of descriptions for MDB @ref errors */ static char *const mdb_errstr[] = { "MDB_KEYEXIST: Key/data pair already exists", "MDB_NOTFOUND: No matching key/data pair found", "MDB_PAGE_NOTFOUND: Requested page not found", "MDB_CORRUPTED: Located page was wrong type", "MDB_PANIC: Update of meta page failed", "MDB_VERSION_MISMATCH: Database environment version mismatch" }; char * mdb_strerror(int err) { if (!err) return ("Successful return: 0"); if (err >= MDB_KEYEXIST && err <= MDB_VERSION_MISMATCH) return mdb_errstr[err - MDB_KEYEXIST]; return strerror(err); } #if DEBUG /** Display a key in hexadecimal and return the address of the result. * @param[in] key the key to display * @param[in] buf the buffer to write into. Should always be #DKBUF. * @return The key in hexadecimal form. */ char * mdb_dkey(MDB_val *key, char *buf) { char *ptr = buf; unsigned char *c = key->mv_data; unsigned int i; if (key->mv_size > MAXKEYSIZE) return "MAXKEYSIZE"; /* may want to make this a dynamic check: if the key is mostly * printable characters, print it as-is instead of converting to hex. */ #if 1 for (i=0; imv_size; i++) ptr += sprintf(ptr, "%02x", *c++); #else sprintf(buf, "%.*s", key->mv_size, key->mv_data); #endif return buf; } #endif int mdb_cmp(MDB_txn *txn, MDB_dbi dbi, const MDB_val *a, const MDB_val *b) { return txn->mt_dbxs[dbi].md_cmp(a, b); } /** Compare two data items according to a particular database. * This returns a comparison as if the two items were data items of * a sorted duplicates #MDB_DUPSORT database. * @param[in] txn A transaction handle returned by #mdb_txn_begin() * @param[in] dbi A database handle returned by #mdb_open() * @param[in] a The first item to compare * @param[in] b The second item to compare * @return < 0 if a < b, 0 if a == b, > 0 if a > b */ int mdb_dcmp(MDB_txn *txn, MDB_dbi dbi, const MDB_val *a, const MDB_val *b) { if (txn->mt_dbxs[dbi].md_dcmp) return txn->mt_dbxs[dbi].md_dcmp(a, b); else return EINVAL; /* too bad you can't distinguish this from a valid result */ } /** Allocate pages for writing. * If there are free pages available from older transactions, they * will be re-used first. Otherwise a new page will be allocated. * @param[in] mc cursor A cursor handle identifying the transaction and * database for which we are allocating. * @param[in] num the number of pages to allocate. * @return Address of the allocated page(s). Requests for multiple pages * will always be satisfied by a single contiguous chunk of memory. */ static MDB_page * mdb_alloc_page(MDB_cursor *mc, int num) { MDB_txn *txn = mc->mc_txn; MDB_page *np; pgno_t pgno = P_INVALID; ID2 mid; if (txn->mt_txnid > 2) { if (!txn->mt_env->me_pghead && mc->mc_dbi != FREE_DBI && txn->mt_dbs[FREE_DBI].md_root != P_INVALID) { /* See if there's anything in the free DB */ MDB_cursor m2; MDB_node *leaf; ULONG *kptr, oldest; m2.mc_txn = txn; m2.mc_dbi = FREE_DBI; m2.mc_snum = 0; m2.mc_flags = 0; mdb_search_page(&m2, NULL, 0); leaf = NODEPTR(m2.mc_pg[m2.mc_top], 0); kptr = (ULONG *)NODEKEY(leaf); { unsigned int i; oldest = txn->mt_txnid - 1; for (i=0; imt_env->me_txns->mti_numreaders; i++) { ULONG mr = txn->mt_env->me_txns->mti_readers[i].mr_txnid; if (mr && mr < oldest) oldest = mr; } } if (oldest > *kptr) { /* It's usable, grab it. */ MDB_oldpages *mop; MDB_val data; pgno_t *idl; mdb_read_data(txn, leaf, &data); idl = (ULONG *)data.mv_data; mop = malloc(sizeof(MDB_oldpages) + MDB_IDL_SIZEOF(idl) - sizeof(pgno_t)); mop->mo_next = txn->mt_env->me_pghead; mop->mo_txnid = *kptr; txn->mt_env->me_pghead = mop; memcpy(mop->mo_pages, idl, MDB_IDL_SIZEOF(idl)); #if DEBUG > 1 { unsigned int i; DPRINTF("IDL read txn %lu root %lu num %lu", mop->mo_txnid, txn->mt_dbs[FREE_DBI].md_root, idl[0]); for (i=0; imt_env->me_pghead) { MDB_oldpages *mop = txn->mt_env->me_pghead; if (num > 1) { /* FIXME: For now, always use fresh pages. We * really ought to search the free list for a * contiguous range. */ ; } else { /* peel pages off tail, so we only have to truncate the list */ pgno = MDB_IDL_LAST(mop->mo_pages); if (MDB_IDL_IS_RANGE(mop->mo_pages)) { mop->mo_pages[2]++; if (mop->mo_pages[2] > mop->mo_pages[1]) mop->mo_pages[0] = 0; } else { mop->mo_pages[0]--; } if (MDB_IDL_IS_ZERO(mop->mo_pages)) { txn->mt_env->me_pghead = mop->mo_next; free(mop); } } } } if (pgno == P_INVALID) { /* DB size is maxed out */ if (txn->mt_next_pgno + num >= txn->mt_env->me_maxpg) return NULL; } if (txn->mt_env->me_dpages && num == 1) { np = txn->mt_env->me_dpages; txn->mt_env->me_dpages = np->mp_next; } else { if ((np = malloc(txn->mt_env->me_psize * num )) == NULL) return NULL; } if (pgno == P_INVALID) { np->mp_pgno = txn->mt_next_pgno; txn->mt_next_pgno += num; } else { np->mp_pgno = pgno; } mid.mid = np->mp_pgno; mid.mptr = np; mdb_mid2l_insert(txn->mt_u.dirty_list, &mid); return np; } /** Touch a page: make it dirty and re-insert into tree with updated pgno. * @param[in] mc cursor pointing to the page to be touched * @return 0 on success, non-zero on failure. */ static int mdb_touch(MDB_cursor *mc) { MDB_page *mp = mc->mc_pg[mc->mc_top]; pgno_t pgno; if (!F_ISSET(mp->mp_flags, P_DIRTY)) { MDB_page *np; if ((np = mdb_alloc_page(mc, 1)) == NULL) return ENOMEM; DPRINTF("touched db %u page %lu -> %lu", mc->mc_dbi, mp->mp_pgno, np->mp_pgno); assert(mp->mp_pgno != np->mp_pgno); mdb_midl_append(mc->mc_txn->mt_free_pgs, mp->mp_pgno); pgno = np->mp_pgno; memcpy(np, mp, mc->mc_txn->mt_env->me_psize); mp = np; mp->mp_pgno = pgno; mp->mp_flags |= P_DIRTY; mc->mc_pg[mc->mc_top] = mp; /** If this page has a parent, update the parent to point to * this new page. */ if (mc->mc_top) SETPGNO(NODEPTR(mc->mc_pg[mc->mc_top-1], mc->mc_ki[mc->mc_top-1]), mp->mp_pgno); } return 0; } int mdb_env_sync(MDB_env *env, int force) { int rc = 0; if (force || !F_ISSET(env->me_flags, MDB_NOSYNC)) { if (fdatasync(env->me_fd)) rc = ErrCode(); } return rc; } static inline void mdb_txn_reset0(MDB_txn *txn); /** Common code for #mdb_txn_begin() and #mdb_txn_renew(). * @param[in] txn the transaction handle to initialize * @return 0 on success, non-zero on failure. This can only * fail for read-only transactions, and then only if the * reader table is full. */ static inline int mdb_txn_renew0(MDB_txn *txn) { MDB_env *env = txn->mt_env; if (txn->mt_flags & MDB_TXN_RDONLY) { MDB_reader *r = pthread_getspecific(env->me_txkey); if (!r) { unsigned int i; pid_t pid = getpid(); pthread_t tid = pthread_self(); LOCK_MUTEX_R(env); for (i=0; ime_txns->mti_numreaders; i++) if (env->me_txns->mti_readers[i].mr_pid == 0) break; if (i == env->me_maxreaders) { UNLOCK_MUTEX_R(env); return ENOMEM; } env->me_txns->mti_readers[i].mr_pid = pid; env->me_txns->mti_readers[i].mr_tid = tid; if (i >= env->me_txns->mti_numreaders) env->me_txns->mti_numreaders = i+1; UNLOCK_MUTEX_R(env); r = &env->me_txns->mti_readers[i]; pthread_setspecific(env->me_txkey, r); } txn->mt_txnid = env->me_txns->mti_txnid; txn->mt_toggle = env->me_txns->mti_me_toggle; r->mr_txnid = txn->mt_txnid; txn->mt_u.reader = r; } else { LOCK_MUTEX_W(env); txn->mt_txnid = env->me_txns->mti_txnid+1; txn->mt_toggle = env->me_txns->mti_me_toggle; txn->mt_u.dirty_list = env->me_dirty_list; txn->mt_u.dirty_list[0].mid = 0; txn->mt_free_pgs = env->me_free_pgs; txn->mt_free_pgs[0] = 0; txn->mt_next_pgno = env->me_metas[txn->mt_toggle]->mm_last_pg+1; env->me_txn = txn; } /* Copy the DB arrays */ LAZY_RWLOCK_RDLOCK(&env->me_dblock); txn->mt_numdbs = env->me_numdbs; txn->mt_dbxs = env->me_dbxs; /* mostly static anyway */ memcpy(txn->mt_dbs, env->me_metas[txn->mt_toggle]->mm_dbs, 2 * sizeof(MDB_db)); if (txn->mt_numdbs > 2) memcpy(txn->mt_dbs+2, env->me_dbs[env->me_db_toggle]+2, (txn->mt_numdbs - 2) * sizeof(MDB_db)); LAZY_RWLOCK_UNLOCK(&env->me_dblock); return MDB_SUCCESS; } int mdb_txn_renew(MDB_txn *txn) { int rc; if (!txn) return EINVAL; if (txn->mt_env->me_flags & MDB_FATAL_ERROR) { DPUTS("environment had fatal error, must shutdown!"); return MDB_PANIC; } rc = mdb_txn_renew0(txn); if (rc == MDB_SUCCESS) { DPRINTF("renew txn %lu%c %p on mdbenv %p, root page %lu", txn->mt_txnid, (txn->mt_flags & MDB_TXN_RDONLY) ? 'r' : 'w', txn, (void *)txn->mt_env, txn->mt_dbs[MAIN_DBI].md_root); } return rc; } int mdb_txn_begin(MDB_env *env, unsigned int flags, MDB_txn **ret) { MDB_txn *txn; int rc; if (env->me_flags & MDB_FATAL_ERROR) { DPUTS("environment had fatal error, must shutdown!"); return MDB_PANIC; } if ((txn = calloc(1, sizeof(MDB_txn) + env->me_maxdbs * sizeof(MDB_db))) == NULL) { DPRINTF("calloc: %s", strerror(ErrCode())); return ENOMEM; } txn->mt_dbs = (MDB_db *)(txn+1); if (flags & MDB_RDONLY) { txn->mt_flags |= MDB_TXN_RDONLY; } txn->mt_env = env; rc = mdb_txn_renew0(txn); if (rc) free(txn); else { *ret = txn; DPRINTF("begin txn %lu%c %p on mdbenv %p, root page %lu", txn->mt_txnid, (txn->mt_flags & MDB_TXN_RDONLY) ? 'r' : 'w', txn, (void *) env, txn->mt_dbs[MAIN_DBI].md_root); } return rc; } /** Common code for #mdb_txn_reset() and #mdb_txn_abort(). * @param[in] txn the transaction handle to reset */ static inline void mdb_txn_reset0(MDB_txn *txn) { MDB_env *env = txn->mt_env; if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY)) { txn->mt_u.reader->mr_txnid = 0; } else { MDB_oldpages *mop; MDB_page *dp; unsigned int i; /* return all dirty pages to dpage list */ for (i=1; i<=txn->mt_u.dirty_list[0].mid; i++) { dp = txn->mt_u.dirty_list[i].mptr; if (!IS_OVERFLOW(dp) || dp->mp_pages == 1) { dp->mp_next = txn->mt_env->me_dpages; txn->mt_env->me_dpages = dp; } else { /* large pages just get freed directly */ free(dp); } } while ((mop = txn->mt_env->me_pghead)) { txn->mt_env->me_pghead = mop->mo_next; free(mop); } env->me_txn = NULL; for (i=2; ime_numdbs; i++) env->me_dbxs[i].md_dirty = 0; /* The writer mutex was locked in mdb_txn_begin. */ UNLOCK_MUTEX_W(env); } } void mdb_txn_reset(MDB_txn *txn) { if (txn == NULL) return; DPRINTF("reset txn %lu%c %p on mdbenv %p, root page %lu", txn->mt_txnid, (txn->mt_flags & MDB_TXN_RDONLY) ? 'r' : 'w', txn, (void *)txn->mt_env, txn->mt_dbs[MAIN_DBI].md_root); mdb_txn_reset0(txn); } void mdb_txn_abort(MDB_txn *txn) { if (txn == NULL) return; DPRINTF("abort txn %lu%c %p on mdbenv %p, root page %lu", txn->mt_txnid, (txn->mt_flags & MDB_TXN_RDONLY) ? 'r' : 'w', txn, (void *)txn->mt_env, txn->mt_dbs[MAIN_DBI].md_root); mdb_txn_reset0(txn); free(txn); } int mdb_txn_commit(MDB_txn *txn) { int n, done; unsigned int i; ssize_t rc; off_t size; MDB_page *dp; MDB_env *env; pgno_t next; MDB_cursor mc; assert(txn != NULL); assert(txn->mt_env != NULL); env = txn->mt_env; if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY)) { mdb_txn_abort(txn); return MDB_SUCCESS; } if (txn != env->me_txn) { DPUTS("attempt to commit unknown transaction"); mdb_txn_abort(txn); return EINVAL; } if (F_ISSET(txn->mt_flags, MDB_TXN_ERROR)) { DPUTS("error flag is set, can't commit"); mdb_txn_abort(txn); return EINVAL; } if (!txn->mt_u.dirty_list[0].mid) goto done; DPRINTF("committing txn %lu %p on mdbenv %p, root page %lu", txn->mt_txnid, txn, (void *)env, txn->mt_dbs[MAIN_DBI].md_root); mc.mc_txn = txn; mc.mc_dbi = FREE_DBI; mc.mc_flags = 0; /* should only be one record now */ if (env->me_pghead) { /* make sure first page of freeDB is touched and on freelist */ mdb_search_page(&mc, NULL, 1); } /* save to free list */ if (!MDB_IDL_IS_ZERO(txn->mt_free_pgs)) { MDB_val key, data; ULONG i; /* make sure last page of freeDB is touched and on freelist */ key.mv_size = MAXKEYSIZE+1; key.mv_data = NULL; mdb_search_page(&mc, &key, 1); mdb_midl_sort(txn->mt_free_pgs); #if DEBUG > 1 { unsigned int i; ULONG *idl = txn->mt_free_pgs; DPRINTF("IDL write txn %lu root %lu num %lu", txn->mt_txnid, txn->mt_dbs[FREE_DBI].md_root, idl[0]); for (i=0; imt_txnid; data.mv_data = txn->mt_free_pgs; /* The free list can still grow during this call, * despite the pre-emptive touches above. So check * and make sure the entire thing got written. */ do { i = txn->mt_free_pgs[0]; data.mv_size = MDB_IDL_SIZEOF(txn->mt_free_pgs); rc = mdb_cursor_put(&mc, &key, &data, 0); if (rc) { mdb_txn_abort(txn); return rc; } } while (i != txn->mt_free_pgs[0]); } /* should only be one record now */ if (env->me_pghead) { MDB_val key, data; MDB_oldpages *mop; mop = env->me_pghead; key.mv_size = sizeof(pgno_t); key.mv_data = (char *)&mop->mo_txnid; data.mv_size = MDB_IDL_SIZEOF(mop->mo_pages); data.mv_data = mop->mo_pages; mdb_cursor_put(&mc, &key, &data, 0); free(env->me_pghead); env->me_pghead = NULL; } /* Update DB root pointers. Their pages have already been * touched so this is all in-place and cannot fail. */ { MDB_val data; data.mv_size = sizeof(MDB_db); mc.mc_dbi = MAIN_DBI; mc.mc_flags = 0; for (i = 2; i < txn->mt_numdbs; i++) { if (txn->mt_dbxs[i].md_dirty) { data.mv_data = &txn->mt_dbs[i]; mdb_cursor_put(&mc, &txn->mt_dbxs[i].md_name, &data, 0); } } } /* Commit up to MDB_COMMIT_PAGES dirty pages to disk until done. */ next = 0; i = 1; do { #ifdef _WIN32 /* Windows actually supports scatter/gather I/O, but only on * unbuffered file handles. Since we're relying on the OS page * cache for all our data, that's self-defeating. So we just * write pages one at a time. We use the ov structure to set * the write offset, to at least save the overhead of a Seek * system call. */ OVERLAPPED ov; memset(&ov, 0, sizeof(ov)); for (; i<=txn->mt_u.dirty_list[0].mid; i++) { size_t wsize; dp = txn->mt_u.dirty_list[i].mptr; DPRINTF("committing page %lu", dp->mp_pgno); size = dp->mp_pgno * env->me_psize; ov.Offset = size & 0xffffffff; ov.OffsetHigh = size >> 16; ov.OffsetHigh >>= 16; /* clear dirty flag */ dp->mp_flags &= ~P_DIRTY; wsize = env->me_psize; if (IS_OVERFLOW(dp)) wsize *= dp->mp_pages; rc = WriteFile(env->me_fd, dp, wsize, NULL, &ov); if (!rc) { n = ErrCode(); DPRINTF("WriteFile: %d", n); mdb_txn_abort(txn); return n; } } done = 1;; #else struct iovec iov[MDB_COMMIT_PAGES]; n = 0; done = 1; size = 0; for (; i<=txn->mt_u.dirty_list[0].mid; i++) { dp = txn->mt_u.dirty_list[i].mptr; if (dp->mp_pgno != next) { if (n) { DPRINTF("committing %u dirty pages", n); rc = writev(env->me_fd, iov, n); if (rc != size) { n = ErrCode(); if (rc > 0) DPUTS("short write, filesystem full?"); else DPRINTF("writev: %s", strerror(n)); mdb_txn_abort(txn); return n; } n = 0; size = 0; } lseek(env->me_fd, dp->mp_pgno * env->me_psize, SEEK_SET); next = dp->mp_pgno; } DPRINTF("committing page %lu", dp->mp_pgno); iov[n].iov_len = env->me_psize; if (IS_OVERFLOW(dp)) iov[n].iov_len *= dp->mp_pages; iov[n].iov_base = dp; size += iov[n].iov_len; next = dp->mp_pgno + (IS_OVERFLOW(dp) ? dp->mp_pages : 1); /* clear dirty flag */ dp->mp_flags &= ~P_DIRTY; if (++n >= MDB_COMMIT_PAGES) { done = 0; i++; break; } } if (n == 0) break; DPRINTF("committing %u dirty pages", n); rc = writev(env->me_fd, iov, n); if (rc != size) { n = ErrCode(); if (rc > 0) DPUTS("short write, filesystem full?"); else DPRINTF("writev: %s", strerror(n)); mdb_txn_abort(txn); return n; } #endif } while (!done); /* Drop the dirty pages. */ for (i=1; i<=txn->mt_u.dirty_list[0].mid; i++) { dp = txn->mt_u.dirty_list[i].mptr; if (!IS_OVERFLOW(dp) || dp->mp_pages == 1) { dp->mp_next = txn->mt_env->me_dpages; txn->mt_env->me_dpages = dp; } else { free(dp); } txn->mt_u.dirty_list[i].mid = 0; } txn->mt_u.dirty_list[0].mid = 0; if ((n = mdb_env_sync(env, 0)) != 0 || (n = mdb_env_write_meta(txn)) != MDB_SUCCESS) { mdb_txn_abort(txn); return n; } done: env->me_txn = NULL; /* update the DB tables */ { int toggle = !env->me_db_toggle; MDB_db *ip, *jp; ip = &env->me_dbs[toggle][2]; jp = &txn->mt_dbs[2]; LAZY_RWLOCK_WRLOCK(&env->me_dblock); for (i = 2; i < txn->mt_numdbs; i++) { if (ip->md_root != jp->md_root) *ip = *jp; ip++; jp++; } for (i = 2; i < txn->mt_numdbs; i++) { if (txn->mt_dbxs[i].md_dirty) txn->mt_dbxs[i].md_dirty = 0; } env->me_db_toggle = toggle; env->me_numdbs = txn->mt_numdbs; LAZY_RWLOCK_UNLOCK(&env->me_dblock); } UNLOCK_MUTEX_W(env); free(txn); return MDB_SUCCESS; } /** Read the environment parameters of a DB environment before * mapping it into memory. * @param[in] env the environment handle * @param[out] meta address of where to store the meta information * @return 0 on success, non-zero on failure. */ static int mdb_env_read_header(MDB_env *env, MDB_meta *meta) { char page[PAGESIZE]; MDB_page *p; MDB_meta *m; int rc, err; /* We don't know the page size yet, so use a minimum value. */ #ifdef _WIN32 if (!ReadFile(env->me_fd, page, PAGESIZE, (DWORD *)&rc, NULL) || rc == 0) #else if ((rc = read(env->me_fd, page, PAGESIZE)) == 0) #endif { return ENOENT; } else if (rc != PAGESIZE) { err = ErrCode(); if (rc > 0) err = EINVAL; DPRINTF("read: %s", strerror(err)); return err; } p = (MDB_page *)page; if (!F_ISSET(p->mp_flags, P_META)) { DPRINTF("page %lu not a meta page", p->mp_pgno); return EINVAL; } m = METADATA(p); if (m->mm_magic != MDB_MAGIC) { DPUTS("meta has invalid magic"); return EINVAL; } if (m->mm_version != MDB_VERSION) { DPRINTF("database is version %u, expected version %u", m->mm_version, MDB_VERSION); return MDB_VERSION_MISMATCH; } memcpy(meta, m, sizeof(*m)); return 0; } /** Write the environment parameters of a freshly created DB environment. * @param[in] env the environment handle * @param[out] meta address of where to store the meta information * @return 0 on success, non-zero on failure. */ static int mdb_env_init_meta(MDB_env *env, MDB_meta *meta) { MDB_page *p, *q; MDB_meta *m; int rc; unsigned int psize; DPUTS("writing new meta page"); GET_PAGESIZE(psize); meta->mm_magic = MDB_MAGIC; meta->mm_version = MDB_VERSION; meta->mm_psize = psize; meta->mm_last_pg = 1; meta->mm_flags = env->me_flags & 0xffff; meta->mm_flags |= MDB_INTEGERKEY; meta->mm_dbs[0].md_root = P_INVALID; meta->mm_dbs[1].md_root = P_INVALID; p = calloc(2, psize); p->mp_pgno = 0; p->mp_flags = P_META; m = METADATA(p); memcpy(m, meta, sizeof(*meta)); q = (MDB_page *)((char *)p + psize); q->mp_pgno = 1; q->mp_flags = P_META; m = METADATA(q); memcpy(m, meta, sizeof(*meta)); #ifdef _WIN32 { DWORD len; rc = WriteFile(env->me_fd, p, psize * 2, &len, NULL); rc = (len == psize * 2) ? MDB_SUCCESS : ErrCode(); } #else rc = write(env->me_fd, p, psize * 2); rc = (rc == (int)psize * 2) ? MDB_SUCCESS : ErrCode(); #endif free(p); return rc; } /** Update the environment info to commit a transaction. * @param[in] txn the transaction that's being committed * @return 0 on success, non-zero on failure. */ static int mdb_env_write_meta(MDB_txn *txn) { MDB_env *env; MDB_meta meta, metab; off_t off; int rc, len, toggle; char *ptr; #ifdef _WIN32 OVERLAPPED ov; #endif assert(txn != NULL); assert(txn->mt_env != NULL); toggle = !txn->mt_toggle; DPRINTF("writing meta page %d for root page %lu", toggle, txn->mt_dbs[MAIN_DBI].md_root); env = txn->mt_env; metab.mm_txnid = env->me_metas[toggle]->mm_txnid; metab.mm_last_pg = env->me_metas[toggle]->mm_last_pg; ptr = (char *)&meta; off = offsetof(MDB_meta, mm_dbs[0].md_depth); len = sizeof(MDB_meta) - off; ptr += off; meta.mm_dbs[0] = txn->mt_dbs[0]; meta.mm_dbs[1] = txn->mt_dbs[1]; meta.mm_last_pg = txn->mt_next_pgno - 1; meta.mm_txnid = txn->mt_txnid; if (toggle) off += env->me_psize; off += PAGEHDRSZ; /* Write to the SYNC fd */ #ifdef _WIN32 { memset(&ov, 0, sizeof(ov)); ov.Offset = off; WriteFile(env->me_mfd, ptr, len, (DWORD *)&rc, &ov); } #else rc = pwrite(env->me_mfd, ptr, len, off); #endif if (rc != len) { int r2; rc = ErrCode(); DPUTS("write failed, disk error?"); /* On a failure, the pagecache still contains the new data. * Write some old data back, to prevent it from being used. * Use the non-SYNC fd; we know it will fail anyway. */ meta.mm_last_pg = metab.mm_last_pg; meta.mm_txnid = metab.mm_txnid; #ifdef _WIN32 WriteFile(env->me_fd, ptr, len, NULL, &ov); #else r2 = pwrite(env->me_fd, ptr, len, off); #endif env->me_flags |= MDB_FATAL_ERROR; return rc; } /* Memory ordering issues are irrelevant; since the entire writer * is wrapped by wmutex, all of these changes will become visible * after the wmutex is unlocked. Since the DB is multi-version, * readers will get consistent data regardless of how fresh or * how stale their view of these values is. */ LAZY_MUTEX_LOCK(&env->me_txns->mti_mutex); txn->mt_env->me_txns->mti_me_toggle = toggle; txn->mt_env->me_txns->mti_txnid = txn->mt_txnid; LAZY_MUTEX_UNLOCK(&env->me_txns->mti_mutex); return MDB_SUCCESS; } /** Check both meta pages to see which one is newer. * @param[in] env the environment handle * @param[out] which address of where to store the meta toggle ID * @return 0 on success, non-zero on failure. */ static int mdb_env_read_meta(MDB_env *env, int *which) { int toggle = 0; assert(env != NULL); if (env->me_metas[0]->mm_txnid < env->me_metas[1]->mm_txnid) toggle = 1; DPRINTF("Using meta page %d", toggle); *which = toggle; return MDB_SUCCESS; } int mdb_env_create(MDB_env **env) { MDB_env *e; e = calloc(1, sizeof(MDB_env)); if (!e) return ENOMEM; e->me_maxreaders = DEFAULT_READERS; e->me_maxdbs = 2; e->me_fd = INVALID_HANDLE_VALUE; e->me_lfd = INVALID_HANDLE_VALUE; e->me_mfd = INVALID_HANDLE_VALUE; *env = e; return MDB_SUCCESS; } int mdb_env_set_mapsize(MDB_env *env, size_t size) { if (env->me_map) return EINVAL; env->me_mapsize = size; return MDB_SUCCESS; } int mdb_env_set_maxdbs(MDB_env *env, int dbs) { if (env->me_map) return EINVAL; env->me_maxdbs = dbs; return MDB_SUCCESS; } int mdb_env_set_maxreaders(MDB_env *env, int readers) { if (env->me_map) return EINVAL; env->me_maxreaders = readers; return MDB_SUCCESS; } int mdb_env_get_maxreaders(MDB_env *env, int *readers) { if (!env || !readers) return EINVAL; *readers = env->me_maxreaders; return MDB_SUCCESS; } /** Further setup required for opening an MDB environment */ static int mdb_env_open2(MDB_env *env, unsigned int flags) { int i, newenv = 0, toggle; MDB_meta meta; MDB_page *p; env->me_flags = flags; memset(&meta, 0, sizeof(meta)); if ((i = mdb_env_read_header(env, &meta)) != 0) { if (i != ENOENT) return i; DPUTS("new mdbenv"); newenv = 1; } if (!env->me_mapsize) { env->me_mapsize = newenv ? DEFAULT_MAPSIZE : meta.mm_mapsize; } #ifdef _WIN32 { HANDLE mh; LONG sizelo, sizehi; sizelo = env->me_mapsize & 0xffffffff; sizehi = env->me_mapsize >> 16; /* pointless on WIN32, only needed on W64 */ sizehi >>= 16; /* Windows won't create mappings for zero length files. * Just allocate the maxsize right now. */ if (newenv) { SetFilePointer(env->me_fd, sizelo, sizehi ? &sizehi : NULL, 0); if (!SetEndOfFile(env->me_fd)) return ErrCode(); SetFilePointer(env->me_fd, 0, NULL, 0); } mh = CreateFileMapping(env->me_fd, NULL, PAGE_READONLY, sizehi, sizelo, NULL); if (!mh) return ErrCode(); env->me_map = MapViewOfFileEx(mh, FILE_MAP_READ, 0, 0, env->me_mapsize, meta.mm_address); CloseHandle(mh); if (!env->me_map) return ErrCode(); } #else i = MAP_SHARED; if (meta.mm_address && (flags & MDB_FIXEDMAP)) i |= MAP_FIXED; env->me_map = mmap(meta.mm_address, env->me_mapsize, PROT_READ, i, env->me_fd, 0); if (env->me_map == MAP_FAILED) return ErrCode(); #endif if (newenv) { meta.mm_mapsize = env->me_mapsize; if (flags & MDB_FIXEDMAP) meta.mm_address = env->me_map; i = mdb_env_init_meta(env, &meta); if (i != MDB_SUCCESS) { munmap(env->me_map, env->me_mapsize); return i; } } env->me_psize = meta.mm_psize; env->me_maxpg = env->me_mapsize / env->me_psize; p = (MDB_page *)env->me_map; env->me_metas[0] = METADATA(p); env->me_metas[1] = (MDB_meta *)((char *)env->me_metas[0] + meta.mm_psize); if ((i = mdb_env_read_meta(env, &toggle)) != 0) return i; DPRINTF("opened database version %u, pagesize %u", env->me_metas[toggle]->mm_version, env->me_psize); DPRINTF("depth: %u", env->me_metas[toggle]->mm_dbs[MAIN_DBI].md_depth); DPRINTF("entries: %lu", env->me_metas[toggle]->mm_dbs[MAIN_DBI].md_entries); DPRINTF("branch pages: %lu", env->me_metas[toggle]->mm_dbs[MAIN_DBI].md_branch_pages); DPRINTF("leaf pages: %lu", env->me_metas[toggle]->mm_dbs[MAIN_DBI].md_leaf_pages); DPRINTF("overflow pages: %lu", env->me_metas[toggle]->mm_dbs[MAIN_DBI].md_overflow_pages); DPRINTF("root: %lu", env->me_metas[toggle]->mm_dbs[MAIN_DBI].md_root); return MDB_SUCCESS; } #ifndef _WIN32 /* Windows doesn't support destructor callbacks for thread-specific storage */ static void mdb_env_reader_dest(void *ptr) { MDB_reader *reader = ptr; reader->mr_txnid = 0; reader->mr_pid = 0; reader->mr_tid = 0; } #endif /* downgrade the exclusive lock on the region back to shared */ static void mdb_env_share_locks(MDB_env *env) { int toggle = 0; if (env->me_metas[0]->mm_txnid < env->me_metas[1]->mm_txnid) toggle = 1; env->me_txns->mti_me_toggle = toggle; env->me_txns->mti_txnid = env->me_metas[toggle]->mm_txnid; #ifdef _WIN32 { OVERLAPPED ov; /* First acquire a shared lock. The Unlock will * then release the existing exclusive lock. */ memset(&ov, 0, sizeof(ov)); LockFileEx(env->me_lfd, 0, 0, 1, 0, &ov); UnlockFile(env->me_lfd, 0, 0, 1, 0); } #else { struct flock lock_info; /* The shared lock replaces the existing lock */ memset((void *)&lock_info, 0, sizeof(lock_info)); lock_info.l_type = F_RDLCK; lock_info.l_whence = SEEK_SET; lock_info.l_start = 0; lock_info.l_len = 1; fcntl(env->me_lfd, F_SETLK, &lock_info); } #endif } static int mdb_env_setup_locks(MDB_env *env, char *lpath, int mode, int *excl) { int rc; off_t size, rsize; *excl = 0; #ifdef _WIN32 if ((env->me_lfd = CreateFile(lpath, GENERIC_READ|GENERIC_WRITE, FILE_SHARE_READ|FILE_SHARE_WRITE, NULL, OPEN_ALWAYS, FILE_ATTRIBUTE_NORMAL, NULL)) == INVALID_HANDLE_VALUE) { rc = ErrCode(); return rc; } /* Try to get exclusive lock. If we succeed, then * nobody is using the lock region and we should initialize it. */ { if (LockFile(env->me_lfd, 0, 0, 1, 0)) { *excl = 1; } else { OVERLAPPED ov; memset(&ov, 0, sizeof(ov)); if (!LockFileEx(env->me_lfd, 0, 0, 1, 0, &ov)) { rc = ErrCode(); goto fail; } } } size = GetFileSize(env->me_lfd, NULL); #else if ((env->me_lfd = open(lpath, O_RDWR|O_CREAT, mode)) == -1) { rc = ErrCode(); return rc; } /* Try to get exclusive lock. If we succeed, then * nobody is using the lock region and we should initialize it. */ { struct flock lock_info; memset((void *)&lock_info, 0, sizeof(lock_info)); lock_info.l_type = F_WRLCK; lock_info.l_whence = SEEK_SET; lock_info.l_start = 0; lock_info.l_len = 1; rc = fcntl(env->me_lfd, F_SETLK, &lock_info); if (rc == 0) { *excl = 1; } else { lock_info.l_type = F_RDLCK; rc = fcntl(env->me_lfd, F_SETLKW, &lock_info); if (rc) { rc = ErrCode(); goto fail; } } } size = lseek(env->me_lfd, 0, SEEK_END); #endif rsize = (env->me_maxreaders-1) * sizeof(MDB_reader) + sizeof(MDB_txninfo); if (size < rsize && *excl) { #ifdef _WIN32 SetFilePointer(env->me_lfd, rsize, NULL, 0); if (!SetEndOfFile(env->me_lfd)) { rc = ErrCode(); goto fail; } #else if (ftruncate(env->me_lfd, rsize) != 0) { rc = ErrCode(); goto fail; } #endif } else { rsize = size; size = rsize - sizeof(MDB_txninfo); env->me_maxreaders = size/sizeof(MDB_reader) + 1; } #ifdef _WIN32 { HANDLE mh; mh = CreateFileMapping(env->me_lfd, NULL, PAGE_READWRITE, 0, 0, NULL); if (!mh) { rc = ErrCode(); goto fail; } env->me_txns = MapViewOfFileEx(mh, FILE_MAP_WRITE, 0, 0, rsize, NULL); CloseHandle(mh); if (!env->me_txns) { rc = ErrCode(); goto fail; } } #else env->me_txns = mmap(0, rsize, PROT_READ|PROT_WRITE, MAP_SHARED, env->me_lfd, 0); if (env->me_txns == MAP_FAILED) { rc = ErrCode(); goto fail; } #endif if (*excl) { #ifdef _WIN32 char *ptr; if (!mdb_sec_inited) { InitializeSecurityDescriptor(&mdb_null_sd, SECURITY_DESCRIPTOR_REVISION); SetSecurityDescriptorDacl(&mdb_null_sd, TRUE, 0, FALSE); mdb_all_sa.nLength = sizeof(SECURITY_ATTRIBUTES); mdb_all_sa.bInheritHandle = FALSE; mdb_all_sa.lpSecurityDescriptor = &mdb_null_sd; mdb_sec_inited = 1; } /* FIXME: only using up to 20 characters of the env path here, * probably not enough to assure uniqueness... */ sprintf(env->me_txns->mti_rmname, "Global\\MDBr%.20s", lpath); ptr = env->me_txns->mti_rmname + sizeof("Global\\MDBr"); while ((ptr = strchr(ptr, '\\'))) *ptr++ = '/'; env->me_rmutex = CreateMutex(&mdb_all_sa, FALSE, env->me_txns->mti_rmname); if (!env->me_rmutex) { rc = ErrCode(); goto fail; } sprintf(env->me_txns->mti_rmname, "Global\\MDBw%.20s", lpath); ptr = env->me_txns->mti_rmname + sizeof("Global\\MDBw"); while ((ptr = strchr(ptr, '\\'))) *ptr++ = '/'; env->me_wmutex = CreateMutex(&mdb_all_sa, FALSE, env->me_txns->mti_rmname); if (!env->me_wmutex) { rc = ErrCode(); goto fail; } #else pthread_mutexattr_t mattr; pthread_mutexattr_init(&mattr); rc = pthread_mutexattr_setpshared(&mattr, PTHREAD_PROCESS_SHARED); if (rc) { goto fail; } pthread_mutex_init(&env->me_txns->mti_mutex, &mattr); pthread_mutex_init(&env->me_txns->mti_wmutex, &mattr); #endif env->me_txns->mti_version = MDB_VERSION; env->me_txns->mti_magic = MDB_MAGIC; env->me_txns->mti_txnid = 0; env->me_txns->mti_numreaders = 0; env->me_txns->mti_me_toggle = 0; } else { if (env->me_txns->mti_magic != MDB_MAGIC) { DPUTS("lock region has invalid magic"); rc = EINVAL; goto fail; } if (env->me_txns->mti_version != MDB_VERSION) { DPRINTF("lock region is version %u, expected version %u", env->me_txns->mti_version, MDB_VERSION); rc = MDB_VERSION_MISMATCH; goto fail; } rc = ErrCode(); if (rc != EACCES && rc != EAGAIN) { goto fail; } #ifdef _WIN32 env->me_rmutex = OpenMutex(SYNCHRONIZE, FALSE, env->me_txns->mti_rmname); if (!env->me_rmutex) { rc = ErrCode(); goto fail; } env->me_wmutex = OpenMutex(SYNCHRONIZE, FALSE, env->me_txns->mti_wmname); if (!env->me_wmutex) { rc = ErrCode(); goto fail; } #endif } return MDB_SUCCESS; fail: close(env->me_lfd); env->me_lfd = INVALID_HANDLE_VALUE; return rc; } /** The name of the lock file in the DB environment */ #define LOCKNAME "/lock.mdb" /** The name of the data file in the DB environment */ #define DATANAME "/data.mdb" int mdb_env_open(MDB_env *env, const char *path, unsigned int flags, mode_t mode) { int oflags, rc, len, excl; char *lpath, *dpath; len = strlen(path); lpath = malloc(len + sizeof(LOCKNAME) + len + sizeof(DATANAME)); if (!lpath) return ENOMEM; dpath = lpath + len + sizeof(LOCKNAME); sprintf(lpath, "%s" LOCKNAME, path); sprintf(dpath, "%s" DATANAME, path); rc = mdb_env_setup_locks(env, lpath, mode, &excl); if (rc) goto leave; #ifdef _WIN32 if (F_ISSET(flags, MDB_RDONLY)) { oflags = GENERIC_READ; len = OPEN_EXISTING; } else { oflags = GENERIC_READ|GENERIC_WRITE; len = OPEN_ALWAYS; } mode = FILE_ATTRIBUTE_NORMAL; if ((env->me_fd = CreateFile(dpath, oflags, FILE_SHARE_READ|FILE_SHARE_WRITE, NULL, len, mode, NULL)) == INVALID_HANDLE_VALUE) { rc = ErrCode(); goto leave; } #else if (F_ISSET(flags, MDB_RDONLY)) oflags = O_RDONLY; else oflags = O_RDWR | O_CREAT; if ((env->me_fd = open(dpath, oflags, mode)) == -1) { rc = ErrCode(); goto leave; } #endif if ((rc = mdb_env_open2(env, flags)) == MDB_SUCCESS) { /* synchronous fd for meta writes */ #ifdef _WIN32 if (!(flags & (MDB_RDONLY|MDB_NOSYNC))) mode |= FILE_FLAG_WRITE_THROUGH; if ((env->me_mfd = CreateFile(dpath, oflags, FILE_SHARE_READ|FILE_SHARE_WRITE, NULL, len, mode, NULL)) == INVALID_HANDLE_VALUE) { rc = ErrCode(); goto leave; } #else if (!(flags & (MDB_RDONLY|MDB_NOSYNC))) oflags |= MDB_DSYNC; if ((env->me_mfd = open(dpath, oflags, mode)) == -1) { rc = ErrCode(); goto leave; } #endif env->me_path = strdup(path); DPRINTF("opened dbenv %p", (void *) env); pthread_key_create(&env->me_txkey, mdb_env_reader_dest); LAZY_RWLOCK_INIT(&env->me_dblock, NULL); if (excl) mdb_env_share_locks(env); env->me_dbxs = calloc(env->me_maxdbs, sizeof(MDB_dbx)); env->me_dbs[0] = calloc(env->me_maxdbs, sizeof(MDB_db)); env->me_dbs[1] = calloc(env->me_maxdbs, sizeof(MDB_db)); env->me_numdbs = 2; } leave: if (rc) { if (env->me_fd != INVALID_HANDLE_VALUE) { close(env->me_fd); env->me_fd = INVALID_HANDLE_VALUE; } if (env->me_lfd != INVALID_HANDLE_VALUE) { close(env->me_lfd); env->me_lfd = INVALID_HANDLE_VALUE; } } free(lpath); return rc; } void mdb_env_close(MDB_env *env) { MDB_page *dp; if (env == NULL) return; while (env->me_dpages) { dp = env->me_dpages; env->me_dpages = dp->mp_next; free(dp); } free(env->me_dbs[1]); free(env->me_dbs[0]); free(env->me_dbxs); free(env->me_path); LAZY_RWLOCK_DESTROY(&env->me_dblock); pthread_key_delete(env->me_txkey); if (env->me_map) { munmap(env->me_map, env->me_mapsize); } close(env->me_mfd); close(env->me_fd); if (env->me_txns) { pid_t pid = getpid(); unsigned int i; for (i=0; ime_txns->mti_numreaders; i++) if (env->me_txns->mti_readers[i].mr_pid == pid) env->me_txns->mti_readers[i].mr_pid = 0; munmap(env->me_txns, (env->me_maxreaders-1)*sizeof(MDB_reader)+sizeof(MDB_txninfo)); } close(env->me_lfd); free(env); } /* only for aligned ints */ static int intcmp(const MDB_val *a, const MDB_val *b) { if (a->mv_size == sizeof(long)) { unsigned long *la, *lb; la = a->mv_data; lb = b->mv_data; return *la - *lb; } else { unsigned int *ia, *ib; ia = a->mv_data; ib = b->mv_data; return *ia - *ib; } } /* ints must always be the same size */ static int cintcmp(const MDB_val *a, const MDB_val *b) { #if __BYTE_ORDER == __LITTLE_ENDIAN unsigned short *u, *c; int x; u = a->mv_data + a->mv_size; c = b->mv_data + a->mv_size; do { x = *--u - *--c; } while(!x && u > (unsigned short *)a->mv_data); return x; #else return memcmp(a->mv_data, b->mv_data, a->mv_size); #endif } static int memncmp(const MDB_val *a, const MDB_val *b) { int diff, len_diff; unsigned int len; len = a->mv_size; len_diff = a->mv_size - b->mv_size; if (len_diff > 0) len = b->mv_size; diff = memcmp(a->mv_data, b->mv_data, len); return diff ? diff : len_diff; } static int memnrcmp(const MDB_val *a, const MDB_val *b) { const unsigned char *p1, *p2, *p1_lim; int diff, len_diff; if (b->mv_size == 0) return a->mv_size != 0; if (a->mv_size == 0) return -1; p1 = (const unsigned char *)a->mv_data + a->mv_size - 1; p2 = (const unsigned char *)b->mv_data + b->mv_size - 1; len_diff = a->mv_size - b->mv_size; if (len_diff < 0) p1_lim = p1 - a->mv_size; else p1_lim = p1 - b->mv_size; while (p1 > p1_lim) { diff = *p1 - *p2; if (diff) return diff; p1--; p2--; } return len_diff; } /* Search for key within a leaf page, using binary search. * Returns the smallest entry larger or equal to the key. * If exactp is non-null, stores whether the found entry was an exact match * in *exactp (1 or 0). * If kip is non-null, stores the index of the found entry in *kip. * If no entry larger or equal to the key is found, returns NULL. */ static MDB_node * mdb_search_node(MDB_cursor *mc, MDB_val *key, int *exactp) { unsigned int i = 0, nkeys; int low, high; int rc = 0; MDB_page *mp = mc->mc_pg[mc->mc_top]; MDB_node *node = NULL; MDB_val nodekey; MDB_cmp_func *cmp; DKBUF; nkeys = NUMKEYS(mp); DPRINTF("searching %u keys in %s page %lu", nkeys, IS_LEAF(mp) ? "leaf" : "branch", mp->mp_pgno); assert(nkeys > 0); low = IS_LEAF(mp) ? 0 : 1; high = nkeys - 1; cmp = mc->mc_txn->mt_dbxs[mc->mc_dbi].md_cmp; if (IS_LEAF2(mp)) { nodekey.mv_size = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; node = NODEPTR(mp, 0); /* fake */ } while (low <= high) { i = (low + high) >> 1; if (IS_LEAF2(mp)) { nodekey.mv_data = LEAF2KEY(mp, i, nodekey.mv_size); } else { node = NODEPTR(mp, i); nodekey.mv_size = node->mn_ksize; nodekey.mv_data = NODEKEY(node); } rc = cmp(key, &nodekey); #if DEBUG if (IS_LEAF(mp)) DPRINTF("found leaf index %u [%s], rc = %i", i, DKEY(&nodekey), rc); else DPRINTF("found branch index %u [%s -> %lu], rc = %i", i, DKEY(&nodekey), NODEPGNO(node), rc); #endif if (rc == 0) break; if (rc > 0) low = i + 1; else high = i - 1; } if (rc > 0) { /* Found entry is less than the key. */ i++; /* Skip to get the smallest entry larger than key. */ if (!IS_LEAF2(mp)) node = NODEPTR(mp, i); } if (exactp) *exactp = (rc == 0); /* store the key index */ mc->mc_ki[mc->mc_top] = i; if (i >= nkeys) /* There is no entry larger or equal to the key. */ return NULL; /* nodeptr is fake for LEAF2 */ return node; } static void cursor_pop_page(MDB_cursor *mc) { MDB_page *top; if (mc->mc_snum) { top = mc->mc_pg[mc->mc_top]; mc->mc_snum--; if (mc->mc_snum) mc->mc_top--; DPRINTF("popped page %lu off db %u cursor %p", top->mp_pgno, mc->mc_dbi, (void *) mc); } } static int cursor_push_page(MDB_cursor *mc, MDB_page *mp) { DPRINTF("pushing page %lu on db %u cursor %p", mp->mp_pgno, mc->mc_dbi, (void *) mc); if (mc->mc_snum >= CURSOR_STACK) return ENOMEM; mc->mc_top = mc->mc_snum++; mc->mc_pg[mc->mc_top] = mp; mc->mc_ki[mc->mc_top] = 0; return MDB_SUCCESS; } static int mdb_get_page(MDB_txn *txn, pgno_t pgno, MDB_page **ret) { MDB_page *p = NULL; if (!F_ISSET(txn->mt_flags, MDB_TXN_RDONLY) && txn->mt_u.dirty_list[0].mid) { unsigned x; x = mdb_mid2l_search(txn->mt_u.dirty_list, pgno); if (x <= txn->mt_u.dirty_list[0].mid && txn->mt_u.dirty_list[x].mid == pgno) { p = txn->mt_u.dirty_list[x].mptr; } } if (!p) { if (pgno <= txn->mt_env->me_metas[txn->mt_toggle]->mm_last_pg) p = (MDB_page *)(txn->mt_env->me_map + txn->mt_env->me_psize * pgno); } *ret = p; if (!p) { DPRINTF("page %lu not found", pgno); assert(p != NULL); } return (p != NULL) ? MDB_SUCCESS : MDB_PAGE_NOTFOUND; } static int mdb_search_page_root(MDB_cursor *mc, MDB_val *key, int modify) { MDB_page *mp = mc->mc_pg[mc->mc_top]; DKBUF; int rc; while (IS_BRANCH(mp)) { MDB_node *node; DPRINTF("branch page %lu has %u keys", mp->mp_pgno, NUMKEYS(mp)); assert(NUMKEYS(mp) > 1); DPRINTF("found index 0 to page %lu", NODEPGNO(NODEPTR(mp, 0))); if (key == NULL) /* Initialize cursor to first page. */ mc->mc_ki[mc->mc_top] = 0; else if (key->mv_size > MAXKEYSIZE && key->mv_data == NULL) { /* cursor to last page */ mc->mc_ki[mc->mc_top] = NUMKEYS(mp)-1; } else { int exact; node = mdb_search_node(mc, key, &exact); if (node == NULL) mc->mc_ki[mc->mc_top] = NUMKEYS(mp) - 1; else if (!exact) { assert(mc->mc_ki[mc->mc_top] > 0); mc->mc_ki[mc->mc_top]--; } } if (key) DPRINTF("following index %u for key [%s]", mc->mc_ki[mc->mc_top], DKEY(key)); assert(mc->mc_ki[mc->mc_top] < NUMKEYS(mp)); node = NODEPTR(mp, mc->mc_ki[mc->mc_top]); if ((rc = mdb_get_page(mc->mc_txn, NODEPGNO(node), &mp))) return rc; if ((rc = cursor_push_page(mc, mp))) return rc; if (modify) { if ((rc = mdb_touch(mc)) != 0) return rc; mp = mc->mc_pg[mc->mc_top]; } } if (!IS_LEAF(mp)) { DPRINTF("internal error, index points to a %02X page!?", mp->mp_flags); return MDB_CORRUPTED; } DPRINTF("found leaf page %lu for key [%s]", mp->mp_pgno, key ? DKEY(key) : NULL); return MDB_SUCCESS; } /* Search for the page a given key should be in. * Pushes parent pages on the cursor stack. * If key is NULL, search for the lowest page (used by mdb_cursor_first). * If modify is true, visited pages are updated with new page numbers. */ static int mdb_search_page(MDB_cursor *mc, MDB_val *key, int modify) { int rc; pgno_t root; /* Make sure the txn is still viable, then find the root from * the txn's db table. */ if (F_ISSET(mc->mc_txn->mt_flags, MDB_TXN_ERROR)) { DPUTS("transaction has failed, must abort"); return EINVAL; } else root = mc->mc_txn->mt_dbs[mc->mc_dbi].md_root; if (root == P_INVALID) { /* Tree is empty. */ DPUTS("tree is empty"); return MDB_NOTFOUND; } if ((rc = mdb_get_page(mc->mc_txn, root, &mc->mc_pg[0]))) return rc; mc->mc_snum = 1; mc->mc_top = 0; DPRINTF("db %u root page %lu has flags 0x%X", mc->mc_dbi, root, mc->mc_pg[0]->mp_flags); if (modify) { /* For sub-databases, update main root first */ if (mc->mc_dbi > MAIN_DBI && !mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty) { MDB_cursor mc2; mc2.mc_txn = mc->mc_txn; mc2.mc_dbi = MAIN_DBI; rc = mdb_search_page(&mc2, &mc->mc_txn->mt_dbxs[mc->mc_dbi].md_name, 1); if (rc) return rc; mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty = 1; } if (!F_ISSET(mc->mc_pg[0]->mp_flags, P_DIRTY)) { if ((rc = mdb_touch(mc))) return rc; mc->mc_txn->mt_dbs[mc->mc_dbi].md_root = mc->mc_pg[0]->mp_pgno; } } return mdb_search_page_root(mc, key, modify); } static int mdb_read_data(MDB_txn *txn, MDB_node *leaf, MDB_val *data) { MDB_page *omp; /* overflow mpage */ pgno_t pgno; int rc; if (!F_ISSET(leaf->mn_flags, F_BIGDATA)) { data->mv_size = NODEDSZ(leaf); data->mv_data = NODEDATA(leaf); return MDB_SUCCESS; } /* Read overflow data. */ data->mv_size = NODEDSZ(leaf); memcpy(&pgno, NODEDATA(leaf), sizeof(pgno)); if ((rc = mdb_get_page(txn, pgno, &omp))) { DPRINTF("read overflow page %lu failed", pgno); return rc; } data->mv_data = METADATA(omp); return MDB_SUCCESS; } int mdb_get(MDB_txn *txn, MDB_dbi dbi, MDB_val *key, MDB_val *data) { MDB_cursor mc; MDB_xcursor mx; int exact = 0; DKBUF; assert(key); assert(data); DPRINTF("===> get db %u key [%s]", dbi, DKEY(key)); if (txn == NULL || !dbi || dbi >= txn->mt_numdbs) return EINVAL; if (key->mv_size == 0 || key->mv_size > MAXKEYSIZE) { return EINVAL; } mc.mc_txn = txn; mc.mc_dbi = dbi; mc.mc_flags = 0; if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) { mc.mc_xcursor = &mx; mdb_xcursor_init0(&mc); } else { mc.mc_xcursor = NULL; } return mdb_cursor_set(&mc, key, data, MDB_SET, &exact); } static int mdb_sibling(MDB_cursor *mc, int move_right) { int rc; unsigned int ptop; MDB_node *indx; MDB_page *mp; if (mc->mc_snum < 2) { return MDB_NOTFOUND; /* root has no siblings */ } ptop = mc->mc_top-1; DPRINTF("parent page is page %lu, index %u", mc->mc_pg[ptop]->mp_pgno, mc->mc_ki[ptop]); cursor_pop_page(mc); if (move_right ? (mc->mc_ki[ptop] + 1u >= NUMKEYS(mc->mc_pg[ptop])) : (mc->mc_ki[ptop] == 0)) { DPRINTF("no more keys left, moving to %s sibling", move_right ? "right" : "left"); if ((rc = mdb_sibling(mc, move_right)) != MDB_SUCCESS) return rc; } else { if (move_right) mc->mc_ki[ptop]++; else mc->mc_ki[ptop]--; DPRINTF("just moving to %s index key %u", move_right ? "right" : "left", mc->mc_ki[ptop]); } assert(IS_BRANCH(mc->mc_pg[ptop])); indx = NODEPTR(mc->mc_pg[ptop], mc->mc_ki[ptop]); if ((rc = mdb_get_page(mc->mc_txn, NODEPGNO(indx), &mp))) return rc;; cursor_push_page(mc, mp); return MDB_SUCCESS; } static int mdb_cursor_next(MDB_cursor *mc, MDB_val *key, MDB_val *data, MDB_cursor_op op) { MDB_page *mp; MDB_node *leaf; int rc; if (mc->mc_flags & C_EOF) { return MDB_NOTFOUND; } assert(mc->mc_flags & C_INITIALIZED); mp = mc->mc_pg[mc->mc_top]; if (mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPSORT) { leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]); if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { if (op == MDB_NEXT || op == MDB_NEXT_DUP) { rc = mdb_cursor_next(&mc->mc_xcursor->mx_cursor, data, NULL, MDB_NEXT); if (op != MDB_NEXT || rc == MDB_SUCCESS) return rc; } } else { mc->mc_xcursor->mx_cursor.mc_flags = 0; if (op == MDB_NEXT_DUP) return MDB_NOTFOUND; } } DPRINTF("cursor_next: top page is %lu in cursor %p", mp->mp_pgno, (void *) mc); if (mc->mc_ki[mc->mc_top] + 1u >= NUMKEYS(mp)) { DPUTS("=====> move to next sibling page"); if (mdb_sibling(mc, 1) != MDB_SUCCESS) { mc->mc_flags |= C_EOF; return MDB_NOTFOUND; } mp = mc->mc_pg[mc->mc_top]; DPRINTF("next page is %lu, key index %u", mp->mp_pgno, mc->mc_ki[mc->mc_top]); } else mc->mc_ki[mc->mc_top]++; DPRINTF("==> cursor points to page %lu with %u keys, key index %u", mp->mp_pgno, NUMKEYS(mp), mc->mc_ki[mc->mc_top]); if (IS_LEAF2(mp)) { key->mv_size = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; key->mv_data = LEAF2KEY(mp, mc->mc_ki[mc->mc_top], key->mv_size); return MDB_SUCCESS; } assert(IS_LEAF(mp)); leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]); if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { mdb_xcursor_init1(mc, leaf); } if (data) { if ((rc = mdb_read_data(mc->mc_txn, leaf, data) != MDB_SUCCESS)) return rc; if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { rc = mdb_cursor_first(&mc->mc_xcursor->mx_cursor, data, NULL); if (rc != MDB_SUCCESS) return rc; } } MDB_SET_KEY(leaf, key); return MDB_SUCCESS; } static int mdb_cursor_prev(MDB_cursor *mc, MDB_val *key, MDB_val *data, MDB_cursor_op op) { MDB_page *mp; MDB_node *leaf; int rc; assert(mc->mc_flags & C_INITIALIZED); mp = mc->mc_pg[mc->mc_top]; if (mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPSORT) { leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]); if (op == MDB_PREV || op == MDB_PREV_DUP) { if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { rc = mdb_cursor_prev(&mc->mc_xcursor->mx_cursor, data, NULL, MDB_PREV); if (op != MDB_PREV || rc == MDB_SUCCESS) return rc; } else { mc->mc_xcursor->mx_cursor.mc_flags = 0; if (op == MDB_PREV_DUP) return MDB_NOTFOUND; } } } DPRINTF("cursor_prev: top page is %lu in cursor %p", mp->mp_pgno, (void *) mc); if (mc->mc_ki[mc->mc_top] == 0) { DPUTS("=====> move to prev sibling page"); if (mdb_sibling(mc, 0) != MDB_SUCCESS) { mc->mc_flags &= ~C_INITIALIZED; return MDB_NOTFOUND; } mp = mc->mc_pg[mc->mc_top]; mc->mc_ki[mc->mc_top] = NUMKEYS(mp) - 1; DPRINTF("prev page is %lu, key index %u", mp->mp_pgno, mc->mc_ki[mc->mc_top]); } else mc->mc_ki[mc->mc_top]--; mc->mc_flags &= ~C_EOF; DPRINTF("==> cursor points to page %lu with %u keys, key index %u", mp->mp_pgno, NUMKEYS(mp), mc->mc_ki[mc->mc_top]); if (IS_LEAF2(mp)) { key->mv_size = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; key->mv_data = LEAF2KEY(mp, mc->mc_ki[mc->mc_top], key->mv_size); return MDB_SUCCESS; } assert(IS_LEAF(mp)); leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]); if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { mdb_xcursor_init1(mc, leaf); } if (data) { if ((rc = mdb_read_data(mc->mc_txn, leaf, data) != MDB_SUCCESS)) return rc; if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { rc = mdb_cursor_last(&mc->mc_xcursor->mx_cursor, data, NULL); if (rc != MDB_SUCCESS) return rc; } } MDB_SET_KEY(leaf, key); return MDB_SUCCESS; } static int mdb_cursor_set(MDB_cursor *mc, MDB_val *key, MDB_val *data, MDB_cursor_op op, int *exactp) { int rc; MDB_node *leaf; DKBUF; assert(mc); assert(key); assert(key->mv_size > 0); /* See if we're already on the right page */ if (mc->mc_flags & C_INITIALIZED) { MDB_val nodekey; if (mc->mc_pg[mc->mc_top]->mp_flags & P_LEAF2) { nodekey.mv_size = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; nodekey.mv_data = LEAF2KEY(mc->mc_pg[mc->mc_top], 0, nodekey.mv_size); } else { leaf = NODEPTR(mc->mc_pg[mc->mc_top], 0); MDB_SET_KEY(leaf, &nodekey); } rc = mc->mc_txn->mt_dbxs[mc->mc_dbi].md_cmp(key, &nodekey); if (rc == 0) { /* Probably happens rarely, but first node on the page * was the one we wanted. */ mc->mc_ki[mc->mc_top] = 0; set1: if (exactp) *exactp = 1; leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]); goto set3; } if (rc > 0) { unsigned int i; if (NUMKEYS(mc->mc_pg[mc->mc_top]) > 1) { if (mc->mc_pg[mc->mc_top]->mp_flags & P_LEAF2) { nodekey.mv_data = LEAF2KEY(mc->mc_pg[mc->mc_top], NUMKEYS(mc->mc_pg[mc->mc_top])-1, nodekey.mv_size); } else { leaf = NODEPTR(mc->mc_pg[mc->mc_top], NUMKEYS(mc->mc_pg[mc->mc_top])-1); MDB_SET_KEY(leaf, &nodekey); } rc = mc->mc_txn->mt_dbxs[mc->mc_dbi].md_cmp(key, &nodekey); if (rc == 0) { /* last node was the one we wanted */ mc->mc_ki[mc->mc_top] = NUMKEYS(mc->mc_pg[mc->mc_top])-1; goto set1; } if (rc < 0) { /* This is definitely the right page, skip search_page */ rc = 0; goto set2; } } /* If any parents have right-sibs, search. * Otherwise, there's nothing further. */ for (i=0; imc_top; i++) if (mc->mc_ki[i] < NUMKEYS(mc->mc_pg[i])-1) break; if (i == mc->mc_top) { /* There are no other pages */ mc->mc_ki[mc->mc_top] = NUMKEYS(mc->mc_pg[mc->mc_top]); return MDB_NOTFOUND; } } } rc = mdb_search_page(mc, key, 0); if (rc != MDB_SUCCESS) return rc; assert(IS_LEAF(mc->mc_pg[mc->mc_top])); set2: leaf = mdb_search_node(mc, key, exactp); if (exactp != NULL && !*exactp) { /* MDB_SET specified and not an exact match. */ return MDB_NOTFOUND; } if (leaf == NULL) { DPUTS("===> inexact leaf not found, goto sibling"); if ((rc = mdb_sibling(mc, 1)) != MDB_SUCCESS) return rc; /* no entries matched */ mc->mc_ki[mc->mc_top] = 0; assert(IS_LEAF(mc->mc_pg[mc->mc_top])); leaf = NODEPTR(mc->mc_pg[mc->mc_top], 0); } set3: mc->mc_flags |= C_INITIALIZED; mc->mc_flags &= ~C_EOF; if (IS_LEAF2(mc->mc_pg[mc->mc_top])) { key->mv_size = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; key->mv_data = LEAF2KEY(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top], key->mv_size); return MDB_SUCCESS; } if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { mdb_xcursor_init1(mc, leaf); } if (data) { if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { if (op == MDB_SET || op == MDB_SET_RANGE) { rc = mdb_cursor_first(&mc->mc_xcursor->mx_cursor, data, NULL); } else { int ex2, *ex2p; if (op == MDB_GET_BOTH) { ex2p = &ex2; ex2 = 0; } else { ex2p = NULL; } rc = mdb_cursor_set(&mc->mc_xcursor->mx_cursor, data, NULL, MDB_SET_RANGE, ex2p); if (rc != MDB_SUCCESS) return rc; } } else if (op == MDB_GET_BOTH || op == MDB_GET_BOTH_RANGE) { MDB_val d2; if ((rc = mdb_read_data(mc->mc_txn, leaf, &d2)) != MDB_SUCCESS) return rc; rc = mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dcmp(data, &d2); if (rc) { if (op == MDB_GET_BOTH || rc > 0) return MDB_NOTFOUND; } } else { if ((rc = mdb_read_data(mc->mc_txn, leaf, data)) != MDB_SUCCESS) return rc; } } /* The key already matches in all other cases */ if (op == MDB_SET_RANGE) MDB_SET_KEY(leaf, key); DPRINTF("==> cursor placed on key [%s]", DKEY(key)); return rc; } static int mdb_cursor_first(MDB_cursor *mc, MDB_val *key, MDB_val *data) { int rc; MDB_node *leaf; rc = mdb_search_page(mc, NULL, 0); if (rc != MDB_SUCCESS) return rc; assert(IS_LEAF(mc->mc_pg[mc->mc_top])); leaf = NODEPTR(mc->mc_pg[mc->mc_top], 0); mc->mc_flags |= C_INITIALIZED; mc->mc_flags &= ~C_EOF; if (IS_LEAF2(mc->mc_pg[mc->mc_top])) { key->mv_size = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; key->mv_data = LEAF2KEY(mc->mc_pg[mc->mc_top], 0, key->mv_size); return MDB_SUCCESS; } if (data) { if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { mdb_xcursor_init1(mc, leaf); rc = mdb_cursor_first(&mc->mc_xcursor->mx_cursor, data, NULL); if (rc) return rc; } else { if (mc->mc_xcursor) mc->mc_xcursor->mx_cursor.mc_flags = 0; if ((rc = mdb_read_data(mc->mc_txn, leaf, data)) != MDB_SUCCESS) return rc; } } MDB_SET_KEY(leaf, key); return MDB_SUCCESS; } static int mdb_cursor_last(MDB_cursor *mc, MDB_val *key, MDB_val *data) { int rc; MDB_node *leaf; MDB_val lkey; lkey.mv_size = MAXKEYSIZE+1; lkey.mv_data = NULL; rc = mdb_search_page(mc, &lkey, 0); if (rc != MDB_SUCCESS) return rc; assert(IS_LEAF(mc->mc_pg[mc->mc_top])); leaf = NODEPTR(mc->mc_pg[mc->mc_top], NUMKEYS(mc->mc_pg[mc->mc_top])-1); mc->mc_flags |= C_INITIALIZED; mc->mc_flags &= ~C_EOF; mc->mc_ki[mc->mc_top] = NUMKEYS(mc->mc_pg[mc->mc_top]) - 1; if (IS_LEAF2(mc->mc_pg[mc->mc_top])) { key->mv_size = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; key->mv_data = LEAF2KEY(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top], key->mv_size); return MDB_SUCCESS; } if (data) { if (F_ISSET(leaf->mn_flags, F_DUPDATA)) { mdb_xcursor_init1(mc, leaf); rc = mdb_cursor_last(&mc->mc_xcursor->mx_cursor, data, NULL); if (rc) return rc; } else { if ((rc = mdb_read_data(mc->mc_txn, leaf, data)) != MDB_SUCCESS) return rc; } } MDB_SET_KEY(leaf, key); return MDB_SUCCESS; } int mdb_cursor_get(MDB_cursor *mc, MDB_val *key, MDB_val *data, MDB_cursor_op op) { int rc; int exact = 0; assert(mc); switch (op) { case MDB_GET_BOTH: case MDB_GET_BOTH_RANGE: if (data == NULL || mc->mc_xcursor == NULL) { rc = EINVAL; break; } /* FALLTHRU */ case MDB_SET: case MDB_SET_RANGE: if (key == NULL || key->mv_size == 0 || key->mv_size > MAXKEYSIZE) { rc = EINVAL; } else if (op == MDB_SET_RANGE) rc = mdb_cursor_set(mc, key, data, op, NULL); else rc = mdb_cursor_set(mc, key, data, op, &exact); break; case MDB_GET_MULTIPLE: if (data == NULL || !(mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPFIXED) || !(mc->mc_flags & C_INITIALIZED)) { rc = EINVAL; break; } rc = MDB_SUCCESS; if (!(mc->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED) || (mc->mc_xcursor->mx_cursor.mc_flags & C_EOF)) break; goto fetchm; case MDB_NEXT_MULTIPLE: if (data == NULL || !(mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPFIXED)) { rc = EINVAL; break; } if (!(mc->mc_flags & C_INITIALIZED)) rc = mdb_cursor_first(mc, key, data); else rc = mdb_cursor_next(mc, key, data, MDB_NEXT_DUP); if (rc == MDB_SUCCESS) { if (mc->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED) { MDB_cursor *mx; fetchm: mx = &mc->mc_xcursor->mx_cursor; data->mv_size = NUMKEYS(mx->mc_pg[mx->mc_top]) * mx->mc_txn->mt_dbs[mx->mc_dbi].md_pad; data->mv_data = METADATA(mx->mc_pg[mx->mc_top]); mx->mc_ki[mx->mc_top] = NUMKEYS(mx->mc_pg[mx->mc_top])-1; } else { rc = MDB_NOTFOUND; } } break; case MDB_NEXT: case MDB_NEXT_DUP: case MDB_NEXT_NODUP: if (!(mc->mc_flags & C_INITIALIZED)) rc = mdb_cursor_first(mc, key, data); else rc = mdb_cursor_next(mc, key, data, op); break; case MDB_PREV: case MDB_PREV_DUP: case MDB_PREV_NODUP: if (!(mc->mc_flags & C_INITIALIZED) || (mc->mc_flags & C_EOF)) rc = mdb_cursor_last(mc, key, data); else rc = mdb_cursor_prev(mc, key, data, op); break; case MDB_FIRST: rc = mdb_cursor_first(mc, key, data); break; case MDB_FIRST_DUP: if (data == NULL || !(mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPSORT) || !(mc->mc_flags & C_INITIALIZED) || !(mc->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED)) { rc = EINVAL; break; } rc = mdb_cursor_first(&mc->mc_xcursor->mx_cursor, data, NULL); break; case MDB_LAST: rc = mdb_cursor_last(mc, key, data); break; case MDB_LAST_DUP: if (data == NULL || !(mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPSORT) || !(mc->mc_flags & C_INITIALIZED) || !(mc->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED)) { rc = EINVAL; break; } rc = mdb_cursor_last(&mc->mc_xcursor->mx_cursor, data, NULL); break; default: DPRINTF("unhandled/unimplemented cursor operation %u", op); rc = EINVAL; break; } return rc; } static int mdb_cursor_touch(MDB_cursor *mc) { int rc; if (mc->mc_dbi > MAIN_DBI && !mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty) { MDB_cursor mc2; mc2.mc_txn = mc->mc_txn; mc2.mc_dbi = MAIN_DBI; rc = mdb_search_page(&mc2, &mc->mc_txn->mt_dbxs[mc->mc_dbi].md_name, 1); if (rc) return rc; mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty = 1; } for (mc->mc_top = 0; mc->mc_top < mc->mc_snum; mc->mc_top++) { if (!F_ISSET(mc->mc_pg[mc->mc_top]->mp_flags, P_DIRTY)) { rc = mdb_touch(mc); if (rc) return rc; if (!mc->mc_top) { mc->mc_txn->mt_dbs[mc->mc_dbi].md_root = mc->mc_pg[mc->mc_top]->mp_pgno; } } } mc->mc_top = mc->mc_snum-1; return MDB_SUCCESS; } int mdb_cursor_put(MDB_cursor *mc, MDB_val *key, MDB_val *data, unsigned int flags) { MDB_node *leaf; MDB_val xdata, *rdata, dkey; MDB_db dummy; char dbuf[PAGESIZE]; int do_sub = 0; size_t nsize; DKBUF; int rc, rc2; if (F_ISSET(mc->mc_txn->mt_flags, MDB_TXN_RDONLY)) return EACCES; DPRINTF("==> put db %u key [%s], size %zu, data size %zu", mc->mc_dbi, DKEY(key), key->mv_size, data->mv_size); dkey.mv_size = 0; if (flags == MDB_CURRENT) { if (!(mc->mc_flags & C_INITIALIZED)) return EINVAL; rc = MDB_SUCCESS; } else if (mc->mc_txn->mt_dbs[mc->mc_dbi].md_root == P_INVALID) { MDB_page *np; /* new database, write a root leaf page */ DPUTS("allocating new root leaf page"); if ((np = mdb_new_page(mc, P_LEAF, 1)) == NULL) { return ENOMEM; } mc->mc_snum = 0; cursor_push_page(mc, np); mc->mc_txn->mt_dbs[mc->mc_dbi].md_root = np->mp_pgno; mc->mc_txn->mt_dbs[mc->mc_dbi].md_depth++; mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty = 1; if ((mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & (MDB_DUPSORT|MDB_DUPFIXED)) == MDB_DUPFIXED) np->mp_flags |= P_LEAF2; mc->mc_flags |= C_INITIALIZED; rc = MDB_NOTFOUND; goto top; } else { int exact = 0; MDB_val d2; rc = mdb_cursor_set(mc, key, &d2, MDB_SET, &exact); if (flags == MDB_NOOVERWRITE && rc == 0) { DPRINTF("duplicate key [%s]", DKEY(key)); *data = d2; return MDB_KEYEXIST; } if (rc && rc != MDB_NOTFOUND) return rc; } /* Cursor is positioned, now make sure all pages are writable */ rc2 = mdb_cursor_touch(mc); if (rc2) return rc2; top: /* The key already exists */ if (rc == MDB_SUCCESS) { /* there's only a key anyway, so this is a no-op */ if (IS_LEAF2(mc->mc_pg[mc->mc_top])) { unsigned int ksize = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; if (key->mv_size != ksize) return EINVAL; if (flags == MDB_CURRENT) { char *ptr = LEAF2KEY(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top], ksize); memcpy(ptr, key->mv_data, ksize); } return MDB_SUCCESS; } leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]); /* DB has dups? */ if (F_ISSET(mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags, MDB_DUPSORT)) { /* Was a single item before, must convert now */ if (!F_ISSET(leaf->mn_flags, F_DUPDATA)) { dkey.mv_size = NODEDSZ(leaf); dkey.mv_data = dbuf; memcpy(dbuf, NODEDATA(leaf), dkey.mv_size); /* data matches, ignore it */ if (!mdb_dcmp(mc->mc_txn, mc->mc_dbi, data, &dkey)) return (flags == MDB_NODUPDATA) ? MDB_KEYEXIST : MDB_SUCCESS; memset(&dummy, 0, sizeof(dummy)); if (mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPFIXED) { dummy.md_pad = data->mv_size; dummy.md_flags = MDB_DUPFIXED; if (mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_INTEGERDUP) dummy.md_flags |= MDB_INTEGERKEY; } dummy.md_root = P_INVALID; if (dkey.mv_size == sizeof(MDB_db)) { memcpy(NODEDATA(leaf), &dummy, sizeof(dummy)); goto put_sub; } mdb_del_node(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top], 0); do_sub = 1; rdata = &xdata; xdata.mv_size = sizeof(MDB_db); xdata.mv_data = &dummy; /* new sub-DB, must fully init xcursor */ if (flags == MDB_CURRENT) flags = 0; goto new_sub; } goto put_sub; } /* same size, just replace it */ if (!F_ISSET(leaf->mn_flags, F_BIGDATA) && NODEDSZ(leaf) == data->mv_size) { memcpy(NODEDATA(leaf), data->mv_data, data->mv_size); goto done; } mdb_del_node(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top], 0); } else { DPRINTF("inserting key at index %i", mc->mc_ki[mc->mc_top]); } rdata = data; new_sub: nsize = IS_LEAF2(mc->mc_pg[mc->mc_top]) ? key->mv_size : mdb_leaf_size(mc->mc_txn->mt_env, key, rdata); if (SIZELEFT(mc->mc_pg[mc->mc_top]) < nsize) { rc = mdb_split(mc, key, rdata, P_INVALID); } else { /* There is room already in this leaf page. */ rc = mdb_add_node(mc, mc->mc_ki[mc->mc_top], key, rdata, 0, 0); } if (rc != MDB_SUCCESS) mc->mc_txn->mt_flags |= MDB_TXN_ERROR; else { /* Remember if we just added a subdatabase */ if (flags & F_SUBDATA) { leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]); leaf->mn_flags |= F_SUBDATA; } /* Now store the actual data in the child DB. Note that we're * storing the user data in the keys field, so there are strict * size limits on dupdata. The actual data fields of the child * DB are all zero size. */ if (do_sub) { leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]); put_sub: if (flags == MDB_CURRENT) mdb_xcursor_init2(mc); else mdb_xcursor_init1(mc, leaf); xdata.mv_size = 0; xdata.mv_data = ""; if (flags == MDB_NODUPDATA) flags = MDB_NOOVERWRITE; /* converted, write the original data first */ if (dkey.mv_size) { rc = mdb_cursor_put(&mc->mc_xcursor->mx_cursor, &dkey, &xdata, flags); if (rc) return rc; leaf->mn_flags |= F_DUPDATA; } rc = mdb_cursor_put(&mc->mc_xcursor->mx_cursor, data, &xdata, flags); mdb_xcursor_fini(mc); memcpy(NODEDATA(leaf), &mc->mc_xcursor->mx_txn.mt_dbs[mc->mc_xcursor->mx_cursor.mc_dbi], sizeof(MDB_db)); } mc->mc_txn->mt_dbs[mc->mc_dbi].md_entries++; } done: return rc; } int mdb_cursor_del(MDB_cursor *mc, unsigned int flags) { MDB_node *leaf; int rc; if (F_ISSET(mc->mc_txn->mt_flags, MDB_TXN_RDONLY)) return EACCES; if (!mc->mc_flags & C_INITIALIZED) return EINVAL; rc = mdb_cursor_touch(mc); if (rc) return rc; leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]); if (!IS_LEAF2(mc->mc_pg[mc->mc_top]) && F_ISSET(leaf->mn_flags, F_DUPDATA)) { if (flags != MDB_NODUPDATA) { mdb_xcursor_init2(mc); rc = mdb_cursor_del(&mc->mc_xcursor->mx_cursor, 0); mdb_xcursor_fini(mc); /* If sub-DB still has entries, we're done */ if (mc->mc_xcursor->mx_txn.mt_dbs[mc->mc_xcursor->mx_cursor.mc_dbi].md_root != P_INVALID) { memcpy(NODEDATA(leaf), &mc->mc_xcursor->mx_txn.mt_dbs[mc->mc_xcursor->mx_cursor.mc_dbi], sizeof(MDB_db)); mc->mc_txn->mt_dbs[mc->mc_dbi].md_entries--; return rc; } /* otherwise fall thru and delete the sub-DB */ } /* add all the child DB's pages to the free list */ rc = mdb_search_page(&mc->mc_xcursor->mx_cursor, NULL, 0); if (rc == MDB_SUCCESS) { MDB_node *ni; MDB_cursor *mx; unsigned int i; mx = &mc->mc_xcursor->mx_cursor; mc->mc_txn->mt_dbs[mc->mc_dbi].md_entries -= mx->mc_txn->mt_dbs[mx->mc_dbi].md_entries; cursor_pop_page(mx); if (mx->mc_snum) { while (mx->mc_snum > 1) { for (i=0; imc_pg[mx->mc_top]); i++) { pgno_t pg; ni = NODEPTR(mx->mc_pg[mx->mc_top], i); pg = NODEPGNO(ni); /* free it */ mdb_midl_append(mc->mc_txn->mt_free_pgs, pg); } rc = mdb_sibling(mx, 1); if (rc) break; } } /* free it */ mdb_midl_append(mc->mc_txn->mt_free_pgs, mx->mc_txn->mt_dbs[mx->mc_dbi].md_root); } } return mdb_del0(mc, leaf); } /* Allocate a page and initialize it */ static MDB_page * mdb_new_page(MDB_cursor *mc, uint32_t flags, int num) { MDB_page *np; if ((np = mdb_alloc_page(mc, num)) == NULL) return NULL; DPRINTF("allocated new mpage %lu, page size %u", np->mp_pgno, mc->mc_txn->mt_env->me_psize); np->mp_flags = flags | P_DIRTY; np->mp_lower = PAGEHDRSZ; np->mp_upper = mc->mc_txn->mt_env->me_psize; if (IS_BRANCH(np)) mc->mc_txn->mt_dbs[mc->mc_dbi].md_branch_pages++; else if (IS_LEAF(np)) mc->mc_txn->mt_dbs[mc->mc_dbi].md_leaf_pages++; else if (IS_OVERFLOW(np)) { mc->mc_txn->mt_dbs[mc->mc_dbi].md_overflow_pages += num; np->mp_pages = num; } return np; } static size_t mdb_leaf_size(MDB_env *env, MDB_val *key, MDB_val *data) { size_t sz; sz = LEAFSIZE(key, data); if (data->mv_size >= env->me_psize / MDB_MINKEYS) { /* put on overflow page */ sz -= data->mv_size - sizeof(pgno_t); } sz += sz & 1; return sz + sizeof(indx_t); } static size_t mdb_branch_size(MDB_env *env, MDB_val *key) { size_t sz; sz = INDXSIZE(key); if (sz >= env->me_psize / MDB_MINKEYS) { /* put on overflow page */ /* not implemented */ /* sz -= key->size - sizeof(pgno_t); */ } return sz + sizeof(indx_t); } static int mdb_add_node(MDB_cursor *mc, indx_t indx, MDB_val *key, MDB_val *data, pgno_t pgno, uint8_t flags) { unsigned int i; size_t node_size = NODESIZE; indx_t ofs; MDB_node *node; MDB_page *mp = mc->mc_pg[mc->mc_top]; MDB_page *ofp = NULL; /* overflow page */ DKBUF; assert(mp->mp_upper >= mp->mp_lower); DPRINTF("add to %s page %lu index %i, data size %zu key size %zu [%s]", IS_LEAF(mp) ? "leaf" : "branch", mp->mp_pgno, indx, data ? data->mv_size : 0, key ? key->mv_size : 0, key ? DKEY(key) : NULL); if (IS_LEAF2(mp)) { /* Move higher keys up one slot. */ int ksize = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad, dif; char *ptr = LEAF2KEY(mp, indx, ksize); dif = NUMKEYS(mp) - indx; if (dif > 0) memmove(ptr+ksize, ptr, dif*ksize); /* insert new key */ memcpy(ptr, key->mv_data, ksize); /* Just using these for counting */ mp->mp_lower += sizeof(indx_t); mp->mp_upper -= ksize - sizeof(indx_t); return MDB_SUCCESS; } if (key != NULL) node_size += key->mv_size; if (IS_LEAF(mp)) { assert(data); if (F_ISSET(flags, F_BIGDATA)) { /* Data already on overflow page. */ node_size += sizeof(pgno_t); } else if (data->mv_size >= mc->mc_txn->mt_env->me_psize / MDB_MINKEYS) { int ovpages = OVPAGES(data->mv_size, mc->mc_txn->mt_env->me_psize); /* Put data on overflow page. */ DPRINTF("data size is %zu, put on overflow page", data->mv_size); node_size += sizeof(pgno_t); if ((ofp = mdb_new_page(mc, P_OVERFLOW, ovpages)) == NULL) return ENOMEM; DPRINTF("allocated overflow page %lu", ofp->mp_pgno); flags |= F_BIGDATA; } else { node_size += data->mv_size; } } node_size += node_size & 1; if (node_size + sizeof(indx_t) > SIZELEFT(mp)) { DPRINTF("not enough room in page %lu, got %u ptrs", mp->mp_pgno, NUMKEYS(mp)); DPRINTF("upper - lower = %u - %u = %u", mp->mp_upper, mp->mp_lower, mp->mp_upper - mp->mp_lower); DPRINTF("node size = %zu", node_size); return ENOSPC; } /* Move higher pointers up one slot. */ for (i = NUMKEYS(mp); i > indx; i--) mp->mp_ptrs[i] = mp->mp_ptrs[i - 1]; /* Adjust free space offsets. */ ofs = mp->mp_upper - node_size; assert(ofs >= mp->mp_lower + sizeof(indx_t)); mp->mp_ptrs[indx] = ofs; mp->mp_upper = ofs; mp->mp_lower += sizeof(indx_t); /* Write the node data. */ node = NODEPTR(mp, indx); node->mn_ksize = (key == NULL) ? 0 : key->mv_size; node->mn_flags = flags; if (IS_LEAF(mp)) SETDSZ(node,data->mv_size); else SETPGNO(node,pgno); if (key) memcpy(NODEKEY(node), key->mv_data, key->mv_size); if (IS_LEAF(mp)) { assert(key); if (ofp == NULL) { if (F_ISSET(flags, F_BIGDATA)) memcpy(node->mn_data + key->mv_size, data->mv_data, sizeof(pgno_t)); else memcpy(node->mn_data + key->mv_size, data->mv_data, data->mv_size); } else { memcpy(node->mn_data + key->mv_size, &ofp->mp_pgno, sizeof(pgno_t)); memcpy(METADATA(ofp), data->mv_data, data->mv_size); } } return MDB_SUCCESS; } static void mdb_del_node(MDB_page *mp, indx_t indx, int ksize) { unsigned int sz; indx_t i, j, numkeys, ptr; MDB_node *node; char *base; DPRINTF("delete node %u on %s page %lu", indx, IS_LEAF(mp) ? "leaf" : "branch", mp->mp_pgno); assert(indx < NUMKEYS(mp)); if (IS_LEAF2(mp)) { int x = NUMKEYS(mp) - 1 - indx; base = LEAF2KEY(mp, indx, ksize); if (x) memmove(base, base + ksize, x * ksize); mp->mp_lower -= sizeof(indx_t); mp->mp_upper += ksize - sizeof(indx_t); return; } node = NODEPTR(mp, indx); sz = NODESIZE + node->mn_ksize; if (IS_LEAF(mp)) { if (F_ISSET(node->mn_flags, F_BIGDATA)) sz += sizeof(pgno_t); else sz += NODEDSZ(node); } sz += sz & 1; ptr = mp->mp_ptrs[indx]; numkeys = NUMKEYS(mp); for (i = j = 0; i < numkeys; i++) { if (i != indx) { mp->mp_ptrs[j] = mp->mp_ptrs[i]; if (mp->mp_ptrs[i] < ptr) mp->mp_ptrs[j] += sz; j++; } } base = (char *)mp + mp->mp_upper; memmove(base + sz, base, ptr - mp->mp_upper); mp->mp_lower -= sizeof(indx_t); mp->mp_upper += sz; } static void mdb_xcursor_init0(MDB_cursor *mc) { MDB_xcursor *mx = mc->mc_xcursor; MDB_dbi dbn; mx->mx_txn = *mc->mc_txn; mx->mx_txn.mt_dbxs = mx->mx_dbxs; mx->mx_txn.mt_dbs = mx->mx_dbs; mx->mx_dbxs[0] = mc->mc_txn->mt_dbxs[0]; mx->mx_dbxs[1] = mc->mc_txn->mt_dbxs[1]; if (mc->mc_dbi > 1) { mx->mx_dbxs[2] = mc->mc_txn->mt_dbxs[mc->mc_dbi]; dbn = 2; } else { dbn = 1; } mx->mx_dbxs[dbn+1].md_parent = dbn; mx->mx_dbxs[dbn+1].md_cmp = mx->mx_dbxs[dbn].md_dcmp; mx->mx_dbxs[dbn+1].md_rel = mx->mx_dbxs[dbn].md_rel; mx->mx_dbxs[dbn+1].md_dirty = 0; mx->mx_txn.mt_numdbs = dbn+2; mx->mx_txn.mt_u = mc->mc_txn->mt_u; mx->mx_cursor.mc_xcursor = NULL; mx->mx_cursor.mc_txn = &mx->mx_txn; mx->mx_cursor.mc_dbi = dbn+1; } static void mdb_xcursor_init1(MDB_cursor *mc, MDB_node *node) { MDB_db *db = NODEDATA(node); MDB_xcursor *mx = mc->mc_xcursor; MDB_dbi dbn; mx->mx_dbs[0] = mc->mc_txn->mt_dbs[0]; mx->mx_dbs[1] = mc->mc_txn->mt_dbs[1]; if (mc->mc_dbi > 1) { mx->mx_dbs[2] = mc->mc_txn->mt_dbs[mc->mc_dbi]; mx->mx_dbxs[2].md_dirty = mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty; dbn = 3; } else { dbn = 2; } DPRINTF("Sub-db %u for db %u root page %lu", dbn, mc->mc_dbi, db->md_root); mx->mx_dbs[dbn] = *db; if (F_ISSET(mc->mc_pg[mc->mc_top]->mp_flags, P_DIRTY)) mx->mx_dbxs[dbn].md_dirty = 1; mx->mx_dbxs[dbn].md_name.mv_data = NODEKEY(node); mx->mx_dbxs[dbn].md_name.mv_size = node->mn_ksize; mx->mx_txn.mt_next_pgno = mc->mc_txn->mt_next_pgno; mx->mx_cursor.mc_snum = 0; mx->mx_cursor.mc_flags = 0; } static void mdb_xcursor_init2(MDB_cursor *mc) { MDB_xcursor *mx = mc->mc_xcursor; MDB_dbi dbn; mx->mx_dbs[0] = mc->mc_txn->mt_dbs[0]; mx->mx_dbs[1] = mc->mc_txn->mt_dbs[1]; if (mc->mc_dbi > 1) { mx->mx_dbs[2] = mc->mc_txn->mt_dbs[mc->mc_dbi]; mx->mx_dbxs[2].md_dirty = mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty; dbn = 3; } else { dbn = 2; } DPRINTF("Sub-db %u for db %u root page %lu", dbn, mc->mc_dbi, mx->mx_dbs[dbn].md_root); mx->mx_txn.mt_next_pgno = mc->mc_txn->mt_next_pgno; } static void mdb_xcursor_fini(MDB_cursor *mc) { MDB_xcursor *mx = mc->mc_xcursor; mc->mc_txn->mt_next_pgno = mx->mx_txn.mt_next_pgno; mc->mc_txn->mt_dbs[0] = mx->mx_dbs[0]; mc->mc_txn->mt_dbs[1] = mx->mx_dbs[1]; if (mc->mc_dbi > 1) { mc->mc_txn->mt_dbs[mc->mc_dbi] = mx->mx_dbs[2]; mc->mc_txn->mt_dbxs[mc->mc_dbi].md_dirty = mx->mx_dbxs[2].md_dirty; } } int mdb_cursor_open(MDB_txn *txn, MDB_dbi dbi, MDB_cursor **ret) { MDB_cursor *mc; size_t size = sizeof(MDB_cursor); if (txn == NULL || ret == NULL || !dbi || dbi >= txn->mt_numdbs) return EINVAL; if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) size += sizeof(MDB_xcursor); if ((mc = calloc(1, size)) != NULL) { mc->mc_dbi = dbi; mc->mc_txn = txn; if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) { MDB_xcursor *mx = (MDB_xcursor *)(mc + 1); mc->mc_xcursor = mx; mdb_xcursor_init0(mc); } } else { return ENOMEM; } *ret = mc; return MDB_SUCCESS; } /* Return the count of duplicate data items for the current key */ int mdb_cursor_count(MDB_cursor *mc, unsigned long *countp) { MDB_node *leaf; if (mc == NULL || countp == NULL) return EINVAL; if (!(mc->mc_txn->mt_dbs[mc->mc_dbi].md_flags & MDB_DUPSORT)) return EINVAL; leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]); if (!F_ISSET(leaf->mn_flags, F_DUPDATA)) { *countp = 1; } else { if (!(mc->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED)) return EINVAL; *countp = mc->mc_xcursor->mx_txn.mt_dbs[mc->mc_xcursor->mx_cursor.mc_dbi].md_entries; } return MDB_SUCCESS; } void mdb_cursor_close(MDB_cursor *mc) { if (mc != NULL) { free(mc); } } static int mdb_update_key(MDB_page *mp, indx_t indx, MDB_val *key) { indx_t ptr, i, numkeys; int delta; size_t len; MDB_node *node; char *base; DKBUF; node = NODEPTR(mp, indx); ptr = mp->mp_ptrs[indx]; DPRINTF("update key %u (ofs %u) [%.*s] to [%s] on page %lu", indx, ptr, (int)node->mn_ksize, (char *)NODEKEY(node), DKEY(key), mp->mp_pgno); delta = key->mv_size - node->mn_ksize; if (delta) { if (delta > 0 && SIZELEFT(mp) < delta) { DPRINTF("OUCH! Not enough room, delta = %d", delta); return ENOSPC; } numkeys = NUMKEYS(mp); for (i = 0; i < numkeys; i++) { if (mp->mp_ptrs[i] <= ptr) mp->mp_ptrs[i] -= delta; } base = (char *)mp + mp->mp_upper; len = ptr - mp->mp_upper + NODESIZE; memmove(base - delta, base, len); mp->mp_upper -= delta; node = NODEPTR(mp, indx); node->mn_ksize = key->mv_size; } memcpy(NODEKEY(node), key->mv_data, key->mv_size); return MDB_SUCCESS; } /* Move a node from csrc to cdst. */ static int mdb_move_node(MDB_cursor *csrc, MDB_cursor *cdst) { int rc; MDB_node *srcnode; MDB_val key, data; DKBUF; /* Mark src and dst as dirty. */ if ((rc = mdb_touch(csrc)) || (rc = mdb_touch(cdst))) return rc;; if (IS_LEAF2(csrc->mc_pg[csrc->mc_top])) { srcnode = NODEPTR(csrc->mc_pg[csrc->mc_top], 0); /* fake */ key.mv_size = csrc->mc_txn->mt_dbs[csrc->mc_dbi].md_pad; key.mv_data = LEAF2KEY(csrc->mc_pg[csrc->mc_top], csrc->mc_ki[csrc->mc_top], key.mv_size); data.mv_size = 0; data.mv_data = NULL; } else { if (csrc->mc_ki[csrc->mc_top] == 0 && IS_BRANCH(csrc->mc_pg[csrc->mc_top])) { unsigned int snum = csrc->mc_snum; /* must find the lowest key below src */ mdb_search_page_root(csrc, NULL, 0); srcnode = NODEPTR(csrc->mc_pg[csrc->mc_top], 0); csrc->mc_snum = snum--; csrc->mc_top = snum; } else { srcnode = NODEPTR(csrc->mc_pg[csrc->mc_top], csrc->mc_ki[csrc->mc_top]); } key.mv_size = NODEKSZ(srcnode); key.mv_data = NODEKEY(srcnode); data.mv_size = NODEDSZ(srcnode); data.mv_data = NODEDATA(srcnode); } DPRINTF("moving %s node %u [%s] on page %lu to node %u on page %lu", IS_LEAF(csrc->mc_pg[csrc->mc_top]) ? "leaf" : "branch", csrc->mc_ki[csrc->mc_top], DKEY(&key), csrc->mc_pg[csrc->mc_top]->mp_pgno, cdst->mc_ki[cdst->mc_top], cdst->mc_pg[cdst->mc_top]->mp_pgno); /* Add the node to the destination page. */ rc = mdb_add_node(cdst, cdst->mc_ki[cdst->mc_top], &key, &data, NODEPGNO(srcnode), srcnode->mn_flags); if (rc != MDB_SUCCESS) return rc; /* Delete the node from the source page. */ mdb_del_node(csrc->mc_pg[csrc->mc_top], csrc->mc_ki[csrc->mc_top], key.mv_size); /* Update the parent separators. */ if (csrc->mc_ki[csrc->mc_top] == 0) { if (csrc->mc_ki[csrc->mc_top-1] != 0) { if (IS_LEAF2(csrc->mc_pg[csrc->mc_top])) { key.mv_data = LEAF2KEY(csrc->mc_pg[csrc->mc_top], csrc->mc_ki[csrc->mc_top], key.mv_size); } else { srcnode = NODEPTR(csrc->mc_pg[csrc->mc_top], csrc->mc_ki[csrc->mc_top]); key.mv_size = NODEKSZ(srcnode); key.mv_data = NODEKEY(srcnode); } DPRINTF("update separator for source page %lu to [%s]", csrc->mc_pg[csrc->mc_top]->mp_pgno, DKEY(&key)); if ((rc = mdb_update_key(csrc->mc_pg[csrc->mc_top-1], csrc->mc_ki[csrc->mc_top-1], &key)) != MDB_SUCCESS) return rc; } if (IS_BRANCH(csrc->mc_pg[csrc->mc_top])) { MDB_val nullkey; nullkey.mv_size = 0; assert(mdb_update_key(csrc->mc_pg[csrc->mc_top], 0, &nullkey) == MDB_SUCCESS); } } if (cdst->mc_ki[cdst->mc_top] == 0) { if (cdst->mc_ki[cdst->mc_top-1] != 0) { if (IS_LEAF2(csrc->mc_pg[csrc->mc_top])) { key.mv_data = LEAF2KEY(cdst->mc_pg[cdst->mc_top], 0, key.mv_size); } else { srcnode = NODEPTR(cdst->mc_pg[cdst->mc_top], 0); key.mv_size = NODEKSZ(srcnode); key.mv_data = NODEKEY(srcnode); } DPRINTF("update separator for destination page %lu to [%s]", cdst->mc_pg[cdst->mc_top]->mp_pgno, DKEY(&key)); if ((rc = mdb_update_key(cdst->mc_pg[cdst->mc_top-1], cdst->mc_ki[cdst->mc_top-1], &key)) != MDB_SUCCESS) return rc; } if (IS_BRANCH(cdst->mc_pg[cdst->mc_top])) { MDB_val nullkey; nullkey.mv_size = 0; assert(mdb_update_key(cdst->mc_pg[cdst->mc_top], 0, &nullkey) == MDB_SUCCESS); } } return MDB_SUCCESS; } static int mdb_merge(MDB_cursor *csrc, MDB_cursor *cdst) { int rc; indx_t i, j; MDB_node *srcnode; MDB_val key, data; DPRINTF("merging page %lu into %lu", csrc->mc_pg[csrc->mc_top]->mp_pgno, cdst->mc_pg[cdst->mc_top]->mp_pgno); assert(csrc->mc_snum > 1); /* can't merge root page */ assert(cdst->mc_snum > 1); /* Mark dst as dirty. */ if ((rc = mdb_touch(cdst))) return rc; /* Move all nodes from src to dst. */ j = NUMKEYS(cdst->mc_pg[cdst->mc_top]); if (IS_LEAF2(csrc->mc_pg[csrc->mc_top])) { key.mv_size = csrc->mc_txn->mt_dbs[csrc->mc_dbi].md_pad; key.mv_data = METADATA(csrc->mc_pg[csrc->mc_top]); for (i = 0; i < NUMKEYS(csrc->mc_pg[csrc->mc_top]); i++, j++) { rc = mdb_add_node(cdst, j, &key, NULL, 0, 0); if (rc != MDB_SUCCESS) return rc; key.mv_data = (char *)key.mv_data + key.mv_size; } } else { for (i = 0; i < NUMKEYS(csrc->mc_pg[csrc->mc_top]); i++, j++) { srcnode = NODEPTR(csrc->mc_pg[csrc->mc_top], i); key.mv_size = srcnode->mn_ksize; key.mv_data = NODEKEY(srcnode); data.mv_size = NODEDSZ(srcnode); data.mv_data = NODEDATA(srcnode); rc = mdb_add_node(cdst, j, &key, &data, NODEPGNO(srcnode), srcnode->mn_flags); if (rc != MDB_SUCCESS) return rc; } } DPRINTF("dst page %lu now has %u keys (%.1f%% filled)", cdst->mc_pg[cdst->mc_top]->mp_pgno, NUMKEYS(cdst->mc_pg[cdst->mc_top]), (float)PAGEFILL(cdst->mc_txn->mt_env, cdst->mc_pg[cdst->mc_top]) / 10); /* Unlink the src page from parent and add to free list. */ mdb_del_node(csrc->mc_pg[csrc->mc_top-1], csrc->mc_ki[csrc->mc_top-1], 0); if (csrc->mc_ki[csrc->mc_top-1] == 0) { key.mv_size = 0; if ((rc = mdb_update_key(csrc->mc_pg[csrc->mc_top-1], 0, &key)) != MDB_SUCCESS) return rc; } mdb_midl_append(csrc->mc_txn->mt_free_pgs, csrc->mc_pg[csrc->mc_top]->mp_pgno); if (IS_LEAF(csrc->mc_pg[csrc->mc_top])) csrc->mc_txn->mt_dbs[csrc->mc_dbi].md_leaf_pages--; else csrc->mc_txn->mt_dbs[csrc->mc_dbi].md_branch_pages--; cursor_pop_page(csrc); return mdb_rebalance(csrc); } static void mdb_cursor_copy(const MDB_cursor *csrc, MDB_cursor *cdst) { unsigned int i; cdst->mc_txn = csrc->mc_txn; cdst->mc_dbi = csrc->mc_dbi; cdst->mc_snum = csrc->mc_snum; cdst->mc_top = csrc->mc_top; cdst->mc_flags = csrc->mc_flags; for (i=0; imc_snum; i++) { cdst->mc_pg[i] = csrc->mc_pg[i]; cdst->mc_ki[i] = csrc->mc_ki[i]; } } static int mdb_rebalance(MDB_cursor *mc) { MDB_node *node; MDB_page *root; int rc; unsigned int ptop; MDB_cursor mn; DPRINTF("rebalancing %s page %lu (has %u keys, %.1f%% full)", IS_LEAF(mc->mc_pg[mc->mc_top]) ? "leaf" : "branch", mc->mc_pg[mc->mc_top]->mp_pgno, NUMKEYS(mc->mc_pg[mc->mc_top]), (float)PAGEFILL(mc->mc_txn->mt_env, mc->mc_pg[mc->mc_top]) / 10); if (PAGEFILL(mc->mc_txn->mt_env, mc->mc_pg[mc->mc_top]) >= FILL_THRESHOLD) { DPRINTF("no need to rebalance page %lu, above fill threshold", mc->mc_pg[mc->mc_top]->mp_pgno); return MDB_SUCCESS; } if (mc->mc_snum < 2) { if (NUMKEYS(mc->mc_pg[mc->mc_top]) == 0) { DPUTS("tree is completely empty"); mc->mc_txn->mt_dbs[mc->mc_dbi].md_root = P_INVALID; mc->mc_txn->mt_dbs[mc->mc_dbi].md_depth = 0; mc->mc_txn->mt_dbs[mc->mc_dbi].md_leaf_pages = 0; mdb_midl_append(mc->mc_txn->mt_free_pgs, mc->mc_pg[mc->mc_top]->mp_pgno); } else if (IS_BRANCH(mc->mc_pg[mc->mc_top]) && NUMKEYS(mc->mc_pg[mc->mc_top]) == 1) { DPUTS("collapsing root page!"); mdb_midl_append(mc->mc_txn->mt_free_pgs, mc->mc_pg[mc->mc_top]->mp_pgno); mc->mc_txn->mt_dbs[mc->mc_dbi].md_root = NODEPGNO(NODEPTR(mc->mc_pg[mc->mc_top], 0)); if ((rc = mdb_get_page(mc->mc_txn, mc->mc_txn->mt_dbs[mc->mc_dbi].md_root, &root))) return rc; mc->mc_txn->mt_dbs[mc->mc_dbi].md_depth--; mc->mc_txn->mt_dbs[mc->mc_dbi].md_branch_pages--; } else DPUTS("root page doesn't need rebalancing"); return MDB_SUCCESS; } /* The parent (branch page) must have at least 2 pointers, * otherwise the tree is invalid. */ ptop = mc->mc_top-1; assert(NUMKEYS(mc->mc_pg[ptop]) > 1); /* Leaf page fill factor is below the threshold. * Try to move keys from left or right neighbor, or * merge with a neighbor page. */ /* Find neighbors. */ mdb_cursor_copy(mc, &mn); mn.mc_xcursor = NULL; if (mc->mc_ki[ptop] == 0) { /* We're the leftmost leaf in our parent. */ DPUTS("reading right neighbor"); mn.mc_ki[ptop]++; node = NODEPTR(mc->mc_pg[ptop], mn.mc_ki[ptop]); if ((rc = mdb_get_page(mc->mc_txn, NODEPGNO(node), &mn.mc_pg[mn.mc_top]))) return rc; mn.mc_ki[mn.mc_top] = 0; mc->mc_ki[mc->mc_top] = NUMKEYS(mc->mc_pg[mc->mc_top]); } else { /* There is at least one neighbor to the left. */ DPUTS("reading left neighbor"); mn.mc_ki[ptop]--; node = NODEPTR(mc->mc_pg[ptop], mn.mc_ki[ptop]); if ((rc = mdb_get_page(mc->mc_txn, NODEPGNO(node), &mn.mc_pg[mn.mc_top]))) return rc; mn.mc_ki[mn.mc_top] = NUMKEYS(mn.mc_pg[mn.mc_top]) - 1; mc->mc_ki[mc->mc_top] = 0; } DPRINTF("found neighbor page %lu (%u keys, %.1f%% full)", mn.mc_pg[mn.mc_top]->mp_pgno, NUMKEYS(mn.mc_pg[mn.mc_top]), (float)PAGEFILL(mc->mc_txn->mt_env, mn.mc_pg[mn.mc_top]) / 10); /* If the neighbor page is above threshold and has at least two * keys, move one key from it. * * Otherwise we should try to merge them. */ if (PAGEFILL(mc->mc_txn->mt_env, mn.mc_pg[mn.mc_top]) >= FILL_THRESHOLD && NUMKEYS(mn.mc_pg[mn.mc_top]) >= 2) return mdb_move_node(&mn, mc); else { /* FIXME: if (has_enough_room()) */ if (mc->mc_ki[ptop] == 0) return mdb_merge(&mn, mc); else return mdb_merge(mc, &mn); } } static int mdb_del0(MDB_cursor *mc, MDB_node *leaf) { int rc; /* add overflow pages to free list */ if (!IS_LEAF2(mc->mc_pg[mc->mc_top]) && F_ISSET(leaf->mn_flags, F_BIGDATA)) { int i, ovpages; pgno_t pg; memcpy(&pg, NODEDATA(leaf), sizeof(pg)); ovpages = OVPAGES(NODEDSZ(leaf), mc->mc_txn->mt_env->me_psize); for (i=0; imc_txn->mt_free_pgs, pg); pg++; } } mdb_del_node(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top], mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad); mc->mc_txn->mt_dbs[mc->mc_dbi].md_entries--; rc = mdb_rebalance(mc); if (rc != MDB_SUCCESS) mc->mc_txn->mt_flags |= MDB_TXN_ERROR; return rc; } int mdb_del(MDB_txn *txn, MDB_dbi dbi, MDB_val *key, MDB_val *data) { MDB_cursor mc; MDB_xcursor mx; MDB_cursor_op op; MDB_val rdata, *xdata; int rc, exact; DKBUF; assert(key != NULL); DPRINTF("====> delete db %u key [%s]", dbi, DKEY(key)); if (txn == NULL || !dbi || dbi >= txn->mt_numdbs) return EINVAL; if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY)) { return EACCES; } if (key->mv_size == 0 || key->mv_size > MAXKEYSIZE) { return EINVAL; } mc.mc_txn = txn; mc.mc_dbi = dbi; mc.mc_flags = 0; if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) { mc.mc_xcursor = &mx; mdb_xcursor_init0(&mc); } else { mc.mc_xcursor = NULL; } exact = 0; if (data) { op = MDB_GET_BOTH; rdata = *data; xdata = &rdata; } else { op = MDB_SET; xdata = NULL; } rc = mdb_cursor_set(&mc, key, xdata, op, &exact); if (rc == 0) rc = mdb_cursor_del(&mc, data ? 0 : MDB_NODUPDATA); return rc; } /* Split page top>, and insert in either left or * right sibling, at index ki> (as if unsplit). Updates mc->top and * mc->ki with the actual values after split, ie if mc->top and mc->ki * refer to a node in the new right sibling page. */ static int mdb_split(MDB_cursor *mc, MDB_val *newkey, MDB_val *newdata, pgno_t newpgno) { uint8_t flags; int rc = MDB_SUCCESS, ins_new = 0; indx_t newindx; pgno_t pgno = 0; unsigned int i, j, split_indx, nkeys, pmax; MDB_node *node; MDB_val sepkey, rkey, rdata; MDB_page *copy; MDB_page *mp, *rp, *pp; unsigned int ptop; MDB_cursor mn; DKBUF; mp = mc->mc_pg[mc->mc_top]; newindx = mc->mc_ki[mc->mc_top]; DPRINTF("-----> splitting %s page %lu and adding [%s] at index %i", IS_LEAF(mp) ? "leaf" : "branch", mp->mp_pgno, DKEY(newkey), mc->mc_ki[mc->mc_top]); if (mc->mc_snum < 2) { if ((pp = mdb_new_page(mc, P_BRANCH, 1)) == NULL) return ENOMEM; /* shift current top to make room for new parent */ mc->mc_pg[1] = mc->mc_pg[0]; mc->mc_ki[1] = mc->mc_ki[0]; mc->mc_pg[0] = pp; mc->mc_ki[0] = 0; mc->mc_txn->mt_dbs[mc->mc_dbi].md_root = pp->mp_pgno; DPRINTF("root split! new root = %lu", pp->mp_pgno); mc->mc_txn->mt_dbs[mc->mc_dbi].md_depth++; /* Add left (implicit) pointer. */ if ((rc = mdb_add_node(mc, 0, NULL, NULL, mp->mp_pgno, 0)) != MDB_SUCCESS) { /* undo the pre-push */ mc->mc_pg[0] = mc->mc_pg[1]; mc->mc_ki[0] = mc->mc_ki[1]; mc->mc_txn->mt_dbs[mc->mc_dbi].md_root = mp->mp_pgno; mc->mc_txn->mt_dbs[mc->mc_dbi].md_depth--; return rc; } mc->mc_snum = 2; mc->mc_top = 1; ptop = 0; } else { ptop = mc->mc_top-1; DPRINTF("parent branch page is %lu", mc->mc_pg[ptop]->mp_pgno); } /* Create a right sibling. */ if ((rp = mdb_new_page(mc, mp->mp_flags, 1)) == NULL) return ENOMEM; mdb_cursor_copy(mc, &mn); mn.mc_pg[mn.mc_top] = rp; mn.mc_ki[ptop] = mc->mc_ki[ptop]+1; DPRINTF("new right sibling: page %lu", rp->mp_pgno); nkeys = NUMKEYS(mp); split_indx = nkeys / 2 + 1; if (IS_LEAF2(rp)) { char *split, *ins; int x; unsigned int lsize, rsize, ksize; /* Move half of the keys to the right sibling */ copy = NULL; x = mc->mc_ki[mc->mc_top] - split_indx; ksize = mc->mc_txn->mt_dbs[mc->mc_dbi].md_pad; split = LEAF2KEY(mp, split_indx, ksize); rsize = (nkeys - split_indx) * ksize; lsize = (nkeys - split_indx) * sizeof(indx_t); mp->mp_lower -= lsize; rp->mp_lower += lsize; mp->mp_upper += rsize - lsize; rp->mp_upper -= rsize - lsize; sepkey.mv_size = ksize; if (newindx == split_indx) { sepkey.mv_data = newkey->mv_data; } else { sepkey.mv_data = split; } if (x<0) { ins = LEAF2KEY(mp, mc->mc_ki[mc->mc_top], ksize); memcpy(rp->mp_ptrs, split, rsize); sepkey.mv_data = rp->mp_ptrs; memmove(ins+ksize, ins, (split_indx - mc->mc_ki[mc->mc_top]) * ksize); memcpy(ins, newkey->mv_data, ksize); mp->mp_lower += sizeof(indx_t); mp->mp_upper -= ksize - sizeof(indx_t); } else { if (x) memcpy(rp->mp_ptrs, split, x * ksize); ins = LEAF2KEY(rp, x, ksize); memcpy(ins, newkey->mv_data, ksize); memcpy(ins+ksize, split + x * ksize, rsize - x * ksize); rp->mp_lower += sizeof(indx_t); rp->mp_upper -= ksize - sizeof(indx_t); mc->mc_ki[mc->mc_top] = x; mc->mc_pg[mc->mc_top] = rp; } goto newsep; } /* For leaf pages, check the split point based on what * fits where, since otherwise add_node can fail. */ if (IS_LEAF(mp)) { unsigned int psize, nsize; /* Maximum free space in an empty page */ pmax = mc->mc_txn->mt_env->me_psize - PAGEHDRSZ; nsize = mdb_leaf_size(mc->mc_txn->mt_env, newkey, newdata); if (newindx < split_indx) { psize = nsize; for (i=0; imn_flags, F_BIGDATA)) psize += sizeof(pgno_t); else psize += NODEDSZ(node); psize += psize & 1; if (psize > pmax) { split_indx = i; break; } } } else { psize = nsize; for (i=nkeys-1; i>=split_indx; i--) { node = NODEPTR(mp, i); psize += NODESIZE + NODEKSZ(node) + sizeof(indx_t); if (F_ISSET(node->mn_flags, F_BIGDATA)) psize += sizeof(pgno_t); else psize += NODEDSZ(node); psize += psize & 1; if (psize > pmax) { split_indx = i+1; break; } } } } /* First find the separating key between the split pages. */ if (newindx == split_indx) { sepkey.mv_size = newkey->mv_size; sepkey.mv_data = newkey->mv_data; } else { node = NODEPTR(mp, split_indx); sepkey.mv_size = node->mn_ksize; sepkey.mv_data = NODEKEY(node); } newsep: DPRINTF("separator is [%s]", DKEY(&sepkey)); /* Copy separator key to the parent. */ if (SIZELEFT(mn.mc_pg[ptop]) < mdb_branch_size(mc->mc_txn->mt_env, &sepkey)) { mn.mc_snum--; mn.mc_top--; rc = mdb_split(&mn, &sepkey, NULL, rp->mp_pgno); /* Right page might now have changed parent. * Check if left page also changed parent. */ if (mn.mc_pg[ptop] != mc->mc_pg[ptop] && mc->mc_ki[ptop] >= NUMKEYS(mc->mc_pg[ptop])) { mc->mc_pg[ptop] = mn.mc_pg[ptop]; mc->mc_ki[ptop] = mn.mc_ki[ptop] - 1; } } else { mn.mc_top--; rc = mdb_add_node(&mn, mn.mc_ki[ptop], &sepkey, NULL, rp->mp_pgno, 0); mn.mc_top++; } if (IS_LEAF2(rp)) { return rc; } if (rc != MDB_SUCCESS) { return rc; } /* Move half of the keys to the right sibling. */ /* grab a page to hold a temporary copy */ if (mc->mc_txn->mt_env->me_dpages) { copy = mc->mc_txn->mt_env->me_dpages; mc->mc_txn->mt_env->me_dpages = copy->mp_next; } else { if ((copy = malloc(mc->mc_txn->mt_env->me_psize)) == NULL) return ENOMEM; } copy->mp_pgno = mp->mp_pgno; copy->mp_flags = mp->mp_flags; copy->mp_lower = PAGEHDRSZ; copy->mp_upper = mc->mc_txn->mt_env->me_psize; mc->mc_pg[mc->mc_top] = copy; for (i = j = 0; i <= nkeys; j++) { if (i == split_indx) { /* Insert in right sibling. */ /* Reset insert index for right sibling. */ j = (i == newindx && ins_new); mc->mc_pg[mc->mc_top] = rp; } if (i == newindx && !ins_new) { /* Insert the original entry that caused the split. */ rkey.mv_data = newkey->mv_data; rkey.mv_size = newkey->mv_size; if (IS_LEAF(mp)) { rdata.mv_data = newdata->mv_data; rdata.mv_size = newdata->mv_size; } else pgno = newpgno; flags = 0; ins_new = 1; /* Update page and index for the new key. */ mc->mc_ki[mc->mc_top] = j; } else if (i == nkeys) { break; } else { node = NODEPTR(mp, i); rkey.mv_data = NODEKEY(node); rkey.mv_size = node->mn_ksize; if (IS_LEAF(mp)) { rdata.mv_data = NODEDATA(node); rdata.mv_size = NODEDSZ(node); } else pgno = NODEPGNO(node); flags = node->mn_flags; i++; } if (!IS_LEAF(mp) && j == 0) { /* First branch index doesn't need key data. */ rkey.mv_size = 0; } rc = mdb_add_node(mc, j, &rkey, &rdata, pgno, flags); } /* reset back to original page */ if (newindx < split_indx) mc->mc_pg[mc->mc_top] = mp; nkeys = NUMKEYS(copy); for (i=0; imp_ptrs[i] = copy->mp_ptrs[i]; mp->mp_lower = copy->mp_lower; mp->mp_upper = copy->mp_upper; memcpy(NODEPTR(mp, nkeys-1), NODEPTR(copy, nkeys-1), mc->mc_txn->mt_env->me_psize - copy->mp_upper); /* return tmp page to freelist */ copy->mp_next = mc->mc_txn->mt_env->me_dpages; mc->mc_txn->mt_env->me_dpages = copy; return rc; } int mdb_put(MDB_txn *txn, MDB_dbi dbi, MDB_val *key, MDB_val *data, unsigned int flags) { MDB_cursor mc; MDB_xcursor mx; assert(key != NULL); assert(data != NULL); if (txn == NULL || !dbi || dbi >= txn->mt_numdbs) return EINVAL; if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY)) { return EACCES; } if (key->mv_size == 0 || key->mv_size > MAXKEYSIZE) { return EINVAL; } if ((flags & (MDB_NOOVERWRITE|MDB_NODUPDATA)) != flags) return EINVAL; mc.mc_txn = txn; mc.mc_dbi = dbi; mc.mc_snum = 0; mc.mc_flags = 0; if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) { mc.mc_xcursor = &mx; mdb_xcursor_init0(&mc); } else { mc.mc_xcursor = NULL; } return mdb_cursor_put(&mc, key, data, flags); } int mdb_env_set_flags(MDB_env *env, unsigned int flag, int onoff) { /** Only a subset of the @ref mdb_env flags can be changed * at runtime. Changing other flags requires closing the environment * and re-opening it with the new flags. */ #define CHANGEABLE (MDB_NOSYNC) if ((flag & CHANGEABLE) != flag) return EINVAL; if (onoff) env->me_flags |= flag; else env->me_flags &= ~flag; return MDB_SUCCESS; } int mdb_env_get_flags(MDB_env *env, unsigned int *arg) { if (!env || !arg) return EINVAL; *arg = env->me_flags; return MDB_SUCCESS; } int mdb_env_get_path(MDB_env *env, const char **arg) { if (!env || !arg) return EINVAL; *arg = env->me_path; return MDB_SUCCESS; } static int mdb_stat0(MDB_env *env, MDB_db *db, MDB_stat *arg) { arg->ms_psize = env->me_psize; arg->ms_depth = db->md_depth; arg->ms_branch_pages = db->md_branch_pages; arg->ms_leaf_pages = db->md_leaf_pages; arg->ms_overflow_pages = db->md_overflow_pages; arg->ms_entries = db->md_entries; return MDB_SUCCESS; } int mdb_env_stat(MDB_env *env, MDB_stat *arg) { int toggle; if (env == NULL || arg == NULL) return EINVAL; mdb_env_read_meta(env, &toggle); return mdb_stat0(env, &env->me_metas[toggle]->mm_dbs[MAIN_DBI], arg); } static void mdb_default_cmp(MDB_txn *txn, MDB_dbi dbi) { if (txn->mt_dbs[dbi].md_flags & MDB_REVERSEKEY) txn->mt_dbxs[dbi].md_cmp = memnrcmp; else if (txn->mt_dbs[dbi].md_flags & MDB_INTEGERKEY) txn->mt_dbxs[dbi].md_cmp = cintcmp; else txn->mt_dbxs[dbi].md_cmp = memncmp; if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) { if (txn->mt_dbs[dbi].md_flags & MDB_INTEGERDUP) { if (txn->mt_dbs[dbi].md_flags & MDB_DUPFIXED) txn->mt_dbxs[dbi].md_dcmp = intcmp; else txn->mt_dbxs[dbi].md_dcmp = cintcmp; } else if (txn->mt_dbs[dbi].md_flags & MDB_REVERSEDUP) { txn->mt_dbxs[dbi].md_dcmp = memnrcmp; } else { txn->mt_dbxs[dbi].md_dcmp = memncmp; } } else { txn->mt_dbxs[dbi].md_dcmp = NULL; } } int mdb_open(MDB_txn *txn, const char *name, unsigned int flags, MDB_dbi *dbi) { MDB_val key, data; MDB_dbi i; int rc, dirty = 0; size_t len; if (txn->mt_dbxs[FREE_DBI].md_cmp == NULL) { mdb_default_cmp(txn, FREE_DBI); } /* main DB? */ if (!name) { *dbi = MAIN_DBI; if (flags & (MDB_DUPSORT|MDB_REVERSEKEY|MDB_INTEGERKEY)) txn->mt_dbs[MAIN_DBI].md_flags |= (flags & (MDB_DUPSORT|MDB_REVERSEKEY|MDB_INTEGERKEY)); mdb_default_cmp(txn, MAIN_DBI); return MDB_SUCCESS; } if (txn->mt_dbxs[MAIN_DBI].md_cmp == NULL) { mdb_default_cmp(txn, MAIN_DBI); } /* Is the DB already open? */ len = strlen(name); for (i=2; imt_numdbs; i++) { if (len == txn->mt_dbxs[i].md_name.mv_size && !strncmp(name, txn->mt_dbxs[i].md_name.mv_data, len)) { *dbi = i; return MDB_SUCCESS; } } if (txn->mt_numdbs >= txn->mt_env->me_maxdbs - 1) return ENFILE; /* Find the DB info */ key.mv_size = len; key.mv_data = (void *)name; rc = mdb_get(txn, MAIN_DBI, &key, &data); /* Create if requested */ if (rc == MDB_NOTFOUND && (flags & MDB_CREATE)) { MDB_cursor mc; MDB_db dummy; data.mv_size = sizeof(MDB_db); data.mv_data = &dummy; memset(&dummy, 0, sizeof(dummy)); dummy.md_root = P_INVALID; dummy.md_flags = flags & 0xffff; mc.mc_txn = txn; mc.mc_dbi = MAIN_DBI; mc.mc_flags = 0; rc = mdb_cursor_put(&mc, &key, &data, F_SUBDATA); dirty = 1; } /* OK, got info, add to table */ if (rc == MDB_SUCCESS) { txn->mt_dbxs[txn->mt_numdbs].md_name.mv_data = strdup(name); txn->mt_dbxs[txn->mt_numdbs].md_name.mv_size = len; txn->mt_dbxs[txn->mt_numdbs].md_rel = NULL; txn->mt_dbxs[txn->mt_numdbs].md_parent = MAIN_DBI; txn->mt_dbxs[txn->mt_numdbs].md_dirty = dirty; memcpy(&txn->mt_dbs[txn->mt_numdbs], data.mv_data, sizeof(MDB_db)); *dbi = txn->mt_numdbs; txn->mt_env->me_dbs[0][txn->mt_numdbs] = txn->mt_dbs[txn->mt_numdbs]; txn->mt_env->me_dbs[1][txn->mt_numdbs] = txn->mt_dbs[txn->mt_numdbs]; mdb_default_cmp(txn, txn->mt_numdbs); txn->mt_numdbs++; } return rc; } int mdb_stat(MDB_txn *txn, MDB_dbi dbi, MDB_stat *arg) { if (txn == NULL || arg == NULL || dbi >= txn->mt_numdbs) return EINVAL; return mdb_stat0(txn->mt_env, &txn->mt_dbs[dbi], arg); } void mdb_close(MDB_txn *txn, MDB_dbi dbi) { char *ptr; if (dbi <= MAIN_DBI || dbi >= txn->mt_numdbs) return; ptr = txn->mt_dbxs[dbi].md_name.mv_data; txn->mt_dbxs[dbi].md_name.mv_data = NULL; txn->mt_dbxs[dbi].md_name.mv_size = 0; free(ptr); } int mdb_set_compare(MDB_txn *txn, MDB_dbi dbi, MDB_cmp_func *cmp) { if (txn == NULL || !dbi || dbi >= txn->mt_numdbs) return EINVAL; txn->mt_dbxs[dbi].md_cmp = cmp; return MDB_SUCCESS; } int mdb_set_dupsort(MDB_txn *txn, MDB_dbi dbi, MDB_cmp_func *cmp) { if (txn == NULL || !dbi || dbi >= txn->mt_numdbs) return EINVAL; txn->mt_dbxs[dbi].md_dcmp = cmp; return MDB_SUCCESS; } int mdb_set_relfunc(MDB_txn *txn, MDB_dbi dbi, MDB_rel_func *rel) { if (txn == NULL || !dbi || dbi >= txn->mt_numdbs) return EINVAL; txn->mt_dbxs[dbi].md_rel = rel; return MDB_SUCCESS; } /** @} */